The platform for open and practice-oriented research

product

Greenfertilizer, zonnemelken voor een carbo-neutrale landbouw

Kunstmest voor de velden en brandstof voor landbouwvoertuigen zijn belangrijke kostenposten voor de landbouw. Kunstmest en dieselbrandstof zijn energie-intensieve producten en daarmee ook een belangrijke bron van CO2 emissies vanuit de landbouw. Technologie voor hernieuwbare energie zoals zonne- en wind energie wordt steeds goedkoper waardoor het rendabeler wordt deze technologie ook te gebruiken. Terug leveren van geproduceerde hernieuwbare elektriciteit aan het elektriciteitsnet is echter niet altijd voordelig. De hernieuwbare energie moet hier concurreren met gesubsidieerde fossiele elektriciteit opgewekt met kolen, gas en kerncentrales. Kleinschalige decentrale productie op het boerenbedrijf van zowel kunstmest als transportbrandstof met behulp van hernieuwbare energie levert de boer en zijn omgeving direct voordeel op:Inkoopkosten voor deze producten worden lagerVermindert de CO2-emissie van de landbouw aanzienlijk, de carbo-footprint wordt verminderdRendement op hernieuwbare energie technologie wordt hogerAmmoniak (NH3) is zowel grondstof voor kunstmest als brandstof voor motoren. Ammoniak kan diesel voor meer dan 90% vervangen in bestaande dieselmotoren. Daarmee is ammoniak een uitstekende vervanger voor diesel in het landbouw en wegverkeer. Ammoniak is ook grondstof voor waterstof (H2) in waterstofmotoren. De technologie om ammoniak te maken is gebaseerd op het Haber-Bosch proces uit het begin van de vorige eeuw. Deze technologie vraagt veel energie voor het creëren van de hoge druk en de hoge temperaturen. Daarom is het voordelig het Haber-Bosch proces in grote installaties uit te voeren.Nieuwe brandstofcel-technologie maakt het mogelijk het Haber-Bosch proces (elektro-katalytisch) op kleine schaal uit te voeren. Het Kiemkracht concept Greenfertilizer onderzoekt de mogelijkheden van deze technologie voor ammoniak productie en benutting op het eigen boerenbedrijf.Het onderzoek is uitgevoerd door TU-Delft en Hanzehogeschool. Het doel was een opgeschaald ammonia elektrolyse synthese proces te ontwikkelen waar een eerste schaal-sprong gemaakt zou worden.Het elektrochemisch ammonia synthese proces is gebaseerd op zuurstofgeleidende elektroden, (proces figuur3. zie onder). Het voordeel van deze zuurstofgeleidende electroden boven proton geleidende electroden is dat er met omgevingslucht gewerkt kan worden in plaats van met stoom. Stoom maakt technologische ontwikkeling van het proces gecompliceerder. Experimenteel en theoretisch onderzoek van TU-Delft laat zien dat met deze elektroden ammonia te produceren is. TU-Delft heeft met zuurstof geleidende electroden ammonia productiesnelheden behaald van 1,84x 10-10 mol s-1 cm-2 bij 650oC. Deze snelheden zijn een factor 100-1000 hoger dan tot nu toe gerapporteerd in literatuur (Kyriakou et al 2017). Simulatie-studies van TU-Delft laten zien dat het ammonia synthese proces met een factor 100-1000 versneld kan worden door het proces onder druk te brengen bij een temperatuur van 400-500C. Op basis van deze simulaties is een ontwerp gemaakt en uitgevoerd voor een “hoge-druk electrolyse reactor”. Technische complicaties met deze hoge druk elektrolyse reactor maakte het onmogelijk betrouwbare resultaten te verkrijgen. Met name gas lekkages bij hoge temperaturen maakten het onmogelijk ammonia massabalansen op te stellen. Bovendien was ammonia productie niet aan te tonen. Hiermee zijn de simulatie voorspellingen niet bevestigd en blijft het onduidelijk of de onderliggende hypothesen correct zijn. De Hanzehogeschool heeft onderzoek uitgevoerd naar het concentreren van ammonia voor toepassing als vloeibare kunstmest. Uitgangspunt hierbij waren de ammonia productieniveau van de experimentele opzet en de voorspelde gesimuleerde opzet. Met de juiste technologie is het mogelijk de ammonia te concentreren voor verdere verwerking als kunstmest. Echter dit proces is economisch rendabel bij een ammonia concentratie in de uitstroom van de elektrolyse reactor die een factor 1000 hoger is dan tot nu toe is gemeten. Het feit dat de TU-Delft er niet in is geslaagd een kleine schaalsprong (factor 10) te maken met de drukreactor betekent dat commerciële toepassing van dit proces voorlopig nog niet aan de orde is. Achteraf gezien was het wellicht beter geweest de keuze te maken voor de proton geleidende electroden die bij lagere temperaturen werkzaam zijn, hier is een schaalsprong van een factor 100 ten opzichte van de recent gerapporteerde ammonia synthese snelheden. Een recente review door Kyriakou et al 2017 geeft als aanbeveling onderzoek te verrichten naar verbeterde elektrodematerialen en geleidende elektrolyten in de reactorcellen. Uiteindelijk zal het elektrochemisch ammonia synthese proces er komen vanwege de vele voordelen die het beidt. Processen moeten met een factor 100-1000 verbeterd worden eer het proces economisch rendabel is. Op dit moment is het nog niet te voospellen wanneer dit moment er is.

