�ݺ�ߣshows by User: sandeepnj7

�ݺ�ߣshows by User: sandeepnj7 / http://www.slideshare.net/images/logo.gif �ݺ�ߣshows by User: sandeepnj7 / Fri, 02 Dec 2016 07:02:07 GMT �ݺ�ߣShare feed for �ݺ�ߣshows by User: sandeepnj7 Development of unfired bricks using industrial waste /slideshow/development-of-unfired-bricks-using-industrial-waste/69750935 developmentofunfiredbricksusingindustrialwastesandeepjain-161202070207
A research project aimed at production of an unfired, non-structural, binder brick with 100% waste material, using fly ash, pond ash, coal cinder, & paper sludge along with lime and gypsum system to alleviate resources like coal, diesel, preservation of top soil, prevention of harmful emissions simultaneously managing the industrial waste. Project Guide: Dr Shashank Bishnoi, Civil Engineering Department, IIT Delhi ]]>
A research project aimed at production of an unfired, non-structural, binder brick with 100% waste material, using fly ash, pond ash, coal cinder, & paper sludge along with lime and gypsum system to alleviate resources like coal, diesel, preservation of top soil, prevention of harmful emissions simultaneously managing the industrial waste. Project Guide: Dr Shashank Bishnoi, Civil Engineering Department, IIT Delhi ]]> Fri, 02 Dec 2016 07:02:07 GMT /slideshow/development-of-unfired-bricks-using-industrial-waste/69750935 sandeepnj7@slideshare.net(sandeepnj7) Development of unfired bricks using industrial waste sandeepnj7 A research project aimed at production of an unfired, non-structural, binder brick with 100% waste material, using fly ash, pond ash, coal cinder, & paper sludge along with lime and gypsum system to alleviate resources like coal, diesel, preservation of top soil, prevention of harmful emissions simultaneously managing the industrial waste. Project Guide: Dr Shashank Bishnoi, Civil Engineering Department, IIT Delhi <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/developmentofunfiredbricksusingindustrialwastesandeepjain-161202070207-thumbnail.jpg?width=120&height=120&fit=bounds" /> A research project aimed at production of an unfired, non-structural, binder brick with 100% waste material, using fly ash, pond ash, coal cinder, & paper sludge along with lime and gypsum system to alleviate resources like coal, diesel, preservation of top soil, prevention of harmful emissions simultaneously managing the industrial waste. Project Guide: Dr Shashank Bishnoi, Civil Engineering Department, IIT Delhi

Development of unfired bricks using industrial waste from Sandeep Jain

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0 Certifcation of Building Using GRIHA Rating System /slideshow/certifcation-of-building-using-griha-rating-system-60638755/60638755 8725a99f-5a8d-434c-8428-a0f2cf232a74-160408041629
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]]> Fri, 08 Apr 2016 04:16:29 GMT /slideshow/certifcation-of-building-using-griha-rating-system-60638755/60638755 sandeepnj7@slideshare.net(sandeepnj7) Certifcation of Building Using GRIHA Rating System sandeepnj7 <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/8725a99f-5a8d-434c-8428-a0f2cf232a74-160408041629-thumbnail.jpg?width=120&height=120&fit=bounds" />

