175,521 research outputs found
Psalmi <dt.>
Autopsie nach Ex. der ULB Sachsen-AnhaltVorlageform des Erscheinungsvermerks: London: Gedruckt und zu bekommen bey Joh. C. Haberkorn, und Joh. N. Gussen, in Gerrard-street, St. Ann's, Soho; Wie auch bey Andreas Linde, Papierhändler, und Buchbinder zu Jhro Königl. Hoheit Printz George, in Katherine-street, in den Strand. 1751
Testamentum novum <dt.>
Titelbl. in Rot- und Schwarzdr.Autopsie nach Ex. der ULB Sachsen-AnhaltVorlageform des Erscheinungsvermerks: London: Gedruckt und verlegt bey Joh. C. Haberkorn, und Joh. N. Gussen, in Gerrard-street, St. Ann's, Soho; Wie auch bey Andreas Linde, Papierhändler, und Buchbinder zu Jhro Königl. Hoheit Printz George, in Katherine-street, in den Strand. 1751
Large Pilot Testing of Linde-BASF Advanced Post-Combustion CO2 Capture Technology at a Coal-Fired Power Plant [CWLP] [FE0031581]
Researchers at the University of Illinois, in partnership with the Linde Group, BASF Corporation, Affiliated Engineers, Inc., and Affiliated Construction Services, Inc., are designing an amine-based carbon dioxide (CO2) capture pilot-scale (10 megawatt-electric [MWe]) system at an existing coal-fired power plant. The system is based on the Linde-BASF advanced CO2 capture process incorporating BASF’s novel solvent with an advanced stripper inter-stage heater design to optimize heat recovery. In a previous U.S. Department of Energy (DOE)-funded project, the Linde-BASF CO2 capture technology showed the potential to be cost-effective and energy-efficient using actual flue gas during pilot-scale (1.5 MWe) testing at the National Carbon Capture Center. The aqueous amine-based solvent was optimized to exhibit long-term stability and a 20 percent reduction in regeneration energy requirements when compared to commercially available solvents; additional improvements in process design further reduce the cost of CO2 capture.
Projects to design, construct, and operate large-scale pilots of transformational coal technologies are being conducted in three phases, with a down-select between phases. In Phase I of this project, the team completed preliminary design and engineering analyses for a 10 MWe capture facility installed at three potential host sites and selected the City, Water, Light and Power’s (CWLP) Dallman Power Plant as the host site based on the studies. The project team also completed an Environmental Information Volume (EIV) for the selected site, updated preliminary cost and schedule estimates, secured cost-share commitments for Phase II, and developed a plan for securing cost-share commitments for Phase III. The project was selected for Phase II (Design), in which the team will complete a front-end engineering design (FEED) study, including a detailed cost and schedule estimate for Phase III for the installation of the 10 MWe pilot at CWLP, complete the National Environmental Policy Act (NEPA) process and any required permitting processes at CWLP, secure Phase III (construction/operation) cost share funding, and complete an updated techno-economic analysis of the technology based on the most recent system design and cost information.
The Phase III objectives are to complete detailed engineering, procurement of equipment and modules, and build and operate a 10 MWe large pilot of the Linde/BASF post-combustion carbon capture technology at the CWLP Dallman Power Plant in Springfield, Illinois. The Phase III scope of work includes: (1) obtaining construction and operating permits for all regulated activities occurring during Phase III; (2) finalizing functional specifications and completing detailed engineering; (3) procuring equipment and materials for inside and outside the boundary limits (ISBL and OSBL); (4) constructing and installing the large pilot; (5) commissioning of the large pilot plant followed by parametric and steady-state operating test campaigns; (6) analyzing test campaign results; and (7) updating the techno-economic analysis (TEA) based on the design and cost information developed during the Phase III test campaign.
