Microturbines are a green new way to power buildings while heating and cooling them. Also, microturbines burn waste gas from landfills, sewage treatment plants, farms and the like, turning it into clean electricity for the electric grid.
Microturbines are small combustion turbines approximately the size of a refrigerator that can generate 25-500 kW of electricity. They provide both electricity and thermal energy for heating and cooling. Microturbines are commercially available and use natural gas, hydrogen, propane or diesel as fuel. They have efficiencies of 20-30% and produce low NOx emissions. Microturbines offer distributed energy generation by producing power on-site, which eliminates transmission losses and enables combined heat and power applications. Their advantages include compact size, long maintenance intervals, low emissions and high efficiency compared to other distributed generation technologies.
Microturbines are small combustion turbines around the size of a refrigerator that can generate 25-500 kW of electricity and provide thermal energy for heating and cooling. They have fewer moving parts than larger turbines and can run on fuels like natural gas, hydrogen, propane, and diesel. Microturbines work by compressing air and fuel in a compressor, combusting the mixture, and driving a generator with the expanding exhaust gases. They can be configured as simple or recuperated cycles, with recuperated microturbines achieving higher efficiencies of 20-30% by recovering heat from the exhaust. Microturbines see applications in distributed power generation and combined heat and power due to their compact size and ability to utilize waste fuels with
The document discusses microturbines and combined heat and power (CHP) systems from an owner's perspective. Microturbines are small, self-contained power plants that are fueled primarily by natural gas and provide both electricity and heat. They offer improved economics, environment, and reliability compared to traditional power generation. The document also provides an example project of installing microturbines at a New York City commercial building, showing the system configuration and projected savings, payback period, and environmental benefits.
This document provides information about a seminar presentation on microturbines given by Mr. Akshay Nawale. It includes an introduction to microturbines, which are small gas turbines approximately the size of a refrigerator that can generate 25-500 kW of power. Microturbines are single shaft machines that integrate a compressor, turbine, and generator. They have applications for distributed power generation and combined heat and power systems. The document outlines the working principles, components, advantages, and experimental testing of microturbines.
Micro turbines can produce 10-100 watts of electrical power and have an energy density 10 times greater than batteries. They can be used for power generation in applications like space vehicles and electronic devices. The document discusses the classification, characteristics, challenges, applications, and recent developments of micro turbines. It notes that micro turbines face unique combustion challenges due to their small size but are still in development for power generation uses.
The document discusses using biogas from sources like landfills and wastewater treatment plants as fuel for onsite power generation using Capstone microturbines. It provides an overview of Capstone technologies, how biogas is conditioned and used as fuel for microturbines, maintenance requirements, and examples of biogas-to-energy projects using Capstone systems at various wastewater treatment plants and landfills.
Microturbines are small combustion turbines that typically generate 25-300kW of power and provide both electricity and thermal energy. They are needed as alternative energy sources for remote locations and as compact, portable generators. Microturbines have higher efficiency than other small generators and require infrequent maintenance. They consist of a compressor, combustor, generator, recuperator/heat exchanger, turbine, and power electronics. Recuperated microturbines recover heat from the exhaust to preheat the incoming air, improving efficiency to 20-30%, compared to 15% for unrecuperated models. Major applications include cogeneration, small-scale power generation, and as automotive turbochargers.
The document discusses the development of microturbines, which are very small gas turbine engines that could power portable electronic devices for long periods from a small fuel source. A team at MIT led by Alan Epstein developed a microturbine design that would be less than 1% the size of a conventional gas turbine. Over seven years of research, they made significant progress developing working microturbine prototypes, addressing challenges like how to support a rotor spinning at over 2 million RPM. Microturbines could potentially deliver 10 times the power per unit weight compared to larger turbines, reducing fuel needs and costs for applications like aircraft.
Microturbines are small combustion turbines approximately the size of a refrigerator that can generate 25-500 kW of electricity. They provide both electricity and thermal energy for heating and cooling. Microturbines are commercially available and use natural gas, hydrogen, propane or diesel as fuel. They have efficiencies of 20-30% and produce low NOx emissions. Microturbines offer distributed energy generation by producing power on-site, which eliminates transmission losses and enables combined heat and power applications. Their advantages include compact size, long maintenance intervals, low emissions and high efficiency compared to other distributed generation technologies.
Microturbines are small combustion turbines around the size of a refrigerator that can generate 25-500 kW of electricity and provide thermal energy for heating and cooling. They have fewer moving parts than larger turbines and can run on fuels like natural gas, hydrogen, propane, and diesel. Microturbines work by compressing air and fuel in a compressor, combusting the mixture, and driving a generator with the expanding exhaust gases. They can be configured as simple or recuperated cycles, with recuperated microturbines achieving higher efficiencies of 20-30% by recovering heat from the exhaust. Microturbines see applications in distributed power generation and combined heat and power due to their compact size and ability to utilize waste fuels with
The document discusses microturbines and combined heat and power (CHP) systems from an owner's perspective. Microturbines are small, self-contained power plants that are fueled primarily by natural gas and provide both electricity and heat. They offer improved economics, environment, and reliability compared to traditional power generation. The document also provides an example project of installing microturbines at a New York City commercial building, showing the system configuration and projected savings, payback period, and environmental benefits.
This document provides information about a seminar presentation on microturbines given by Mr. Akshay Nawale. It includes an introduction to microturbines, which are small gas turbines approximately the size of a refrigerator that can generate 25-500 kW of power. Microturbines are single shaft machines that integrate a compressor, turbine, and generator. They have applications for distributed power generation and combined heat and power systems. The document outlines the working principles, components, advantages, and experimental testing of microturbines.
Micro turbines can produce 10-100 watts of electrical power and have an energy density 10 times greater than batteries. They can be used for power generation in applications like space vehicles and electronic devices. The document discusses the classification, characteristics, challenges, applications, and recent developments of micro turbines. It notes that micro turbines face unique combustion challenges due to their small size but are still in development for power generation uses.
The document discusses using biogas from sources like landfills and wastewater treatment plants as fuel for onsite power generation using Capstone microturbines. It provides an overview of Capstone technologies, how biogas is conditioned and used as fuel for microturbines, maintenance requirements, and examples of biogas-to-energy projects using Capstone systems at various wastewater treatment plants and landfills.
Microturbines are small combustion turbines that typically generate 25-300kW of power and provide both electricity and thermal energy. They are needed as alternative energy sources for remote locations and as compact, portable generators. Microturbines have higher efficiency than other small generators and require infrequent maintenance. They consist of a compressor, combustor, generator, recuperator/heat exchanger, turbine, and power electronics. Recuperated microturbines recover heat from the exhaust to preheat the incoming air, improving efficiency to 20-30%, compared to 15% for unrecuperated models. Major applications include cogeneration, small-scale power generation, and as automotive turbochargers.
