This report provides a life cycle carbon footprint analysis comparing single-use OREX garments to reusable textile garments used in the US nuclear industry. Previous studies had limitations by not fully accounting for transportation impacts, waste disposal needs, and realistic reuse cycles of textiles. This report aims to address data gaps by conducting a robust assessment following international standards. The results show the carbon footprint per use of OREX garments is not significantly different from textiles up to 80-90 uses, and in some cases OREX has a lower footprint. The report provides a more comprehensive analysis than previous work.
Corrosion under insulation detection, mitigation & prevention trainingMarcep Inc.
Mining 1% ($0.1 billion), Petroleum Refining 21% ($3.7
billion), Chemical, Petrochemical, Pharmaceutical 10% ($1.7
billion), Pulp and Paper 34% ($6 billion), Agricultural 6%
($1.1 billion), Food Processing 12% ($2.1 billion), Home
Appliances 9% ($1.5 billion), Oil and Gas Exploration and
Production 8% ($1.4 billion),
Annual cost of corrosion in the production & manufacturing
category
Most facility managers, engineers, maintenance and construction personnel now know that corrosion under insulation
(CUI) exists and left to its own devices, can cause serious problems and even catastrophic consequences.
It is also widely known that the results of CUI are costly. How costly? That is harder to define. Most studies on the topic
involve all forms of corrosion and their associated costs without providing the individual cost of corrosion related to
insulation.
What is clear, however, is that the cost of corrosion in the World continues to increase. A study completed in 2011 by a
research team of corrosion specialists enlisted by Congress titled, "Corrosion Costs and Preventative Strategies in the
World" reported the direct cost of corrosion to be $276 billion per year, with that number potentially doubling when indirect
costs are also considered.
Additional factors encourage CUI: the environment, insulation design and specifications, installation craftsmanship and
maintenance. Let's examine what can be done to reduce the risks.
Mr Gurudas Aras, Director, A.T.E. Enterprises made a presentation on "Technological advancements in technical textiles" at the inaugural session of the Techtextil International Conference, Mumbai on 21 November 2019. The presentation mainly focused on the most relevant technological developments in technical textiles in the Indian context today and covered 'sustainability', 'durability', and 'functionality' aspects of the business. The presentation covered products like flushable and bio-degradable wipes, textile reinforced concrete, thermoplastic UD tapes for automobiles and coating and lamination for special applications respectively. Click here to view the presentation.
The document describes a renewal-based clothing company located in Denton, Texas that remakes pre-owned garments and sells them along with their own designs made from donations. Their mission is to provide an eco-friendly and affordable service that decreases waste by recycling clothing. They target college students on a budget who care about the environment. Services include redesigning clothes for a low price. They aim to reduce their carbon footprint through sustainable practices like using recycled materials and LED lighting. Customer loyalty programs and clothing swap parties are also described.
The document discusses carbon footprints in the textile industry. It defines carbon footprint as the total greenhouse gas emissions caused by an organization, product, or activity. The textile industry has a large carbon footprint due to the energy and resources required for production. Calculating carbon footprints involves quantifying direct emissions from energy use as well as indirect emissions from a product's entire lifecycle. Reducing the textile industry's carbon footprint can be achieved through methods like using renewable energy sources, modernizing equipment, optimizing processes, and utilizing sustainable materials. Measuring and lowering carbon footprints is important for the textile industry to reduce its environmental impact.
This document summarizes key findings from a study on the life cycle greenhouse gas emissions of the apparel industry. It finds that laundering accounts for 40-80% of total emissions for most garments due to the energy required. Fiber type is also important, with synthetics generally having higher emissions than plant-based fibers. The type of care, such as dry cleaning versus washing, can also significantly impact the carbon footprint of different fabrics. Overall, use phase and fiber selection are the two most important factors in determining a garment's life cycle greenhouse gas emissions.
The Effect of Plasma and Enzyme Treatment on the Comfort Properties of Organi...IRJET Journal
The document discusses a study on the effect of plasma and enzyme treatment on the comfort properties of organic cotton woven fabric. Plasma treatment with atmospheric air and treatment with the cellulase enzyme were performed on plain woven organic cotton fabric. The comfort properties of air permeability, water vapour permeability, and wickability were evaluated. The plasma treated fabric showed better air permeability and wickability compared to the enzyme treated and untreated fabrics. However, the enzyme treated fabric demonstrated better water vapour permeability characteristics. The research helps understand how the surface modifications impact the comfort properties of organic cotton fabric.
Life Cycle Assessment of An Air FreshenerLuke Martin
This document provides a life cycle assessment of an air freshener produced by OMI Industries. It summarizes the goal of quantifying the environmental impacts of the product and identifying high impact processes. The functional unit is 1000kg of gel. Key processes include essential oil production, surfactant manufacture, and product assembly. Transportation of materials and electricity usage during production contribute significantly to global warming potential. The study was limited by a lack of data on upstream and downstream processes.
Corrosion under insulation detection, mitigation & prevention trainingMarcep Inc.
Mining 1% ($0.1 billion), Petroleum Refining 21% ($3.7
billion), Chemical, Petrochemical, Pharmaceutical 10% ($1.7
billion), Pulp and Paper 34% ($6 billion), Agricultural 6%
($1.1 billion), Food Processing 12% ($2.1 billion), Home
Appliances 9% ($1.5 billion), Oil and Gas Exploration and
Production 8% ($1.4 billion),
Annual cost of corrosion in the production & manufacturing
category
Most facility managers, engineers, maintenance and construction personnel now know that corrosion under insulation
(CUI) exists and left to its own devices, can cause serious problems and even catastrophic consequences.
It is also widely known that the results of CUI are costly. How costly? That is harder to define. Most studies on the topic
involve all forms of corrosion and their associated costs without providing the individual cost of corrosion related to
insulation.
What is clear, however, is that the cost of corrosion in the World continues to increase. A study completed in 2011 by a
research team of corrosion specialists enlisted by Congress titled, "Corrosion Costs and Preventative Strategies in the
World" reported the direct cost of corrosion to be $276 billion per year, with that number potentially doubling when indirect
costs are also considered.
Additional factors encourage CUI: the environment, insulation design and specifications, installation craftsmanship and
maintenance. Let's examine what can be done to reduce the risks.
Mr Gurudas Aras, Director, A.T.E. Enterprises made a presentation on "Technological advancements in technical textiles" at the inaugural session of the Techtextil International Conference, Mumbai on 21 November 2019. The presentation mainly focused on the most relevant technological developments in technical textiles in the Indian context today and covered 'sustainability', 'durability', and 'functionality' aspects of the business. The presentation covered products like flushable and bio-degradable wipes, textile reinforced concrete, thermoplastic UD tapes for automobiles and coating and lamination for special applications respectively. Click here to view the presentation.
The document describes a renewal-based clothing company located in Denton, Texas that remakes pre-owned garments and sells them along with their own designs made from donations. Their mission is to provide an eco-friendly and affordable service that decreases waste by recycling clothing. They target college students on a budget who care about the environment. Services include redesigning clothes for a low price. They aim to reduce their carbon footprint through sustainable practices like using recycled materials and LED lighting. Customer loyalty programs and clothing swap parties are also described.
The document discusses carbon footprints in the textile industry. It defines carbon footprint as the total greenhouse gas emissions caused by an organization, product, or activity. The textile industry has a large carbon footprint due to the energy and resources required for production. Calculating carbon footprints involves quantifying direct emissions from energy use as well as indirect emissions from a product's entire lifecycle. Reducing the textile industry's carbon footprint can be achieved through methods like using renewable energy sources, modernizing equipment, optimizing processes, and utilizing sustainable materials. Measuring and lowering carbon footprints is important for the textile industry to reduce its environmental impact.
This document summarizes key findings from a study on the life cycle greenhouse gas emissions of the apparel industry. It finds that laundering accounts for 40-80% of total emissions for most garments due to the energy required. Fiber type is also important, with synthetics generally having higher emissions than plant-based fibers. The type of care, such as dry cleaning versus washing, can also significantly impact the carbon footprint of different fabrics. Overall, use phase and fiber selection are the two most important factors in determining a garment's life cycle greenhouse gas emissions.
The Effect of Plasma and Enzyme Treatment on the Comfort Properties of Organi...IRJET Journal
The document discusses a study on the effect of plasma and enzyme treatment on the comfort properties of organic cotton woven fabric. Plasma treatment with atmospheric air and treatment with the cellulase enzyme were performed on plain woven organic cotton fabric. The comfort properties of air permeability, water vapour permeability, and wickability were evaluated. The plasma treated fabric showed better air permeability and wickability compared to the enzyme treated and untreated fabrics. However, the enzyme treated fabric demonstrated better water vapour permeability characteristics. The research helps understand how the surface modifications impact the comfort properties of organic cotton fabric.
Life Cycle Assessment of An Air FreshenerLuke Martin
This document provides a life cycle assessment of an air freshener produced by OMI Industries. It summarizes the goal of quantifying the environmental impacts of the product and identifying high impact processes. The functional unit is 1000kg of gel. Key processes include essential oil production, surfactant manufacture, and product assembly. Transportation of materials and electricity usage during production contribute significantly to global warming potential. The study was limited by a lack of data on upstream and downstream processes.
Exploring ways of reducing carbon footprints in clothing care and maintenance...Ninette Afi Pongo
Competency-based instruction significantly increases the likelihood of adequately preparing students for the world of work. This is a major objective of TVET.
NOISE ABSORBING MATERIAL USING BIOPOLYMERSIRJET Journal
This document discusses research into developing noise absorbing materials using biopolymers. Specifically, it analyzed different mixtures of agricultural waste, tire powder, and nylon to create novel nanocomposites and evaluated their material properties such as density, tensile strength, and acoustic absorption performance. Testing was conducted according to ASTM standards to measure properties like noise absorption factor and tensile strength. The results showed that whole-stalk hemp biocomposites exhibited notable acoustic absorption, with a peak absorption of 0.42 at 1500 Hz for a composite with 30% hemp. Biopolymers show potential for reducing environmental impacts compared to traditional materials and their properties can be optimized for noise absorption through adjusting fiber ratios and production methods.
IRJET- Multifinishing of Cotton using Reduced Graphene OxideIRJET Journal
This document discusses applying reduced graphene oxide (rGO) and titanium dioxide (TiO2) to cotton fabric to provide antimicrobial and UV protection properties. Scanning electron microscopy, Fourier-transform infrared spectroscopy, and X-ray diffraction were used to characterize the rGO material. The rGO-TiO2 mixture was applied to cotton using a padding method and achieved over 99% reduction of both gram-positive and gram-negative bacteria based on AATCC testing. UV protection testing showed the treatment blocked over 90% of UV rays depending on the concentration of rGO used. The study demonstrated cotton fabric with both antimicrobial and UV protection functions can be achieved through this rGO-TiO2 treatment method.
Industrial Waste Water Treatment Using An Attached MediaIRJET Journal
This document summarizes a study that evaluated the use of coconut coir as an attached growth media for treating industrial wastewater. The study investigated the effect of organic loading rate (OLR) and hydraulic retention time (HRT) on the removal of chemical oxygen demand (COD) in a reactor system using coir media. It found that COD removal efficiency increased with OLR up to 1.33 kg COD/m3d, above which removal efficiency decreased. The maximum COD removal of 89.9% was achieved at an OLR of 1.33 kg COD/m3d and HRT of 36 hours.
