Working Principle: Achieves high-efficiency adsorption without mechanical moving parts Performance Features: Multi-stage ejector design delivers high vacuum flow while significantly reducing air consumption, markedly improving energy efficiency Structural Quality: Ensures stable and extended service life in industrial environments Installation Flexibility: Compact design with standardized mounting options and multiple vacuum ports Application Versatility: Suitable for diverse material handling tasks, including packaging, machining, and assembly processes requiring reliable vacuum sources

Working Principle: Achieves high-efficiency adsorption without mechanical moving parts Performance Features: Multi-stage ejector design delivers high vacuum flow while significantly reducing air consumption, markedly improving energy efficiency Structural Quality: Ensures stable and extended service life in industrial environments Installation Flexibility: Compact design with standardized mounting options and multiple vacuum ports Application Versatility: Suitable for diverse material handling tasks, including packaging, machining, and assembly processes requiring reliable vacuum sources

Working Principle: Achieves high-efficiency adsorption without mechanical moving parts Performance Features: Multi-stage ejector design delivers high vacuum flow while significantly reducing air consumption, markedly improving energy efficiency Structural Quality: Ensures stable and extended service life in industrial environments Installation Flexibility: Compact design with standardized mounting options and multiple vacuum ports Application Versatility: Suitable for diverse material handling tasks, including packaging, machining, and assembly processes requiring reliable vacuum sources

Working Principle: Achieves high-efficiency adsorption without mechanical moving parts Performance Features: Multi-stage ejector design delivers high vacuum flow while significantly reducing air consumption, markedly improving energy efficiency Structural Quality: Ensures stable and extended service life in industrial environments Installation Flexibility: Compact design with standardized mounting options and multiple vacuum ports Application Versatility: Suitable for diverse material handling tasks, including packaging, machining, and assembly processes requiring reliable vacuum sources

Working Principle: Achieves high-efficiency adsorption without mechanical moving parts Performance Features: Multi-stage ejector design delivers high vacuum flow while significantly reducing air consumption, markedly improving energy efficiency Structural Quality: Ensures stable and extended service life in industrial environments Installation Flexibility: Compact design with standardized mounting options and multiple vacuum ports Application Versatility: Suitable for diverse material handling tasks, including packaging, machining, and assembly processes requiring reliable vacuum sources

Working Principle: Achieves high-efficiency adsorption without mechanical moving parts Performance Features: Multi-stage ejector design delivers high vacuum flow while significantly reducing air consumption, markedly improving energy efficiency Structural Quality: Ensures stable and extended service life in industrial environments Installation Flexibility: Compact design with standardized mounting options and multiple vacuum ports Application Versatility: Suitable for diverse material handling tasks, including packaging, machining, and assembly processes requiring reliable vacuum sources

Working Principle: Achieves high-efficiency adsorption without mechanical moving parts Performance Features: Multi-stage ejector design delivers high vacuum flow while significantly reducing air consumption, markedly improving energy efficiency Structural Quality: Ensures stable and extended service life in industrial environments Installation Flexibility: Compact design with standardized mounting options and multiple vacuum ports Application Versatility: Suitable for diverse material handling tasks, including packaging, machining, and assembly processes requiring reliable vacuum sources

Working Principle: Achieves high-efficiency adsorption without mechanical moving parts Performance Features: Multi-stage ejector design delivers high vacuum flow while significantly reducing air consumption, markedly improving energy efficiency Structural Quality: Ensures stable and extended service life in industrial environments Installation Flexibility: Compact design with standardized mounting options and multiple vacuum ports Application Versatility: Suitable for diverse material handling tasks, including packaging, machining, and assembly processes requiring reliable vacuum sources

Working Principle: Achieves high-efficiency adsorption without mechanical moving parts Performance Features: Multi-stage ejector design delivers high vacuum flow while significantly reducing air consumption, markedly improving energy efficiency Structural Quality: Ensures stable and extended service life in industrial environments Installation Flexibility: Compact design with standardized mounting options and multiple vacuum ports Application Versatility: Suitable for diverse material handling tasks, including packaging, machining, and assembly processes requiring reliable vacuum sources