The document discusses the development of microturbines, which are very small gas turbine engines that could power portable electronic devices for long periods from a small fuel source. A team at MIT led by Alan Epstein developed a microturbine design that would be less than 1% the size of a conventional gas turbine. Over seven years of research, they made significant progress developing working microturbine prototypes, addressing challenges like how to support a rotor spinning at over 2 million RPM. Microturbines could potentially deliver 10 times the power per unit weight compared to larger turbines, reducing fuel needs and costs for applications like aircraft.
project report MICROTURBINE BY -Asif quamarAsif Quamar
This document summarizes a seminar report on microturbines. It includes 4 chapters:
1) A literature review on microturbines, noting their advantages over other small-scale power generation technologies.
2) An overview of gas turbine systems, including the Brayton cycle and types of gas turbines.
3) A focus on microturbines, defining them as small combustion turbines from 25-500 kW that have evolved from automotive and aircraft technologies.
4) Details on microturbine components, types, and their increasing use for distributed power generation and cogeneration applications.
This document presents information on micro turbines, including their components, characteristics, advantages, applications, challenges, and recent developments. Micro turbines are small combustion turbines that can generate 25-500 kW of power and have moderate costs and efficiencies. They have high-frequency outputs and rotate at high speeds. Micro turbines have applications in distributed generation, quality power and reliability, stand-by power, peak shaving, and combined heat and power. Their advantages include compact size, good efficiencies, lightweight design, and low emissions. Challenges include heat loss, cooling, manufacturing turbine blades, and designing air bearings. Recent developments include coupling with solid oxide fuel cells to increase efficiency.
This document is a seminar report on micro turbines submitted by Rajneesh Kumar Singh in partial fulfillment of the requirements for a Bachelor of Technology degree in Mechanical Engineering. The report provides an overview of micro turbines, including their design, operation, advantages, and applications. It includes sections on gas turbine cycles, characteristics of micro turbines, components of micro turbines, and conclusions.
Microturbine generator systems are small, distributed energy generation systems suitable for small to medium commercial and industrial loads. They consist of a microturbine that provides mechanical energy to a generator, which converts it to electrical energy. Microturbines are a relatively new technology that offers efficiency and clean power generation. They have potential advantages over other distributed generation technologies due to their small size, low cost, and automatic electronic control. The document then provides details on the components, operation, modeling, and control of microturbine generator systems.
This document discusses Elliott Microturbines and their 100kW TA100 combined heat and power (CHP) system. It provides an overview of microturbines compared to conventional generators, describing their higher rpm and use of a permanent magnet generator. The microturbine CHP package is turnkey and integrates components like a heat exchanger. The document also summarizes an installation of 15 TA100 microturbines to provide 1.5MW of power and hot water to a large facility, reducing electrical demand charges. It includes diagrams of the microturbine system and CHP block.
This seminar discusses micro-turbine generator (MTG) systems. MTGs are small, high-speed power plants that typically include a turbine, compressor, generator, and power electronics. They can be used for distributed energy applications to provide power for small to medium commercial and industrial loads. MTGs have recuperated or unrecuperated designs, with recuperated MTGs having higher efficiency due to heat recovery. They work by drawing in air, compressing and combusting it to power a turbine and generator. The generator output is then conditioned and converted to utility frequencies and voltages. MTGs have applications for backup power, power quality/reliability, and cogeneration. Future developments
The document discusses the potential for micro-turbines to become even smaller, possibly reaching a personal scale. It outlines the history of electricity generation moving from localized to large centralized systems. Micro-turbines currently range from 5kW to 300kW and could potentially become as small as 100W units. However, challenges remain around fuel supply, safety, reliability, manufacturing challenges, and regulatory and consumer adoption barriers that must still be overcome before personal-scale micro-turbines become widely used. If these challenges can be addressed, the document suggests personal micro-turbines may start to emerge commercially in the mid-2020s.
This document is a seminar report on micro turbines submitted by Ishfaq Ahmad Najar in partial fulfillment of a Bachelor of Technology degree. It provides an overview of micro turbines, including their basic components and operation. Micro turbines are small combustion turbines that produce both heat and electricity on a relatively small scale. They consist of a compressor, combustor, turbine, alternator, and generator. The turbine turns the compressor and generator, while the combustor adds heat in between. Recuperators are also often included to improve efficiency by capturing waste heat.
This document provides an overview of micro gas turbines. It discusses that micro turbines are small combustion turbines that can generate 25-500 kW of power. They have high power-to-weight ratios and reliability compared to reciprocating engines. Micro turbines are used in distributed generation applications and can utilize various fuels to provide both power and heat in a combined heat and power system. They have potential applications in India to help address power shortages by generating electricity on-site using fuels like biogas.
Micro turbines are a new type of small-scale combustion turbine that produces both heat and electricity efficiently and cleanly for applications like compression and air conditioning. This report focuses on designing and developing a micro turbine powered by compressed nitrogen gas. It reviews literature on micro turbine design aspects, studies gas turbine cycles and micro turbine operation, and designs turbine blades and nozzles using software before analyzing the turbine and nozzle assembly using computational fluid dynamics simulations to obtain velocity vectors.
This document discusses case studies of microturbine combined heat and power (CHP) systems providing cost savings and increased security. It provides three examples: 1) A Radisson hotel in California with two microturbine CHP units providing electricity and hot water, saving $66,336/year. 2) An Inns of America hotel in California with a microturbine CHP unit, saving 40% on energy costs and providing power during a wildfire outage. 3) A restaurant in Italy with a microturbine CHP unit that provided power during a multi-hour blackout. In all cases, the microturbine CHP systems provided both economic and security benefits.
Simulation of a small scale cogeneration system using a microturbinePietro Galli
The aim of the thesis was to develop an operating model of some sizes of Microturbines on the software eQuest.
Then used the model developed to simulate the installation of a Cogeneration (CHP) plant to satisfy the heat and electric demand of a school. The final step was to consider the economics of the investment and choosing which size and use of the turbine was the most convenient for the building.
The key topics of the project were the following:
• Collecting experimental data about some size of Microturbines
• Development of the turbine model for the software eQuest
• Development of the building following the ASHRAE standard
• Simulation of some size of Cogeneration Plants
• Analysis of the results of the simulations
• Energy auditing of the building and analysis of the cost of the current and new plant
• Choice of the best solution for the building
The thesis was developed in collaboration between Politecnico di Torino and the University of Illinois at Chicago, during the course of the double degree program TOP-UIC
A microturbine is a turbine engine-generator typically sized at 250 kW or less that is installed inside or near a building to continuously supply electricity and optionally heat. Microturbines provide opportunities to save money on energy costs, avoid demand charges, support conservation efforts, and help solve facility power problems by producing power on-site to isolate loads and provide backup power during outages or emergencies.