PDF

Greenfertilizer, zonnemelken voor een carbo-neutrale landbouw

product

Transient repression of the synthesis of OmpF and aspartate transcarbamoylase in Escherichia K12 as a response to pollutant stress

The synthesis of total cellular proteins in Escherichia coli K12 was studied in batch culture following exposure of cells to low concentrations of monochlorophenol, pentachlorophenol and cadmium chloride. Changes in protein patterns were identified after pulse-chase labelling of proteins with [35S]methionine and subsequent two-dimensional gel electrophoresis (2D-PAGE). We demonstrated that besides the induction of some stress proteins, also a transient decrease in the rate of synthesis of other proteins occurred. Two of these proteins were identified as OmpF and aspartate transcarbamoylase (ATCase). Their transient repression appeared to be a general response to stress elicited by different pollutants and may therefore be used as a general and sensitive early warning system for pollutant stress.

PDF

Transient repression of the synthesis of OmpF and aspartate transcarbamoylase in Escherichia K12 as a response to pollutant stress

product

Power to methane.

Wind and solar power generation will continue to grow in the energy supply of the future, but its inherent variability (intermittency) requires appropriate energy systems for storing and using power. Storage of possibly temporary excess of power as methane from hydrogen gas and carbon dioxide is a promising option. With electrolysis hydrogen gas can be generated from (renewable) power. The combination of such hydrogen with carbon dioxide results in the energy carrier methane that can be handled well and may may serve as carbon feedstock of the future. Biogas from biomass delivers both methane and carbon dioxide. Anaerobic microorganisms can make additional methane from hydrogen and carbon dioxide in a biomethanation process that compares favourably with its chemical counterpart. Biomethanation for renewable power storage and use makes appropriate use of the existing infrastructure and knowledge base for natural gas. Addition of hydrogen to a dedicated biogas reactor after fermentation optimizes the biomethanation conditions and gives maximum flexibility. The low water solubility of hydrogen gas limits the methane production rate. The use of hollow fibers, nano-bubbles or better-tailored methane-forming microorganisms may overcome this bottleneck. Analyses of patent applications on biomethanation suggest a lot of freedom to operate. Assessment of biomethanation for economic feasibility and environmental value is extremely challenging and will require future data and experiences. Currently biomethanation is not yet economically feasible, but this may be different in the energy systems of the near future.