Working Principle: Achieves high-efficiency adsorption without mechanical moving parts Performance Features: Multi-stage ejector design delivers high vacuum flow while significantly reducing air consumption, markedly improving energy efficiency Structural Quality: Ensures stable and extended service life in industrial environments Installation Flexibility: Compact design with standardized mounting options and multiple vacuum ports Application Versatility: Suitable for diverse material handling tasks, including packaging, machining, and assembly processes requiring reliable vacuum sources

Working Principle: Achieves high-efficiency adsorption without mechanical moving parts Performance Features: Multi-stage ejector design delivers high vacuum flow while significantly reducing air consumption, markedly improving energy efficiency Structural Quality: Ensures stable and extended service life in industrial environments Installation Flexibility: Compact design with standardized mounting options and multiple vacuum ports Application Versatility: Suitable for diverse material handling tasks, including packaging, machining, and assembly processes requiring reliable vacuum sources

Working Principle: Achieves high-efficiency adsorption without mechanical moving parts Performance Features: Multi-stage ejector design delivers high vacuum flow while significantly reducing air consumption, markedly improving energy efficiency Structural Quality: Ensures stable and extended service life in industrial environments Installation Flexibility: Compact design with standardized mounting options and multiple vacuum ports Application Versatility: Suitable for diverse material handling tasks, including packaging, machining, and assembly processes requiring reliable vacuum sources

Working Principle: Achieves high-efficiency adsorption without mechanical moving parts Performance Features: Multi-stage ejector design delivers high vacuum flow while significantly reducing air consumption, markedly improving energy efficiency Structural Quality: Ensures stable and extended service life in industrial environments Installation Flexibility: Compact design with standardized mounting options and multiple vacuum ports Application Versatility: Suitable for diverse material handling tasks, including packaging, machining, and assembly processes requiring reliable vacuum sources

Das Scott SCOTT Trail Flow DRI S/S Herren Bikeshirt ist ein technisches Shirt im lässigen Look. Mit dem recycelten DRIrelease ECO-Material und dem Mesh-Rückenpanel für bessere Belüftung bleibt dieses Shirt trocken und frisch, egal wie lange du auf dem Bike unterwegs bist. - Drirelease E.C.O.-Strick - Ausgezeichneter Tragekomfort durch ein weiches Tragegefühl - Mesh-Einsatz auf der Rückseite für verbesserte Luftzirkulation - Re-Source Produkt - Gewicht laut Hersteller: 135g - Obermaterial 2: 85 % Polyester (recycelt), 15 % Bio-Baumwolle - Obermaterial: 85 % Polyester (recycelt), 15 % Bio-Baumwolle - Technologie: drirelease E.C.O.-Strick

Das Scott Trail Flow Dri Damen Bikeshirt ist ein technisches Shirt im Casual Look. Mit seinem recycelten DRIrelease E.C.O-Material sowie dem Rückeneinsatz aus Mesh für bessere Belüftung bleibt dieses Shirt länger trocken und frisch, wenn du im Sommer auf deinen Lieblingsstrecken unterwegs bist. - DRIrelease E.C.O.-Strick leitet die Feuchtigkeit ab und sorgt für ein frisches Gefühl - Ausgezeichneter Tragekomfort durch ein weiches Tragegefühl - Mesh-Einsatz am Rücken für verbesserte Luftzirkulation - Obermaterial: 76 % recyceltes Polyester, 14 % Bio-Baumwolle, 10 % Elasthan - Obermaterial 2: 85 % recycelter Polyester, 15 % Bio-Baumwolle - Passform: Regular - Re-Source Produkt - Gewicht laut Hersteller: 130 g

Das Scott Trail Flow Dri Damen Bikeshirt ist ein technisches Shirt im Casual Look. Mit seinem recycelten DRIrelease E.C.O-Material sowie dem Rückeneinsatz aus Mesh für bessere Belüftung bleibt dieses Shirt länger trocken und frisch, wenn du im Sommer auf deinen Lieblingsstrecken unterwegs bist. - DRIrelease E.C.O.-Strick leitet die Feuchtigkeit ab und sorgt für ein frisches Gefühl - Ausgezeichneter Tragekomfort durch ein weiches Tragegefühl - Mesh-Einsatz am Rücken für verbesserte Luftzirkulation - Obermaterial: 76 % recyceltes Polyester, 14 % Bio-Baumwolle, 10 % Elasthan - Obermaterial 2: 85 % recycelter Polyester, 15 % Bio-Baumwolle - Passform: Regular - Re-Source Produkt - Gewicht laut Hersteller: 130 g

