This document provides information about an environmental performance assessment study of the alcohol industry conducted in Uttar Pradesh, India. It lists the study team which included members from the Uttar Pradesh Pollution Control Board and an environmental consultancy. The document outlines the analytical framework used in the study, which evaluated distilleries based on their plant performance, regulatory compliance, and environmental initiatives. Various environmental performance criteria were identified and weighted to calculate scores. The results of the study included ratings of distilleries and identification of opportunities for improved environmental performance.
This document provides information about an environmental performance assessment study of the alcohol industry conducted in Uttar Pradesh, India. It lists the study team which included members from the Uttar Pradesh Pollution Control Board and an environmental consultancy. The document outlines the analytical framework used in the study, which evaluated distilleries based on their plant performance, regulatory compliance, and environmental initiatives. It provides details on the evaluation criteria and weightings used to calculate environmental performance ratings for each distillery. Summary statistics and rankings are also given for some of the key plant performance indicators analyzed in the study.
An ecological assessment of food waste composting using a hybrid life cycle a...Ramy Salemdeeb
A conference paper published at the 8th Conference of the International Society for Industrial Ecology, At University of Surrey, Guildford, UK, At Surrey
The document discusses Life Cycle Assessment (LCA), including its definition, ISO requirements, and steps. LCA looks at a product's environmental impacts from raw material extraction to disposal. It discusses case studies on LCAs of olive oil packaging (tin vs plastic), PET water bottles in California, expanded polystyrene packaging in Europe, and electric vs gasoline vehicles. For the olive oil study, tin packaging had a lower overall environmental impact than plastic. The PET bottle LCA found packaging and disposal stages impact water pollution the most. Expanded polystyrene and polypropylene packaging were compared for energy use and water pollution impacts. Electric vehicles require less total energy over their lifetime than gasoline vehicles.
Review paper on operation and maintenance of effluent treatment plant of pape...IRJET Journal
This document summarizes a review paper on the operation and maintenance of the effluent treatment plant at a paper industry in India. It describes the company and production processes that generate wastewater effluent. The effluent treatment plant uses a 5-stage process including primary and secondary clarification, aeration, filtration, and chlorination to treat over 22,500 cubic meters of wastewater per day before discharge or reuse. Monitoring shows the treated effluent meets standards for parameters like pH, BOD, COD and TSS. The plant helps minimize environmental impacts and pollution from the industry's operations.
This document provides a final report for the process design and technoeconomic analysis of two downstream recovery and purification processes for diethyl malonate (DEM) from a fermentation reactor. Experimental results found that decreasing pH decreases DEM solubility in water in a nonlinear fashion, and the partition coefficient of DEM in a water-pentane system was determined to be 2.4 ± 0.2. A sensitivity analysis of process parameters found that liquid-liquid extraction with n-pentane could achieve 99.96% DEM recovery at a unit cost of $0.016/kg, while a series process using decantation followed by extraction could achieve 99.95% recovery at $0.011/kg. The extraction only process
This document provides an overview of a presentation on evaluating environmental impacts of alternative transport fuels and powertrains via a life cycle approach. The research aims to conduct a holistic sustainability assessment of alternative fuels and powertrains in the transport sector. Key research objectives include identifying gaps in existing studies, comparing triple bottom line impacts, and identifying which alternate fuel best mitigates emissions. The methodology section outlines using the SimaPro software and life cycle impact assessment to model and analyze impacts. Preliminary results show well-to-tank and tank-to-wheel emissions and energy use for different vehicle fuel systems. A timeline is provided for research activities over four years, including data collection, modeling, analysis, conference presentations, and thesis writing
Vishal Shivprasad Purohit is seeking new career opportunities. He has over 15 years of experience in environmental roles, including operating effluent treatment plants, stripper plants, and incinerators. His experience includes roles at Alembic Pharmaceuticals, Alembic Ltd., Tonira Pharma, and Narmada Chematur Petrochemicals, where he managed staff and was responsible for plant operations, compliance reporting, and process optimization. He holds an MSc in Ecology and Environment and is currently a Senior Executive at Alembic Ltd., earning 5 lakhs annually.
This document provides an overview of environmental product declarations (EPDs) for pavements. It discusses how full life cycle assessment considering all impacts and interactions over the full life can help advance sustainability goals. Key topics covered include quantifying impacts through life cycle assessment, developing product category rules to standardize EPDs, important processes and materials considered in pavement LCA and EPDs, and potential future developments to improve sustainability evaluation. The document aims to explain how EPDs can be used along with other tools to optimize pavement design, materials selection, and management over the full life cycle.
This document provides information about an environmental performance assessment study of the alcohol industry conducted in Uttar Pradesh, India. It lists the study team which included members from the Uttar Pradesh Pollution Control Board and an environmental consultancy. The document outlines the analytical framework used in the study, which evaluated distilleries based on their plant performance, regulatory compliance, and environmental initiatives. It provides details on the evaluation criteria and weightings used to calculate environmental performance ratings for each distillery. Summary statistics and rankings are also given for some of the key plant performance indicators analyzed in the study.
An ecological assessment of food waste composting using a hybrid life cycle a...Ramy Salemdeeb
A conference paper published at the 8th Conference of the International Society for Industrial Ecology, At University of Surrey, Guildford, UK, At Surrey
The document discusses Life Cycle Assessment (LCA), including its definition, ISO requirements, and steps. LCA looks at a product's environmental impacts from raw material extraction to disposal. It discusses case studies on LCAs of olive oil packaging (tin vs plastic), PET water bottles in California, expanded polystyrene packaging in Europe, and electric vs gasoline vehicles. For the olive oil study, tin packaging had a lower overall environmental impact than plastic. The PET bottle LCA found packaging and disposal stages impact water pollution the most. Expanded polystyrene and polypropylene packaging were compared for energy use and water pollution impacts. Electric vehicles require less total energy over their lifetime than gasoline vehicles.
Review paper on operation and maintenance of effluent treatment plant of pape...IRJET Journal
This document summarizes a review paper on the operation and maintenance of the effluent treatment plant at a paper industry in India. It describes the company and production processes that generate wastewater effluent. The effluent treatment plant uses a 5-stage process including primary and secondary clarification, aeration, filtration, and chlorination to treat over 22,500 cubic meters of wastewater per day before discharge or reuse. Monitoring shows the treated effluent meets standards for parameters like pH, BOD, COD and TSS. The plant helps minimize environmental impacts and pollution from the industry's operations.
This document provides a final report for the process design and technoeconomic analysis of two downstream recovery and purification processes for diethyl malonate (DEM) from a fermentation reactor. Experimental results found that decreasing pH decreases DEM solubility in water in a nonlinear fashion, and the partition coefficient of DEM in a water-pentane system was determined to be 2.4 ± 0.2. A sensitivity analysis of process parameters found that liquid-liquid extraction with n-pentane could achieve 99.96% DEM recovery at a unit cost of $0.016/kg, while a series process using decantation followed by extraction could achieve 99.95% recovery at $0.011/kg. The extraction only process
This document provides an overview of a presentation on evaluating environmental impacts of alternative transport fuels and powertrains via a life cycle approach. The research aims to conduct a holistic sustainability assessment of alternative fuels and powertrains in the transport sector. Key research objectives include identifying gaps in existing studies, comparing triple bottom line impacts, and identifying which alternate fuel best mitigates emissions. The methodology section outlines using the SimaPro software and life cycle impact assessment to model and analyze impacts. Preliminary results show well-to-tank and tank-to-wheel emissions and energy use for different vehicle fuel systems. A timeline is provided for research activities over four years, including data collection, modeling, analysis, conference presentations, and thesis writing
Vishal Shivprasad Purohit is seeking new career opportunities. He has over 15 years of experience in environmental roles, including operating effluent treatment plants, stripper plants, and incinerators. His experience includes roles at Alembic Pharmaceuticals, Alembic Ltd., Tonira Pharma, and Narmada Chematur Petrochemicals, where he managed staff and was responsible for plant operations, compliance reporting, and process optimization. He holds an MSc in Ecology and Environment and is currently a Senior Executive at Alembic Ltd., earning 5 lakhs annually.
This document provides an overview of environmental product declarations (EPDs) for pavements. It discusses how full life cycle assessment considering all impacts and interactions over the full life can help advance sustainability goals. Key topics covered include quantifying impacts through life cycle assessment, developing product category rules to standardize EPDs, important processes and materials considered in pavement LCA and EPDs, and potential future developments to improve sustainability evaluation. The document aims to explain how EPDs can be used along with other tools to optimize pavement design, materials selection, and management over the full life cycle.
Matt Boyle, Environment and Sustainability Manager from Midfield Meats Inc., Warrnambool presented to VCE Environmental Science students at Hawkesdale p12 College
This report details an EMS audit conducted at Reliance Industries by DDU and provides exposure to EMS system implementation in the petrochemical industry. The audit assessed parameters like air, water, effluent and waste to ensure compliance with GPCB guidelines. Reliance has implemented an effective EMS based on the PDCA cycle and monitors parameters daily to meet targets and legal requirements. Key aspects of the EMS include an air and effluent monitoring system, landsink ladder for waste management, and a secured landfill site for hazardous waste disposal. The training exposure provided insight into Reliance's EMS procedures and a visit to the effluent treatment plant.
One of the most common methodologies for quantifying sustainability is life cycle assessment (LCA). An LCA is a systematic analysis of environmental impact over the course of the entire life cycle of a product, material, process, or other measurable activity.E-LCA is a time tested assessment technique that evaluates environmental performance throughout the life cycle of a product or from performing a service. The extraction and consumption of resources (including energy), as well as releases to air, water, and soil, are quantified throughout all stages. Their potential contribution to environmental impact categories is then assessed. These categories include climate change, human and eco-toxicity, ionizing radiation, and resource base deterioration (e.g. water, non-renewable primary energy resources, land, etc.). The Life Cycle Initiative played a key role in the development of the life cycle assessment midpoint-damage framework, which conceptualizes the linkages between a product’s environmental interventions and their ultimate damage caused to human health, resource depletion and ecosystem quality – information which is of critical importance to decision makers.