Development of an experimental rig for bioremediation studiesAlexander Decker
The document describes the development of an experimental rig for bioremediation studies using indigenous technology. Key details include:
- The rig consists of various units like air pretreatment, fixed bed bioreactors, volatile organic compound traps, air flow meter, and carbon dioxide traps.
- Components were sized, designed, and fabricated locally at low cost. Testing showed the rig effectively degraded 75% of oil and grease from contaminated soil over 10 weeks.
- The rig was used to study bioremediation of soil contaminated with spent motor oil in 6 treatments with various additives over room temperature.
Characteristics of fabrics in automated handling systemsMahmoud Morsy
This document summarizes research on the low-force frictional characteristics of fabrics used in automated handling systems. It describes fabric and surface samples tested, as well as tests conducted to determine the effect of humidity and other parameters on fabric friction properties. The results indicate that humidity, fabric structure, and surface material strongly influence friction, which has implications for the reliability and design of automated fabric handling equipment operating at low forces.
LIFE CYCLE ASSESSMENT OF PPE KIT USING OPEN -LCA SOFTWAREIRJET Journal
This study conducted a life cycle assessment of common personal protective equipment (PPE) items like face shields, gloves, surgical gowns, and masks using open LCA software to identify their potential environmental impacts. The results of the LCA showed that single-use surgical gowns have the most environmental impact compared to the other PPE items in terms of acidification, ozone layer depletion, human toxicity, and global warming. Recommendations are provided to reduce the environmental impacts of PPE production, use, and disposal.
RESEARCH Life Cycle Assessment of Reusable and Disposable Cleanroom CoverallsCinet_PTC
This document summarizes a life cycle assessment that compares the environmental impacts of reusable and disposable cleanroom coveralls. The study examined three representative coverall types: a reusable woven PET coverall and two disposable coveralls made of HDPE and SMS PP. The reusable coverall showed substantial improvements over the disposable options in all environmental impact categories, including 34-59% lower energy usage, 23-56% lower greenhouse gas emissions, and 73-77% lower water consumption. Between the two disposable types, the HDPE coverall had somewhat lower impacts than the SMS PP coverall. The reusable coverall also reduced solid waste from cleanroom facilities by 94-96% compared to the disposable options.
IJRET : International Journal of Research in Engineering and Technology is an international peer reviewed, online journal published by eSAT Publishing House for the enhancement of research in various disciplines of Engineering and Technology. The aim and scope of the journal is to provide an academic medium and an important reference for the advancement and dissemination of research results that support high-level learning, teaching and research in the fields of Engineering and Technology. We bring together Scientists, Academician, Field Engineers, Scholars and Students of related fields of Engineering and Technology
IRJET- Soil Stabilization using Waste Clothes (Cotton Clothes and Synthetic C...IRJET Journal
1) The document presents research on using waste cotton and synthetic clothes for soil stabilization. Laboratory tests were conducted to evaluate the effects on soil properties.
2) Modified proctor tests and CBR tests were performed on soil samples with 1% additions of cotton and synthetic clothes by weight. The tests aimed to determine optimum moisture content, maximum dry density, and bearing capacity.
3) The results showed that adding 1% synthetic clothes increased the optimum moisture content, maximum dry density, and CBR values of the soil compared to untreated soil. However, adding cotton clothes resulted in lower dry density and CBR values than untreated soil, due to cotton's higher moisture absorption. Therefore, synthetic clothes were deemed better for soil reinforcement
FABRICATION OF A SIMPLE BUBBLE COLUMN CO2 CAPTURE UNIT UTILIZING MICROALGAE ijbbjournal
This paper focuses on the fabrication of a vertical column CO2 bioreactor and the experimentation of
microalgae. On the manufacturing aspect of the project, the base design was modelled on Solidworks and
assigned a material. The model was then loaded onto a finite element analysis (FEA) software to determine
various engineering stresses and strains to confirm the specimen’s strength. Once the simulation had
completed, the model was ready for 3-D printing. The species of microalgae to be used in this study was
Chlorella Vulgaris. The medium solution was prepared by mixing many types of salts suitable for this type
of algae. Experimental trials of algae growth were conducted mainly to see whether the algae would indeed
grow more rapidly using the developed medium. After failure in early trials, some experiments were
conducted to determine which concentration of stock solution would be the most ideal for the algae to grow
in. These early experiments proved the major impacts of the concentration of the medium on the rate of
growth of the algae. The knowledge gained in these experiments will be instrumental during the next stages
of this project.
FABRICATION OF A SIMPLE BUBBLE COLUMN CO2 CAPTURE UNIT UTILIZING MICROALGAEijbbjournal
This document summarizes the fabrication of a vertical column photobioreactor to capture CO2 using microalgae. It describes the design and 3D printing of the reactor base, cultivation of Chlorella Vulgaris microalgae in the reactor, and experimental trials testing different growth medium concentrations. The best growth was found at a 20% concentration. The reactor design aims to efficiently capture CO2 from flue gases through microalgae photosynthesis in a controlled environment.
Cost and energy efficiency assessment of odour abatement systems 7_1_15 Actio...Gábor Horváth
This document summarizes pilot studies conducted on 4 odor abatement systems: 1) regenerative thermal oxidation (RTO), 2) biofilters, 3) adsorption, and 4) ignition. The RTO system was tested at a Finnish iron foundry. Biofilters were tested at 2 German steel foundries. Adsorption was tested at a steel foundry using a bag filter with adsorbent. Ignition was tested at a Finnish cupola furnace foundry to increase the burning phase of gas emissions. Pilot periods ranged from 4-8 weeks with continuous monitoring. Measurements found the systems effectively reduced odors and hazardous air pollutants.
IRJET- Biofilter System for Air Pollution Control: A ReviewIRJET Journal
This document reviews biofilter systems for air pollution control. Biofilters use microorganisms to biologically degrade volatile organic compounds and odorous gases from industrial air streams in a cost-effective manner. Biofilters have advantages over other air pollution control technologies in that they can treat dilute gas streams while producing less secondary waste. The document discusses the history of biofilters, how they work by passing contaminated air through a bed of microorganisms, and their advantages in comparison to other air pollution control systems.
Impact of environmental protection requirements on the designMohammed Mhnds
The document discusses the impact of environmental protection requirements on the design of marine vehicles. It outlines how ships can negatively impact the environment during construction, operation, and breaking. International regulations have been implemented by IMO to protect the environment from shipping impacts. These regulations influence marine vehicle design in ways that minimize environmental pollution during production, operation, and dismantling. Design trends focus on improving energy efficiency, reducing emissions and waste, and selecting green materials and equipment to lessen environmental impacts. Future ship designs may utilize solar, wind and wave energy with lightweight composite materials.
Quality is a relative term. It means customer needs is to be satisfied. Quality is of prime importance in any aspect of business. Customers demand and expect value for money. As producers of apparel there must be a constant endeavor to produce work of good quality. To assess the quality of textile product Textile Testing is very important work or process. Testing In response to ever-changing governmental regulations and the ever-increasing consumer demand for high quality, softlines testing and textile testing help to minimize risk and protect the interest of both manufacturers and consumers. It is important that testing is not undertaken without adding some benefit to the final product.
Textile Testing & Quality Control (TTQC) is very important work or process in each department of export oriented industry. Buyers want quality but not quantity. In every department of textile industry quality maintained of each material, Because one material’s quality depend on another’s quality. For example, if qualified fiber is inputted then output will be good yarn.
Customer Bulletin 0410 A Comparison of ISO-C1 and HT-300Joe Hughes
This Customer Bulletin is part of a series of white papers aimed at providing our clients, engineers, contractors, fabricators, and friends with objective information on competitive products. Marketing literature on the internet and in printed media address the physical and performance characteristics of competing polyisocyanurate rigid foam insulations fabricated from bunstock. As is often the case, some literature can be misleading and/or in some cases there may not be sufficient information to credibly compare products. This Customer Bulletin provides factual, clarifying information which should allow for an objective comparison of Dyplast’s ISO-C1® with HiTherm’s HT-300 (each 2 lb/ft3 density).
The Light Decontamination System is a portable backpack that uses atomization technology to create a fine mist for decontaminating surfaces and air. It can be used against chemical, biological, and radiological threats. The system is lightweight at 22kg and allows effective decontamination in confined or remote environments without damaging sensitive equipment. It offers flexibility through a choice of decontaminants and can be upgraded for larger-scale or remote-controlled decontamination needs.
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Exploring ways of reducing carbon footprints in clothing care and maintenance...Ninette Afi Pongo
Competency-based instruction significantly increases the likelihood of adequately preparing students for the world of work. This is a major objective of TVET.
NOISE ABSORBING MATERIAL USING BIOPOLYMERSIRJET Journal
This document discusses research into developing noise absorbing materials using biopolymers. Specifically, it analyzed different mixtures of agricultural waste, tire powder, and nylon to create novel nanocomposites and evaluated their material properties such as density, tensile strength, and acoustic absorption performance. Testing was conducted according to ASTM standards to measure properties like noise absorption factor and tensile strength. The results showed that whole-stalk hemp biocomposites exhibited notable acoustic absorption, with a peak absorption of 0.42 at 1500 Hz for a composite with 30% hemp. Biopolymers show potential for reducing environmental impacts compared to traditional materials and their properties can be optimized for noise absorption through adjusting fiber ratios and production methods.
IRJET- Multifinishing of Cotton using Reduced Graphene OxideIRJET Journal
This document discusses applying reduced graphene oxide (rGO) and titanium dioxide (TiO2) to cotton fabric to provide antimicrobial and UV protection properties. Scanning electron microscopy, Fourier-transform infrared spectroscopy, and X-ray diffraction were used to characterize the rGO material. The rGO-TiO2 mixture was applied to cotton using a padding method and achieved over 99% reduction of both gram-positive and gram-negative bacteria based on AATCC testing. UV protection testing showed the treatment blocked over 90% of UV rays depending on the concentration of rGO used. The study demonstrated cotton fabric with both antimicrobial and UV protection functions can be achieved through this rGO-TiO2 treatment method.
Industrial Waste Water Treatment Using An Attached MediaIRJET Journal
This document summarizes a study that evaluated the use of coconut coir as an attached growth media for treating industrial wastewater. The study investigated the effect of organic loading rate (OLR) and hydraulic retention time (HRT) on the removal of chemical oxygen demand (COD) in a reactor system using coir media. It found that COD removal efficiency increased with OLR up to 1.33 kg COD/m3d, above which removal efficiency decreased. The maximum COD removal of 89.9% was achieved at an OLR of 1.33 kg COD/m3d and HRT of 36 hours.
Development of an experimental rig for bioremediation studiesAlexander Decker
The document describes the development of an experimental rig for bioremediation studies using indigenous technology. Key details include:
- The rig consists of various units like air pretreatment, fixed bed bioreactors, volatile organic compound traps, air flow meter, and carbon dioxide traps.
- Components were sized, designed, and fabricated locally at low cost. Testing showed the rig effectively degraded 75% of oil and grease from contaminated soil over 10 weeks.
- The rig was used to study bioremediation of soil contaminated with spent motor oil in 6 treatments with various additives over room temperature.