SFP+ 10GBASE-SR Multi-Mode-Glasfaser-Transceiver (300 m) Der DEM-431XT ist ein leistungsstarker 850-nm-Multi-Mode-SFP+-Transceiver, der für Entfernungen bis zu 300 m ausgelegt ist. Er unterstützt Vollduplex, 10 Gigabit-Geschwindigkeiten auf Multi-Mode-Glasfaserkabeln. Der DEM-431XT ist 802.3ae 10GBASE-SR-kompatibel und unterstützt Vollduplex 802.3x Flow Control. Der DEM-431XT bietet die notwendige Signalverstärkung für die Datenübertragung vom Port zum Netzwerkkabel und umgekehrt. Kostengünstige Lösung für eine 10G-Glasfaserverbindung Kleiner Formfaktor, der höhere Portdichten für 10G-Verbindungen ermöglicht Geringere Verlustleistung Hot-plug-fähig Kompatibel mit Ethernet 802.3ae Entspricht der Faser-MSA (Multiple Source Agreement)

AESME STUDIO offer a masterclass in designing naturalistic floral arrangements with a sense of place in a range of stunning settings, from the English countryside to Europe and beyond. Sisters Ally and Jess are the founders of leading London flower company AESME STUDIO and have created a unique naturalistic style that connects floral design back to nature. This, their first book, takes the reader on a journey through the seasons. The sisters visit twelve unique locations throughout the UK, Europe and beyond to gather flowers and create seasonal floral arrangements with a sense of place. Naturalistic floral design is about using local, wild and seasonal flowers to create beautiful, sustainable arrangements that are in harmony with their location. From English country houses to a garden in Provence, Jess and Ally have spent a year documenting their travels to provide a unique guide to how to create stunning - and often inexpensive - arrangements wherever you are. Each chapter tells the story of the sisters' discoveries along the way and explores a location through its regional flowers and scenery, offering plenty of ideas for styling flowers along with arrangement 'recipes' that show how each was designed and created. Whether you are interested in naturalistic floral design or just looking for tips and ideas to style flowers more sustainably at home, this journey through a year of floral arrangements will be a rich source of inspiration for anyone looking to decorate with seasonal flowers.

AESME STUDIO offer a masterclass in designing naturalistic floral arrangements with a sense of place in a range of stunning settings, from the English countryside to Europe and beyond. Sisters Ally and Jess are the founders of leading London flower company AESME STUDIO and have created a unique naturalistic style that connects floral design back to nature. This, their first book, takes the reader on a journey through the seasons. The sisters visit twelve unique locations throughout the UK, Europe and beyond to gather flowers and create seasonal floral arrangements with a sense of place. Naturalistic floral design is about using local, wild and seasonal flowers to create beautiful, sustainable arrangements that are in harmony with their location. From English country houses to a garden in Provence, Jess and Ally have spent a year documenting their travels to provide a unique guide to how to create stunning - and often inexpensive - arrangements wherever you are. Each chapter tells the story of the sisters' discoveries along the way and explores a location through its regional flowers and scenery, offering plenty of ideas for styling flowers along with arrangement 'recipes' that show how each was designed and created. Whether you are interested in naturalistic floral design or just looking for tips and ideas to style flowers more sustainably at home, this journey through a year of floral arrangements will be a rich source of inspiration for anyone looking to decorate with seasonal flowers.

The short-channel and hot-carrier effects that arise when MOSFET devices are scaled down to very short channel lengths is a major topic of research in the area of VLSI technology. Grooved gate MOSFETS alleviate many of these. Here a systematic study of the major electrical characteristics of grooved gate device is done at gate lengths of 100 nm. An optimised process flow is presented to overcome two of its major drawbacks - higher gate-to-source/drain parasitic capacitance and lack of a self-aligned and integrated gate structure. The resulting device exhibits significantly enhanced characteristics. An analytical model for the gate-to-source/drain capacitance characteristics of the grooved gate device is then presented. It features an extrinsic capacitance model that incorporates the strong bias dependence of overlap capacitance and deals with the issues involved in optimisation and analysis of not only such novel device structures but source/drain engineered conventional planar devices also. This work should be especially useful to professionals and students in Microelectronics field who are engaged in processing, characterization and modelling of deep sub-micron VLSI devices.