PDF

product

Molecular insights into human taste perception and umami tastants: A review

Understanding taste is key for optimizing the palatability of seaweeds and other non-animal-based foods rich in protein. The lingual papillae in the mouth hold taste buds with taste receptors for the five gustatory taste qualities. Each taste bud contains three distinct cell types, of which Type II cells carry various G protein-coupled receptors that can detect sweet, bitter, or umami tastants, while type III cells detect sour, and likely salty stimuli. Upon ligand binding, receptor-linked intracellular heterotrimeric G proteins initiate a cascade of downstream events which activate the afferent nerve fibers for taste perception in the brain. The taste of amino acids depends on the hydrophobicity, size, charge, isoelectric point, chirality of the alpha carbon, and the functional groups on their side chains. The principal umami ingredient monosodium l-glutamate, broadly known as MSG, loses umami taste upon acetylation, esterification, or methylation, but is able to form flat configurations that bind well to the umami taste receptor. Ribonucleotides such as guanosine monophosphate and inosine monophosphate strongly enhance umami taste when l-glutamate is present. Ribonucleotides bind to the outer section of the venus flytrap domain of the receptor dimer and stabilize the closed conformation. Concentrations of glutamate, aspartate, arginate, and other compounds in food products may enhance saltiness and overall flavor. Umami ingredients may help to reduce the consumption of salts and fats in the general population and increase food consumption in the elderly.

MULTIFILE

Molecular insights into human taste perception and umami tastants: A review

product

Responsive cyclohexane-based low-molecular-weight hydrogelators with modular architecture

pH-sensitive gels: By using a cyclohexane-based scaffold to which various amino acid based substituents can be connected, low-molecular-weight compounds were obtained that can gelate water at very low concentrations. Their modular design (see picture: AA = amino acid(s), X = hydrophilic substituent, dark purple = hydrophobic region, light purple = hydrophilic region), allows tuning of the thermally and pH-induced reversible gel-to-sol transition of their gels.

PDF

product

Past and current components-based detailing of particle image velocimetry

Particle image velocimetry has been widely used in various sectors from the automotive to aviation, research, and development, energy, medical, turbines, reactors, electronics, education, refrigeration for flow characterization and investigation. In this study, articles examined in open literature containing the particle image velocimetry techniques are reviewed in terms of components, lasers, cameras, lenses, tracers, computers, synchronizers, and seeders. The results of the evaluation are categorized and explained within the tables and figures. It is anticipated that this paper will be a starting point for researchers willing to study in this area and industrial companies willing to include PIV experimenting in their portfolios. In addition, the study shows in detail the advantages and disadvantages of past and current technologies, which technologies in existing PIV laboratories can be renewed, and which components are used in the PIV laboratories to be installed.