Characteristics of fabrics in automated handling systemsMahmoud Morsy
This document summarizes research on the low-force frictional characteristics of fabrics used in automated handling systems. It describes fabric and surface samples tested, as well as tests conducted to determine the effect of humidity and other parameters on fabric friction properties. The results indicate that humidity, fabric structure, and surface material strongly influence friction, which has implications for the reliability and design of automated fabric handling equipment operating at low forces.
LIFE CYCLE ASSESSMENT OF PPE KIT USING OPEN -LCA SOFTWAREIRJET Journal
This study conducted a life cycle assessment of common personal protective equipment (PPE) items like face shields, gloves, surgical gowns, and masks using open LCA software to identify their potential environmental impacts. The results of the LCA showed that single-use surgical gowns have the most environmental impact compared to the other PPE items in terms of acidification, ozone layer depletion, human toxicity, and global warming. Recommendations are provided to reduce the environmental impacts of PPE production, use, and disposal.
RESEARCH Life Cycle Assessment of Reusable and Disposable Cleanroom CoverallsCinet_PTC
This document summarizes a life cycle assessment that compares the environmental impacts of reusable and disposable cleanroom coveralls. The study examined three representative coverall types: a reusable woven PET coverall and two disposable coveralls made of HDPE and SMS PP. The reusable coverall showed substantial improvements over the disposable options in all environmental impact categories, including 34-59% lower energy usage, 23-56% lower greenhouse gas emissions, and 73-77% lower water consumption. Between the two disposable types, the HDPE coverall had somewhat lower impacts than the SMS PP coverall. The reusable coverall also reduced solid waste from cleanroom facilities by 94-96% compared to the disposable options.
IJRET : International Journal of Research in Engineering and Technology is an international peer reviewed, online journal published by eSAT Publishing House for the enhancement of research in various disciplines of Engineering and Technology. The aim and scope of the journal is to provide an academic medium and an important reference for the advancement and dissemination of research results that support high-level learning, teaching and research in the fields of Engineering and Technology. We bring together Scientists, Academician, Field Engineers, Scholars and Students of related fields of Engineering and Technology
IRJET- Soil Stabilization using Waste Clothes (Cotton Clothes and Synthetic C...IRJET Journal
1) The document presents research on using waste cotton and synthetic clothes for soil stabilization. Laboratory tests were conducted to evaluate the effects on soil properties.
2) Modified proctor tests and CBR tests were performed on soil samples with 1% additions of cotton and synthetic clothes by weight. The tests aimed to determine optimum moisture content, maximum dry density, and bearing capacity.
3) The results showed that adding 1% synthetic clothes increased the optimum moisture content, maximum dry density, and CBR values of the soil compared to untreated soil. However, adding cotton clothes resulted in lower dry density and CBR values than untreated soil, due to cotton's higher moisture absorption. Therefore, synthetic clothes were deemed better for soil reinforcement
FABRICATION OF A SIMPLE BUBBLE COLUMN CO2 CAPTURE UNIT UTILIZING MICROALGAE ijbbjournal
This paper focuses on the fabrication of a vertical column CO2 bioreactor and the experimentation of
microalgae. On the manufacturing aspect of the project, the base design was modelled on Solidworks and
assigned a material. The model was then loaded onto a finite element analysis (FEA) software to determine
various engineering stresses and strains to confirm the specimen’s strength. Once the simulation had
completed, the model was ready for 3-D printing. The species of microalgae to be used in this study was
Chlorella Vulgaris. The medium solution was prepared by mixing many types of salts suitable for this type
of algae. Experimental trials of algae growth were conducted mainly to see whether the algae would indeed
grow more rapidly using the developed medium. After failure in early trials, some experiments were
conducted to determine which concentration of stock solution would be the most ideal for the algae to grow
in. These early experiments proved the major impacts of the concentration of the medium on the rate of
growth of the algae. The knowledge gained in these experiments will be instrumental during the next stages
of this project.
FABRICATION OF A SIMPLE BUBBLE COLUMN CO2 CAPTURE UNIT UTILIZING MICROALGAEijbbjournal
This document summarizes the fabrication of a vertical column photobioreactor to capture CO2 using microalgae. It describes the design and 3D printing of the reactor base, cultivation of Chlorella Vulgaris microalgae in the reactor, and experimental trials testing different growth medium concentrations. The best growth was found at a 20% concentration. The reactor design aims to efficiently capture CO2 from flue gases through microalgae photosynthesis in a controlled environment.
Cost and energy efficiency assessment of odour abatement systems 7_1_15 Actio...Gábor Horváth
This document summarizes pilot studies conducted on 4 odor abatement systems: 1) regenerative thermal oxidation (RTO), 2) biofilters, 3) adsorption, and 4) ignition. The RTO system was tested at a Finnish iron foundry. Biofilters were tested at 2 German steel foundries. Adsorption was tested at a steel foundry using a bag filter with adsorbent. Ignition was tested at a Finnish cupola furnace foundry to increase the burning phase of gas emissions. Pilot periods ranged from 4-8 weeks with continuous monitoring. Measurements found the systems effectively reduced odors and hazardous air pollutants.
IRJET- Biofilter System for Air Pollution Control: A ReviewIRJET Journal
This document reviews biofilter systems for air pollution control. Biofilters use microorganisms to biologically degrade volatile organic compounds and odorous gases from industrial air streams in a cost-effective manner. Biofilters have advantages over other air pollution control technologies in that they can treat dilute gas streams while producing less secondary waste. The document discusses the history of biofilters, how they work by passing contaminated air through a bed of microorganisms, and their advantages in comparison to other air pollution control systems.
Impact of environmental protection requirements on the designMohammed Mhnds
The document discusses the impact of environmental protection requirements on the design of marine vehicles. It outlines how ships can negatively impact the environment during construction, operation, and breaking. International regulations have been implemented by IMO to protect the environment from shipping impacts. These regulations influence marine vehicle design in ways that minimize environmental pollution during production, operation, and dismantling. Design trends focus on improving energy efficiency, reducing emissions and waste, and selecting green materials and equipment to lessen environmental impacts. Future ship designs may utilize solar, wind and wave energy with lightweight composite materials.
Quality is a relative term. It means customer needs is to be satisfied. Quality is of prime importance in any aspect of business. Customers demand and expect value for money. As producers of apparel there must be a constant endeavor to produce work of good quality. To assess the quality of textile product Textile Testing is very important work or process. Testing In response to ever-changing governmental regulations and the ever-increasing consumer demand for high quality, softlines testing and textile testing help to minimize risk and protect the interest of both manufacturers and consumers. It is important that testing is not undertaken without adding some benefit to the final product.
Textile Testing & Quality Control (TTQC) is very important work or process in each department of export oriented industry. Buyers want quality but not quantity. In every department of textile industry quality maintained of each material, Because one material’s quality depend on another’s quality. For example, if qualified fiber is inputted then output will be good yarn.
Customer Bulletin 0410 A Comparison of ISO-C1 and HT-300Joe Hughes
This Customer Bulletin is part of a series of white papers aimed at providing our clients, engineers, contractors, fabricators, and friends with objective information on competitive products. Marketing literature on the internet and in printed media address the physical and performance characteristics of competing polyisocyanurate rigid foam insulations fabricated from bunstock. As is often the case, some literature can be misleading and/or in some cases there may not be sufficient information to credibly compare products. This Customer Bulletin provides factual, clarifying information which should allow for an objective comparison of Dyplast’s ISO-C1® with HiTherm’s HT-300 (each 2 lb/ft3 density).
Similar to Orex Carbon Footprint report (USA) - Final Version 1.1 (20)
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Medi9 is a new biocide technology that combines conventional biocides with a polymer backbone. This allows lower concentrations of biocides to be effective against microorganisms. Medi9 has been tested against various bacteria, fungi, and viruses according to European standards, showing effectiveness as a broad-spectrum sanitizer. It can be formulated into products for hand sanitization, hard surface cleaning, and disinfecting medical devices to target markets in healthcare, food production, and other industries.
Medi9 is an alcohol-free, chlorine-free, and triclosan-free sanitization system that kills 99.9% of germs, spores, viruses and bacteria. It is available in various forms like wipes, sprays, foams and fogging solutions. Medi9 is effective against bacteria, spores, fungi and viruses. Testing shows it achieves high log reductions of various pathogens in under 5 minutes, even under dirty conditions. Medi9 breaks down into non-toxic compounds and can be used in various areas like kitchens, hospitals, and transportation to support infection control.
Medi9 Product Guide Issue 01 - FROM integritex europe MAY 2015Andrew P. Robertson
This document provides information on Medi9, an alcohol-free hand and surface sanitizer. It discusses how Medi9 is more effective than alcohol-based sanitizers at killing germs like Norovirus and Clostridium difficile. Medi9 is proven to kill 99.9% of bacteria, spores, viruses and fungi, and provides residual protection for up to 45 minutes after application. The document provides information on Medi9's testing according to European standards and its effectiveness against various bacteria, spores, fungi and viruses.
The document introduces OREX processing and the development of its Generation 2 processors. It discusses the history and improvements of OREX processors from 2000 to present. Key points include: Generation 2 processors were developed starting in 2010, can process 180 kg per batch in two 6-hour steps of chemical then thermal oxidation, and have automated controls. Emissions are low levels of CO2, O2, and CO, while water effluent is virtually distilled water. Benefits over conventional waste handling include eliminating waste volume/costs and improving worker comfort/hygiene while reducing impacts to plant schedules and costs.
The document is a catalog from OREX, a company that produces single-use protective clothing for nuclear and industrial applications. It introduces their lineup of fabrics and products including coveralls, lab coats, booties and more. Their flagship product is the OREX Ultra coverall which uses a patented breathable fabric that provides unprecedented protection from radioactive contamination. The catalog describes the various product lines and their intended uses for low, moderate and high contamination environments. It aims to provide customers with the right protective clothing solution for any nuclear or industrial application.
Medi9 produces a range of sanitizing products including wipes, sprays, foams and foggers that kill viruses and bacteria. Their products can be used for sanitizing surfaces in both medical and non-medical settings. Medi9 offers small and bulk sized sanitizing products for personal use and for sanitizing large areas and equipment. Independent testing shows Medi9 products are effective against pathogens like Ebola, MRSA, and norovirus.
The document discusses Ebola virus, how it spreads, symptoms, and prevention methods. It describes Ebola as a virus that causes hemorrhagic fever and is spread through contact with infected bodily fluids. Symptoms include fever, vomiting, and bleeding, and the mortality rate is high. Prevention includes avoiding contact with infected individuals, properly handling and cooking meat from infected animals, and frequent handwashing. The document also outlines European standard EN14126 for classifying protective equipment based on resistance to biological hazards, and describes some protective clothing options from Indutex that meet the highest protection level.
Orex Carbon Footprint report (USA) - Final Version 1.1
1. Report
Final Version 1.1
Document Reference: ENE/0068-US/AP/03
To: John Steward
Eastern Technologies Inc.
