Read more.īuilding the world’s smartest pharma company with Orion Together we have, for instance, implemented machine learning for food search and recommendations in their online grocery stores. With complete ownership of their AI roadmap, Kesko has various business-critical machine learning applications in production. We’ve been an integral part of Kesko’s AI journey, significantly ramping up their capabilities. Moving efficiently from Data Science to AI with Kesko
REAKTOR CHEMICZNY CRACK
Focusing on problems that are the easiest to crack won’t take you forward – if they were crucial to your business, they would have been resolved already.ĪI is an investment beyond money: it requires continuous learning, cross-functional collaboration – and sometimes even a complete revamp of your practices, processes, and culture. Instead of going for the low-hanging fruits, organizations should look for the opportunities that create the most value.
REAKTOR CHEMICZNY FULL
Harnessing AI to its full potential, however, takes more than an experiment here and there. Catching up with the competition is still possible for almost anyone, especially with so many open-sourced machine learning innovations widely available. This provides immense potential for companies at all stages of technological maturity. Yet, only a few companies are truly changing their business with AI: 80% of the companies are still in the proof-of-concept factory phase, and less than 20% are scaling AI. These latter one should be the subject of further development, since it offers a non-equilibrium course of the synthesis process at low temperatures and at surprisingly low energy expenditure.We are on the verge of widespread adoption of artificial intelligence in business and society at large. The conclusions drawn on the basis of the results of this work permit to recommend both the technology of microwave synthesis and the synthesis involving pulse induction. The analysis of powders was carried out by XRD and BET methods, and observations of the morphology of the powders was carried out by means of a scanning electron microscope. Another novel reactor involving the reaction induction with high voltage was also applied, and an autoclave with a heated Teflon container was used as the fifth's chemical reactor. A reactor of the ERTEC company was utilized, used in three variants -as a microwave reactor, as a reactor with a meander etectric heater and as reactor utilizing current flow through liquid reactants: Joule's heat. Five different methods of inducing chemical reactions were used for performing the experiments. The purpose of the work was to study the effect of the induction technique applied on the morphology and properties of nano zinc oxide. Te ostatnie powinny stać się obiektem dalszego rozwoju, gdyż oferują nierównowagowy przebieg procesu syntezy w niskich temperaturach i przy zaskakująco niskim wydatku energetycznym. Wnioski wyciągnięte na podstawie wyników tej pracy pozwalają rekomendować do wykorzystania zarówno technologie syntez mikrofalowych jak też syntez przy pobudzeniu impulsowym. Analizy proszków przeprowadzono metodami XRD, BET oraz przeprowadzono obserwację morfologii proszków przy użyciu skaningowego mikroskopu elektronowego SEM. Wykorzystano reaktor firmy ERTEC, który był stosowany w trzach wariantach - jako reaktor mikrofalowy, jako reaktor z meandrową grzałką elektryczną oraz jako reaktor wykorzystujący przepływ prądu przez ciekłe reagenty: Zastosowano również inny nowatorski reaktor z pobudzeniem reakcji impulsami wysokiego napięcia, zaś jako piąty reaktor chemiczny zastosowany został autoklaw z podgrzewanym teflonowym zbiornikiem. Przy realizacji eksperymentów użyto pięciu różnych metod pobudzania reakcji chemicznych. Celem niniejszej pracy było zbadanie wpływu rodzaju zastosowanej techniki wzbudzania reakcji na morfologię oraz właściwości nano tlenku cynku.