PDF

Past and current components-based detailing of particle image velocimetry

product

The design of a novel, environmentally improved cotton pre-treatment proces

The scope of this thesis of Gerrit Bouwhuis, lecturer at Saxion Research Centre for Design and Technology in Enschede is the development of a new industrial applicable pre-treatment process for cotton based on catalysis. The pre-treatment generally consists of desizing, scouring and bleaching. These processes can be continuous or batch wise. Advances in the science of biocatalytic pre-treatment of cotton and catalytic bleaching formed the scientific basis for this work. The work of Agrawal on enzymes for bio-scouring and of Topalovic on catalytic bleaching led to the conclusion that reduced reaction temperatures for the pre-treatment processes of cotton are possible. A second reason for the present work is a persistent and strong pressure on the industry to implement ‘more sustainable’ and environmental friendlier processes. It was clear that for the industrial implementation of the newly developed process it would be necessary to ‘translate’ the academic knowledge based on the catalysts, into a process at conditions that are applicable in textile industry. Previous experiences learned that the transition from academic knowledge into industrial applicable processes often failed. This is caused by lack of experience of university researchers with industrial product and process development as well as a lack of awareness of industrial developers of academic research. This is especially evident for the so-called Small and Medium Enterprises (SME’s). To overcome this gap a first step was to organize collaboration between academic institutes and industries. The basis for the collaboration was the prospect of this work for benefits for all parties involved. A rational approach has been adopted by first gathering knowledge about the properties and morphology of cotton and the know how on the conventional pre-treatment process. To be able to understand the conventional processes it was necessary not only to explore the chemical and physical aspects but also to evaluate the process conditions and equipment that are used. This information has been the basis for the present lab research on combined bio-catalytic desizing and scouring as well as catalytic bleaching. For the measurement of the performance of the treatments and the process steps, the performance indicators have been evaluated and selected. Here the choice has been made to use industrially known and accepted performance indicators. For the new bio-catalytic pre-treatment an enzyme cocktail, consisting of amylase, cutinase and pectinase has been developed. The process conditions in the enzyme cocktail tests have been explored reflecting different pre-treatment equipment as they are used in practice and for their different operation conditions. The exploration showed that combined bio-catalytic desizing and scouring seemed attractive for industrial application, with major reduction of the reaction and the rinsing temperatures, leading to several advantages. The performance of this treatment, when compared with the existing industrial treatment showed that the quality of the treated fabric was comparable or better than the present industrial standard, while concentrations enzymes in the cocktail have not yet been fully optimized. To explore the application of a manganese catalyst in the bleaching step of the pre-treatment process the fabrics were treated with the enzyme cocktail prior to the bleaching. It has been decided not to use conventional pre-treatment processes because in that case the combined desizing and scouring step would not be integrated in the newly developed process. To explore catalytic bleaching it has been tried to mimic the existing industrial processes where possible. The use of the catalyst at 100°C, as occurs in a conventional steamer, leads to decomposition of the catalyst and thus no bleach activation occurs. This led to the conclusion that catalytic bleaching is not possible in present steamers nor at low temperatur

MULTIFILE

product

Surface and Bulk Modification of Synthetic Textiles to Improve Dyeability

Synthetic fibers, mainly polyethylene terephthalate (PET), polyamide (PA), polyacrylonitrile (PAN) and polypropylene (PP), are the most widely used polymers in the textile industry. These fibers surpass the production of natural fibers with a market share of 54.4%. The advantages of these fibers are their high modulus and strength, stiffness, stretch or elasticity, wrinkle and abrasion resistances, relatively low cost, convenient processing, tailorable performance and easy recycling. The downside to synthetic fibers use are reduced wearing comfort, build-up of electrostatic charge, the tendency to pill, difficulties in finishing, poor soil release properties and low dyeability. These disadvantages are largely associated with their hydrophobic nature. To render their surfaces hydrophilic, various physical, chemical and bulk modification methods are employed to mimic the advantageous properties of their natural counterparts. This review is focused on the application of recent methods for the modification of synthetic textiles using physical methods (corona discharge, plasma, laser, electron beam and neutron irradiations), chemical methods (ozone-gas treatment, supercritical carbon dioxide technique, vapor deposition, surface grafting, enzymatic modification, sol-gel technique, layer-by-layer deposition of nano-materials, micro-encapsulation method and treatment with different reagents) and bulk modification methods by blending polymers with different compounds in extrusion to absorb different colorants. Nowadays, the bulk and surface functionalization of synthetic fibers for various applications is considered as one of the best methods for modern textile finishing processes (Tomasino, 1992). This last stage of textile processing has employed new routes to demonstrate the great potential of nano-science and technology for this industry (Lewin, 2007). Combination of physical technologies and nano-science enhances the durability of textile materials against washing, ultraviolet radiation, friction, abrasion, tension and fading (Kirk–Othmer, 1998). European methods for application of new functional finishing materials must meet high ethical demands for environmental-friendly processing (Fourne, 1999). For this purpose the process of textile finishing is optimized by different researchers in new findings (Elices & Llorca, 2002). Application of inorganic and organic nano-particles have enhanced synthetic fibers attributes, such as softness, durability, breathability, water repellency, fire retardancy and antimicrobial properties (Franz, 2003; McIntyre, 2005; Xanthos, 2005). This review article gives an application overview of various physical and chemical methods of inorganic and organic structured material as potential modifying agents of textiles with emphasis on dyeability enhancements. The composition of synthetic fibers includes polypropylene (PP), polyethylene terephthalate (PET), polyamides (PA) or polyacrylonitrile (PAN). Synthetic fibers already hold a 54% market share in the fiber market. Of this market share, PET alone accounts for almost 50% of all fiber materials in 2008 (Gubitz & Cavaco-Paulo, 2008). Polypropylene, a major component for the nonwovens market accounts for 10% of the market share of both natural and synthetic fibers worldwide (INDA, 2008 and Aizenshtein, 2008). It is apparent that synthetic polymers have unique properties, such as high uniformity, mechanical strength and resistance to chemicals or abrasion. However, high hydrophobicity, the build-up of static charges, poor breathability, and resistant to finishing are undesirable properties of synthetic materials (Gubitz & Cavaco-Paulo, 2008). Synthetic textile fibers typically undergo a variety of pre-treatments before dyeing and printing is feasible. Compared to their cotton counterparts, fabrics made from synthetic fibers undergo mild scouring before dyeing. Nonetheless, these treatments still create undesirable process conditions wh