215 Second Avenue
P.O. Box 409
Ashford, Alabama (AL) USA 36312
Date: 26th
October 2012
From: Dr Adrian Punt Dr Bryony Cunningham
Eden Nuclear and Environment SKM Enviros
Eden Nuclear and Environment Ltd SKM Enviros
www.eden-ne.co.uk www.enviros.com
Quantifying the Carbon
Footprint associated with
OREX®
and Textile Garment
use in the USA
3. Executive Summary
The decisive move over the last decade by the US nuclear industry from the use of
launderable garments to specialized single use OREX garments has been primarily
driven by the fact that launderable garments are woven and inherently contain thousands
of “holes” in the weave per square inch of fabric. Holes that on average are much larger
than the mean diameter of the radioactive particulate the garment is intended to protect
against. With each washing these holes get larger, and more numerous, thus increasing
the risk of radioactive particulate penetration. This report further supports the move away
from launderable garments by considering the environmental sustainability (in terms of
the life cycle carbon footprint) of protective garment use in the US nuclear industry by
comparing specialized single use OREX garments against the historical approach of use
of launderable textiles.
This assessment has been based on a detailed understanding of the supply and
processing of OREX®
garments from Eastern Technologies Inc. (ETI) who have created
and supply the only single use protective clothing that is specifically tested and certified to
offer radiological protection. The OREX garments and paired processing technology
provides both superior performance for the wearer and virtual elimination of solid waste.
The garment uses a polyvinyl alcohol (PVA) polymer, a dissolvable material, and has set
a new standard for radiation protection clothing within the US nuclear industry. Single
use OREX garments have been shown to offer numerous benefits, not just in terms of
radiological protection, but also in terms of cost, comfort and hygiene perception, and
supply logistics and waste minimization; this report also demonstrates that under the full
range of credible launderable garment use, OREX offers a more environmentally
sustainable option than a multi-use launderable one.
This assessment has considered the full life cycle of the garments from production and
distribution, processing (including, in the case of textiles, laundering after each use),
transportation and ultimately waste disposal needs. The report identifies that previous
work on this subject has not provided a fully comparative analysis between specialized
single use and launderable textiles. Key aspects such as transportation and waste
disposal requirements have previously been omitted and the technical operating aspects
of the specialized single use garments have not been accurately reflected in calculations.
The inputs, boundaries, assumptions and calculations associated with the assessment
process have been explained fully with the reporting unit of the study set as kg CO2 per
garment per use. It has been completed following US and international guidance and has
used well established and robust data sets to assess the life cycle carbon footprint. This
analysis allows for the manufacture, distribution and final disposal impacts of a garment to
be allocated to either the single use of an OREX garment, or spread throughout the
lifetime of multiple uses of a textile garment. A point for debate within the report is the
number of times that the launderable garment could be used prior to final disposal.
Although the maximum theoretical use / wash cycle number may be 100 times, this is
virtually never achieved in operational practice. Evidence collected associated with this
report would suggest that issues such as rejection due to residual contamination means
the re-use value is more likely to be between 25 to 50 times for launderable garments. To
ensure completeness in the approach the carbon footprint has been considered on a per
use basis, and the assessment has considered a range of reuse cycles for a launderable
textile.
The results show that the carbon footprint, whether for a single use OREX garment, or a
multiple use nylon one, given on a per use basis, are not significantly different. In fact, up
4. to 80 to 90 uses, the carbon footprint of a single use garment offers better environmental
performance compared to a nylon one.
5. CONTENTS
1 INTRODUCTION .....................................................................................................................1
1.1 BACKGROUND .....................................................................................................................1
1.2 AIM AND OBJECTIVES ..........................................................................................................2
1.3 STRUCTURE OF THIS REPORT ..............................................................................................2
2 REVIEW OF PREVIOUS WORK ............................................................................................3
3 OREX AND TEXTILE GARMENT LIFE CYCLES ..................................................................5
3.1 OREX GARMENT MANUFACTURE, TRANSPORT, PROCESSING AND DISPOSAL ........................5
3.2 TEXTILE GARMENT MANUFACTURE, TRANSPORT, LAUNDRY AND DISPOSAL............................6
3.3 SUMMARY COMPARISON......................................................................................................7
4 LIFE CYCLE ASSESSMENT METHODOLOGY ....................................................................9
4.1 BACKGROUND TO CARBON FOOTPRINTING ...........................................................................9
4.2 ASSESSMENT APPROACH AND INPUT PARAMETERS.............................................................10
4.3 ASSUMPTIONS AND INPUT VALUES .....................................................................................12
4.4 SUMMARY IMPACTS ...........................................................................................................15
5 CARBON FOOTPRINT RESULTS .......................................................................................17
5.1 OREX GARMENT CARBON FOOTPRINT...............................................................................17
5.2 TEXTILE GARMENT CARBON FOOTPRINT.............................................................................17
5.3 OREX AND TEXTILE COMPARISON.....................................................................................19
6 SUMMARY AND CONCLUSIONS........................................................................................20
APPENDIX 1 – REPORT AUTHORS..............................................................................................22
AUTHOR – DR ADRIAN PUNT – PHD, MSC, BSC (HONS), CRADP ................................................22
AUTHOR – DR BRYONY CUNNINGHAM – ENGD, MSC, BSC (HONS), AIEMA .................................23
6. Client Name: Eastern Technologies Inc.
Report Title: Quantifying the Carbon Footprint associated with OREX and Textile Garment use in the USA
Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 1
1 Introduction
This report considers the environmental sustainability (in terms of the life cycle carbon
footprint) of protective garment use in the US nuclear industry. It focuses on the
intercomparison of the carbon footprint of single use OREX garments, versus the historic
approach of the use of textile garments and their respective laundry and final disposal needs.
Although a preliminary assessment of the life cycle carbon footprint of single use OREX
garments verses a typical textile one has been made (see Chapter 2), this is subject to a
number of uncertainties. Addressing these uncertainties is a key aspect of the work reported
here.
This programme of work has been undertaken by the specialist nuclear industry consultancy
Eden Nuclear and Environment (Eden NE) in collaboration with the global leader in
environmental consultancy assessments and specialist in carbon footprint analysis, Sinclair
Knight Merz (SKM Enviros). Details of Eden NE and SKM Enviros and the key authors of this
report are provided in Appendix 1.
1.1 Background
Over the last decade there has been a paradigm shift in the US with a decisive move away
from launderable garments to specialized single use garments. The main driver is that
launderable garments are woven and inherently contain thousands of “holes” in the weave per
square inch of fabric. Holes that on average are much larger than the mean diameter of the
radioactive particulate the garment is intended to protect against. With each washing, these
holes get larger, and more numerous, thus increasing the risk of radioactive particulate
penetration. Although commercial nuclear laundry operators are capable of ‘decontaminating’
used protective clothing, not all the contamination is removed from the fabric. Some level of
residual contamination will remain in the garment and will be present during any subsequent
use by another worker. During heavy work conditions at many plants, perspiration can ‘wick’
residual contamination from the garments resulting in contamination of the skin of the wearer.
Textile garments that cannot be appropriately cleaned to some predetermined activity level
have to be rejected and dispositioned as radioactive waste.
Eastern Technologies Inc. (ETI) has created and supplies the only single use protective
clothing technology that offers proven radiological protection. The technology carries the
trademark OREX®
. The OREX garments and paired processing technology (see Chapter 3)
provides both superior performance for the wearer and virtual elimination of solid waste. This
‘Certified Soluble®
’ technology, which uses a polyvinyl alcohol (PVA) polymer, a dissolvable
material, has set a new standard for radiation protection clothing within the US nuclear industry
while also significantly reducing the solid radioactive waste that has to be disposed of.
Although single use OREX garments have been shown to offer numerous benefits, not just in
terms of radiological protection, but also in terms of cost, comfort and hygiene perception, and
supply logistics and waste minimization; the question remains as to whether a single use
garment represents a more environmentally sustainable option than a multi-use launderable
one.
With the international concern over global warming, a valuable metric to measure
environmental sustainability, is the carbon footprint of a particular product. For any such
assessment to be robust, it needs to consider the full life cycle of that product from production
and distribution, through processing (including, in the case of textiles, laundering following
each use), and ultimately waste disposal needs. Such assessments need to include respective
7. Client Name: Eastern Technologies Inc.
Report Title: Quantifying the Carbon Footprint associated with OREX and Textile Garment use in the USA
Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 2
transportation impacts, and how the carbon implications of manufacture, processing and final
waste disposal are attributed to the number of times that particular product is used. Most
importantly any intercomparison needs to be undertaken on a like for like basis, while also
ensuring that key process differences are accounted for.
1.2 Aim and Objectives
To date, there has been limited reporting of carbon footprint comparisons between single use
OREX garments and launderable textiles (see Chapter 2 for details). The aim of this study is to
therefore provide an underpinned and robust comparison of the carbon footprint of single use
OREX garments versus those of launderable textiles. The specific objectives are to ensure
that the full life cycle of each product is addressed – from manufacture through to final waste
disposal, using robust input data and ensuring the process is reported in a clear and auditable
way. This will be undertaken in a number of core steps:
Step One: Define the goal of the study and build the process description of the product’s
life cycle, from raw materials to disposal, including material and energy use;
Step Two: Confirm boundaries and perform high-level footprint calculations to help
prioritize efforts (at this point the process description completed in Step One is updated
with new information);
Step Three: Collect data on material amounts, activities, and emission factors across all
life cycle stages; and,
Step Four: Calculate the product footprint and report in a clear and informative way.
1.3 Structure of this Report
The following sections of this report describe the carbon footprint assessment undertaken and
results of this study, specifically:
Chapter 2 summarizes previous work and identifies data gaps;
The life cycle, in terms of energy and material use of an OREX garment compared to a
textile one, is discussed in Chapter 3;
Background to carbon footprint life cycle assessment and the approach adopted here is
discussed in Chapter 4 along with input parameters and assumptions made.
Chapter 5 sets out the results of this study and summary and conclusions are given in
Chapter 6.
In addition, details of the authors of this report and of the Eden NE and SKM Enviros
organizations are provided in Appendix 1.
8. Client Name: Eastern Technologies Inc.
Report Title: Quantifying the Carbon Footprint associated with OREX and Textile Garment use in the USA
Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 3
2 Review of Previous Work
As noted in Chapter 1, there has to date been limited comparison of the carbon footprint of
OREX garments compared to textile ones. Some previous work was undertaken by Exponent
on behalf of UniTech Services laundry group to produce a life cycle inventory (LCI)
comparison of radiological protective garments (2010)1
. A review of this study is described
below.
A review of the Exponent work by Cournoyer, Wannigman and Dodge (2011) “Pollution
Prevention Benefits of Dissolvable Protective Clothing”2
observed that, although the Exponent
report includes energy use associated with OREX processing, it then assumed that the end-of-
life final waste disposal needs of OREX and textile garments were the same. Hence it failed to
recognize that after OREX processing, the volume of secondary waste associated with a
single use garment is significantly less than a launderable, in fact it is virtually zero, and hence
the transport and final waste disposal needs for an OREX garment are many times lower than
that of a textile garment. Overall, Cournoyer described the Exponent report as “...incomplete
and inconclusive”. Further review points assessed by the expert authors of this report are
described below.
The Exponent study was based on the use of launderable nylon garments that are relatively
lightweight (c. 0.4 kg per coverall). It was assumed that an OREX garment weighs 35% less
than a launderable textile garment. However, Cournoyer points out that in comparison to a
heavier, poly-cotton garment (c. 1 kg per coverall), OREX garments weigh around 70% less
than a launderable textile (a typical OREX coverall weights 0.25 kg). However, the Exponent
work does make the reasonable assumption that the most typical coverall used in the US is
nylon and this approach has been adopted in this report.