Certifcation of Building Using GRIHA Rating System from Sandeep Jain

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0 Development of hypothetical eco industrial park at bellary, karnataka (india) /sandeepnj7/development-of-hypothetical-eco-industrial-park-at-bellary-karnataka-india developmentofhypotheticaleco-industrialparkatbellarykarnatakaindia-151104204846-lva1-app6892
In this report an attempt is made to develop a hypothetical Eco-Industrial Park in the Bellary district of Karnataka state of India. Efforts are made to demonstrate possible interactions between current local businesses and other virtual industries in order to increase profitability and reduce environmental pollution. The scope of this report is limited to identify the material and energy exchanges between the existing industries along with some proposed industries at Bellary district in order to further closing the loop.]]>
In this report an attempt is made to develop a hypothetical Eco-Industrial Park in the Bellary district of Karnataka state of India. Efforts are made to demonstrate possible interactions between current local businesses and other virtual industries in order to increase profitability and reduce environmental pollution. The scope of this report is limited to identify the material and energy exchanges between the existing industries along with some proposed industries at Bellary district in order to further closing the loop.]]> Wed, 04 Nov 2015 20:48:45 GMT /sandeepnj7/development-of-hypothetical-eco-industrial-park-at-bellary-karnataka-india sandeepnj7@slideshare.net(sandeepnj7) Development of hypothetical eco industrial park at bellary, karnataka (india) sandeepnj7 In this report an attempt is made to develop a hypothetical Eco-Industrial Park in the Bellary district of Karnataka state of India. Efforts are made to demonstrate possible interactions between current local businesses and other virtual industries in order to increase profitability and reduce environmental pollution. The scope of this report is limited to identify the material and energy exchanges between the existing industries along with some proposed industries at Bellary district in order to further closing the loop. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/developmentofhypotheticaleco-industrialparkatbellarykarnatakaindia-151104204846-lva1-app6892-thumbnail.jpg?width=120&height=120&fit=bounds" /> In this report an attempt is made to develop a hypothetical Eco-Industrial Park in the Bellary district of Karnataka state of India. Efforts are made to demonstrate possible interactions between current local businesses and other virtual industries in order to increase profitability and reduce environmental pollution. The scope of this report is limited to identify the material and energy exchanges between the existing industries along with some proposed industries at Bellary district in order to further closing the loop.

Development of hypothetical eco industrial park at bellary, karnataka (india) from Sandeep Jain

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0 Utilization of waste paper sludge in construction industry /slideshow/utilization-of-waste-paper-sludge-in-construction-industry-49398380/49398380 utilizationofwastepapersludgeinconstructionindustry-150615095103-lva1-app6892
This technical note is recapitulation of the work carried out by researchers round the globe on characterization of waste paper sludge based on physical, chemical and mineralogical properties, activation mechanisms, pozzolanic reactivity, reaction kinematics and durability; for its possible utilization in construction industry as supplementary cementitious material, mineral admixture, partial replacement of binders in concrete, raw material for clay brick manufacturing, production of ceramics, soil stabilization in road works, reduction in carbon-dioxide emission etc., in order to encash various socio-economic and environmental benefits.]]>
This technical note is recapitulation of the work carried out by researchers round the globe on characterization of waste paper sludge based on physical, chemical and mineralogical properties, activation mechanisms, pozzolanic reactivity, reaction kinematics and durability; for its possible utilization in construction industry as supplementary cementitious material, mineral admixture, partial replacement of binders in concrete, raw material for clay brick manufacturing, production of ceramics, soil stabilization in road works, reduction in carbon-dioxide emission etc., in order to encash various socio-economic and environmental benefits.]]> Mon, 15 Jun 2015 09:51:03 GMT /slideshow/utilization-of-waste-paper-sludge-in-construction-industry-49398380/49398380 sandeepnj7@slideshare.net(sandeepnj7) Utilization of waste paper sludge in construction industry sandeepnj7 This technical note is recapitulation of the work carried out by researchers round the globe on characterization of waste paper sludge based on physical, chemical and mineralogical properties, activation mechanisms, pozzolanic reactivity, reaction kinematics and durability; for its possible utilization in construction industry as supplementary cementitious material, mineral admixture, partial replacement of binders in concrete, raw material for clay brick manufacturing, production of ceramics, soil stabilization in road works, reduction in carbon-dioxide emission etc., in order to encash various socio-economic and environmental benefits. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/utilizationofwastepapersludgeinconstructionindustry-150615095103-lva1-app6892-thumbnail.jpg?width=120&height=120&fit=bounds" /> This technical note is recapitulation of the work carried out by researchers round the globe on characterization of waste paper sludge based on physical, chemical and mineralogical properties, activation mechanisms, pozzolanic reactivity, reaction kinematics and durability; for its possible utilization in construction industry as supplementary cementitious material, mineral admixture, partial replacement of binders in concrete, raw material for clay brick manufacturing, production of ceramics, soil stabilization in road works, reduction in carbon-dioxide emission etc., in order to encash various socio-economic and environmental benefits.