This document discusses environmental auditing, its objectives and benefits. It begins by defining environmental auditing as a management tool that inspects environmental management activities of industries to make them aware of cleaner technologies. The objectives of environmental auditing include enhancing environmental performance, optimizing resource use, evaluating waste characteristics, and ensuring regulatory compliance. Key activities of an environmental audit involve pre-audit planning, on-site assessment of records, interviews and inspections, and post-audit reporting. Benefits include improving pollution control, verifying legal compliance, and enhancing loss prevention. The document concludes that environmental auditing can help apply best practices to preserve the environment from industrial impacts.
Ctran Consulting Pvt. Ltd. is an environmental consulting firm that was founded in 2007. It has its headquarters in Bhubaneswar and operates throughout India. The company provides consulting services in the areas of energy, environment, climate change and rural infrastructure. It conducted an environmental impact assessment study for a proposed fibre cement manufacturing plant as part of a summer internship project to establish the environmental baseline, assess impacts, and develop a management plan to minimize adverse effects.
Performance evaluation of Effluent Treatment Plant of Dairy IndustryIJERA Editor
Dairy industry is among the most polluting of the food industries in regard to its large water consumption. Dairy
is one of the major industries causing water pollution. Considering the increased milk demand, the dairy
industry in India is expected to grow rapidly and have the waste generation and related environmental problems
are also assumed increased importance. Poorly treated wastewater with high level of pollutants caused by poor
design, operation or treatment systems creates major environmental problems when discharged to the surface
land or water. Various operations in a dairy industry may include pasteurization, cream, cheese, milk powder
etc. Considering the above stated implications an attempt has been made in the present project to evaluate one of
the Effluent Treatment Plant for dairy waste. Samples are collected from three points; Collection tank (CT),
primary clarifier (PC) and Secondary clarifier (SC) to evaluate the performance of Effluent Treatment Plant.
Parameters analyzed for evaluation of performance of Effluent Treatment Plant are pH, TDS, TSS, COD, and
BOD at 200C The pH, TDS, TSS, COD and BOD removal efficiency of Effluent Treatment Plant were 26.14 %,
33.30 %, 93.85 %, 94.19 % and 98.19 % respectively.
This document summarizes a study evaluating the performance of an effluent treatment plant (ETP) for a dairy industry in India. Samples were collected from three points in the ETP - the collection tank, primary clarifier, and secondary clarifier. The ETP achieved removal efficiencies of 26.14% for pH, 33.30% for TDS, 93.85% for TSS, 94.19% for COD, and 98.19% for BOD. The treated effluent met standards for discharge set by the Gujarat Pollution Control Board. The ETP was effective at removing pollutants and bringing wastewater characteristics in line with regulatory requirements for reuse or discharge.
The document discusses life cycle assessment (LCA) methodology in the context of environmentally sustainable development. LCA examines the environmental aspects and potential impacts of a product throughout its life cycle, from raw material extraction through production, use, and disposal. It aims to reduce environmental impacts by identifying opportunities for improvement at each stage. LCA follows ISO standards and involves defining goals and boundaries, conducting an inventory of inputs and outputs, assessing potential environmental impacts, and interpreting the results. It provides a holistic perspective for evaluating and comparing products or systems to support more sustainable decisions.
Dr t e_lim_environmental_management_system_for_a_printing_company_standards_c...zubeditufail
This document outlines steps for a printing company to implement an environmental management system based on ISO 14001. It identifies the company's key processes and their environmental aspects and impacts. An environmental management program is established to minimize pollutants from packaging, cleaning, printing and transportation. The company establishes an environmental policy and conducts management reviews to ensure the system's effectiveness. Implementing an ISO 14001 environmental management system can help the company save costs and enhance its reputation while protecting the environment.
OPTIMIZATION OF SODA ASH ENVIRONMENTAL IMPACT USING LCA TOOLIJARIIE JOURNAL
The document discusses life cycle assessment (LCA) as a tool to analyze the environmental impacts of soda ash production. It provides background on soda ash (sodium carbonate), describing its main production process as the Solvay process. The document then discusses LCA methodology based on ISO standards, including its goals of quantifying impacts and identifying improvement opportunities. It notes LCA can help optimize the environmental impacts of soda ash production. Reviews from other studies are presented discussing LCA's role in environmental management and its developments over time.
This document summarizes strategies to reduce worker exposure to diesel engine exhaust in mining industries. It begins by describing diesel exhaust as a human carcinogen and estimates that 560 lung cancers are caused by occupational exposure annually. It then introduces a "bowtie diagram" infographic developed to visually explain multiple exposure control options in mining in a proactive-reactive framework. The rest of the document discusses various exposure controls like alternative fuels, engine upgrades, ventilation, enclosed cabs, and respiratory protection. It concludes by discussing policy needs like lower exposure limits and calls for further research on the health impacts of different exhaust components and effectiveness of controls.
Incorporation of Life Cycle Management in producing chemical assets: a Brazil...Oxiteno
1) A Brazilian chemical company conducted a life cycle assessment of its sodium lauryl ether sulfate (SLES) production process to identify opportunities to improve environmental performance and reduce costs.
2) The study analyzed the current production process and a prospective scenario involving sourcing palm kernel oil (PKO) from local Brazilian suppliers rather than imported from Malaysia.
3) The results showed the prospective Brazilian PKO scenario improved impacts in six of seven categories due to differences in cultivation practices and reduced transport compared to importing from Asia. Further economic analysis is needed to evaluate feasibility.
The document introduces product life cycle design (LCD) which integrates environmental requirements into the product design process. It discusses that LCD evaluates the environmental impacts of a product over its entire life cycle from material extraction, production, distribution, use, and end of life. Key aspects of LCD include minimizing resource use, selecting low impact materials, optimizing product life, extending material life, and designing for disassembly and recyclability. The life cycle approach considers how to reduce environmental effects from both resource inputs and waste outputs at each stage of the product life cycle.
The Hillsborough County Wastewater BEST Group developed three models - BioWin, Ansys, and a Neural Network - to optimize the Valrico Advanced Wastewater Treatment Facility. BioWin accurately models the plant processes and kinetics using experimental influent data. Ansys models flow patterns in oxidation ditches. A Neural Network smooths noisy influent data and predicts future flows to help operators control the plant economically. Aerator energy consumption was correlated to the BioWin model to assess energy impacts. The models enable testing control strategies without risking plant performance. The goals of Hillsborough County Public Utilities Department have been met to continue optimizing Valrico's operation.
Natural Capital at Risk: The Top 100 Externalities of BusinessSustainable Brands
This document is a report by Trucost PLC that ranks the top 100 externalities of business and the top 20 region-sectors based on their environmental impacts. It uses an environmentally extended input-output model to estimate the natural capital costs in a company's supply chain from unpriced impacts such as land use, water consumption, greenhouse gas emissions, air and water pollution, and waste. The report finds that consumer sectors drive most of the natural capital costs and that accounting for environmental externalities can help businesses better understand their financial risks from dependency on natural resources.
Natural Capital at Risk: The Top 100 Externalities of BusinessSustainable Brands
This report offers a high level perspective on the world’s biggest natural capital risks for business, investors and governments. To provide a business perspective, it presents natural capital risk in financial terms. In doing so, it finds that the world’s 100 biggest risks are costing the economy around $4.7 trillion per year in terms of the environmental and social costs of lost ecosystem services and pollution. The aim of the report is to provide insight into how companies and their investors can measure and manage natural capital impacts and to inspire further research and debate.
Iso 14001 consulting by Netpeckers Consulting IndiaIskcon Ahmedabad
This document provides an overview of ISO 14001 and the benefits of implementing an environmental management system. It discusses key aspects of ISO 14001 such as the principles, documentation requirements, audit process and certification. Direct benefits include cost savings, compliance with regulations, improved public image and preferential treatment from government organizations. The presentation recommends working with Netpeckers Consulting, an ISO-certified organization, to implement an environmental management system and achieve ISO 14001 certification.
Dear fellow my network this is my actual view point plz share me for more learning help with your knowledge
thanks
Regarding...........,,
AB TABUSSAM(MBA-UM3rd
Using Municipal Solid Waste as a Biofuel FeedstockHeather Troutman
The document summarizes a study analyzing the feasibility of converting municipal solid waste (MSW) into biofuels. It discusses waste conversion technologies like gasification and pyrolysis. The study examines the life cycle assessment and environmental impacts of different waste processing scenarios. It also uses North Carolina waste generation and management data as a case study. The primary findings are that MSW to biofuels conversion has a high energy demand and requires significant waste preprocessing. While conversion may be promising, economic feasibility and costs need further analysis to demonstrate scaling the technology.
Life Cycle Assessment on Personal Computermerlin1491
1) This document summarizes the results of a life cycle assessment (LCA) conducted on a personal computer. The LCA followed the four steps of goal and scope definition, inventory analysis, impact assessment, and improvement assessment.
2) The pre-manufacturing stage, which involves production of components and parts, was found to be the largest contributor to most environmental impact categories.
3) The use stage, particularly for office computers used over 12 hours per week, also significantly contributed to environmental impacts due to energy consumption.
4) The LCA results can be used to identify priority areas for improving the design of PCs and their components to reduce environmental impacts over the product lifecycle.