In addition, the Exponent report has not included transportation elements within their
calculation. The transport to and from laundry operations or for secondary waste management
and disposal have the potential to be substantial and would appear to be a critical factor that
was not addressed. It is also important to note that not only are OREX garments lighter, but
when packaged are smaller and can be transported more efficiently. During outage, nuclear
power stations that have transitioned to OREX report over a 90% reduction in transport needs
compared to the transportation requirements for reusable garments since such clothing must
be shipped for laundering and returned multiple times during outage periods. This was not
considered in the Exponent report.
Exponent based their assessment on the assumption that a textile garment can be used and
laundered 100 times. This number may be a theoretical maximum quoted by the manufacturer,
but in reality the number of uses will be significantly less (prospectively between 25 to 50
times), particularly where textile garments are rejected due to residual contamination and
subsequently dispositioned as waste. Under any typical regime of use the Exponent study will
therefore underestimate the carbon impact per wear per textile garment. It is interesting to note
1
Exponent (2010) “Life Cycle Inventory Comparison of Radiological Protective Garments” prepared for
UniTech Services Group Limited, available at:
http://www.arta1.com/cms/uploads/UniTech%20Shares%20Life%20Cycle%20Evaluation%20of%20Reu
sable%20Protective%20Work%20Wear.2010.pdf
2
Cournoyer, M.E.; Wanningman, D.L. and Dodge, R.L. (2011) “Pollution Benefits of Dissolvable
Protective Clothing” in Proceedings of the ASME 2011 14
th
International Conference on Environmental
Remediation and Radioactive Waste Management ICEM2011 September 25-29, 2011, Reims, France
9. Client Name: Eastern Technologies Inc.
Report Title: Quantifying the Carbon Footprint associated with OREX and Textile Garment use in the USA
Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 4
that the Exponent study used a report by Franklin Associates, 19933
that quoted a figure of 40
uses (for a woman’s blouse) and 75 uses (for a hospital garment). They then assumed 100
wears for a protective coverall. It must also be noted that a number of sources of data in the
Franklin Associates report date back to the 1970s and may no longer be valid.
It is important to note that the source data employed by Exponent in their study to calculate the
impact of OREX material production was based on polyethylene terephthalate (PET) data from
the Franklin report and polypropylene (PPE) data from work by Ponder and Overcash (2007)4
and Ponder (2009)5
. However, the OREX ‘Certified Soluble®
’ technology uses the PVA
polymer, rather than PET or PPE, with a seemingly lower carbon impact for material
production compared to these.
Exponent assumed that each batch of OREX garments processed only treated 240 garments.
However, the MB-600 processor developed by OREX at their Alabama, USA, facility operates
on a batch basis with each batch consisting of 600 lbs (c. 270 kg), dry weight, of OREX
material. Based on a typical coverall weight of 0.25 kg each, this equates to approximately
1,000 OREX garments that can be processed in a single batch. It is therefore likely that
Exponent have overestimated the energy use of OREX processing (on a per garment basis)
by a factor of four. Although Exponent quoted totals for energy use associated with
manufacture and processing / laundering of both OREX and textile garments, it is not clear
how these values have been derived and further review is therefore difficult.
The Exponent work provides a useful starting point, but as discussed above does not provide
a fully comparative analysis between OREX and launderable textiles. It also omits key aspects
of the life cycle assessment, such as transportation and lacks the detailed understanding of
the specialized OREX technology and subsequent waste disposal requirements needed for a
proper assessment.
3
Franklin Associates, 1993, file available at: http://www.fibersource.com/f-tutor/lca-page.htm Life Cycle
Analysis (LCA): Woman’s knit polyester blouse. Resource and environmental profile analysis of a
manufactured apparel product. Final report. Prepared for American Fiber Manufacturers Association
4
Ponder C.S. and Overcash N. (2007) LCA of healthcare garments. Presented at In LCA/LCM2007,
Portland, Oregon, October 4 http://lcacenter.org/inlca2007/presentations/75.pdf
5
Ponder, C.S. (2009) Life cycle inventory analysis of medical textiles and their prevention of nosocomial
infections. Dissertation. North Carolina State University, 2009-08-11. Reference is unavailable, but
content is expected to be the same as the 2007 presentation referenced above.
10. Client Name: Eastern Technologies Inc.
Report Title: Quantifying the Carbon Footprint associated with OREX and Textile Garment use in the USA
Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 5
3 OREX and Textile Garment Life Cycles
The process descriptions given in this chapter aim to describe the key stages in the life cycle
of both a single use OREX garment and a multi-use textile (nylon) garment and provide a more
definitive description of the OREX process than considered in earlier studies.
3.1 OREX Garment Manufacture, Transport, Processing and
Disposal
The range of OREX protective clothing has been designed specifically for the nuclear industry
in the USA and globally. The innovative nature of the OREX technology has meant that the
company has grown rapidly, with 70% of the US commercial nuclear fleet making the transition
away from reusable garments to OREX protective clothing in the last six years with significant
company growth each year since its establishment in 2001. Details of OREX garment
manufacture and distribution, processing and final waste disposal are discussed below.
All OREX products are single use, and as noted before, are based on a PVA polymer,
although a small proportion of elastic, hook and loop closure and zipper material is present
(typically about 15 g per garment, around 6% in terms of mass). An OREX Original coverall
weights 0.25 kg and a full dress-out about 0.3 kg.
The PVA material and the garments are produced in China and shipped from Shanghai to the
USA, a sea freight distance of just over 10,000 nautical miles. 41,000 OREX garments are
packaged within a single 40 ft ocean freight container and typically 7,000 containers are
transported per ship. Freight containers are then transported by highway an additional 300
miles to the OREX distribution warehouse. The average distance between the distribution
warehouse and nuclear facilities using OREX is currently approximately 800 miles.
Used OREX garments are then transported by road to the processing facility in Ashford,
Alabama (an average road distance of about 835 miles). A key point to note is that used
OREX garments can be easily compressed and return shipments can achieve a high
packaging efficiency (typically 20,000 garments per sealand container. Unlike textile garments
that need to be laundered and then returned to service promptly, used OREX can be stored on
site until a container is full. This means that used OREX shipping movements off-site can be
10% or less than that associated with a site using launderable garments (which needs much
more regular shipments to maintain sufficient garment stocks).
At Ashford, ETI currently operates two MB-600 processors for the dissolution of OREX. OREX
is processed on a batch basis, with each batch consisting of 270 kg of OREX (dry weight),
where a batch is equivalent to just over 1,000 coveralls. Both processors operate at full
capacity and the dissolution process takes about 5 to 6 hours.
Each MB-600 processor batch uses 5,300 litres of water where the water is heated to and then
maintained at between 100 and 120ºC under a pressure of around 1.05 kg cm2
to convert the
PVA items to liquid form. The MB-600 uses a gas-powered pre-heater (energy use equivalent
to 4 hours of power consumption at 30 kW) followed by an 80 kW final heat-up phase (which is
three to four hours long). When not in heat up mode (for the last two hours), power
consumption is around 6 kW. The typical energy requirement to process each coverall as
assessed here is just over 600 kJ.
The effluent generated from the dissolution phase is initially a 5% solution of PVA. The second
step of the treatment process chemically converts the PVA solution to a more suitable form for
subsequent biodegradation within the local municipal waste water treatment works. The
11. Client Name: Eastern Technologies Inc.
Report Title: Quantifying the Carbon Footprint associated with OREX and Textile Garment use in the USA
Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 6
process solubilises the PVA materials and subsequently converts the materials to a dilute
solution of organic constituents through a Fenton oxidation reaction. This step uses a catalyst
with heat to produce a dilute solution of weak organic acids, mostly acetic and formic acids.
This effluent is then neutralised, tested, filtered and then discharged to the local municipal
waste water treatment works (equivalent to about 5 litres per garment).
All PVA material is 100% dissolved in this process. Some limited components of the protective
clothing, as noted above, are made of non-PVA materials that contribute to solid secondary
waste products. These components, which for a typical coverall equate to about 6% of the
original garment mass, are contained at the bottom of the processor (94% mass reduction).
This secondary waste is further volume-reduced (at a separate authorized facility 450 miles
away from Ashford) through a high-temperature thermal treatment (pyrolysis) process which
achieves an approximate 98% mass reduction of this residual material. The final waste, at less
than 0.01% of the original mass is then transported an additional 1,900 miles (by road) for
landfill disposal in Clive, Utah.
Based on an annual throughput of in excess of 300,000 kg of OREX material, the Ashford
facility generates about 5,000 spent polyester yarn effluent filter cartridges (around 2,000 kg).
These are compacted and then dispositioned to landfill in Utah. Once compacted the annual
volume disposed is around 2 m3
. On a per garment basis, the secondary filter waste generated
is very small (about 1 g of spent filter cartridge per garment) and transportation and disposal
needs are minimal.
3.2 Textile Garment Manufacture, Transport, Laundry and Disposal
Although heavier poly-cotton coveralls may be used, this study focuses on the more typical
nylon coverall used in the USA. As part of this study we have weighed a US size 2X (median
size) nylon coverall which gave a result of 0.56 kg (slightly heavier than the Exponent results
of 0.41 kg). However, to try and ensure, where appropriate, consistency with early studies, the
lighter 0.41 kg weight of a nylon coverall has been used (which will slightly under predict the
carbon emissions from the nylon garment with respect to a median sized garment).
Unlike OREX garments, where there is a single manufacturing point and distribution route,
nylon coveralls may be manufactured in a variety of countries and enter the USA via a number
of different routes, hence a greater number of assumptions have to be made here. Based on
shipping documents obtained, we have assumed manufacture near Shanghai, China and sea
freight to the USA via the Dominican Republic, a sea freight distance of just under 11,000
nautical miles. As with OREX distribution we have assumed 7,000 freight containers per ship;
however, due to the greater bulk of textile garments compared to OREX garments, we have
assumed that 20,000 textile garments (as opposed to 41,000 OREX garments) are included
within any one 40 ft freight container.
To ensure consistency wherever possible, we have assumed the same road transport
distances from port of entry to distribution warehouse and from this to sites, noting though that
each road shipment of textile garments includes about half the number of garments compared
to that of OREX.
It is important to note that there are multiple commercial laundry sites servicing the US nuclear
industry, our assessment has therefore assumed that the median distance (one way) from a
site to a laundry is 350 miles. This will obviously vary on a site by site basis, but typically
ranges from 10 to 800 miles. However, to maintain an operational stock of textile garments,
laundry shipments have to be made on a much more frequent basis compared to the
occasional shipments of used OREX garments for processing. Based on common industry
12. Client Name: Eastern Technologies Inc.
Report Title: Quantifying the Carbon Footprint associated with OREX and Textile Garment use in the USA
Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 7
knowledge, this equates to around 10 times the transport needs compared to OREX where a
typical shipment for laundering only carries around 2,000 garments.