The approach used for design, construction, and commissioning is an important feature of the technology and will help enable the commercialization process. The regional economic benefit and the ability to repurpose some existing workforce at CWLP will also demonstrate how carbon capture can aid regional economies when it is deployed. If the technology performs as planned, there is a desire to have the capture plant remain in place and be utilized for future testing of capture and utilization technologies.Open Restriction set for Item 118175 on 2021-08-25T18:02:54Z with date null by [email protected] by Laura Barnes ([email protected]) on 2021-08-25T18:21:42Z
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Previous issue date: 2019-10-01U.S. Department of Energy ; DE-FE0007453 (predecessor project)U.S. Department of Energy ; DE-FE0026588 (predecessor project)U.S. Department of Energy ; DE-FE0031581Ope
An In Vitro Pilot Fermentation Study on the Impact of Chlorella pyrenoidosa on Gut Microbiome Composition and Metabolites in Healthy and Coeliac Subjects
© 2021 C. van der Linde, M. Barone, S. Turroni, P. Brigidi, E. Keleszade, J. Swann, A. Costabile. This is an open-access article distributed under the terms of the Creative Commons Attribution 4.0 International License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. See http://creativecommons.org/licenses/by/4.0
tæt talks med Sofie Linde
2022 – Matas - tæt talk med Sofie Linde - https://www.matas.dk/taet?fbclid=IwAR1JZplnve0R2ocK-GqnHQ-kFtYLknG4zwLAJCQAaZX0KYZK2gXUyZvdzz
Large Pilot Scale Testing of Linde/BASF Post-Combustion CO2 Capture Technology at the Abbott Coal-Fired Power Plant
The work summarized in this report is the first step towards a project that will re-train and create jobs for personnel in the coal industry and continue regional economic development to benefit regions impacted by previous downturns. The larger project is aimed at capturing ~300 tons/day (272 metric tonnes/day) CO2 at a 90% capture rate from existing coal- fired boilers at the Abbott Power Plant on the campus of University of Illinois (UI). It will employ the Linde-BASF novel amine-based advanced CO2 capture technology, which has already shown the potential to be cost-effective, energy efficient and compact at the 0.5-1.5 MWe pilot scales. The overall objective of the project is to design and install a scaled-up system of nominal 15 MWe size, integrate it with the Abbott Power Plant flue gas, steam and other utility systems, and demonstrate the viability of continuous operation under realistic conditions with high efficiency and capacity. The project will also begin to build a workforce that understands how to operate and maintain the capture plants by including students from regional community colleges and universities in the operation and evaluation of the capture system. This project will also lay the groundwork for follow-on projects that pilot utilization of the captured CO2 from coal-fired power plants. The net impact will be to demonstrate a replicable means to (1) use a standardized procedure to evaluate power plants for their ability to be retrofitted with a pilot capture unit; (2) design and construct reliable capture systems based on the Linde-BASF technology; (3) operate and maintain these systems; (4) implement training programs with local community colleges and universities to establish a workforce to operate and maintain the systems; and (5) prepare to evaluate at the large pilot scale level various methods to utilize the resulting captured CO2. Towards the larger project goal, the UI-led team, together with Linde, has completed a preliminary design for the carbon capture pilot plant with basic engineering and cost estimates, established permitting needs, identified approaches to address Environmental, Health, and Safety concerns related to pilot plant installation and operation, developed approaches for long-term use of the captured carbon, and established strategies for workforce development and job creation that will re-train coal operators to operate carbon capture plants. This report describes Phase I accomplishments and demonstrates that the project team is well-prepared for full implementation of Phase 2, to design, build, and operate the carbon capture pilot plant.Open Restriction set for Item 104030 on 2017-11-02T20:10:15Z with date null by [email protected] by Laura Barnes ([email protected]) on 2017-11-02T20:17:33Z
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Previous issue date: 2017-08-18U.S. Department of Energy National Energy Technology Laboratory ; Award number DE-FE0026588Ope
Large Pilot Scale Testing of Linde/BASF Post-Combustion CO2 Capture Technology at the Abbott Coal-Fired Power Plant: Final Report : Grant Period: October 1, 2015 to May 31, 2017 [Phase I]
The work summarized in this report is the first step towards a project that will re-train and create jobs for personnel in the coal industry and continue regional economic development to benefit regions impacted by previous downturns. The larger project is aimed at capturing ~300 tons/day (272 metric tonnes/day) CO2 at a 90% capture rate from existing coal- fired boilers at the Abbott Power Plant on the campus of University of Illinois (UI). It will employ the Linde-BASF novel amine-based advanced CO2 capture technology, which has already shown the potential to be cost-effective, energy efficient and compact at the 0.5-1.5 MWe pilot scales. The overall objective of the project is to design and install a scaled-up system of nominal 15 MWe size, integrate it with the Abbott Power Plant flue gas, steam and other utility systems, and demonstrate the viability of continuous operation under realistic conditions with high efficiency and capacity. The project will also begin to build a workforce that understands how to operate and maintain the capture plants by including students from regional community colleges and universities in the operation and evaluation of the capture system. This project will also lay the groundwork for follow-on projects that pilot utilization of the captured CO2 from coal-fired power plants. The net impact will be to demonstrate a replicable means to (1) use a standardized procedure to evaluate power plants for their ability to be retrofitted with a pilot capture unit; (2) design and construct reliable capture systems based on the Linde-BASF technology; (3) operate and maintain these systems; (4) implement training programs with local community colleges and universities to establish a workforce to operate and maintain the systems; and (5) prepare to evaluate at the large pilot scale level various methods to utilize the resulting captured CO2. Towards the larger project goal, the UI-led team, together with Linde, has completed a preliminary design for the carbon capture pilot plant with basic engineering and cost estimates, established permitting needs, identified approaches to address Environmental, Health, and Safety concerns related to pilot plant installation and operation, developed approaches for long-term use of the captured carbon, and established strategies for workforce development and job creation that will re-train coal operators to operate carbon capture plants. This report describes Phase I accomplishments and demonstrates that the project team is well-prepared for full implementation of Phase 2, to design, build, and operate the carbon capture pilot plant.U.S. Department of Energy Award Number DE-FE0026588Ope
Informe Final Empresa Linde Colombia
El presente trabajo describe las actividades realizadas como practicante profesional en la empresa Linde Colombia, la cual es la empresa más grande a nivel mundial de ingeniería, tecnología, gases industriales y medicinales. A demás, está posicionada a nivel mundial como lideres en ingeniería química. Colombia pertenece a Linde Latam Norte conformado por 10 países en América latina. Una de sus sedes principales en Colombia está ubicada en Tocancipá, Cundinamarca con dirección parque industrial Gran Sabana Lote M Unidad 62. La duración de las prácticas fue de 6 meses, cumpliendo con el tiempo establecido para la validación de las mismas como opción de grado en la Universidad Santo Tomás. El trabajo presenta un contexto completo de la empresa, incluyendo su actividad económica, historia, organigrama y valores.