Virginia attorney Bradford Jacob serves as the president of EPC Consulting, LLC, a consultancy serving clients in the oil, gas, chemical, construction, and energy industries. Among other services, Bradford Jacob of Virginia has negotiated energy contracts worth, in aggregate, a total of more than $50 billion, some of which concern combined-cycle power plants.
Combined Heat and Power Generation - Commercial Energy Efficiency with Cogene...The Brewer-Garrett Company
www.brewer-garrett.com
Best practices in combined heat and power (CHP) promote commercial energy efficiency. Presented by energy services company Brewer-Garrett.
Combined heat and power (CHP) refers to the use of a production unit's exhaust heat for another process requirement, improving energy utilization. By capturing waste heat, overall thermal efficiency can increase from 40-50% to 70-90%. CHP installations can be large or small, using fuels like natural gas or biomass, and are used for industrial steam production, agriculture heating, district heating, and small-scale building heating. CHP provides benefits like high efficiency, reduced emissions, cost savings, and power reliability.
Shreya sankrityayan completed a summer training project at the Koderma Thermal Power Station. The report provides an overview of the thermal power generation process, describing the key components of a thermal power plant including the coal handling plant, water treatment plant, boiler system, ash handling plant, electrostatic precipitator, steam turbine, steam condensing system, generator, transformer, and switchyard. It also discusses control and instrumentation systems and concludes with lessons learned from the training experience.
A presentation on summer training at NTPC corporate office noidaAshutosh Tripathi
This document provides a summary of a presentation about a summer training at NTPC Noida. It discusses NTPC's profile, including that it is India's largest power company and was established in 1975. It outlines NTPC's plants, power sharing in India, use of communication technologies like satellites, and new technologies being used like ultra supercritical plants. It also discusses NTPC's use of ash from plants and efforts to increase ash utilization. The presentation concludes by discussing the importance of conserving energy and developing renewable sources to improve the environment.
The combined-cycle power plant uses two gas turbines that produce electricity from combustion of natural gas. Exhaust from the gas turbines powers a steam turbine, increasing total electricity production. Emissions are controlled through selective catalytic reduction and aqueous ammonia injection. The plant can produce up to 600 megawatts of electricity total. Water is treated and recycled to produce steam and for cooling before being returned to the city. Electricity is transmitted to the grid through transformers and a switchyard.
Cogeneration involves the sequential conversion of fuel into multiple usable energy forms. It can produce both electrical and thermal energy, unlike conventional systems. There are two types of cogeneration systems - inplant power generation and reject heat utilization. Inplant power generation produces steam at a higher temperature than needed for manufacturing to also generate electricity using a turbine generator. Reject heat utilization uses excess steam from a power plant for manufacturing. Topping cycles produce electricity first while bottoming cycles produce heat first. Cogeneration provides benefits like fuel economy, lower capital costs, and protection from power outages. Common technologies are steam turbine, gas turbine, combined cycle, and diesel engine systems.
Pro Engineer (Pro/E) is a 3D CAD software used for mechanical design and manufacturing. It uses a parametric, feature-based modeling approach. The key modes in Pro/E include sketching, part creation, assembly, and drawing generation. Common commands like extrude, fillet, pattern, and trim are used to create the features of a turbine part model consisting of an inlet, storage, nozzle, rotor, coupling/shaft, outlet, clip, and housing. The individual parts are then assembled together to form the complete turbine assembly model.
The document provides an overview of Solar Wind Energy, Inc. and its hybrid solar/wind energy technology. The technology uses a hollow tower that injects water at the top to create evaporative cooling and induce winds inside the tower. These winds are harnessed by turbines to generate electricity without requiring solar exposure or unpredictable winds. The summary is:
Solar Wind Energy has developed a hybrid solar/wind energy technology using hollow towers to generate electricity. By injecting water at the top of the towers, evaporative cooling creates winds that turn turbines inside to produce power continuously without needing sunlight or wind. The technology offers a lower-cost alternative to traditional solar and wind with predictable output. Solar Wind Energy is seeking partners to develop projects
project report MICROTURBINE BY -Asif quamarAsif Quamar
This document summarizes a seminar report on microturbines. It includes 4 chapters:
1) A literature review on microturbines, noting their advantages over other small-scale power generation technologies.
2) An overview of gas turbine systems, including the Brayton cycle and types of gas turbines.
3) A focus on microturbines, defining them as small combustion turbines from 25-500 kW that have evolved from automotive and aircraft technologies.
4) Details on microturbine components, types, and their increasing use for distributed power generation and cogeneration applications.
This document presents information on micro turbines, including their components, characteristics, advantages, applications, challenges, and recent developments. Micro turbines are small combustion turbines that can generate 25-500 kW of power and have moderate costs and efficiencies. They have high-frequency outputs and rotate at high speeds. Micro turbines have applications in distributed generation, quality power and reliability, stand-by power, peak shaving, and combined heat and power. Their advantages include compact size, good efficiencies, lightweight design, and low emissions. Challenges include heat loss, cooling, manufacturing turbine blades, and designing air bearings. Recent developments include coupling with solid oxide fuel cells to increase efficiency.
This document is a seminar report on micro turbines submitted by Rajneesh Kumar Singh in partial fulfillment of the requirements for a Bachelor of Technology degree in Mechanical Engineering. The report provides an overview of micro turbines, including their design, operation, advantages, and applications. It includes sections on gas turbine cycles, characteristics of micro turbines, components of micro turbines, and conclusions.
Microturbine generator systems are small, distributed energy generation systems suitable for small to medium commercial and industrial loads. They consist of a microturbine that provides mechanical energy to a generator, which converts it to electrical energy. Microturbines are a relatively new technology that offers efficiency and clean power generation. They have potential advantages over other distributed generation technologies due to their small size, low cost, and automatic electronic control. The document then provides details on the components, operation, modeling, and control of microturbine generator systems.
This document discusses Elliott Microturbines and their 100kW TA100 combined heat and power (CHP) system. It provides an overview of microturbines compared to conventional generators, describing their higher rpm and use of a permanent magnet generator. The microturbine CHP package is turnkey and integrates components like a heat exchanger. The document also summarizes an installation of 15 TA100 microturbines to provide 1.5MW of power and hot water to a large facility, reducing electrical demand charges. It includes diagrams of the microturbine system and CHP block.