Use PyCharm for remote debugging of WSL on a Windo cf5c162d672e4e58b4dde5d797...shadow0702a
This document serves as a comprehensive step-by-step guide on how to effectively use PyCharm for remote debugging of the Windows Subsystem for Linux (WSL) on a local Windows machine. It meticulously outlines several critical steps in the process, starting with the crucial task of enabling permissions, followed by the installation and configuration of WSL.
The guide then proceeds to explain how to set up the SSH service within the WSL environment, an integral part of the process. Alongside this, it also provides detailed instructions on how to modify the inbound rules of the Windows firewall to facilitate the process, ensuring that there are no connectivity issues that could potentially hinder the debugging process.
The document further emphasizes on the importance of checking the connection between the Windows and WSL environments, providing instructions on how to ensure that the connection is optimal and ready for remote debugging.
It also offers an in-depth guide on how to configure the WSL interpreter and files within the PyCharm environment. This is essential for ensuring that the debugging process is set up correctly and that the program can be run effectively within the WSL terminal.
Additionally, the document provides guidance on how to set up breakpoints for debugging, a fundamental aspect of the debugging process which allows the developer to stop the execution of their code at certain points and inspect their program at those stages.
Finally, the document concludes by providing a link to a reference blog. This blog offers additional information and guidance on configuring the remote Python interpreter in PyCharm, providing the reader with a well-rounded understanding of the process.
Discover the latest insights on Data Driven Maintenance with our comprehensive webinar presentation. Learn about traditional maintenance challenges, the right approach to utilizing data, and the benefits of adopting a Data Driven Maintenance strategy. Explore real-world examples, industry best practices, and innovative solutions like FMECA and the D3M model. This presentation, led by expert Jules Oudmans, is essential for asset owners looking to optimize their maintenance processes and leverage digital technologies for improved efficiency and performance. Download now to stay ahead in the evolving maintenance landscape.
Matt Boyle, Environment and Sustainability Manager from Midfield Meats Inc., Warrnambool presented to VCE Environmental Science students at Hawkesdale p12 College
This report details an EMS audit conducted at Reliance Industries by DDU and provides exposure to EMS system implementation in the petrochemical industry. The audit assessed parameters like air, water, effluent and waste to ensure compliance with GPCB guidelines. Reliance has implemented an effective EMS based on the PDCA cycle and monitors parameters daily to meet targets and legal requirements. Key aspects of the EMS include an air and effluent monitoring system, landsink ladder for waste management, and a secured landfill site for hazardous waste disposal. The training exposure provided insight into Reliance's EMS procedures and a visit to the effluent treatment plant.
One of the most common methodologies for quantifying sustainability is life cycle assessment (LCA). An LCA is a systematic analysis of environmental impact over the course of the entire life cycle of a product, material, process, or other measurable activity.E-LCA is a time tested assessment technique that evaluates environmental performance throughout the life cycle of a product or from performing a service. The extraction and consumption of resources (including energy), as well as releases to air, water, and soil, are quantified throughout all stages. Their potential contribution to environmental impact categories is then assessed. These categories include climate change, human and eco-toxicity, ionizing radiation, and resource base deterioration (e.g. water, non-renewable primary energy resources, land, etc.). The Life Cycle Initiative played a key role in the development of the life cycle assessment midpoint-damage framework, which conceptualizes the linkages between a product’s environmental interventions and their ultimate damage caused to human health, resource depletion and ecosystem quality – information which is of critical importance to decision makers.
This document discusses environmental auditing, its objectives and benefits. It begins by defining environmental auditing as a management tool that inspects environmental management activities of industries to make them aware of cleaner technologies. The objectives of environmental auditing include enhancing environmental performance, optimizing resource use, evaluating waste characteristics, and ensuring regulatory compliance. Key activities of an environmental audit involve pre-audit planning, on-site assessment of records, interviews and inspections, and post-audit reporting. Benefits include improving pollution control, verifying legal compliance, and enhancing loss prevention. The document concludes that environmental auditing can help apply best practices to preserve the environment from industrial impacts.
Ctran Consulting Pvt. Ltd. is an environmental consulting firm that was founded in 2007. It has its headquarters in Bhubaneswar and operates throughout India. The company provides consulting services in the areas of energy, environment, climate change and rural infrastructure. It conducted an environmental impact assessment study for a proposed fibre cement manufacturing plant as part of a summer internship project to establish the environmental baseline, assess impacts, and develop a management plan to minimize adverse effects.
Performance evaluation of Effluent Treatment Plant of Dairy IndustryIJERA Editor
Dairy industry is among the most polluting of the food industries in regard to its large water consumption. Dairy
is one of the major industries causing water pollution. Considering the increased milk demand, the dairy
industry in India is expected to grow rapidly and have the waste generation and related environmental problems
are also assumed increased importance. Poorly treated wastewater with high level of pollutants caused by poor
design, operation or treatment systems creates major environmental problems when discharged to the surface
land or water. Various operations in a dairy industry may include pasteurization, cream, cheese, milk powder
etc. Considering the above stated implications an attempt has been made in the present project to evaluate one of
the Effluent Treatment Plant for dairy waste. Samples are collected from three points; Collection tank (CT),
primary clarifier (PC) and Secondary clarifier (SC) to evaluate the performance of Effluent Treatment Plant.
Parameters analyzed for evaluation of performance of Effluent Treatment Plant are pH, TDS, TSS, COD, and
BOD at 200C The pH, TDS, TSS, COD and BOD removal efficiency of Effluent Treatment Plant were 26.14 %,
33.30 %, 93.85 %, 94.19 % and 98.19 % respectively.
This document summarizes a study evaluating the performance of an effluent treatment plant (ETP) for a dairy industry in India. Samples were collected from three points in the ETP - the collection tank, primary clarifier, and secondary clarifier. The ETP achieved removal efficiencies of 26.14% for pH, 33.30% for TDS, 93.85% for TSS, 94.19% for COD, and 98.19% for BOD. The treated effluent met standards for discharge set by the Gujarat Pollution Control Board. The ETP was effective at removing pollutants and bringing wastewater characteristics in line with regulatory requirements for reuse or discharge.
The document discusses life cycle assessment (LCA) methodology in the context of environmentally sustainable development. LCA examines the environmental aspects and potential impacts of a product throughout its life cycle, from raw material extraction through production, use, and disposal. It aims to reduce environmental impacts by identifying opportunities for improvement at each stage. LCA follows ISO standards and involves defining goals and boundaries, conducting an inventory of inputs and outputs, assessing potential environmental impacts, and interpreting the results. It provides a holistic perspective for evaluating and comparing products or systems to support more sustainable decisions.
Dr t e_lim_environmental_management_system_for_a_printing_company_standards_c...zubeditufail
This document outlines steps for a printing company to implement an environmental management system based on ISO 14001. It identifies the company's key processes and their environmental aspects and impacts. An environmental management program is established to minimize pollutants from packaging, cleaning, printing and transportation. The company establishes an environmental policy and conducts management reviews to ensure the system's effectiveness. Implementing an ISO 14001 environmental management system can help the company save costs and enhance its reputation while protecting the environment.
OPTIMIZATION OF SODA ASH ENVIRONMENTAL IMPACT USING LCA TOOLIJARIIE JOURNAL
The document discusses life cycle assessment (LCA) as a tool to analyze the environmental impacts of soda ash production. It provides background on soda ash (sodium carbonate), describing its main production process as the Solvay process. The document then discusses LCA methodology based on ISO standards, including its goals of quantifying impacts and identifying improvement opportunities. It notes LCA can help optimize the environmental impacts of soda ash production. Reviews from other studies are presented discussing LCA's role in environmental management and its developments over time.
This document summarizes strategies to reduce worker exposure to diesel engine exhaust in mining industries. It begins by describing diesel exhaust as a human carcinogen and estimates that 560 lung cancers are caused by occupational exposure annually. It then introduces a "bowtie diagram" infographic developed to visually explain multiple exposure control options in mining in a proactive-reactive framework. The rest of the document discusses various exposure controls like alternative fuels, engine upgrades, ventilation, enclosed cabs, and respiratory protection. It concludes by discussing policy needs like lower exposure limits and calls for further research on the health impacts of different exhaust components and effectiveness of controls.
Incorporation of Life Cycle Management in producing chemical assets: a Brazil...Oxiteno
1) A Brazilian chemical company conducted a life cycle assessment of its sodium lauryl ether sulfate (SLES) production process to identify opportunities to improve environmental performance and reduce costs.
2) The study analyzed the current production process and a prospective scenario involving sourcing palm kernel oil (PKO) from local Brazilian suppliers rather than imported from Malaysia.
3) The results showed the prospective Brazilian PKO scenario improved impacts in six of seven categories due to differences in cultivation practices and reduced transport compared to importing from Asia. Further economic analysis is needed to evaluate feasibility.
The document introduces product life cycle design (LCD) which integrates environmental requirements into the product design process. It discusses that LCD evaluates the environmental impacts of a product over its entire life cycle from material extraction, production, distribution, use, and end of life. Key aspects of LCD include minimizing resource use, selecting low impact materials, optimizing product life, extending material life, and designing for disassembly and recyclability. The life cycle approach considers how to reduce environmental effects from both resource inputs and waste outputs at each stage of the product life cycle.
The Hillsborough County Wastewater BEST Group developed three models - BioWin, Ansys, and a Neural Network - to optimize the Valrico Advanced Wastewater Treatment Facility. BioWin accurately models the plant processes and kinetics using experimental influent data. Ansys models flow patterns in oxidation ditches. A Neural Network smooths noisy influent data and predicts future flows to help operators control the plant economically. Aerator energy consumption was correlated to the BioWin model to assess energy impacts. The models enable testing control strategies without risking plant performance. The goals of Hillsborough County Public Utilities Department have been met to continue optimizing Valrico's operation.