Utilization of waste paper sludge in construction industry from Sandeep Jain

]]> 2939 4 https://cdn.slidesharecdn.com/ss_thumbnails/utilizationofwastepapersludgeinconstructionindustry-150615095103-lva1-app6892-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post

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0 Utilization of Waste Paper Sludge in Construction Industry /slideshow/utilization-of-waste-paper-sludge-in-construction-industry-49398118/49398118 utilizationofwastepapersludgeinconstructionindustry-150615094333-lva1-app6892
This technical note is recapitulation of the work carried out by researchers round the globe on characterization of waste paper sludge based on physical, chemical and mineralogical properties, activation mechanisms, pozzolanic reactivity, reaction kinematics and durability; for its possible utilization in construction industry as supplementary cementitious material, mineral admixture, partial replacement of binders in concrete, raw material for clay brick manufacturing, production of ceramics, soil stabilization in road works, reduction in carbon-dioxide emission etc., in order to en-cash various socio-economic and environmental benefits.]]>
This technical note is recapitulation of the work carried out by researchers round the globe on characterization of waste paper sludge based on physical, chemical and mineralogical properties, activation mechanisms, pozzolanic reactivity, reaction kinematics and durability; for its possible utilization in construction industry as supplementary cementitious material, mineral admixture, partial replacement of binders in concrete, raw material for clay brick manufacturing, production of ceramics, soil stabilization in road works, reduction in carbon-dioxide emission etc., in order to en-cash various socio-economic and environmental benefits.]]> Mon, 15 Jun 2015 09:43:33 GMT /slideshow/utilization-of-waste-paper-sludge-in-construction-industry-49398118/49398118 sandeepnj7@slideshare.net(sandeepnj7) Utilization of Waste Paper Sludge in Construction Industry sandeepnj7 This technical note is recapitulation of the work carried out by researchers round the globe on characterization of waste paper sludge based on physical, chemical and mineralogical properties, activation mechanisms, pozzolanic reactivity, reaction kinematics and durability; for its possible utilization in construction industry as supplementary cementitious material, mineral admixture, partial replacement of binders in concrete, raw material for clay brick manufacturing, production of ceramics, soil stabilization in road works, reduction in carbon-dioxide emission etc., in order to en-cash various socio-economic and environmental benefits. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/utilizationofwastepapersludgeinconstructionindustry-150615094333-lva1-app6892-thumbnail.jpg?width=120&height=120&fit=bounds" /> This technical note is recapitulation of the work carried out by researchers round the globe on characterization of waste paper sludge based on physical, chemical and mineralogical properties, activation mechanisms, pozzolanic reactivity, reaction kinematics and durability; for its possible utilization in construction industry as supplementary cementitious material, mineral admixture, partial replacement of binders in concrete, raw material for clay brick manufacturing, production of ceramics, soil stabilization in road works, reduction in carbon-dioxide emission etc., in order to en-cash various socio-economic and environmental benefits.

Utilization of Waste Paper Sludge in Construction Industry from Sandeep Jain

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0 MIVAN_An Aluminum Formwork Construction Technique /slideshow/mivan-an-aluminum-formwork-construction-technique/46693486 mivananaluminumformworkconstructiontechnique-150406142058-conversion-gate01
"MIVAN_An Aluminum Formwork Construction Technique"]]>
"MIVAN_An Aluminum Formwork Construction Technique"]]> Mon, 06 Apr 2015 14:20:58 GMT /slideshow/mivan-an-aluminum-formwork-construction-technique/46693486 sandeepnj7@slideshare.net(sandeepnj7) MIVAN_An Aluminum Formwork Construction Technique sandeepnj7 "MIVAN_An Aluminum Formwork Construction Technique" <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/mivananaluminumformworkconstructiontechnique-150406142058-conversion-gate01-thumbnail.jpg?width=120&height=120&fit=bounds" /> "MIVAN_An Aluminum Formwork Construction Technique"