This seminar discusses micro-turbine generator (MTG) systems. MTGs are small, high-speed power plants that typically include a turbine, compressor, generator, and power electronics. They can be used for distributed energy applications to provide power for small to medium commercial and industrial loads. MTGs have recuperated or unrecuperated designs, with recuperated MTGs having higher efficiency due to heat recovery. They work by drawing in air, compressing and combusting it to power a turbine and generator. The generator output is then conditioned and converted to utility frequencies and voltages. MTGs have applications for backup power, power quality/reliability, and cogeneration. Future developments
The document discusses the potential for micro-turbines to become even smaller, possibly reaching a personal scale. It outlines the history of electricity generation moving from localized to large centralized systems. Micro-turbines currently range from 5kW to 300kW and could potentially become as small as 100W units. However, challenges remain around fuel supply, safety, reliability, manufacturing challenges, and regulatory and consumer adoption barriers that must still be overcome before personal-scale micro-turbines become widely used. If these challenges can be addressed, the document suggests personal micro-turbines may start to emerge commercially in the mid-2020s.
This document is a seminar report on micro turbines submitted by Ishfaq Ahmad Najar in partial fulfillment of a Bachelor of Technology degree. It provides an overview of micro turbines, including their basic components and operation. Micro turbines are small combustion turbines that produce both heat and electricity on a relatively small scale. They consist of a compressor, combustor, turbine, alternator, and generator. The turbine turns the compressor and generator, while the combustor adds heat in between. Recuperators are also often included to improve efficiency by capturing waste heat.
This document provides an overview of micro gas turbines. It discusses that micro turbines are small combustion turbines that can generate 25-500 kW of power. They have high power-to-weight ratios and reliability compared to reciprocating engines. Micro turbines are used in distributed generation applications and can utilize various fuels to provide both power and heat in a combined heat and power system. They have potential applications in India to help address power shortages by generating electricity on-site using fuels like biogas.
Micro turbines are a new type of small-scale combustion turbine that produces both heat and electricity efficiently and cleanly for applications like compression and air conditioning. This report focuses on designing and developing a micro turbine powered by compressed nitrogen gas. It reviews literature on micro turbine design aspects, studies gas turbine cycles and micro turbine operation, and designs turbine blades and nozzles using software before analyzing the turbine and nozzle assembly using computational fluid dynamics simulations to obtain velocity vectors.
This document discusses case studies of microturbine combined heat and power (CHP) systems providing cost savings and increased security. It provides three examples: 1) A Radisson hotel in California with two microturbine CHP units providing electricity and hot water, saving $66,336/year. 2) An Inns of America hotel in California with a microturbine CHP unit, saving 40% on energy costs and providing power during a wildfire outage. 3) A restaurant in Italy with a microturbine CHP unit that provided power during a multi-hour blackout. In all cases, the microturbine CHP systems provided both economic and security benefits.
Simulation of a small scale cogeneration system using a microturbinePietro Galli
The aim of the thesis was to develop an operating model of some sizes of Microturbines on the software eQuest.
Then used the model developed to simulate the installation of a Cogeneration (CHP) plant to satisfy the heat and electric demand of a school. The final step was to consider the economics of the investment and choosing which size and use of the turbine was the most convenient for the building.
The key topics of the project were the following:
• Collecting experimental data about some size of Microturbines
• Development of the turbine model for the software eQuest
• Development of the building following the ASHRAE standard
• Simulation of some size of Cogeneration Plants
• Analysis of the results of the simulations
• Energy auditing of the building and analysis of the cost of the current and new plant
• Choice of the best solution for the building
The thesis was developed in collaboration between Politecnico di Torino and the University of Illinois at Chicago, during the course of the double degree program TOP-UIC
A microturbine is a turbine engine-generator typically sized at 250 kW or less that is installed inside or near a building to continuously supply electricity and optionally heat. Microturbines provide opportunities to save money on energy costs, avoid demand charges, support conservation efforts, and help solve facility power problems by producing power on-site to isolate loads and provide backup power during outages or emergencies.
Virginia attorney Bradford Jacob serves as the president of EPC Consulting, LLC, a consultancy serving clients in the oil, gas, chemical, construction, and energy industries. Among other services, Bradford Jacob of Virginia has negotiated energy contracts worth, in aggregate, a total of more than $50 billion, some of which concern combined-cycle power plants.
Combined Heat and Power Generation - Commercial Energy Efficiency with Cogene...The Brewer-Garrett Company
www.brewer-garrett.com
Best practices in combined heat and power (CHP) promote commercial energy efficiency. Presented by energy services company Brewer-Garrett.
Combined heat and power (CHP) refers to the use of a production unit's exhaust heat for another process requirement, improving energy utilization. By capturing waste heat, overall thermal efficiency can increase from 40-50% to 70-90%. CHP installations can be large or small, using fuels like natural gas or biomass, and are used for industrial steam production, agriculture heating, district heating, and small-scale building heating. CHP provides benefits like high efficiency, reduced emissions, cost savings, and power reliability.
Shreya sankrityayan completed a summer training project at the Koderma Thermal Power Station. The report provides an overview of the thermal power generation process, describing the key components of a thermal power plant including the coal handling plant, water treatment plant, boiler system, ash handling plant, electrostatic precipitator, steam turbine, steam condensing system, generator, transformer, and switchyard. It also discusses control and instrumentation systems and concludes with lessons learned from the training experience.
A presentation on summer training at NTPC corporate office noidaAshutosh Tripathi
This document provides a summary of a presentation about a summer training at NTPC Noida. It discusses NTPC's profile, including that it is India's largest power company and was established in 1975. It outlines NTPC's plants, power sharing in India, use of communication technologies like satellites, and new technologies being used like ultra supercritical plants. It also discusses NTPC's use of ash from plants and efforts to increase ash utilization. The presentation concludes by discussing the importance of conserving energy and developing renewable sources to improve the environment.
The combined-cycle power plant uses two gas turbines that produce electricity from combustion of natural gas. Exhaust from the gas turbines powers a steam turbine, increasing total electricity production. Emissions are controlled through selective catalytic reduction and aqueous ammonia injection. The plant can produce up to 600 megawatts of electricity total. Water is treated and recycled to produce steam and for cooling before being returned to the city. Electricity is transmitted to the grid through transformers and a switchyard.
Cogeneration involves the sequential conversion of fuel into multiple usable energy forms. It can produce both electrical and thermal energy, unlike conventional systems. There are two types of cogeneration systems - inplant power generation and reject heat utilization. Inplant power generation produces steam at a higher temperature than needed for manufacturing to also generate electricity using a turbine generator. Reject heat utilization uses excess steam from a power plant for manufacturing. Topping cycles produce electricity first while bottoming cycles produce heat first. Cogeneration provides benefits like fuel economy, lower capital costs, and protection from power outages. Common technologies are steam turbine, gas turbine, combined cycle, and diesel engine systems.