Based on the energy use of textile laundry operations that are maintained at the Ashford
facility for clients that have not yet fully transitioned to OREX, a value of 700 kJ per garment
per wash and about 1,100 kJ per dry cycle (about 1,800 kJ total per garment) has been
derived with about 7.5 litres of waste laundry water per kg of garment laundered discharged to
the municipal water treatment system. No allowance has been made for laundry detergent use
in our assessment. Although waste water treatment filters (and other secondary waste, for
example from lint accumulation from the dryers) will be generated, these have been assumed
to be trivial on a per garment per wash basis and have not been considered further.
A small number of garments may retain residual levels of activity after washing and hence may
need to be rewashed and again dried. We have assumed that 5% of garments go through the
wash-dry cycle twice before being returned to a site for use6
.
At the end of a textile garment’s life, whether dispositioned from a site, or from a laundry, we
have assumed landfill disposal comparable to that for the final waste residues from the OREX
process, with a median road transport distance of again 1,400 miles (assuming 5,000 trashed
garments per container). No processes of volume reduction, whether via compaction or
thermal processes, have been considered prior to disposal of textile garments.
A big question remains as to the number of uses that can be reasonably achieved with a textile
garment (particularly a relatively light weight nylon one). Although the maximum theoretical
use / wash cycle number may be 100 times, this is virtually never achieved in operational
practice. Garment damage and issues of residual contamination mean that the typical number
of uses may be as little as a quarter of this. To avoid any basis in our assessment from a
presumed number of uses, we have performed calculations based on a wide number of uses.
This approach is described further in the next chapter.
3.3 Summary Comparison
A summary comparison of the similarities and differences between OREX and textile garments
pertinent to this carbon footprint assessment is given below:
Material and Mass – OREX material is a PVA polymer, textiles coveralls are typically
nylon. A median sized OREX Original weigh 0.25 kg. An equivalent nylon one weighs at
least 0.4 kg (a 2X size was weighed at 0.56 kg).
Point of Manufacture and Distribution – OREX PVA material and garments are
manufactured in China and shipped by sea to the US and then by road to a distribution
center and from here to user sites. Transport distances for textile garments are probably
similar (although more variable). However, due to the packaged size and weight of an
OREX garment, approximately twice the number of new OREX garments can be shipped
per container compared to nylon ones.
Transport for Processing and Laundry – OREX garments are used once then
consigned for processing. Currently there is one OREX processing site in the USA,
located in Ashford, Alabama, and the average transport distance from sites using OREX
6
Based on laundry data from 7 nuclear power plants prior to transition to OREX, the percentage of
garments requiring two washes typically ranged from 4 to 5%, but in one instance was over 14% (mean
of 5.7%). A value of 5% was therefore taken as realistic estimated for rewash requirement.
13. Client Name: Eastern Technologies Inc.
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Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 8
to this facility is 835 miles. Laundry facilities can be closer (we have assumed 350 miles);
however, used OREX can be stored on site while launderables have to be shipped and
returned for reuse on a much more regular basis. As a result, off-site shipments of OREX
can be as low as 10% of that of launderables.
Processing and Laundry – OREX processing requires about 600 kJ of energy per
coverall. Laundry and drying of a 0.4 kg nylon garment requires about 1,800 kJ energy
(three times the amount). OREX processing achieves around a 94% reduction in
garment mass, the residual (non-dissolvable components) then becomes secondary
waste and hence this significantly reduces onward transport and disposal needs
compared to rejected, damaged or worn out textile garments.
Secondary Waste Transport, Treatment and Disposal – Secondary waste from OREX
processing is then further volume reduced (by thermal treatment) to achieve a
subsequent reduction in secondary waste mass of an additional 98% such that the final
waste form is of the order of 1:10,000 of the original garment mass (that is, disposal of
one nylon coverall is equivalent to that of over 15,000 OREX garments post processing).
Hence, although additional energy and transport needs arise with OREX secondary
waste processing, significantly reduced volumes of waste are transported and finally
disposed (to landfill) on a “per use” basis.
14. Client Name: Eastern Technologies Inc.
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Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 9
4 Life Cycle Assessment Methodology
The assessment approach adopted in this work is described in this chapter and the results of
the study provided in Chapter 5.
4.1 Background to Carbon Footprinting
Life Cycle Assessment (LCA) is used to evaluate the environmental impact from products,
using a life cycle perspective. The ongoing discussion about carbon labeling has resulted in
the development of specialized standards and guidelines, specifically designed for calculating
the carbon footprint of products. The World Resources Institute (WRI) and World Business
Council for Sustainable Development (WBCSD) have created what is considered today as the
de-facto standard for disclosing carbon footprints7
.
In the US, the Energy Information Administration (EIA)8
and the Environmental Protection
Agency (EPA)9
have both produced a set of guidelines and tools. In addition, the US
Department of Energy (DoE) is supporting the voluntary disclosure of carbon emissions via
their 1605(b) Program10
.
In the UK, PAS205011
(2011) is a specification developed for assessing the life cycle
greenhouse gas (GHG) emissions (such as carbon dioxide, CO2) of goods and services. The
PAS2050 is to a large extent based on the LCA standards12
, but in some areas it is more
specific in how to calculate the carbon footprint.
To ensure conformity with the standards and guidelines in the US (and drawing on additional
guidelines from the UK); a review of applicable guidelines and standards highlighted that the
assessment should demonstrate the following:
Relevance: select GHG sources, carbon storage, data and methods appropriate to the
assessment of the GHG emissions arising from products;
Completeness: include all specified GHG emissions and storage that provide a material
contribution to the assessment of GHG emissions arising from products;
Consistency: enable meaningful comparisons in GHG-related information; and,
Accuracy: Reduce bias and uncertainties as far as practicable; and where the results of
life cycle GHG emissions assessment are carried out in accordance with relevant
guidance and communicated to third parties; the organization communicating the results
shall disclose GHG emissions-related information sufficient to allow such third parties to
make associated decisions with confidence.
7
See: http://www.ghgprotocol.org/ for details
8
See: http://www.eia.gov/oiaf/1605/reporting_tools.html for further details
9
See: http://www.epa.gov/ttn/chief/efpac/abefpac.html for further details
10
See: http://energy.gov/articles/doe-strengthens-public-registry-track-greenhouse-gas-emissions for
further details
11
British Standards Institute, PAS2050:2011, Specification for the measurement of the embodied green
house gas emissions in products and services, (updated from a 2008 version) available at:
http://www.bsigroup.com/upload/Standards%20&%20Publications/Energy/PAS2050.pdf
12
British Standards Institute, BS EN ISO 14040: 2006, Environmental Management – Life cycle
assessment – requirements and guidelines, 2006.
15. Client Name: Eastern Technologies Inc.
Report Title: Quantifying the Carbon Footprint associated with OREX and Textile Garment use in the USA
Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 10
4.2 Assessment Approach and Input Parameters
The assessment approach set out below describes how the study has defined the reporting
unit and boundaries of the assessment and the calculation method used. To provide a readily
accessible assessment, the approach documented here is limited to standard coveralls
equivalent to an OREX Original and a nylon textile one. However, the results can be directly
scaled to a full dress-out.
4.2.1 Reporting Unit
The reporting unit of this study is kg CO2 per garment per use. This approach allows for the
manufacture, distribution and final disposal impacts of a garment to be allocated to either the
single use of an OREX garment, or spread throughout the lifetime of multiple uses of a textile
garment (noting that the number of uses achieved can be debated). With the addition of
energy requirements for OREX processing, or of laundering a textile garment, a direct
comparison, on a per use per garment basis, is therefore possible (noting that this needs to
consider a range of use / laundry cycles for a textile garment).
4.2.2 Establishing the Boundaries of the Footprint
This study has been completed within the context of protective garment use within the USA
nuclear industry and considers raw materials, garment manufacture, transportation loads and
distances, laundering and treatment requirements and end of life waste disposal. A key factor
in this comparison is the number of times that a textile garment is laundered and reused. The
impact of manufacturing the garment (and final disposal) can then be divided by the number of
garment uses; whereas for a single use garment (whether OREX material or other disposable)
the carbon footprint of manufacture and disposal are borne by that single use of the garment.
The number of times that a launderable garment is reused is not a definitive amount and will
vary based on activities during each use and the potential for residual contamination where the
garment has to be rejected and dispositioned as waste. Our approach here has therefore
considered the carbon footprint on a per use basis, where the assessment considers a range
of reuse cycles for a launderable textile.
As noted in Chapter 2, transportation was omitted from previous studies. Transportation
includes not only distribution from the country of manufacture to the USA, but also the
distribution to the user facility or site. It also needs to consider distance between the site and
the laundry facility or OREX processing facility and finally, transportation and any processing
of secondary waste prior to final disposal. These metrics can vary on a site by site basis and
for this reason average values that are likely to be indicative of actual US Nuclear Power
Plants experiences have been used.
The carbon footprint guidance discussed previously highlights the need to make clear which
materials and which processes are included within any analysis (as not all inputs will be
relevant or available). This process of definition is referred to as the “system boundary”. The
selection of the system boundary must be consistent with the goal of the study. Table 1 below
shows the data that was included and excluded in the analysis undertaken here based on the
process descriptions given in Chapter 3. Assumptions and input parameters are then
discussed in Section 4.3.
16. Client Name: Eastern Technologies Inc.
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Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 11
Table 1: System Boundary
Garment Data Included Data Excluded
OREX
Garment
Garment manufacture (includes raw
material manufacture of PVA)
Transportation from country of
manufacture to distribution; distribution
to sites; sites to OREX processor;
secondary waste from processor for
onward treatment and disposal
Treatment process (including energy,
water use and treatment; and filter use
associated with the process)
Secondary waste disposal with volume
reduction via thermal treatment and
landfill disposal of the thermally treated
residue
Treatment chemicals and neutralization
acids used during OREX processing
Land transportation from place of
manufacture to distribution port
PE film packaging for each garment
(when new) – primary packaging
Cardboard carton / secondary packaging
of garments
Wood pallets used during transport
Impact from manufacture, maintenance
and disposal of OREX processing
equipment
Fire retardant or other specialized
coatings
Textile
Garment
Garment manufacture (includes raw
material manufacture of nylon)
Transportation from country of
manufacture to distribution; distribution
to sites; sites to laundry (and back); and
for final waste disposal
Textile laundering (including washing
and drying assuming a 2% need to re-
wash and dry in instances where a
single wash fails to achieve a
“radiologically clean” garment);
Trashed and rejected garment disposal
to landfill
Land transportation from place of
manufacture to distribution port
PE film packaging for each garment –
primary packaging
Cardboard carton / secondary packaging
of garments
Wood pallets used during transport
Washing agents used in the laundry
process
Lint collected from drying process, filters
and secondary waste disposal needs
Impact from manufacture, maintenance
and disposal of washing and drying
machines
Fire retardant of other specialized
coatings
4.2.3 Calculations
As recommended by guidance described in Section 4.1, the carbon footprint for materials and
energy use has been completed using the Intergovernmental Panel on Climate Change (IPCC)
2007 carbon impacts based on a 100 year time frame that present the resulting data as kg
CO2 equivalent. The analysis has been completed within a bespoke MS Excel sheet with the
primary data as described in Section 4.3.1. The emission factors used have been obtained
from a variety of sources, but principally from the EcoInvent database (Version 2.2)13
. The
13
See: http://www.ecoinvent.org/home/ EcoInvent database – the world’s leading database with
consistent and transparent, up-to-date LCI data. With more than 4,000 LCI datasets in the areas of
agriculture, energy supply, transport, biofuels and biomaterials, bulk and speciality chemicals,
construction materials, packaging materials, basic and precious metals, metals processing, Information
Communication Technology and electronics as well as waste treatment, it is one of the most
comprehensive international LCI databases. The high-quality generic LCI datasets are based on
17. Client Name: Eastern Technologies Inc.
Report Title: Quantifying the Carbon Footprint associated with OREX and Textile Garment use in the USA
Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 12
emission factors have been used to reflect USA operating requirements (for example,
emission factors for electricity have been taken to suit the USA infrastructure impacts) and are
given in Section 4.3.2. SimaPro (Version 7)14
(the most widely used life cycle assessment
software) was then used to obtain the emission factors15
and used to double check the
calculations completed in the bespoke MS Excel sheet to ensure accuracy.