Natural Capital at Risk: The Top 100 Externalities of BusinessSustainable Brands
This document is a report by Trucost PLC that ranks the top 100 externalities of business and the top 20 region-sectors based on their environmental impacts. It uses an environmentally extended input-output model to estimate the natural capital costs in a company's supply chain from unpriced impacts such as land use, water consumption, greenhouse gas emissions, air and water pollution, and waste. The report finds that consumer sectors drive most of the natural capital costs and that accounting for environmental externalities can help businesses better understand their financial risks from dependency on natural resources.
Natural Capital at Risk: The Top 100 Externalities of BusinessSustainable Brands
This report offers a high level perspective on the world’s biggest natural capital risks for business, investors and governments. To provide a business perspective, it presents natural capital risk in financial terms. In doing so, it finds that the world’s 100 biggest risks are costing the economy around $4.7 trillion per year in terms of the environmental and social costs of lost ecosystem services and pollution. The aim of the report is to provide insight into how companies and their investors can measure and manage natural capital impacts and to inspire further research and debate.
Iso 14001 consulting by Netpeckers Consulting IndiaIskcon Ahmedabad
This document provides an overview of ISO 14001 and the benefits of implementing an environmental management system. It discusses key aspects of ISO 14001 such as the principles, documentation requirements, audit process and certification. Direct benefits include cost savings, compliance with regulations, improved public image and preferential treatment from government organizations. The presentation recommends working with Netpeckers Consulting, an ISO-certified organization, to implement an environmental management system and achieve ISO 14001 certification.
Dear fellow my network this is my actual view point plz share me for more learning help with your knowledge
thanks
Regarding...........,,
AB TABUSSAM(MBA-UM3rd
Using Municipal Solid Waste as a Biofuel FeedstockHeather Troutman
The document summarizes a study analyzing the feasibility of converting municipal solid waste (MSW) into biofuels. It discusses waste conversion technologies like gasification and pyrolysis. The study examines the life cycle assessment and environmental impacts of different waste processing scenarios. It also uses North Carolina waste generation and management data as a case study. The primary findings are that MSW to biofuels conversion has a high energy demand and requires significant waste preprocessing. While conversion may be promising, economic feasibility and costs need further analysis to demonstrate scaling the technology.
Life Cycle Assessment on Personal Computermerlin1491
1) This document summarizes the results of a life cycle assessment (LCA) conducted on a personal computer. The LCA followed the four steps of goal and scope definition, inventory analysis, impact assessment, and improvement assessment.
2) The pre-manufacturing stage, which involves production of components and parts, was found to be the largest contributor to most environmental impact categories.
3) The use stage, particularly for office computers used over 12 hours per week, also significantly contributed to environmental impacts due to energy consumption.
4) The LCA results can be used to identify priority areas for improving the design of PCs and their components to reduce environmental impacts over the product lifecycle.
Use PyCharm for remote debugging of WSL on a Windo cf5c162d672e4e58b4dde5d797...shadow0702a
This document serves as a comprehensive step-by-step guide on how to effectively use PyCharm for remote debugging of the Windows Subsystem for Linux (WSL) on a local Windows machine. It meticulously outlines several critical steps in the process, starting with the crucial task of enabling permissions, followed by the installation and configuration of WSL.
The guide then proceeds to explain how to set up the SSH service within the WSL environment, an integral part of the process. Alongside this, it also provides detailed instructions on how to modify the inbound rules of the Windows firewall to facilitate the process, ensuring that there are no connectivity issues that could potentially hinder the debugging process.
The document further emphasizes on the importance of checking the connection between the Windows and WSL environments, providing instructions on how to ensure that the connection is optimal and ready for remote debugging.
It also offers an in-depth guide on how to configure the WSL interpreter and files within the PyCharm environment. This is essential for ensuring that the debugging process is set up correctly and that the program can be run effectively within the WSL terminal.
Additionally, the document provides guidance on how to set up breakpoints for debugging, a fundamental aspect of the debugging process which allows the developer to stop the execution of their code at certain points and inspect their program at those stages.
Finally, the document concludes by providing a link to a reference blog. This blog offers additional information and guidance on configuring the remote Python interpreter in PyCharm, providing the reader with a well-rounded understanding of the process.
Discover the latest insights on Data Driven Maintenance with our comprehensive webinar presentation. Learn about traditional maintenance challenges, the right approach to utilizing data, and the benefits of adopting a Data Driven Maintenance strategy. Explore real-world examples, industry best practices, and innovative solutions like FMECA and the D3M model. This presentation, led by expert Jules Oudmans, is essential for asset owners looking to optimize their maintenance processes and leverage digital technologies for improved efficiency and performance. Download now to stay ahead in the evolving maintenance landscape.
Advanced control scheme of doubly fed induction generator for wind turbine us...IJECEIAES
This paper describes a speed control device for generating electrical energy on an electricity network based on the doubly fed induction generator (DFIG) used for wind power conversion systems. At first, a double-fed induction generator model was constructed. A control law is formulated to govern the flow of energy between the stator of a DFIG and the energy network using three types of controllers: proportional integral (PI), sliding mode controller (SMC) and second order sliding mode controller (SOSMC). Their different results in terms of power reference tracking, reaction to unexpected speed fluctuations, sensitivity to perturbations, and resilience against machine parameter alterations are compared. MATLAB/Simulink was used to conduct the simulations for the preceding study. Multiple simulations have shown very satisfying results, and the investigations demonstrate the efficacy and power-enhancing capabilities of the suggested control system.
Comparative analysis between traditional aquaponics and reconstructed aquapon...bijceesjournal
The aquaponic system of planting is a method that does not require soil usage. It is a method that only needs water, fish, lava rocks (a substitute for soil), and plants. Aquaponic systems are sustainable and environmentally friendly. Its use not only helps to plant in small spaces but also helps reduce artificial chemical use and minimizes excess water use, as aquaponics consumes 90% less water than soil-based gardening. The study applied a descriptive and experimental design to assess and compare conventional and reconstructed aquaponic methods for reproducing tomatoes. The researchers created an observation checklist to determine the significant factors of the study. The study aims to determine the significant difference between traditional aquaponics and reconstructed aquaponics systems propagating tomatoes in terms of height, weight, girth, and number of fruits. The reconstructed aquaponics system’s higher growth yield results in a much more nourished crop than the traditional aquaponics system. It is superior in its number of fruits, height, weight, and girth measurement. Moreover, the reconstructed aquaponics system is proven to eliminate all the hindrances present in the traditional aquaponics system, which are overcrowding of fish, algae growth, pest problems, contaminated water, and dead fish.
Embedded machine learning-based road conditions and driving behavior monitoringIJECEIAES
Car accident rates have increased in recent years, resulting in losses in human lives, properties, and other financial costs. An embedded machine learning-based system is developed to address this critical issue. The system can monitor road conditions, detect driving patterns, and identify aggressive driving behaviors. The system is based on neural networks trained on a comprehensive dataset of driving events, driving styles, and road conditions. The system effectively detects potential risks and helps mitigate the frequency and impact of accidents. The primary goal is to ensure the safety of drivers and vehicles. Collecting data involved gathering information on three key road events: normal street and normal drive, speed bumps, circular yellow speed bumps, and three aggressive driving actions: sudden start, sudden stop, and sudden entry. The gathered data is processed and analyzed using a machine learning system designed for limited power and memory devices. The developed system resulted in 91.9% accuracy, 93.6% precision, and 92% recall. The achieved inference time on an Arduino Nano 33 BLE Sense with a 32-bit CPU running at 64 MHz is 34 ms and requires 2.6 kB peak RAM and 139.9 kB program flash memory, making it suitable for resource-constrained embedded systems.
Applications of artificial Intelligence in Mechanical Engineering.pdfAtif Razi
Historically, mechanical engineering has relied heavily on human expertise and empirical methods to solve complex problems. With the introduction of computer-aided design (CAD) and finite element analysis (FEA), the field took its first steps towards digitization. These tools allowed engineers to simulate and analyze mechanical systems with greater accuracy and efficiency. However, the sheer volume of data generated by modern engineering systems and the increasing complexity of these systems have necessitated more advanced analytical tools, paving the way for AI.
AI offers the capability to process vast amounts of data, identify patterns, and make predictions with a level of speed and accuracy unattainable by traditional methods. This has profound implications for mechanical engineering, enabling more efficient design processes, predictive maintenance strategies, and optimized manufacturing operations. AI-driven tools can learn from historical data, adapt to new information, and continuously improve their performance, making them invaluable in tackling the multifaceted challenges of modern mechanical engineering.
Introduction- e - waste – definition - sources of e-waste– hazardous substances in e-waste - effects of e-waste on environment and human health- need for e-waste management– e-waste handling rules - waste minimization techniques for managing e-waste – recycling of e-waste - disposal treatment methods of e- waste – mechanism of extraction of precious metal from leaching solution-global Scenario of E-waste – E-waste in India- case studies.
Batteries -Introduction – Types of Batteries – discharging and charging of battery - characteristics of battery –battery rating- various tests on battery- – Primary battery: silver button cell- Secondary battery :Ni-Cd battery-modern battery: lithium ion battery-maintenance of batteries-choices of batteries for electric vehicle applications.
Fuel Cells: Introduction- importance and classification of fuel cells - description, principle, components, applications of fuel cells: H2-O2 fuel cell, alkaline fuel cell, molten carbonate fuel cell and direct methanol fuel cells.