Pro Engineer (Pro/E) is a 3D CAD software used for mechanical design and manufacturing. It uses a parametric, feature-based modeling approach. The key modes in Pro/E include sketching, part creation, assembly, and drawing generation. Common commands like extrude, fillet, pattern, and trim are used to create the features of a turbine part model consisting of an inlet, storage, nozzle, rotor, coupling/shaft, outlet, clip, and housing. The individual parts are then assembled together to form the complete turbine assembly model.
The document provides an overview of Solar Wind Energy, Inc. and its hybrid solar/wind energy technology. The technology uses a hollow tower that injects water at the top to create evaporative cooling and induce winds inside the tower. These winds are harnessed by turbines to generate electricity without requiring solar exposure or unpredictable winds. The summary is:
Solar Wind Energy has developed a hybrid solar/wind energy technology using hollow towers to generate electricity. By injecting water at the top of the towers, evaporative cooling creates winds that turn turbines inside to produce power continuously without needing sunlight or wind. The technology offers a lower-cost alternative to traditional solar and wind with predictable output. Solar Wind Energy is seeking partners to develop projects
Circontrol - EV charging station - Circarlife - Innovation AwardMoises Barea
The document describes CirPark's CirCarLife intelligent electric vehicle charging system. It provides an overview of the company and product range, which includes charging stations for various vehicle types (cars, motorcycles, etc.) that allow smart, networked charging. The system manages charging loads to prevent overloading electric grids and includes payment, monitoring, and integration capabilities. CirCarLife provides a complete solution for electric vehicle charging needs in parking facilities.
Intro on different waste treatment technologies by Bernard AmmounBernard Ammoun
This document is a summary of the different waste treatment options developed by Bernard Ammoun as part of his recommendation to the Lebanese Government 2010
talk on waste management & recovery by sailesh khawaniSailesh Khawani
The document discusses various types of waste and techniques for waste management. It describes municipal solid waste as consisting of biodegradable, recyclable, inert, and hazardous components. Key waste management techniques include landfilling, incineration, and recycling. Landfilling involves burying waste but can cause environmental issues, while incineration converts waste into ash but is more common where land is scarce. Recycling reprocesses materials to reduce consumption of raw materials and pollution.
The document proposes a solution to convert municipal solid waste into energy in urban areas of India. It estimates that 55 million tons of solid waste is generated annually in urban India. The solution involves segregating, collecting, and treating waste to produce syngas via pyrolysis, which would then be used to generate electricity. This waste-to-energy process could help address India's increasing energy demands while reducing waste and pollution from landfills. The proposal estimates the system could generate 3 megawatts of power per day from treating 300 tons of waste and create over 500,000 jobs.
The document provides information about training facilities and opportunities available to Marine Engineer Apprentices at the Pakistan National Shipping Corporation (PNSC). It outlines various workshops that provide hands-on learning including boiler, diesel, electrical, welding, and machine shops. It also introduces the author, Zeeshan Ahmed, and his background as a Marine Engineer who completed training at PNSC workshops onboard various vessels.
This document is a funding proposal from TGE Tech, an Israeli company seeking $3 million to build and demonstrate a municipal solid waste gasification system. TGE has developed a patented gasification technology that transforms waste into synthesis gas and inert ashes. The system is more cost effective and environmentally friendly than incineration. TGE intends to partner with waste management companies to implement the technology and generate revenue from equipment sales, waste treatment services, and energy/carbon credits.
Chromatography is a scientific technique used to separate mixtures based on how compounds interact with two phases - a stationary phase and a mobile phase. There are several types of chromatography including thin layer chromatography, gas chromatography, high performance liquid chromatography, electrophoresis, and paper chromatography. Each type uses different stationary and mobile phases and has various applications such as determining compound compositions, analyzing organic reactions, and identifying unknown substances.
The document provides information about various mountains, mountain ranges, plateaus and plains located in India and surrounding regions. It discusses the highest peaks in the Himalayan mountain range including Mount Everest, K2, Kanchenjunga, Nanga Parbat, Annapurna, Manaslu, Dhaulagiri and Lhotse. It also describes several plateaus found in India such as the Chota Nagpur Plateau, Deccan Plateau, Malwa Plateau and Mysore Plateau. Additionally, it summarizes key plains like the Indo-Gangetic Plain, Western Coastal Plains and Terai region.
PHYSICAL DIVISIONS OF INDIA
India may be divided broadly into SIX physical units : –
1) The Great Northern Mountains.
2) The Northern Plains.
3) The Peninsular Plateau.
4) The Desert.
5) The Coastal Plains.
6) The Islands.
This document describes C2E Energy Holdings Group, a global energy company that invests in energy projects and green technology. It highlights C2E's focus on clean fuel production, waste conversion, and electricity generation from coal, gas, and biomass. The document also provides details on C2E's leadership team, business groups, projects, valuation of a proposed share offering, and invites the reader to purchase shares through an exclusive marketing partner for over 50 times return on investment within 24 months.
This document discusses solid waste management issues in India. It notes that rapid urbanization, neglect by authorities, and public apathy have led to a garbage crisis. To address this, authorities must implement proper waste management systems as per regulations by treating waste via composting, anaerobic digestion, or other technologies. The document outlines several waste treatment options and recommends that vermicomposting is suitable for individual homes, composting is best for medium capacities, and anaerobic digestion is appropriate for large volumes of waste. Effective waste management requires proper collection, transportation, treatment, disposal and public awareness.
Supercritical Fluids for this Super Critical Timecheekygerr
Supercritical fluids have properties between gases and liquids and can be used for environmentally friendly manufacturing. Carbon dioxide is commonly used as a supercritical fluid due to its low critical temperature and pressure and because it is non-toxic, non-flammable, and can be recycled. Supercritical CO2 can be used for extractions, fluoropolymer production, cleaning, nanoparticle formation, and drying without surface tension. Its use could help address pollution, global warming, and energy and resource challenges in the future through more sustainable manufacturing and applications in medicine, energy, and space exploration. Widespread adoption of supercritical fluid technology requires further research and awareness of its benefits over traditional solvents.
Surface mount technology is a method of assembling circuit boards where components are attached to the surface of the board rather than inserted into holes. There are three main types of surface mount assemblies depending on where components are placed on the board. The key processes for surface mount technology include surface mount design, solder paste application, component placement, soldering, cleaning, and potential rework. Infrared and hot gas soldering are two common techniques used for soldering surface mount components.