MULTIFILE

Surface and Bulk Modification of Synthetic Textiles to Improve Dyeability

product

Innovative water quality and ecology monitoring using underwater unmanned vehicles: field applications, challenges and feedback from water managers

With climate change and urban development, water systems are changing faster than ever. Currently, the ecological status of water systems is still judged based on single point measurements, without taking into account the spatial and temporal variability of water quality and ecology. There is a need for better and more dynamic monitoring methods and technologies. Aquatic drones are becoming accessible and intuitive tools that may have an important role in water management. This paper describes the outcomes, field experiences and feedback gathered from the use of underwater drones equipped with sensors and video cameras in various pilot applications in The Netherlands, in collaboration with local water managers. It was observed that, in many situations, the use of underwater drones allows one to obtain information that would be costly and even impossible to obtain with other methods and provides a unique combination of three-dimensional data and underwater footage/images. From data collected with drones, it was possible to map different areas with contrasting vegetation, to establish connections between fauna/flora species and local water quality conditions, or to observe variations of water quality parameters with water depth. This study identifies opportunities for the application of this technology, discusses their limitations and obstacles, and proposes recommendation guidelines for new technical designs

LINK

Search results

Products 23

Greenfertilizer, zonnemelken voor een carbo-neutrale landbouw

Transient repression of the synthesis of OmpF and aspartate transcarbamoylase in Escherichia K12 as a response to pollutant stress

Power to methane.

Molecular insights into human taste perception and umami tastants: A review

Responsive cyclohexane-based low-molecular-weight hydrogelators with modular architecture

Past and current components-based detailing of particle image velocimetry

The design of a novel, environmentally improved cotton pre-treatment proces

Surface and Bulk Modification of Synthetic Textiles to Improve Dyeability

Innovative water quality and ecology monitoring using underwater unmanned vehicles: field applications, challenges and feedback from water managers

Navigate to

Categories

Filters

Products 23

Greenfertilizer, zonnemelken voor een carbo-neutrale landbouw

Transient repression of the synthesis of OmpF and aspartate transcarbamoylase in Escherichia K12 as a response to pollutant stress

Power to methane.

Molecular insights into human taste perception and umami tastants: A review

Responsive cyclohexane-based low-molecular-weight hydrogelators with modular architecture

Past and current components-based detailing of particle image velocimetry

The design of a novel, environmentally improved cotton pre-treatment proces

Surface and Bulk Modification of Synthetic Textiles to Improve Dyeability

Innovative water quality and ecology monitoring using underwater unmanned vehicles: field applications, challenges and feedback from water managers