Electric vehicle and photovoltaic advanced roles in enhancing the financial p...IJECEIAES
Climate change's impact on the planet forced the United Nations and governments to promote green energies and electric transportation. The deployments of photovoltaic (PV) and electric vehicle (EV) systems gained stronger momentum due to their numerous advantages over fossil fuel types. The advantages go beyond sustainability to reach financial support and stability. The work in this paper introduces the hybrid system between PV and EV to support industrial and commercial plants. This paper covers the theoretical framework of the proposed hybrid system including the required equation to complete the cost analysis when PV and EV are present. In addition, the proposed design diagram which sets the priorities and requirements of the system is presented. The proposed approach allows setup to advance their power stability, especially during power outages. The presented information supports researchers and plant owners to complete the necessary analysis while promoting the deployment of clean energy. The result of a case study that represents a dairy milk farmer supports the theoretical works and highlights its advanced benefits to existing plants. The short return on investment of the proposed approach supports the paper's novelty approach for the sustainable electrical system. In addition, the proposed system allows for an isolated power setup without the need for a transmission line which enhances the safety of the electrical network
Electric vehicle and photovoltaic advanced roles in enhancing the financial p...
34079509.ppt
1. ENVIRONMENTAL PERFORMANCE
ASSESSMENT OF ALCOHOL
INDUSTRY
IN UTTAR PRADESH
DR. YASHPAL SINGH
CHIEF ENVIRONMENT OFFICER
U.P. Pollution Control Board
Lucknow,India
2. 2
The Study Team
A. Coordination:
1. Dr. C.S.Bhatt, Member Secretary, UPPCB
2. Dr. Yashpal Singh, Chief Environment Officer, UPPCB
3. Er. Pradeep Sharma, Asstt. Environment Engr., UPPCB.
B. Study Executed by:
ENV Developmental Assistance Systems (INDIA) Pvt. Ltd.,
Lucknow.
Experts:
1. Er. T.N.Chaturvedi,
Professional & Chartered Engineer
2. Er. R.K.Bajaj,
Environmental Engineer
C. Data Analysis & DTP
1. Mr. T.Wilson, Data Analyst & DTP, DAS India.
2. Mr. R.K.Bajpai, Data Entry Operator, UPPCB . Contd...
3. 3
The Study Team (… contd.)
Our gratitude to:
Sri Pradeep Kumar
The then Principal Secretary Environment and
Chairman UP Pollution Control Board
For conceiving and designing the study and for his
inspiring leadership and guidance.
Excise Department
Govt. of Uttar Pradesh.
For providing valuable data
Senior Officers of the U.P. Pollution Control Board
For their valuable inputs.
4. 4
EVOLUTION OF ENVIRONMENTAL
REGULATION
• FIRST WAVE – THE TRADITIONAL REGULATORY APPROACH
• SECOND WAVE – MARKET BASED INSTRUMENTS
- POLLUTION CHARGES
- PRODUCT CHARGES
- USER FEE
- PERFORMANCE BONDS
- LIABILITY PAYMENTS
- NON COMPLIANCE FEES
- DEPOSIT REFUND SCHEME
- TRADEABLE PERMITS
• THIRD WAVE – PUBLIC DISCLOSURE
5. 5
BENEFITS OF PUBLIC DISCLOSURE
• CREATION OF MARKET OPPORTUNITIES
• IMPROVEMENTS IN ENVIRONMENTAL PERFORMANCE
• INCREASED CONFIDENCE OF INVESTORS, INSURERS AND
FINANCIAL INSTITUTIONS
• IMPROVED RELATIONSHIP WITH LOCAL COMMUNITIES,
REGULATORS AND NON GOVERNMENT ORGANISATIIONS
•GREATER CONTROL OF ENVIRONMENTAL DISCLOSURE
•INCREASED STAFF COMMITTMENT
6. 6
PRACTICED AS
• Involuntary – Media Exposures, Notices, PIL Etc.
• Mandatory – The Regulatory Mechanism like consents
• Voluntary – Press Release, Public Reports Etc.
DRIVERS
• Transparency
- Society Wants To Be Told What Is Going On
• Accountability
- Fear Of Losing Significant Economic Value Of
Good Corporate Reputation
• Synergy Between Economic And Environmental
Performance
7. 7
ENVIRONMENTAL LEGISLATION
• THE WATER (PREVENTION AND CONTROL OF POLLUTION )
ACT, 1974 AS AMENDED IN 1988.
• THE WATER ( PREVENTION AND CONTROL OF POLLUTION)
CESS ACT, 1977 AS AMENDED IN 1991.
• THE AIR (PREVENTION AND CONTROL OF POLLUTION) ACT,
1981 AS AMENDED IN 1987.
• THE ENVIRONMENT (PROTECTION) ACT, 1986
• THE PUBLIC LIABILITY INSURANCE ACT, 1991
• THE NATIONAL ENVIRONMENTAL TRIBUNALACT, 1995
• THE NATIONAL ENVIRONMENT APPELLATE AUTHORITYACT,
1997
• NATIONAL BIODIVERSITYACT, 2002
8. 8
•INSTITUTIONAL MECHANISM
- CENTRAL POLLUTION CONTROL BOARD
- STATE POLLUTION CONTROL BOARDS
• INCENTIVES / DISINCENTIVES
- FINES
- BANK GUARANTEES
- CESS REBATE
- CONSENT VALIDITY
- LOCATION
- CLOSURES
- PROSECUTION
9. 9
Environmental Performance Rating
A Pioneering Initiative
U.P. Pollution Control Board, in a pioneering
initiative is making efforts to change the paradigm of
the way Pollution Control is commonly understood.
Dispel the notion that, Pollution Control is an end of
process, cost-intensive, loss-making effort.
Rather, environmental management and pollution
control means harmonizing resources, process and
outputs.
10. 10
Objectives of this Study
To place a Mirror before the industry in the
form of Environmental Performance Rating
to make them aware about their strengths
and weaknesses as also the opportunities &
threats, so as to enable self-correction and
continual improvement in their
environmental performance.
To encourage pro-active role by the Industry
to improve its Environmental Performance
through benchmarking.
11. 11
Significance of Alcohol Industry
Downstream unit of Sugar Industry- Synergy with
Sugar & Paper
Utilising wastes (Molasses) to produce Alcohol, an
essential input of the Chemical & Pharmaceutical
Industry and a product for human consumption.
Alcohol – great potential for use as Fuel for
automobiles – GASOHOL.
But, also known for discharging highly polluted
effluents and is included in ‘Schedule-1’ of Water
Cess Act. An EIA is a pre-requisite before setting up
of any unit or expansion thereof.
(Contd…….)
12. 12
Significance of Alcohol Industry
(…. Contd.)
Significance in U.P.
Alongwith sugar, the largest value enhancer to
agricultural produce.
Contributes a significant part of State GDP – next
only to Trade Tax.
Major catalyst of Employment in the Primary &
Secondary Sectors.
Unfortunately, also amongst the most polluting
industries.
Over 10 MT of BOD load per day into the river
systems of the State.
13. 13
Alcohol Industry in Uttar Pradesh
and Uttaranchal – a profile
No. of Distilleries in U.P. & Uttaranchal - 43
No. of Operational Distilleries - 37
No. of Molasses Based Distilleries - 35
No. of Grain Based Distilleries - 02
Units not operated in 2000-01 - 02
Total Annual Production Capacity
of the Operational Distilleries - 6,79,777 KL
Alcohol Production during 2000-01 - 4,32,489 KL
14. 14
Analytical Framework and
Methodology
The basic hypothesis for this environmental
performance rating exercise has been:
Optimal resource utilisation and improved
production processes are likely to result in better
environmental performance.
Minimal but conscious efforts can result in
achieving the environmental norms.
Therefore, the framework of the rating has three axes:
Plant performance
Regulatory compliance &
Environmental initiatives
(Contd…...)
15. 15
Analytical Framework and
Methodology ( …. Contd.)
The study is based on data obtained from –
The industry
Excise Department
U.P. Pollution Control Board
The study is diachronic & covers a span of three (3)
years:
1998-99, 1999-2000 & 2000-01 and includes trend
of Performance
(Contd…...)
16. 16
Analytical Framework and
Methodology (…….Contd.)
Evaluation parameters identified.
Basic data obtained from Industry on a customized
questionnaire.
The Data received analyzed and clarifications obtained
from the units, as required.
Consultants’ team visited Eight (8) Distillery units,
selected on geographical location and size, to verify
credibility of the reported data on a sample basis.
Feedback taken from Senior Technical officers of UPPCB,
during a series of presentations.
Authentication of the data, considered for calculating the
environmental parameters, obtained from the top
management of the distillery units.
(Contd…...)
17. 17
Analytical Framework and
Methodology (…….Contd.)
Environmental parameters calculated for various
units from the authenticated data obtained.
Latest (2000-01) performance & Trend analyzed.
The two grain based units separately analyzed.
Two (2) molasses-based units- one started in 2000-01 and
the other not worked during the year 2000-01, excluded.
Draft Report prepared and presented to the industry
in an “Open-house (05.02.02)” for feedback, after
which the final report with ratings, prepared.
Individual units informed about their environmental
performance scores as well as the potential for cost
savings through improvement - “Action Plans
requested”
18. 18
The Environmental Performance
Criteria & Weightages
Plant Level Performance (40%)
% utilization of installed production capacity (2+1)
Raw Material, MT per KL Alcohol(5+1)
Alcohol Recovery, Ltrs. Per MT TRS (3+1)
Water Consumption, KL per KL Alcohol(10+1)
Total Energy, GJ per KL Alcohol(4+1)
% Renewable out of the Total Energy(4+1)
Net External Energy, GJ per KL Alcohol(5+1)
(Contd…..)
19. 19
The Environmental Performance
Criteria & Weightages (……Contd.)
Regulatory Compliance Status (5%)
‘Consent’ – Water (2000) obtained from UPPCB
(5 for yes, 0 for no)
‘Marginal’/’Heavy’ Default (without dilution)
- UPPCB’ internal norms
- Negative Marking (Heavy –5; marginal –2)
(Contd…..)