THE ROLE OF SPCB IN MUNICIPAL SOLID WASTE TREATMENT- INDIAN CONTEXTManoj Chaurasia
This document provides an overview of municipal solid waste collection and disposal in India. It discusses the key governing bodies like the Ministry of Environment and Forests and Pollution Control Boards. Typical municipal solid waste composition in India is described. The need for scientific disposal is outlined due to issues with open dumping. Available municipal solid waste treatment technologies are then summarized, including composting, landfilling, and recycling. Key aspects of operating a municipal solid waste treatment facility are also covered.
Gas chromatography is a technique used to separate and analyze compounds that can be vaporized, with typical uses being testing purity or separating mixture components. It works by having an inert carrier gas move compounds through a column coated with a liquid or polymer stationary phase. Each compound interacts differently with the stationary phase and elutes from the column at different retention times, allowing separation and analysis. Key aspects of gas chromatography include the carrier gas, sample injection port, column temperature control, and various detector types that can identify and quantify the separated compounds.
Integrating fuel cell systems in critical industrial processesZondits
This document presents a case study on using fuel cells to provide premium power for a semiconductor crystal growth facility. Currently, power outages and quality issues at the facility result in shutdowns that cost $50,000-$500,000 per hour. The study evaluates using a 200kW phosphoric acid fuel cell system integrated with the existing backup system at a cost of $9.6 million. Analysis shows the fuel cell system would pay for itself within 8 years due to avoiding losses from power issues, making it a cost-effective solution for providing reliable power to this critical industrial process.
Hydrogen fuel cells as a commercial energy optionLogan Energy Ltd
John Lidderdale from Logan Energy Park gave a presentation on whether fuel cells are commercially viable for on-site energy generation. Logan Energy has experience installing fuel cells since 1994 and provides customer solutions for fuel cell integration. Fuel cells have benefits such as high efficiency, low emissions, reliability, and security of supply. They can reduce carbon emissions by over 40% compared to gas boilers. While capital costs are currently higher than conventional generators, fuel cells have lower lifetime costs and maintenance requirements. Several commercial and government organizations have installed fuel cell systems for their data centers and emergency power needs.
Developing a new generation of energy efficiency products for reciprocating e...Bowman Power
Learn how a new energy efficiency product gets made, from opportunity to concept, design, validation and production, with this free presentation from the 73rd Indonesia National Electricity Day & POWER-GEN Asia. #PGASIA
The document discusses Ballard Fuel Cells and its role in providing clean energy solutions using renewable resources like hydrogen fuel cells. It summarizes Ballard's products in areas like backup power, material handling, bus transportation and distributed generation. Ballard aims to leverage its expertise in proton exchange membrane (PEM) fuel cells to address various clean energy markets worth billions of dollars through established and growing applications.
The document discusses how the Braintree Electric Light Department (BELD) installed two Rolls Royce gas turbines as part of a $110 million power plant repowering project to meet growing energy demands in the region. The turbines provide 116 MW of power during peak demand periods and offer more flexibility than traditional combined cycle plants. They can go from cold start to full power in under 10 minutes, allowing them to rapidly respond to fluctuations in power supply and demand. Having operated for a few years, BELD has found the new turbines to be more cost-effective than the previous plant, lowering electricity rates and saving significant costs during peak demand periods.
PowerSecure is a leading provider of innovative energy solutions to electric utilities and their industrial, institutional, and commercial customers. PowerSecure provides energy solutions in the areas of distributed energy infrastructure, energy efficiency, and utility infrastructure. Distributed energy infrastructure solutions include Interactive Distributed Generation® (iDG®), solar energy, fuel cells, energy storage and microgrid solutions. PowerSecure is a pioneer in developing distributed power systems and integration of distributed energy resources in a sophisticated microgrid.
(1) Granada Green Energy provides clean energy and infrastructure solutions in the USA, Pakistan, Saudi Arabia and MENA region utilizing natural gas, biogas and waste-to-energy technologies.
(2) They design, install and operate natural gas fueling infrastructure for transportation, power generation and marine vessels, as well as combined cooling, heating and power systems and biogas and wastewater treatment facilities.
(3) Their energy solutions are based on Capstone microturbine generators that efficiently convert natural gas to electricity with overall system efficiencies up to 90% when paired with absorption chillers.
An intelligent boiler cleaning system can significantly improve plant profitability by increasing boiler efficiency and reducing operating costs. The document discusses several case studies where intelligent cleaning systems, using sensors and controls to optimize cleaning, increased profits by 30-50% with payback periods of less than 6 months. It also provides guidance on evaluating if a plant is a good candidate for an intelligent cleaning system based on factors like fuel changes, burner retrofits, and slagging issues.
Capstone Turbine develops, manufactures, and services microturbine technology for distributed power generation. As an authorized distributor, E-Finity supports customers in the mid-Atlantic and southeastern U.S. with factory-certified Capstone solutions. Capstone microturbines provide reliable electricity, hot water, and chilled water using a patented air bearing turbine in a simple modular design that is easy to operate and maintain.
This document provides an overview of Cummins Power Generation (CPG), a business unit of Cummins Inc. that manufactures generator sets and power solutions. It discusses CPG's global operations, with manufacturing facilities and technical centers in over 190 countries. CPG serves various markets such as data centers, healthcare, industry, and facilities. The document also highlights some of CPG's customer examples and provides sales information by region and business segment for both Cummins and CPG in 2010.
Conservation Solutions Corporation provides energy and water efficiency services and renewable energy systems. They conduct detailed energy and water audits of commercial buildings to develop efficiency projects. They represent various technology manufacturers and offer services including water treatment, steam trap installation, and pressure independent control valves. Case studies describe projects installing these technologies that achieved energy and water savings as well as improved comfort and reduced maintenance needs.
The document discusses Optimum Energy's HVAC optimization solutions which can reduce energy consumption and costs by 30-60% through technologies like OptimumHVAC, OptimumLOOP, and OptimumTRAV. It provides examples of universities, airports, and research facilities that achieved annual energy savings of 150,000 kWh to over 6,000,000 kWh through Optimum Energy's solutions, with payback periods ranging from 12 to 36 months.
Tecogen-pressRelease-2016 2 9 -Cultivated Power Chiller Salejgkelly1
Tecogen Inc. sold two 150-ton TECOCHILL natural gas engine-driven chillers to an indoor growing facility in Denver, Colorado. The chillers are expected to save the facility over $100,000 per year by significantly reducing electrical demand and energy usage. The chillers also provide free carbon dioxide from cleaned exhaust to improve growing conditions and recover waste heat from the engines for heating and humidity control. This installation will utilize Tecogen chillers and incorporate carbon dioxide capture and utilization for the first time in an indoor growing facility, providing an efficient and ideal growth environment.