MIVAN_An Aluminum Formwork Construction Technique from Sandeep Jain

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0 Safety & Quality Aspects in '3-S' System of Construction /slideshow/safety-quality-aspects-of-3-s-system-of-construction/41350541 safetyqualityaspectsof3ssystemofconstruction-141110072535-conversion-gate02
‘3-S’ system is the brand name of prefab building construction system fully developed and perfected by B.G. Shirke Construction Technology Pvt. Ltd. After years of strenuous R&D supplemented by extensive field trials. ‘3-S’ PREFAB components are erected, aligned and connected; on site using SCC i.e. Self-Compacting Concrete of M30 grade screeding along with secured embedded reinforcement. The things that we tried to know through this project include- • Understanding the 3-S system of construction. • How it has improved the safety and quality of construction? • What are the loopholes of this method pertaining to safety and quality control? We started with the study of Quality, Environment, Health& Safety policy of the company. Knowing the basics of the 3-S system of construction we went ahead with the 4-stage process consisting of manufacturing of components, storage and curing, transit to site & erection and assembly. In manufacturing of various components like shear walls, beams, columns, slabs, staircase etc., other than the manufacturing techniques of 3-S system we focused on its safety and quality parameter. After the manufacturing bay we went to the storage & curing yard with a view to understand the safe storage practices and then moved ahead to get an understanding of safety in transit of cured components fromyard to the erection site. And last but not the least we learned the safe erecting practices and quality control while erection and assembling the components at site. The topics covered are: • Safety management in:  Manufacturing& storage phase  Transit  Erection phase and  Personnel safety • Quality assurance in:  Manufacturing and  Erection phase. After knowing this technology we now tried to compare the pros and cons over the conventional system of construction. Pros: 1. Considerable reduction in time of Construction 2. Controlled work environment 3. Improved quality control and safe 4. Mass production process Cons: 1. Can only be used for repetitive units 2. Improper joint may cause leakages 3. Accumulation of stresses 4. Requirement of skilled labor in erection 5. High initial capital investment]]>
‘3-S’ system is the brand name of prefab building construction system fully developed and perfected by B.G. Shirke Construction Technology Pvt. Ltd. After years of strenuous R&D supplemented by extensive field trials. ‘3-S’ PREFAB components are erected, aligned and connected; on site using SCC i.e. Self-Compacting Concrete of M30 grade screeding along with secured embedded reinforcement. The things that we tried to know through this project include- • Understanding the 3-S system of construction. • How it has improved the safety and quality of construction? • What are the loopholes of this method pertaining to safety and quality control? We started with the study of Quality, Environment, Health& Safety policy of the company. Knowing the basics of the 3-S system of construction we went ahead with the 4-stage process consisting of manufacturing of components, storage and curing, transit to site & erection and assembly. In manufacturing of various components like shear walls, beams, columns, slabs, staircase etc., other than the manufacturing techniques of 3-S system we focused on its safety and quality parameter. After the manufacturing bay we went to the storage & curing yard with a view to understand the safe storage practices and then moved ahead to get an understanding of safety in transit of cured components fromyard to the erection site. And last but not the least we learned the safe erecting practices and quality control while erection and assembling the components at site. The topics covered are: • Safety management in:  Manufacturing& storage phase  Transit  Erection phase and  Personnel safety • Quality assurance in:  Manufacturing and  Erection phase. After knowing this technology we now tried to compare the pros and cons over the conventional system of construction. Pros: 1. Considerable reduction in time of Construction 2. Controlled work environment 3. Improved quality control and safe 4. Mass production process Cons: 1. Can only be used for repetitive units 2. Improper joint may cause leakages 3. Accumulation of stresses 4. Requirement of skilled labor in erection 5. High initial capital investment]]> Mon, 10 Nov 2014 07:25:35 GMT /slideshow/safety-quality-aspects-of-3-s-system-of-construction/41350541 sandeepnj7@slideshare.net(sandeepnj7) Safety & Quality Aspects in '3-S' System of Construction sandeepnj7 ‘3-S’ system is the brand name of prefab building construction system fully developed and perfected by B.G. Shirke Construction Technology Pvt. Ltd. After years of strenuous R&D supplemented by extensive field trials. ‘3-S’ PREFAB components are erected, aligned and connected; on site using SCC i.e. Self-Compacting Concrete of M30 grade screeding along with secured