20. 20
The Environmental Performance
Criteria & Weightages (……Contd.)
Corporate & Environmental Management
Aspects (55%)
ISO 14001 E M S (10 for yes; 0 for no)
Completeness of ETP(10)
Effluent Disposal Practice - Stream/Land or
Conversion into Bio-compost (10)
Spent Wash generated, KL per KL Alcohol(10)
Biogas generation, Nm3 per KL Spent Wash(15)
Dilution Factor (-10)
21. 21
Plant Level Performance
Capacity Utilisation
• Minimum - 2.90%
• Maximum - 105.15%
• Average - 64.56%
• Mode - 73.50
Environmental Performance Evaluation
Capacity Utilisation,%
1 1
5
7
2
6
8
3
0
1
2
3
4
5
6
7
8
9
2.90 - 15.68 15.68 - 28.46 28.46 - 41.24 41.24 - 54.03 54.03 - 66.81 66.81 - 79.59 79.59 - 92.37 92.37 -
105.15
Range
No.
of
Units
No. of Units with negative
performance compared to modal
value – 19
22. 22
Plant Level Performance
Capacity Utilisation – The Top & Bottom Five Units
The Top Five (5) units are:
Rank Name of Distillery Performance
Value (%)
Weighted Score
(Performance + Trend)
1 Shamli Distly. & Chem. Works, Shamli,
Muzaffarnagar
100.30 2.994
2 Rampur Distillery, Rampur 103.82 2.924
3 UDBL, Shekhpur, Unnao 105.15 2.897
4 Simbhaoli Sugar Mills Ltd., Distlly, Simbhaoli,
Ghaziabad
92.25 2.845
5 Shadilal Distly. & Chem. Works,
Muzaffarnagar
90.40 2.808
The Bottom Five (5) units are:
Rank Name of Distillery Performance
Value (%)
Weighted Score
(Performance + Trend)
29 Doon Valley Distly., Kuanwala, Dehradun 46.74 0.935
30 Daurala Sugar Works (Distly.), Daurala,
Meerut
46.52 0.930
31 Bajpur Coop. Sugar Factory, Bajpur,
U.S.Nagar
39.94 0.799
32 Central Distilleries & Breweries Ltd, Meerut
Cantt.
34.96 0.699
33 Kisan Sahakari Chini Mills Ltd., Kayamganj,
Farrukhbad
02.90 0.058
23. 23
Plant Level Performance
Molasses Consumption, MT/KL Alcohol
• Minimum - 4.53
• Maximum - 6.28
• Average - 4.97
• Mode - 4.97
No. of Units with negative
performance compared to modal
value – 14
Molasses, MT /KL Alcohol
9
10 10
1 1
0
1 1
0
2
4
6
8
10
12
4.53 - 4.75 4.75 - 4.97 4.97 - 5.19 5.19 - 5.40 5.40 - 5.62 5.62 - 5.84 5.84 - 6.06 6.06 - 6.28
Range
No.
of
Units
24. 24
Plant Level Performance
Molasses Consumption - The Top & Bottom Five Units
The Top Five (5) units are:
Rank Name of Distillery Performance
Value (MT/KL)
Weighted Score
(Performance + Trend)
1 UDBL, Shekhpur, Unnao 4.63 4.571
2 Balrampur Chini Mills, Balrampur 4.53 3.984
3 Bajaj Hindustan Ltd., Gola Gokaran Nath,
Kheri
4.57 3.817
4 UP State Sugar Coop. Fed. Ltd. Nanauta,
Saharanpur
4.62 3.596
5 Kisan Sahakari hini Mills Ltd. (Distly.),
Ghosi, Mau
4.63 3.543
The Bottom Five (5) units are:
Rank Name of Distillery Performance
Value (MT/KL)
Weighted Score
(Performance + Trend)
29 DSM Mills Ltd, (Distly.), Dhampur, Bijnor 5.16 1.204
30 Narang Industries, Nawabgunj, Gonda 5.39 0.208
31 Mohan Meakins Ltd, Lucknow 5.59 0.000
32 Central Distilleries & Breweries Ltd, Meerut
Cantt.
6.03 0.000
33 Kisan Sahakari Chini Mills Ltd., Kayamganj,
Farrukhbad
6.28 0.000
25. 25
Plant Level Performance
Recovery of Alcohol in Ltrs./MT. TRS
• Minimum - 379.40
• Maximum - 536.78
• Average - 463.73
• Mode - 467.93
No. of Units with negative
performance compared to modal
value – 13
Alcohol Recovery,Ltrs. /MT TRS Content
2
1
2
4
18
4
1 1
0
2
4
6
8
10
12
14
16
18
20
379.40 -
399.08
399.08 -
418.75
418.75 -
438.42
438.42 -
458.09
458.09 -
477.76
477.76 -
497.43
497.43 -
517.11
517.11 -
536.78
Range
No.
of
Units
26. 26
Plant Level Performance
Recovery of Alcohol - The Top & Bottom Five Units
The Top Five (5) units are:
Rank Name of Distillery Performance
Value (Ltrs./MT)
Weighted Score
(Performance + Trend)
1 Majhola Distly. & Chem. Works, Majhola,
Pilibhit
536.78 3.372
2 Balrampur Chini Mills, Balrampur 509.28 1.989
3 Rampur Distillery, Rampur 490.27 1.724
4 Bajaj Hindustan Ltd., Gola Gokaran Nath,
Kheri
483.94 1.635
5 India Glycols Ltd., Kashipur, U.S.Nagar 482.36 1.613
The Bottom Five (5) units are:
Rank Name of Distillery Performance
Value (Ltrs./MT)
Weighted Score
(Performance + Trend)
29 Modi Distly. Modinagar, Ghaziabad 435.73 0.963
30 Doon Valley Distly., Kuanwala, Dehradun 427.44 0.847
31 Mohan Meakins Ltd, Lucknow 402.61 0.501
32 Central Distilleries & Breweries Ltd,
Meerut Cantt.
387.88 0.295
33 Kisan Sahakari Chini Mills Ltd.,
Kayamganj, Farrukhbad
379.40 0.177
27. 27
Plant Level Performance
Water Consumption, KL / KL Alcohol
• Minimum - 14.69
• Maximum - 512.88
• Average - 125.22
• Mode - 94.75
No. of Units with negative
performance compared to modal
value – 20
Water Consumption,KL /KL Alcohol
10
14
4
3
1
0 0
1
0
2
4
6
8
10
12
14
16
14.69 - 76.96 76.96 - 139.24 139.24 -
201.51
201.51 -
263.79
263.79 -
326.06
326.06 -
388.33
388.33 -
450.61
450.61 -
512.88
Range
No.
of
Units
28. 28
Plant Level Performance
Water Consumption- The Top & Bottom Five Units
The Top Five (5) units are:
Rank Name of Distillery Performance
Value (KL/KL)
Weighted Score
(Performance + Trend)
1 Jubliant Organosys Ltd. (VAM Organics),
Gajraula
14.69 8.027
2 Simbhaoli Sugar Mills Ltd., Distlly,
Simbhaoli, Ghaziabad
32.61 7.454
3 Somaiya Organics Ltd, Kushinagar 31.99 6.508
4 India Glycols Ltd., Kashipur, U.S.Nagar 48.27 6.079
5 Mohan Meakins Ltd, Mohan Nagar,
Ghaziabad
52.11 5.742
The Bottom Five (5) units are:
Rank Name of Distillery Performance
Value (KL/KL)
Weighted Score
(Performance + Trend)
29 Modi Distly. Modinagar, Ghaziabad 205.50 0.000
30 Saraiya Distilleries, Sardarnagar, GKP 206.08 0.000
31 DSM Mills Ltd, (Distly.), Dhampur, Bijnor 237.84 0.000
32 Daurala Sugar Works (Distly.), Daurala,
Meerut
283.79 0.000
33 Central Distilleries & Breweries Ltd, Meerut
Cantt.
512.88 0.000
29. 29
Plant Level Performance
Total Energy Consumption in GJ/KL Alcohol
• Minimum - 10.17
• Maximum - 123.56
• Average - 26.04
• Mode - 18.32
No. of Units with negative
performance compared to modal
value – 18
Total Energy Consumption, GJ /KL Alcohol
23
6
1 1
0
1
0
1
0
5
10
15
20
25
10.17 -
24.34
24.34 -
38.51
38.51 -
52.69
52.69 -
66.86
66.86 -
81.04
81.04 -
95.21
95.21 -
109.38
109.38 -
123.56
Range
No.
of
Units
30. 30
Plant Level Performance
Total Energy Consumption - The Top & Bottom Five Units
The Top Five (5) units are:
Rank Name of Distillery Performance
Value (GJ/KL)
Weighted Score
(Performance + Trend)
1 Doon Valley Distly., Kuanwala, Dehradun 11.98 3.757
2 Daurala Sugar Works (Distly.), Daurala,
Meerut
13.33 3.424
3 Saraiya Distilleries, Sardarnagar, GKP 13.37 3.414
4 Simbhaoli Sugar Mills Ltd., Distlly,
Simbhaoli, Ghaziabad
10.17 3.201
5 UDBL, Shekhpur, Unnao 15.18 2.971
The Bottom Five (5) units are:
Rank Name of Distillery Performance
Value (GJ/KL)
Weighted Score
(Performance + Trend)
29 Modi Distly. Modinagar, Ghaziabad 26.70 0.000
30 DSM Mills Ltd, (Distly.), Dhampur, Bijnor 31.25 0.000
31 Mohan Meakins Ltd, Mohan Nagar,
Ghaziabad
31.56 0.000
32 Central Distilleries & Breweries Ltd, Meerut
Cantt.