The input data that was collected has then been adjusted to a per garment basis, based on
understanding the number of garments involved within each process stage (for example the
number (or mass) of garments in a transportation container, or the number (or mass)
laundered per cycle or OREX processed per batch). The material / energy use input data has
then been multiplied by the emission factors that were identified. The relative areas of the
output (for example production and final waste disposal) have then been divided by the
number of uses applicable to the garment type (multiple use for launderable garments and
single use for an OREX garment) to give the carbon (C) impact per garment per use as
follows:
Where:
C M&D = carbon impact of manufacture and distribution (including transportation);
C L&P = carbon impact of laundering a textile garment or processing an OREX
garment (including transportation);
C P&D = carbon impact of secondary waste processing and disposal (including
transportation);
No. = number of uses (noting that for an OREX garment this is always one use).
Considering the uncertainty associated with the number of times a textile garment is used,
these calculations have been repeated assuming that the number of uses of a textile garment
varies from between 1 and 100 times. It is not suggested that either of these two extremes is
likely (as stated the most likely range of number of uses of a textile garment is from 25 to 50
times). Nevertheless, this approach accounts for the uncertainty in number of textile garment
uses and identifies the point (in terms of number of uses) where the per use life cycle carbon
emissions of a textile garment exceed that of a single use OREX garment. This comparison is
plotted graphically and discussed in Chapter 5.
4.3 Assumptions and Input Values
Detailed discussions and data gathering has been undertaken by the authors of this report with
support from ETI with input from large-scale, non-nuclear industrial laundering organizations
and input from nuclear site laundry facilities to quantify the input data needed. The material
and energy needs and associated assumptions and rationale associated with OREX and
textile garments are given in Table 2. As noted above, the final carbon impact results, when
given on a per use basis, are clearly governed by the number of uses considered. The input
industrial data and have been compiled by internationally renowned research institutes and LCA
consultants.
14
See: http://www.pre-sustainability.com/content/simapro-lca-software
15
Measure of the average amount of a specific pollutant or material discharged into the atmosphere by
a specific process, fuel, equipment, or source. It is expressed as number of pounds (or kilograms) of
particulate per ton (or metric ton) of the material or fuel.
18. Client Name: Eastern Technologies Inc.
Report Title: Quantifying the Carbon Footprint associated with OREX and Textile Garment use in the USA
Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 13
data provided in Table 2 is therefore limited to a ‘per garment’ basis and the results ‘per use’
are described in Chapter 5.
Table 2: Life cycle input Parameters for an OREX and a textile coverall
Garment OREX Coverall Textile Coverall
1. Number of uses One Assessed from 1 to 100 times,
noting that this is most typically
between 25 and 50 times
2. Material and
weight
0.25 kg consisting of a PVA
polymer material (OREX Original)
0.411 kg consisting of nylon
material (larger garments will
weigh more, for example a 2X size
weighs 0.56 kg)
3. Place of
manufacture
China China
4. Transportation
associated with
distribution
Sea freight distance of 10,350
Nautical Miles (assessed as one
way) – 19,714 km
41,000 OREX garments per 40 ft
container and 7,000 containers
per ship
Road transport (40ft container)
distance from port to distribution
warehouse of 300 miles (483 km)
and from here to user sites of 800
miles (1,288 km). Assumes return
trip of truck without load).
Sea freight distance of 10,645
Nautical Miles (transport via
Dominican Republic) (assessed as
one way) – 18,840 km
20,000 nylon garments per 40 ft
container and 7,000 containers
per ship
Road transport (40ft container)
distance from port to distribution
warehouse of 300 miles (483 km)
and from here to user sites of 800
miles (1,288 km). Assumes return
trip of truck without load).
5. Transportation
needs associated
with OREX
processing and
textile laundering
Assumes 20,000 OREX coveralls
per shipment
Road transport distance of 835
miles to Ashford processor (1,345
km). Assumes return trip of truck
without load.
Assumes 2,000 nylon coveralls
per shipment
Road transport distance of 350
miles (800 km) to a laundry.
Assumes return trip of truck with
laundered garment load.
6. Energy
requirements
associated with
OREX processing
and textile
laundering
600 kJ energy requirement per
garment associated with OREX
dissolution
5 liters of waste water per garment
discharged to municipal waste
water treatment works
Treatment chemicals used (100-
150 kg per load)
94% mass reduction achieved, 6%
(15 g) on non-dissolvable
components become secondary
waste
1 g of polyester yarn filter
generated per garment processed
700 kJ per wash and 1,800 kJ per
dry cycle per garment associated
with laundry
3 liters of waste water per garment
discharged to municipal waste
water treatment works
19. Client Name: Eastern Technologies Inc.
Report Title: Quantifying the Carbon Footprint associated with OREX and Textile Garment use in the USA
Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 14
Garment OREX Coverall Textile Coverall
7. Transportation of
OREX secondary
waste for
treatment (thermal
treatment)
Road transportation distance from
Ashford, AL, of 450 miles (723 km)
for thermal treatment (assumes
return trip of truck without load).
Assumes residuals from 10 times
the original number of garments
stated in Point 4 per shipment
Not applicable
8. Energy
requirements for
secondary waste
treatment
Based on energy use of
incineration
Assumes 98% mass reduction
achieved
Not applicable
9. Transportation for
final disposal
Road transportation (40ft
container) from secondary waste
treatment site to Utah for disposal
of 1,875 miles (3,018 km).
Assumes return trip of truck
without load.
Road transportation (40ft
container) from sites to Utah for
disposal of 1,400 miles (2,254
km). Assumes return trip of truck
without load.
10. Energy
requirements for
final disposal
Based on landfill, but accounting
for the massive volume reduction
achieved value per garment (or
rather remains of) disposed
Based on landfill, but assuming no
volume reduction per garment
disposed
As stated in Section 4.2.3 the carbon footprint for materials and energy use has been
completed using the Intergovernmental Panel on Climate Change (IPCC) 200716
carbon
impacts based on a 100 year time frame that present the resulting data as a kg CO2
equivalent17
. For the majority of inputs this was possible (used for all materials and activities
apart from PVA) using the EcoInvent database.
There is some research available on the carbon emissions from the production of PVA that
has been consulted, however as noted above, there are not definitive values given in the
EcoInvent database, therefore some uncertainty associated with the emission factor
associated with the manufacture of the OREX material is unavoidable. However, PVA is a
water-soluble polymer made by hydrolysis of a polyvinyl ester (such as polyvinyl acetate) for
which data is available. Dissertations and publications were therefore researched to identify
likely emission factors applicable to PVA. One dissertation from Utrecht University
(Netherlands) was identified detailing gross energy requirements and gross CO2 emissions for
products from the organic chemical industry18
. This paper gives the carbon emission factor for
polyvinyl acetate (one process down from PVA) as 2,060 kg CO2 per metric tonne (1,000 kg)
of product, which equates to 2.06 kg CO2 per kg of material. This figure was benchmarked
against other polyvinyl products (such as polyvinyl chloride) contained within EcoInvent
databases in SimaPro, which gave a comparable or lower level of emission. An additional
16
http://www.ipcc.ch/index.htm
17
Global-warming potential (GWP) is a relative measure of how much heat a greenhouse gas traps in
the atmosphere. It compares the amount of heat trapped by a certain mass of the gas in question to the
amount of heat trapped by a similar mass of carbon dioxide. A GWP is calculated over a specific time
interval, commonly 20, 100 or 500 years. CO2 equivalent is a measure for describing how much global
warming a given type and amount of greenhouse gas may cause, using the functionally equivalent
amount or concentration of carbon dioxide (CO2) as the reference.
18
Jochem, E Fraunhofer for Systems and Innovation Research, available at: http://igitur-
archive.library.uu.nl/dissertations/1894529/c4.pdf
20. Client Name: Eastern Technologies Inc.
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Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 15
source of information, Environmental Assessment of Bio-Based Polymers and Natural Fibers19
provided an emission factor of 1,730 kg CO2 per metric tonne of PVA product, which equates
to 1.73 kg CO2 per kg of material. However, the “bio-based” nature of the material used in this
analysis would suggest that this would likely be an underestimation, so despite it being an
appropriate material it was not used and the more conservative (worst-case) value of 2.06 kg
CO2 per kg was seen as more representative (and was larger than the other values identified
in the EcoInvent databases by about 0.05 kg CO2 per kg or more).
As noted other carbon equivalent emission factors have been derived from the well-
established EcoInvent database within SimaPro software. The values used in this assessment
are given in Table 3 below:
Table 3: Carbon Equivalent Emission factors
Garment
Carbon Equivalent Emission Factors (kg CO2)
OREX Coverall Textile Coverall
Material 2.06 per kg PVA 9.22 per kg nylon
Road transportation
(per shipment)
1.12 per km for 20-28 tonne truck with load
0.74 per km for 20-28 tonne truck without load
Sea freight (per ship) 10.7 per km
Washing and drying
process
Not applicable 0.000206 per kJ electricity used
OREX processing 0.000206 per kJ electricity used
1 to 1.5 per kg treatment chemicals
Not applicable
Waste water
treatment
0.000324 per litre discharged
Filter use 19.6 per kg Not applicable
Secondary waste
(thermal treatment)
1.4 per kg Not applicable
Disposal to landfill 0.000557 per kg disposed to landfill
4.4 Summary Impacts
Production of nylon has a carbon footprint of around 4.5 times that of PVA per unit weight, and
at a minimum a nylon garment weighs over 1.6 times that of an OREX garment. As a
consequence the carbon footprint of producing a nylon garment is therefore over 7 times that
of an OREX garment.
Our assessment has assumed that transportation distances from the place of manufacture to
site of use are broadly similar, but that twice the number of OREX garments can be
transported per freight container compared to nylon garments. On a per garment basis, the
carbon footprint of transporting a new nylon garment is therefore about twice that of a new
OREX one.
19
Patel, M; Bastioli, C; Marini, L; Wurdinger, E Encyclopedia “Biopolymers”, 2003 Vol.10, pp. 409-452.
21. Client Name: Eastern Technologies Inc.
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The energy requirements associated with processing an OREX garment are about one-third of
that of washing and drying a textile garment (which is incurred on a per use basis). However, a
key point is that transportation needs can be ten times lower when using OREX garments.
OREX processing achieves a 94% reduction in mass, thermal treatment achieves a 98%
reduction in mass of the remaining residuals. As a consequence, final transportation and
waste disposal requirements of OREX garments are significantly less (0.01%) than that of
launderable garments.