embedded reinforcement. The things that we tried to know through this project include- • Understanding the 3-S system of construction. • How it has improved the safety and quality of construction? • What are the loopholes of this method pertaining to safety and quality control? We started with the study of Quality, Environment, Health& Safety policy of the company. Knowing the basics of the 3-S system of construction we went ahead with the 4-stage process consisting of manufacturing of components, storage and curing, transit to site & erection and assembly. In manufacturing of various components like shear walls, beams, columns, slabs, staircase etc., other than the manufacturing techniques of 3-S system we focused on its safety and quality parameter. After the manufacturing bay we went to the storage & curing yard with a view to understand the safe storage practices and then moved ahead to get an understanding of safety in transit of cured components fromyard to the erection site. And last but not the least we learned the safe erecting practices and quality control while erection and assembling the components at site. The topics covered are: • Safety management in:  Manufacturing& storage phase  Transit  Erection phase and  Personnel safety • Quality assurance in:  Manufacturing and  Erection phase. After knowing this technology we now tried to compare the pros and cons over the conventional system of construction. Pros: 1. Considerable reduction in time of Construction 2. Controlled work environment 3. Improved quality control and safe 4. Mass production process Cons: 1. Can only be used for repetitive units 2. Improper joint may cause leakages 3. Accumulation of stresses 4. Requirement of skilled labor in erection 5. High initial capital investment <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/safetyqualityaspectsof3ssystemofconstruction-141110072535-conversion-gate02-thumbnail.jpg?width=120&height=120&fit=bounds" /> ‘3-S’ system is the brand name of prefab building construction system fully developed and perfected by B.G. Shirke Construction Technology Pvt. Ltd. After years of strenuous R&D supplemented by extensive field trials. ‘3-S’ PREFAB components are erected, aligned and connected; on site using SCC i.e. Self-Compacting Concrete of M30 grade screeding along with secured embedded reinforcement. The things that we tried to know through this project include- • Understanding the 3-S system of construction. • How it has improved the safety and quality of construction? • What are the loopholes of this method pertaining to safety and quality control? We started with the study of Quality, Environment, Health& Safety policy of the company. Knowing the basics of the 3-S system of construction we went ahead with the 4-stage process consisting of manufacturing of components, storage and curing, transit to site & erection and assembly. In manufacturing of various components like shear walls, beams, columns, slabs, staircase etc., other than the manufacturing techniques of 3-S system we focused on its safety and quality parameter. After the manufacturing bay we went to the storage & curing yard with a view to understand the safe storage practices and then moved ahead to get an understanding of safety in transit of cured components fromyard to the erection site. And last but not the least we learned the safe erecting practices and quality control while erection and assembling the components at site. The topics covered are: • Safety management in:  Manufacturing& storage phase  Transit  Erection phase and  Personnel safety • Quality assurance in:  Manufacturing and  Erection phase. After knowing this technology we now tried to compare the pros and cons over the conventional system of construction. Pros: 1. Considerable reduction in time of Construction 2. Controlled work environment 3. Improved quality control and safe 4. Mass production process Cons: 1. Can only be used for repetitive units 2. Improper joint may cause leakages 3. Accumulation of stresses 4. Requirement of skilled labor in erection 5. High initial capital investment

Safety & Quality Aspects in '3-S' System of Construction from Sandeep Jain

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0 https://cdn.slidesharecdn.com/profile-photo-sandeepnj7-48x48.jpg?cb=1580650005 Even if I don't know the answer, I will know how to find it. http://www.marvelrealtors.com https://cdn.slidesharecdn.com/ss_thumbnails/developmentofunfiredbricksusingindustrialwastesandeepjain-161202070207-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/development-of-unfired-bricks-using-industrial-waste/69750935 Development of unfired... https://cdn.slidesharecdn.com/ss_thumbnails/8725a99f-5a8d-434c-8428-a0f2cf232a74-160408041629-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/certifcation-of-building-using-griha-rating-system-60638755/60638755 Certifcation of Buildi... https://cdn.slidesharecdn.com/ss_thumbnails/developmentofhypotheticaleco-industrialparkatbellarykarnatakaindia-151104204846-lva1-app6892-thumbnail.jpg?width=320&height=320&fit=bounds sandeepnj7/development-of-hypothetical-eco-industrial-park-at-bellary-karnataka-india Development of hypothe...