56.02 0.000
33 Bajpur Coop. Sugar Factory, Bajpur,
U.S.Nagar
81.19 0.000
31. 31
Plant Level Performance
Total Renewable Energy % of Total Energy
• Minimum - 7.92
• Maximum - 100.00
• Average - 79.51
• Mode - 93.42
No. of Units with negative
performance compared to modal
value – 17
Renewable Energy %
2 2
1
2
0
1
5
20
0
5
10
15
20
25
7.92 -
19.43
19.43 -
30.94
30.94 -
42.45
42.45 -
53.96
53.96 -
65.47
65.47 -
76.98
76.98 -
88.49
88.49 -
100.00
Range
No.
of
Units
32. 32
Plant Level Performance
Total Renewable Energy- The Top & Bottom Five Units
The Top Five (5) units are:
Rank Name of Distillery Performance
Value (%)
Weighted Score
(Performance + Trend)
1 Narang Industries, Nawabgunj, Gonda 100.00 4.999
2 DSM Mills Ltd, (Distly.), Dhampur, Bijnor 100.00 4.999
3 Jubliant Organosys Ltd. (VAM Organics),
Gajraula
100.00 4.999
4 Somaiya Organics Ltd, Kushinagar 96.23 4.312
5 Bajaj Hindustan Ltd., Gola Gokaran Nath,
Kheri
99.66 3.936
The Bottom Five (5) units are:
Rank Name of Distillery Performance
Value (%)
Weighted Score
(Performance + Trend)
29 Saraiya Distilleries, Sardarnagar, Gorakhpur 77.86 0.000
30 Lords Distillery Ltd., Nandganj, Ghazipur 76.74 0.000
31 Daurala Sugar Works (Distly.), Daurala,
Meerut
52.20 0.000
32 UDBL, Shekhpur, Unnao 25.59 0.000
33 Central Distilleries & Breweries Ltd, Meerut
Cantt.
11.31 0.000
33. 33
Plant Level Performance
Net External Energy in GJ / KL Alcohol
• Minimum - 0.00
• Maximum - 123.56
• Average - 17.70
• Mode - 9.44
No. of Units with negative
performance compared to modal
value – 21
External Energy Consumption,GJ / KL Alcohol
22
8
0
1
0
1
0
1
0
5
10
15
20
25
0.00 -
15.44
15.44 -
30.89
30.89 -
46.33
46.33 -
61.78
61.78 -
77.22
77.22 -
92.67
92.67 -
108.11
108.11 -
123.56
Range
No.
of
Units
34. 34
Plant Level Performance
Net External Energy - The Top & Bottom Five Units
The Top Five (5) units are:
Rank Name of Distillery Performance
Value (GJ/KL)
Weighted Score
(Performance + Trend)
1 Jubliant Organosys Ltd. (VAM Organics),
Gajraula
0.00 6.000
2 Rampur Distillery, Rampur 3.26 4.963
3 Shamli Distly. & Chem. Works, Shamli,
Muzaffarnagar
4.01 4.725
4 KM Sugar Mills Ltd. (Distly.), Motinagar,
Faizabad
4.05 4.713
5 Simbhaoli Sugar Mills Ltd., Distlly,
Simbhaoli, Ghaziabad
1.13 4.641
The Bottom Five (5) units are:
Rank Name of Distillery Performance
Value (GJ/KL)
Weighted Score
(Performance + Trend)
29 Modi Distly. Modinagar, Ghaziabad 17.63 0.000
30 DSM Mills Ltd, (Distly.), Dhampur, Bijnor 19.69 0.000
31 Kisan Sahakari Chini Mills Ltd., Kayamganj,
Farrukhbad
22.08 0.000
32 Central Distilleries & Breweries Ltd, Meerut
Cantt.
49.68 0.000
33 Bajpur Coop. Sugar Factory, Bajpur,
U.S.Nagar
81.19 0.000
35. 35
Regulatory Compliance
Consent Water Molasses Grain
Based Based
• Consent Granted - 17 02
• Consent Not Granted - 16 -
Water Consent
19
16
0
2
4
6
8
10
12
14
16
18
20
Granted Not Granted
No.
of
Units
36. 36
Default Status (without dilution)
• Heavy Default - 22
• Marginal Default - 11
• Zero Discharge - 02
Regulatory Compliance
Default Status (without dillution)
22
11
2
0
5
10
15
20
25
Heavy Default Marginal Default Zero Discharge
No.
of
Units
37. 37
Environmental Management
ISO 14001/EMS not granted to any Unit
Completeness of ETP
• In 2 Units, Primary (Biogas generation) stage
not functional. In other 3 units, biogas not
monitored & not consumed.
• 16 Units do not have the Second Aerobic Stage
of the Secondary Treatment
• 2 Units are converting the entire effluent into
Bio-manure
• 8 Units have started partly converting the
effluent into Bio-manure
38. 38
Environmental Management
Spent Wash Generation in KL/KL Alcohol
• Minimum - 10.87
• Maximum - 38.34
• Average - 15.48
• Mode - 14.92
No. of Units with negative
performance compared to modal
value – 16
Spent Wash,KL / KL Alcohol
13
16
2
0 0 0 0
1
0
2
4
6
8
10
12
14
16
18
10.87 -
14.31
14.31 -
17.74
17.74 -
21.17
21.17 -
24.61
24.61 -
28.04
28.04 -
31.47
31.47 -
34.90
34.90 -
38.34
Range
No.
of
Units
39. 39
Environmental Management
Spent Wash Generation - The Top & Bottom Five Units
The Top Five (5) units are:
Rank Name of Distillery Performance
Value (KL/KL)
Weighted
Score
1 Central Distilleries & Breweries Ltd, Meerut
Cantt.
10.87 7.995
2 DSM Mills Ltd, (Distly.), Dhampur, Bijnor 11.36 7.517
3 KM Sugar Mills Ltd. (Distly.), Motinagar,
Faizabad
11.93 6.948
4 Balrampur Chini Mills, Balrampur 12.65 6.242
5 Upper Ganges Sugar Mills Ltd. (Distly.),
Seohara, Bijnor
12.66 6.233
The Bottom Five (5) units are:
Rank Name of Distillery Performance
Value (KL/KL)
Weighted
Score
28 UPCSFF Ltd, Anoopshahar, Bulandshahar 16.13 2.800
29 Mohan Meakins Ltd, Lucknow 16.82 2.119
30 Bajpur Coop. Sugar Factory, Bajpur,
U.S.Nagar
19.34 0.000
31 Mohan Meakins Ltd, Mohan Nagar, Ghaziabad 20.58 0.000
32 Doon Valley Distly., Kuanwala, Dehradun 38.34 0.000
40. 40
Environmental Management
Biogas Generation in Nm3 /KL Spent Wash
• Minimum - 7.26
• Maximum - 54.30
• Average - 32.31
• Mode - 32.38
No. of Units with negative
performance compared to modal
value – 16
Biogas, Nm3
/ KL Spent Wash
1 1
3
6
9
1
3
2
0
1
2
3
4
5
6
7
8
9
10
7.26 -
13.14
13.14 -
19.02
19.02 -
24.90
24.90 -
30.78
30.78 -
36.66
36.66 -
42.54
42.54 -
48.42
48.42 -
54.30
Range
No.
of
Units
41. 41
Environmental Management
Biogas Generation - The Top & Bottom Five Units
The Top Five (5) units are:
Rank Name of Distillery Performance
Value (Nm3
/KL)
Weighted
Score
1 Jubliant Organosys Ltd. (VAM Organics),
Gajraula
54.30 12.001
2 DSM Mills Ltd, (Distly.), Dhampur, Bijnor 48.60 10.598
3 India Glycols Ltd., Kashipur, U.S.Nagar 47.48 10.321
4 Oudh Sugar Mills (Distly.) Hargaon 45.49 9.830
5 Rampur Distillery, Rampur 43.81 9.416
The Bottom Five (5) units, excluding those not having biogas generation
facilities are:
Rank Name of Distillery Performance
Value (Nm3
/KL)
Weighted
Score
22 Daurala Sugar Works (Distly.), Daurala,
Meerut
23.73 4.469
23 Bajaj Hindustan Ltd., Gola Gokaran Nath,
Kheri
23.31 4.365
24 UDBL, Shekhpur, Unnao 23.04 4.298
25 Majhola Distly. & Chem. Works, Majhola,
Pilibhit
18.95 3.291
26 Doon Valley Distly., Kuanwala, Dehradun 07.26 0.408
42. 42
Environmental Management
Dilution Ratio – KL Water/KL Treated Effluent
• Minimum - 0.31
• Maximum - 44.81
• Average - 7.88
• Mode - 5.50
No. of Units with negative
performance compared to modal
value – 18
Dilution Ratio
14
13
2 2
0 0 0
1
0
2
4
6
8
10
12
14
16
0.31 - 5.87 5.87 -
11.44
11.44 -
17.00
17.00 -
22.56
22.56 -
28.12
28.12 -
33.69
33.69 -
39.25
39.25 -
44.81
Range
No.
of
Units
43. 43
Environmental Management
Dilution Ratio – The Top & Bottom Five Units
The Top Five (5) units are:
Rank Name of Distillery Performance
Value
Weighted
Score
1 Jubliant Organosys Ltd. (VAM Organics),
Gajraula
0.31 0.000
2 Somaiya Organics Ltd, Kushinagar 1.18 -2.000
3 Simbhaoli Sugar Mills Ltd., Distlly, Simbhaoli,
Ghaziabad
1.49 -2.000
4 Doon Valley Distly., Kuanwala, Dehradun 1.51 -2.000
5 Mohan Meakins Ltd, Mohan Nagar, Ghaziabad 1.62 -2.000
The Bottom Five (5) units are:
Rank Name of Distillery Performance
Value
Weighted
Score
28 Modi Distly. Modinagar, Ghaziabad 11.86 -10.000
29 Saraiya Distilleries, Sardarnagar, GKP 14.59 -10.000
30 Daurala Sugar Works (Distly.), Daurala,
Meerut
18.24 -10.000
31 DSM Mills Ltd, (Distly.), Dhampur, Bijnor 19.50 -10.000
32 Central Distilleries & Breweries Ltd, Meerut
Cantt.