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5 Carbon Footprint Results
Carbon footprint results (kg CO2) determined in this study are presented in this chapter and
are given on a per garment per use basis.
5.1 OREX Garment Carbon Footprint
The carbon footprint results for a single use OREX coverall are given in Figure 1.
Figure 1 Carbon Footprint Breakdown for an OREX Garment
Figure 1 shows that lifecycle carbon footprint of an OREX garment expressed per garment per
wear is around 1 kg CO2. Of this, production of the PVA material accounts for 0.52 kg CO2
(50%), OREX processing 0.28 kg CO2 (27%), delivery transportation 0.08 kg CO2 (8%), and
transportation of used OREX to Ashford, AL, for processing of 0.13 kg CO2 (12%).
Transportation associated with secondary waste treatment, OREX processing and final waste
disposal was 0.03 kg CO2 (3%).
5.2 Textile Garment Carbon Footprint
The carbon footprint results for a nylon coverall are given in the following figures based on a
realistic range of 25 uses (Figure 2), and 50 uses (Figure 3).
Figure 2 shows that lifecycle carbon footprint of a nylon garment expressed per garment per
wear (assuming 25 wears) is 1.16 kg CO2. Of this, production of the nylon material accounts
for 0.15 kg CO2 (13%), transportation for laundering 0.59 kg CO2 (51%), laundry processing
0.38 kg CO2 (33%) and transportation for disposal 0.03 kg CO2 (3%).
Based on a prospective 25 uses, the carbon footprint of a nylon garment, per garment, per use
is 1.16 kg CO2, just over 0.13 kg CO2 (12%) more than an OREX garment. This is primarily
due to the per use transportation requirements associated with launderable garments.
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Figure 2 Carbon Footprint Breakdown for a Nylon Garment (25 uses)
Figure 3 shows that lifecycle carbon footprint of a nylon garment expressed per garment per
wear (assuming 50 wears) is 1.07 kg CO2. Of this the contribution from the production of the
nylon material has halved (twice the number of uses) to 0.076 kg CO2 (7%), while
transportation for laundering, which is assessed on a per use basis, remains constant at 0.59
kg CO2 (but now 55% of the total per wear) and that for actual laundry processing remains
constant at 0.38 kg CO2 (but now 33% of the total per wear).
Figure 3 Carbon Footprint Breakdown for a Nylon Garment (50 uses)
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5.3 OREX and Textile Comparison
As shown above and discussed previously the relative carbon footprint performance of an
OREX garment compared to a nylon one depends, in part, upon the number of uses of that
nylon garment.
The assessment of the carbon footprint given in section 5.2 has therefore been repeated on an
iterative basis from 1 to 100 uses of a nylon garment. The carbon footprint per use of an
OREX garment compared to the per use carbon footprint of a nylon garment, expressed as
percentage, is shown in Figure 4. This shows that, on a per use basis, OREX consistently
offers a lower carbon footprint than textiles up to around 80 to 90 uses of a nylon garment.
Although a nylon garment could theoretically be used and laundered up to 100 times,
achieving such a number of uses from a launderable garment is very unlikely and would also
significantly increase the chance of personal contamination events.
Figure 4 Carbon footprint comparison based on number of uses
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6 Summary and Conclusions
A detailed carbon footprint assessment of OREX and nylon protective garments used in the
US nuclear industry has been undertaken and has been reported here.
This study has followed US and international guidance and has used well established and
robust data sets to assess the life cycle carbon footprint, expressed on a per use basis for
OREX and nylon garments. The study has responded to critical review of previous work and
has included manufacture and distribution, transportation, processing and laundering,
secondary waste treatment and final waste disposition. Results have then been presented to
account for the uncertainty in the number of prospective uses of a textile garment.
Overall the results show that the carbon footprint, whether for a single use OREX garment, or
a multiple use nylon one, given on a per use basis, are not significantly different. In fact, the
carbon footprint of a single use OREX garment offers better environmental performance
compared to a nylon one up to 80 to 90 uses. Where nylon garments can be maintained in
service beyond this number of uses, they may offer, in terms of carbon footprint per wear,
better environmental performance, but even at 100 wears this the carbon footprint on a per
use basis is virtually indistinguishable from that of an OREX garment. This study has not
accounted for the use of detergents and possible water conditioners in the carbon footprint for
launderable garments, hence the carbon footprint of their use will be higher than assessed
here. It is also important to note that although the garment manufacturers may quote a
theoretical number of uses of 100 times, in practical terms this is unlikely to be achieved due to
garment damage and issues of residual contamination. As noted in the introduction to this
report, launderable garments are woven and inherently contain thousands of “holes” in the
weave per square inch of fabric and where, with each washing, these holes get larger and
more numerous. Hence the radiological protection of worker can be compromised where
garments are used many times.
The results of this assessment are very different to the preliminary study discussed in Chapter
2 which declared that one use of a PVA garment releases almost 18 times more greenhouse
gas equivalents than one use of a reusable nylon garment. However, as noted in Chapter 2
key aspects of both garment life cycles were excluded in this preliminary study (particularly
transportation and waste disposal and the respective requirements of both) and the emissions
from PVA production were based on higher values from polyester type substances. Therefore
the results of the two studies are not comparable.
Based on the preliminary study discussed in Chapter 2, Exponent multiplied the per garment
per use carbon footprint of OREX and nylon garments to give an indication of absolute
differences in carbon emissions. Following the USA and typical site use metrics they give, we
have recalculated values based on the more comprehensive approach taken here. A
calculation such as this needs to make an assumption on the realistic number of uses of a
textile garment. For the purpose of this calculation we have used an optimistic value of 50
uses of a nylon garment. If OREX garment supply to the US nuclear industry over the last ten
years is considered, a US industry use of 30,000,000 OREX garments, this would imply a total
carbon footprint saving to the industry of over a 1,000 metric tonnes of CO2 emissions.
Any assessment such as this, which includes factors such as transportation distance,
particularly within country, road transportation is clearly influenced by the assumed distances
and by quantities per shipment. Nonetheless, we have tried to use reasonable average values
applicable to a broad number of user sites.
Although not assessed here, sustainability is not just about carbon footprint, in its broadest
sense it also needs to consider worker protection, cost to the industry and availability of waste
26. Client Name: Eastern Technologies Inc.
Report Title: Quantifying the Carbon Footprint associated with OREX and Textile Garment use in the USA
Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 21
disposition routes. These are all areas where OREX garments may offer enhanced
performance compared to the historic use of textiles.
27. Client Name: Eastern Technologies Inc.
Report Title: Quantifying the Carbon Footprint associated with OREX and Textile Garment use in the USA
Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 22
Appendix 1 – Report Authors
This report has been produced by a partnership between Eden Nuclear and Environment
(Eden NE) and SKM Enviros. Dr Adrian Punt (Eden NE) and Dr Bryony Cunningham (SKM
Enviros) are the prime authors of this report.
Eden NE is accredited to ISO 9001:2008 for the provision of consultancy services to the
nuclear industry and specializes in nuclear industry waste management, radiation protection
and environmental sustainability and safety assessments. Eden NE are based in Great Britain,
but support an international client base that includes organizations like the Electric Power
Research Institute (EPRI) in the USA, the Nuclear Waste Management Organisation (NWMO)
of Canada, fuel production, reprocessing and nuclear power plant operators in Great Britain
and radioactive waste management organisations throughout Europe and in Asia. For more
information and for contact details please visit www.eden-ne.co.uk.
Sinclair Knight Merz (SKM) is a leading projects firm, with global capability in strategic
consulting, engineering and project delivery. It operates in three regions: Asia Pacific, the
Americas and EMEA (Europe, Middle East & Africa), deploying some 7,000 people from more
than 40 offices while serving the Buildings and Infrastructure, Mining and Metals, Power and
Energy and Water and Environment sectors.
SKM Enviros works extensively with national and international organizations to calculate and
report their carbon footprints. These clients range from public sector organizations such as
local and national government authorities, higher education establishments, to private sector
organizations like Coca-Cola and Nestle. These assignments involve the development of
assessment tools and models to calculate carbon emissions to ensure that clients are able to
report robust and technically underpin assessments of the carbon footprint of their operations.
These studies are based on a detailed appraisal of life cycle impacts (as well as modeling end-
of-life scenarios). For more information and for contact details please visit
www.skmenviros.com.
Author - Dr Adrian Punt – PhD, MSc, BSc (Hons), CRadP
Dr Punt, Associate Director, Eden NE is an environmental and waste
management expert with over 20 years’ experience and is a Chartered
Radiation Protection Professional (CRadP). Dr Punt has worked with a
diverse range of operational and decommissioning nuclear facilities in areas
of radiation and environmental protection, waste management and
sustainability assessments. This experience covers the development of
carbon footprints for radioactive waste management and options
assessments and optimisation programmes to minimise the environmental
impact of waste management. He is an expert in the development of integrated waste
management strategies that provide a holistic and optimized approach to life cycle waste
management and the hazardous and radiological impacts of gaseous, aqueous and solid
waste disposal needs. Dr Punt has been the primary author for a number of key reports written
on behalf of the environmental regulators in Great Britain, particularly the Environment Agency
of England and Wales and the Scottish Environment Protection Agency. He has also provided
specialist advisory services to the British Government and to the European Commission and
has presented his work at international conferences such as Waste Management in Phoenix
and for the International Atomic Energy Agency (IAEA) in Vienna.
28. Client Name: Eastern Technologies Inc.
Report Title: Quantifying the Carbon Footprint associated with OREX and Textile Garment use in the USA
Eden Project Reference Number: ENE/0068-US/AP Issue: Issue 3 – Final V1.1 Page No. 23
Author – Dr Bryony Cunningham – EngD, MSc, BSc (Hons), AIEMA
Dr Bryony Cunningham, Principal Consultant, SKM Enviros is an
environmental expert with 14 years experience with posts in industry,
academia, government and consultancy, experience with a specific
focus on life cycle carbon assessment and its application to
environmental decision making. Dr Cunningham has both a Bachelor
and Masters degree in environmental impact assessment. She was
awarded an Engineering PhD Doctorate (EngD) whilst working for
Shell in the UK, where her research studies focused on elements of life cycle assessment
(LCA) techniques and the establishment of bespoke environmental and carbon modeling tools
for the oil and gas sector. She has then gone on to manage a range of LCA and carbon
footprinting projects for a range of subjects for national and international clients, including
analysis of packaging, fuels, agricultural products, foodstuffs and waste treatment techniques
for companies including Tata and Cadbury’s (now part of Nestle group). This work includes the
carbon footprint analysis for a nuclear industry client assessing the carbon impact of
radioactive contaminated oil incineration, radioactive contaminated metal recycling and solid
radioactive waste disposal. She has also been part of a small team that worked to produce UK
government guidance on LCA and carbon footprinting for the waste sector, ‘Carbon Sense for
Better Waste Management’20
. She is an expert user of SimaPro (utilising the EcoInvent
database) and an Associate Member of the UK Institute of Environmental Management and
Assessment (AIEMA).
20
Available at: http://www.adeptnet.org.uk/assets/userfiles/documents/000101.pdf
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Eden Nuclear and Environment Ltd registered address:
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