Download this at http://parker.com/egt
Currently, cooling, modularity, monitoring and control are common issues in grid tie applications, resulting in decreased efficiency and costly downtime. Future trends are driving towards power converter systems that offer lower cost, higher power density, higher efficiency, as well as high availability and yield. All this while demanding modularity for plug and play and with predictive and preventative maintenance monitoring.
As providers of 85 MGW grid tie conversion systems worldwide, Parker has an extensive product portfolio, application knowledge and experience, therefore well positioned to guide on methods to solve these specific industry challenges, through:
Advanced 2-phase refrigerant invert cooling - 60% smaller in size and provides increased energy output over air cooled solutions
Modular power electronics – ensuring units can be replaced quickly and easily
Implementing a predictive maintenance schedule, such as self-monitoring to reduce potential downtime issues
Techniques to improve the control of your system.
Engage with...TPS | Driving the Electric Revolution WebinarKTN
Turbo Power Systems (TPS) provides innovative high-speed machines and power electronic solutions for the Transport, Energy and Industrial markets. In this webinar, Turbo Power Systems provided insights into the specific expertise and facilities they can bring to the design and deployment of PEMD solutions and critical supply chains, and possible opportunities for collaborative projects and relationships.
How do I apply the most innovative solutions, products and services to my live environment?
In answer to the above question Airedale will demonstrate how you can maximise the efficiency of your live environment without compromising resilience.
With over 40 years’ experience in IT cooling design, build and retrofit across systems, services and controls integration, Airedale is uniquely positioned to present this seminar. The presentation will include a case study on BAE Systems where a year-long retrofit programme has achieved annual savings of 70-80% on computer room air conditioning energy costs, equivalent to £350,000, with a payback of under 15 months.
Speakers: Stuart Kay, Business Development Director & Adrian Trevelyan, Aftersales Manager
Stuart Kay has been involved in specifying some of the UK’s most important data centre installations since the 1990s. With more than 30 years’ experience, his understanding of past and leading-edge technological developments within the industry arm him with a unique knowledge bank that can be applied both to designing new build data centres as well as re-engineering the vast installed base.
Adrian Trevelyan heads up a 50-strong technical team which provides a national installation, maintenance, refurbishment and project management service. With 25 years at Airedale he has significant experience of upgrading live, critical installations to maximise energy efficiency and redundancy. Adrian will present a case study on BAE Systems where a year-long retrofit programme has achieved annual savings of 70-80% on computer room air conditioning energy costs, equivalent to £350,000, with a payback of under 15 months.
The document summarizes information presented at a seminar on heat pumps and renewable energy technologies. It discusses sustainable development and various forms of renewable energy like heat pumps, solar, and wind. It then focuses on heat pumps, explaining how they work, their advantages over gas boilers in terms of cost and carbon emissions, and different types of ground source heat pumps. Micro district heating solutions are also introduced. The document concludes by covering incentives for renewable technologies like the Renewable Heat Incentive and loans available for businesses and organizations.
Secure Supplies provides combined heat and power (CHP) systems ranging from 30kw to 4500kw powered by engines from Cummins, MAN, MWM and CNPC. CHP systems generate electricity while capturing waste heat, achieving overall efficiencies of 65-80%. CHP plants provide local heat, electricity, and sometimes cooling, avoiding transmission losses of conventional power generation.
Essentials of Automations: Exploring Attributes & Automation ParametersSafe Software
Building automations in FME Flow can save time, money, and help businesses scale by eliminating data silos and providing data to stakeholders in real-time. One essential component to orchestrating complex automations is the use of attributes & automation parameters (both formerly known as “keys”). In fact, it’s unlikely you’ll ever build an Automation without using these components, but what exactly are they?
Attributes & automation parameters enable the automation author to pass data values from one automation component to the next. During this webinar, our FME Flow Specialists will cover leveraging the three types of these output attributes & parameters in FME Flow: Event, Custom, and Automation. As a bonus, they’ll also be making use of the Split-Merge Block functionality.
You’ll leave this webinar with a better understanding of how to maximize the potential of automations by making use of attributes & automation parameters, with the ultimate goal of setting your enterprise integration workflows up on autopilot.
Programming Foundation Models with DSPy - Meetup SlidesZilliz
Prompting language models is hard, while programming language models is easy. In this talk, I will discuss the state-of-the-art framework DSPy for programming foundation models with its powerful optimizers and runtime constraint system.
Monitoring and Managing Anomaly Detection on OpenShift.pdfTosin Akinosho
Monitoring and Managing Anomaly Detection on OpenShift
Overview
Dive into the world of anomaly detection on edge devices with our comprehensive hands-on tutorial. This SlideShare presentation will guide you through the entire process, from data collection and model training to edge deployment and real-time monitoring. Perfect for those looking to implement robust anomaly detection systems on resource-constrained IoT/edge devices.
Key Topics Covered
1. Introduction to Anomaly Detection
- Understand the fundamentals of anomaly detection and its importance in identifying unusual behavior or failures in systems.
2. Understanding Edge (IoT)
- Learn about edge computing and IoT, and how they enable real-time data processing and decision-making at the source.
3. What is ArgoCD?
- Discover ArgoCD, a declarative, GitOps continuous delivery tool for Kubernetes, and its role in deploying applications on edge devices.
4. Deployment Using ArgoCD for Edge Devices
- Step-by-step guide on deploying anomaly detection models on edge devices using ArgoCD.
5. Introduction to Apache Kafka and S3
- Explore Apache Kafka for real-time data streaming and Amazon S3 for scalable storage solutions.
6. Viewing Kafka Messages in the Data Lake
- Learn how to view and analyze Kafka messages stored in a data lake for better insights.
7. What is Prometheus?
- Get to know Prometheus, an open-source monitoring and alerting toolkit, and its application in monitoring edge devices.
8. Monitoring Application Metrics with Prometheus
- Detailed instructions on setting up Prometheus to monitor the performance and health of your anomaly detection system.
9. What is Camel K?
- Introduction to Camel K, a lightweight integration framework built on Apache Camel, designed for Kubernetes.
10. Configuring Camel K Integrations for Data Pipelines
- Learn how to configure Camel K for seamless data pipeline integrations in your anomaly detection workflow.
11. What is a Jupyter Notebook?
- Overview of Jupyter Notebooks, an open-source web application for creating and sharing documents with live code, equations, visualizations, and narrative text.
12. Jupyter Notebooks with Code Examples
- Hands-on examples and code snippets in Jupyter Notebooks to help you implement and test anomaly detection models.
Your One-Stop Shop for Python Success: Top 10 US Python Development Providersakankshawande
Simplify your search for a reliable Python development partner! This list presents the top 10 trusted US providers offering comprehensive Python development services, ensuring your project's success from conception to completion.