44.81 -10.000
44. 44
• Minimum - -1.82
• Maximum - 54.15
• Average - 25.27
• Mode - 26.17
Overall Environmental Performance
(Molasses Based Units)
No. of Units with negative
performance compared to modal
value – 18
Overall Environmental Performance
3
5 5
9
5
3 3
0
1
2
3
4
5
6
7
8
9
10
-1.82 -
6.18
6.18 -
14.17
14.17 -
22.17
22.17 -
30.16
30.16 -
38.16
38.16 -
46.16
46.16 -
54.15
Range
No.
of
Units
Mode - 26.17
Average - 25.27
45. 45
Conclusion
1. Regional Comparison of Environmental Performance
Region No. of Units Performance Avg.
Eastern 06 23.55
Central 07 25.61
Western 17 26.47
Uttaranchal 03 21.14
Regional Comparision of Environmental Performance
23.55
25.61
26.47
21.14
0.00
5.00
10.00
15.00
20.00
25.00
30.00
Eastern Central Western Uttaranchal
Region
Env
ironme
ntal
Pe
rformance
(Av
e
rage
)
6
Units
7
Units
17
Units
3
Units
46. 46
2. River Catchment-wise – No. of Distilleries
River Catchment Units Discharging Land disposal/
to River Bio-Composting
Ghagra 06 05 01
Gomti 03 01 02
Ganga 20 18 02
Yamuna 06 06 -
(Including 2 Grain Based distilleries)
River Catchmentwise Comparision - No. of Distilleries
6
3
20
6
1
18
6
5
0
5
10
15
20
25
Ghagra Gomti Ganga Yamuna
River Catchment
No.
of
Units
Total no. of Distlry.
No. discharging to River
47. 47
3. Locational Comparison of Environmental Performance
Location No. of Units Performance Avg.
Rural 23 24.90
Semi Urban 02 29.97
Urban 08 25.18
Locational Comparision of Environmental Performance
(Molasses Based Units)
24.90
29.97
25.18
0.00
5.00
10.00
15.00
20.00
25.00
30.00
35.00
Rural Semi-Urban Urban
Location
Environmental
Performance
(Average)
23
Units
2
Units
8
Units
48. 48
5. Environmental Performance vs Gross Profit
Gross Profit is directly proportional to Environmental
Performance. (Available data for 14 units)
Better the Environmental Performance, higher is the
Profitability.
Gross Profit/KL Alcohol vs Environmental Performance
(Molasses Based Units)
0
500
1000
1500
2000
2500
3000
3500
4000
4500
5000
0 10 20 30 40 50 60
Environmental Performance
Gross
Profit/Unit
49. 49
6. Better Environmental Performance of Grain Based
Distilleries
• The environmental performance of Grain
Based is better in comparison to molasses
based distilleries
• Even Though their energy requirements are
much higher.
• Notably, there is no recognition for IMFL as
Whisky by WTO.
50. 50
Savings’ Potential in the overall industry
through improved environmental
performance
• Potential for annual cost savings on
achieving industry-best performance value:
• Molasses Consumption : Rs. 26.95 Crores
• Water Consumption : Rs. 12.04 Crores
• Biogas Utilization : Rs. 22.50 Crores
• Reduction in Total
Energy Consumption : Rs. 45.32 Crores
51. 51
Recommendations
1. Serious thinking required in respect of the bottom
five (5) units having alarmingly poor environmental
performance with the consequent adverse
environmental impacts.
2. Mandatory installation of Primary (Biogas) stage of
effluent treatment in all the molasses-based plants
to generate & utilize biogas as also its close
monitoring and control. Retrofitting or replacement
of inefficient plants to be carried out to achieve best
performance.
3. Ensuring two stage aerobic treatment in Secondary
stage of the Effluent Treatment Plant in all
molasses-based units discharging into stream or
land.
(Contd ……)
52. 52
Recommendations
4. Minimizing water consumption by maximum
recycling and reuse.
5. Installation of metering systems at identified
locations for monitoring the consumption of
Biogas, Water, Electricity & fuel.
6. Conversion of Spent Wash into bio-manure or
cattle feed to be preferred disposal practice.
7. Energy Conservation training programs and
periodic energy audits to identify and eliminate
energy wastage and reduce energy consumption.
(Contd ……)
53. 53
Recommendation (…….Contd.)
8. Maximum utilization of the treated effluent for
irrigation, where bio-composting is not feasible.
9. Adoption of the best available technologies in the
following areas,
• Fermentation
• Distillation
• Co-generation of steam/power
• Effluent Treatment
10. Upgradation of the Management through the
implementation of :
• ISO 14001 Environmental Management System
• ISO 9001 Quality Management System
56. 56
Overall Environmental Performance Rating
(Molasses Based Units)
Sl. Name of Distillery Total Score
(Max. Marks - 100)
23 Majhola Distly. & Chem. Works, Majhola, Pilibhit 18.258
24 Doon Valley Distly., Kuanwala, Dehradun 17.266
25 Mohan Meakins Ltd, Lucknow 16.049
26 SKS Chini Mills (Distly.), Nanpara, Bahraich 13.798
27 Central Distilleries & Breweries Ltd, Meerut Cantt. 13.124
28 Modi Distly. Modinagar, Ghaziabad 10.208
29 UPCSFF Ltd, Anoopshahar, Bulandshahar 8.445
30 Kisan Sahakari Chini Mills Ltd. (Distly.), Ghosi, Mau 6.257
31 UP State Sugar Coop. Fed. Ltd. Nanauta, Saharanpur 3.845
32 Kisan Sahakari Chini Mills Ltd., Kayamganj, Farrukhbad 1.514
33 Bajpur Coop. Sugar Factory, Bajpur, U.S.Nagar -1.820
…… Contd.
57. 57
PILOT PROGRAMME FOR ENVIRONMENTAL
PERFORMANCE RATING AND PUBLIC
DISCLOSURE FOR INDUSTRIES
• PART OF WORLD BANK PROGRAMME
• SIMILAR IN DESIGN PRINCIPLES TO STUDIES IN
INDONESIA, CHINAAND PHILIPINES
• COLLECTIVE EFFORT OF CII, WORLD BANK AND
THE U.P. POLLUTION CONTROL BOARD.
58. 58
• INITIATED IN MAY 2001
• COVERED 33 INDUSTRIES OF DIFFERENT SIZES AND
DIFFERENT SECTORS AT GHAZIABAD AND NOIDA
• CLASSIFIED BLACK, RED (IMPLYING LACK OF
COMPLIANCE) AND BLUE GREEN AND GOLD
(LEVELS OF PERFORMANCE MEETING EXISTING
STANDARDS)
• 6 RATED GOLD AND GREEN
• 16 RATED BLUE
• 11 RATED BLACK AND RED
59. 59
PILOT INCLUDES
• LOCATION SPECIFIC PROGRAMME
• INCLUDES SMALLAND MEDIUM ENTERPRISE ALSO
• INVOLVES A YES / NO
• COMPLIANCE RATING AS AGAINST PERFORMANCE
RATING
60. 60
FUTURE OUTLOOK
• DATAACQUISITION SUCCESSFUL ONLY IF ASSISTED
BY REGULATORYAUTHORITIES.
• SEPARATE IDENTITY OF ENVIRONMENTAL RATING
PROGRAM
• INVOLVEMENT OFA MULTI STAKEHOLDER PANEL FOR
RATING VERIFICATION AND OVERSEEING THE RATING
PROCESS IS MUST
• INVOLVEMENT OF TECHNICAL EXPERTS
• INDEPENDENT FINANCIAL BACKING FOR THE PROJECT
• PUBLIC ACCESS TO THE DATA GENERATED BY THE
RATING PROCESS
• COMPLETE COOPERATION OF SPCB IS MUST.
61. 61
CHARTER FOR CORPORATE
RESPONSIBILITY 2003
BANK GUARANTEE AND ACTION PLAN TO ENSURE
COMPLIANCE WITH ANY OR COMBINATION OF
FOLLOWING MEASURES
•COMPOST MAKING WITH PRESS MUD/AGRICULTURAL
RESIDUE/MUNICIPAL WASTE
•CONCENTRATION AND DRYING / INCINERATION
•BIOMETHANATION, TWO STAGE SECONDARY TREATMENT
AND DILUTION WITH PROCESS WATER FOR USE OF EFFLUENTS
IN IRRIGATION
•BIOMETHANATION, SECONDARY TREATMENT AND
CONTROLLED DISCHARGE INTO SEA.
•ONE TIME CONTROLLED APPLICATION ON LAND. STUDY IN
THREE MONTHS.
62. 62
ROAD MAP FOR ACHIEVING ZERO DISCHARGE IN
INLAND SURFACE WATERS
• 50 % UTILIZATION OF SPENT WASH BY MARCH 2004
• 75% UTILIZATION OF SPENT WASH BY MARCH 2005
• 100 % UTILIZATION OF SPENT WASH BY DECEMBER 2005
NEW DISTILLERIES AND EXPANSION OF EXISTING
DISTILLERIES
• NEW STAND ALONE DISTILLERIES AND EXPANSION OF
EXISTING DISTILLERIES WITHOUT ACHIEVING ZERO
DISCHARGE IN SURFACE/GROUND WATER NOT TO BE
CONSIDERED