Por otro lado, se describe el cargo obtenido durante las prácticas, las funciones desempeñadas y la ejecución de proyectos asignados en el área financiera y comercial de Linde. El desarrollo de estas actividades permitió una comprensión más profunda del funcionamiento interno de una empresa multinacional, así como la aplicación de conocimientos adquiridos en la carrera de negocios internacionales.This work describes the activities performed as a professional intern in the company Linde Colombia, which is the world's largest company in engineering, technology, industrial and medical gases. In addition, it is positioned worldwide as a leader in chemical engineering. Colombia belongs to Linde Latam North, which is made up of 10 countries in Latin America. One of its main offices in Colombia is located in Tocancipá, Cundinamarca with address Gran Sabana Industrial Park, Lot M Unit 62. The duration of the internship was 6 months, complying with the time established for the validation of the internship as a degree option at Universidad Santo Tomás. The work presents a complete context of the company, including its economic activity, history, organization chart and values.
On the other hand, it describes the position obtained during the internship, the functions performed and the execution of projects assigned in the financial and commercial area of Linde. The development of these activities allowed a deeper understanding of the inner workings of a multinational company, as well as the application of knowledge acquired in the international business career.Profesional en Negocios Internacionaleshttp://www.ustavillavicencio.edu.co/home/index.php/unidades/extension-y-proyeccion/investigacionPregrad
Electrical therapies for the heart: a 50-year story projected into the future.
Celebrating 50 years of electrical therapies for the heart
Around Fifty years ago, on 8 October 1958, Elmqvist and Senning, at the Karolinska Hospital in Stockholm, implanted the first endocardial pacemaker to treat a patient with recurrent Adam–Stokes episodes.1
Since this pioneering experience, arrhythmia management has evolved enormously in the last 50 years, with electrophysiology being one of the areas of medicine where technology has had the strongest impact.2 The technologically driven evolution of devices and tools has been complemented by the acquisition of important scientific evidence of benefit in specific patient settings. Accumulation of hard evidence has allowed us to progress from pioneering experiences with pacemakers, implantable cardioverter-defibrillators (ICDs), and ablative techniques in very sick subjects treated in a handful of research centres to widespread routine use of such interventions in hundreds of thousands of patients around the world. The type of therapeutic target has also evolved: from ‘rescue’ interventions in high-risk conditions (complete atrioventricular block for pacemakers, multiple cardiac arrests for ICDs, high-risk ventricular pre-excitation for ablation) to ‘preventive’ interventions designed to avoid the risk of serious consequences stemming from the development of severe bradyarrhythmias, ventricular tachyarrhythmias or supraventricular tachyarrhythmias, or related to heart failure.
In view of the need to keep clinical practice abreast of the ongoing changes in the potential for care, this evolution has required extensive cooperation between physicians, scientists, engineers, manufacturers, regulatory agencies, and health care providers. Clearly, the rapidity and extent of change has many important practical implications, related to themes such as emerging clinical skills, the complexity of current technology, treatment costs, the need for consensus guidelines, re-organization of care delivery, and the potential of telemedicine.
In this supplement we have collected some of the most prominent issues in the field today in the context of lessons learnt in these 50 years of co-operative engagement. We have chosen to spotlight topical issues within the broad spectrum of electrical therapies for the heart: antibradycardia pacing (current and new indications, sensors, autocapture, alternative sites of pacing, etc.); sudden death prevention (risk stratification, current use of ICDs, and barriers to implementation of current guidelines); cardiac resyncronization therapy for heart failure (patient selection, haemodynamic and clinical effects); arrhythmia ablation (indications and technical advances); atrial fibrillation management in the real world, and ablation therapy for atrial fibrillation (mapping and ablation techniques)
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