For the full video of this presentation, please visit: https://www.edge-ai-vision.com/2024/06/how-axelera-ai-uses-digital-compute-in-memory-to-deliver-fast-and-energy-efficient-computer-vision-a-presentation-from-axelera-ai/
Bram Verhoef, Head of Machine Learning at Axelera AI, presents the “How Axelera AI Uses Digital Compute-in-memory to Deliver Fast and Energy-efficient Computer Vision” tutorial at the May 2024 Embedded Vision Summit.
As artificial intelligence inference transitions from cloud environments to edge locations, computer vision applications achieve heightened responsiveness, reliability and privacy. This migration, however, introduces the challenge of operating within the stringent confines of resource constraints typical at the edge, including small form factors, low energy budgets and diminished memory and computational capacities. Axelera AI addresses these challenges through an innovative approach of performing digital computations within memory itself. This technique facilitates the realization of high-performance, energy-efficient and cost-effective computer vision capabilities at the thin and thick edge, extending the frontier of what is achievable with current technologies.
In this presentation, Verhoef unveils his company’s pioneering chip technology and demonstrates its capacity to deliver exceptional frames-per-second performance across a range of standard computer vision networks typical of applications in security, surveillance and the industrial sector. This shows that advanced computer vision can be accessible and efficient, even at the very edge of our technological ecosystem.
[OReilly Superstream] Occupy the Space: A grassroots guide to engineering (an...Jason Yip
The typical problem in product engineering is not bad strategy, so much as “no strategy”. This leads to confusion, lack of motivation, and incoherent action. The next time you look for a strategy and find an empty space, instead of waiting for it to be filled, I will show you how to fill it in yourself. If you’re wrong, it forces a correction. If you’re right, it helps create focus. I’ll share how I’ve approached this in the past, both what works and lessons for what didn’t work so well.
Generating privacy-protected synthetic data using Secludy and MilvusZilliz
During this demo, the founders of Secludy will demonstrate how their system utilizes Milvus to store and manipulate embeddings for generating privacy-protected synthetic data. Their approach not only maintains the confidentiality of the original data but also enhances the utility and scalability of LLMs under privacy constraints. Attendees, including machine learning engineers, data scientists, and data managers, will witness first-hand how Secludy's integration with Milvus empowers organizations to harness the power of LLMs securely and efficiently.
How information systems are built or acquired puts information, which is what they should be about, in a secondary place. Our language adapted accordingly, and we no longer talk about information systems but applications. Applications evolved in a way to break data into diverse fragments, tightly coupled with applications and expensive to integrate. The result is technical debt, which is re-paid by taking even bigger "loans", resulting in an ever-increasing technical debt. Software engineering and procurement practices work in sync with market forces to maintain this trend. This talk demonstrates how natural this situation is. The question is: can something be done to reverse the trend?
Freshworks Rethinks NoSQL for Rapid Scaling & Cost-EfficiencyScyllaDB
Freshworks creates AI-boosted business software that helps employees work more efficiently and effectively. Managing data across multiple RDBMS and NoSQL databases was already a challenge at their current scale. To prepare for 10X growth, they knew it was time to rethink their database strategy. Learn how they architected a solution that would simplify scaling while keeping costs under control.
Discover top-tier mobile app development services, offering innovative solutions for iOS and Android. Enhance your business with custom, user-friendly mobile applications.
HCL Notes and Domino License Cost Reduction in the World of DLAUpanagenda
Webinar Recording: https://www.panagenda.com/webinars/hcl-notes-and-domino-license-cost-reduction-in-the-world-of-dlau/
The introduction of DLAU and the CCB & CCX licensing model caused quite a stir in the HCL community. As a Notes and Domino customer, you may have faced challenges with unexpected user counts and license costs. You probably have questions on how this new licensing approach works and how to benefit from it. Most importantly, you likely have budget constraints and want to save money where possible. Don’t worry, we can help with all of this!
We’ll show you how to fix common misconfigurations that cause higher-than-expected user counts, and how to identify accounts which you can deactivate to save money. There are also frequent patterns that can cause unnecessary cost, like using a person document instead of a mail-in for shared mailboxes. We’ll provide examples and solutions for those as well. And naturally we’ll explain the new licensing model.
Join HCL Ambassador Marc Thomas in this webinar with a special guest appearance from Franz Walder. It will give you the tools and know-how to stay on top of what is going on with Domino licensing. You will be able lower your cost through an optimized configuration and keep it low going forward.
These topics will be covered
- Reducing license cost by finding and fixing misconfigurations and superfluous accounts
- How do CCB and CCX licenses really work?
- Understanding the DLAU tool and how to best utilize it
- Tips for common problem areas, like team mailboxes, functional/test users, etc
- Practical examples and best practices to implement right away
Northern Engraving | Nameplate Manufacturing Process - 2024Northern Engraving
Manufacturing custom quality metal nameplates and badges involves several standard operations. Processes include sheet prep, lithography, screening, coating, punch press and inspection. All decoration is completed in the flat sheet with adhesive and tooling operations following. The possibilities for creating unique durable nameplates are endless. How will you create your brand identity? We can help!
The Microsoft 365 Migration Tutorial For Beginner.pptxoperationspcvita
This presentation will help you understand the power of Microsoft 365. However, we have mentioned every productivity app included in Office 365. Additionally, we have suggested the migration situation related to Office 365 and how we can help you.
You can also read: https://www.systoolsgroup.com/updates/office-365-tenant-to-tenant-migration-step-by-step-complete-guide/
Connector Corner: Seamlessly power UiPath Apps, GenAI with prebuilt connectorsDianaGray10
Join us to learn how UiPath Apps can directly and easily interact with prebuilt connectors via Integration Service--including Salesforce, ServiceNow, Open GenAI, and more.
The best part is you can achieve this without building a custom workflow! Say goodbye to the hassle of using separate automations to call APIs. By seamlessly integrating within App Studio, you can now easily streamline your workflow, while gaining direct access to our Connector Catalog of popular applications.
We’ll discuss and demo the benefits of UiPath Apps and connectors including:
Creating a compelling user experience for any software, without the limitations of APIs.
Accelerating the app creation process, saving time and effort
Enjoying high-performance CRUD (create, read, update, delete) operations, for
seamless data management.
Speakers:
Russell Alfeche, Technology Leader, RPA at qBotic and UiPath MVP
Charlie Greenberg, host
What is an RPA CoE? Session 1 – CoE VisionDianaGray10
In the first session, we will review the organization's vision and how this has an impact on the COE Structure.
Topics covered:
• The role of a steering committee
• How do the organization’s priorities determine CoE Structure?
Speaker:
Chris Bolin, Senior Intelligent Automation Architect Anika Systems