From the article: Abstract. This exploratory and conceptual article sets out to research what arguments and possibilities for experimentation in construction exists and if experimentation can contribute towards more innovative construction as a whole. Traditional, -western- construction is very conservative and regional, often following a traditional and linear design process, which focuses on front-loaded cost savings and repetitive efficiency, rather than securing market position through innovation. Thus becoming a hindrance for the development of the sector as a whole. Exploring the effects of using the, in other design-sectors commonly and successfully practiced, “four-phased iterative method” in architectural construction could be the start of transforming the conservative construction industry towards a more innovative construction industry. The goal of this research is to find whether the proposed strategy would indeed result in a higher learning curve and more innovation during the - architectural- process. Preliminary research indicates that there is argumentation for a more experimental approach to construction.
Re-structuring of a Dutch mono-industrial region; example of TwenteTable of contents of the chapter Introduction Geography and location of Twente Industrialization of Twente and development of the Textile Industry Decline of the Textile Industry Restructuring Twente: arguments for a regional innovation strategy Moving towards a more diversified economy Stronger co-operation between governments, universities, and industries The role of universities and the example of ‘Kennispark Twente’ Further regional and international co-operation Twente today
MULTIFILE
Much research effort is invested in developing enzymatic treatments of textiles by focusing on the performance of enzymes at the laboratory scale. Despite all of this work, upgrading these developments from the laboratory scale to an industrial scale has not been very successful.Nowadays,companies are confronted with rapid developments of markets, logistics, and social and environmental responsibilities. Moreover, these organizations have to supply an ever-increasing amount of information to the authorities, shareholders, lobbyists, and pressure groups. Companies have tried to fulfill all of these demands, but this has often led to the loss of focus on new products and process development. However, both theory and practices of breakthrough innovations have shown that those rightfully proud of previous successes are usually not the ones that led the introduction of new technology, as shown and excellently documented by Christensen [1]. The textile industry is no exception to this observation.With the lack of management impetus for new product and process developments, companies began to reduce investments in these activities.However, this results in a reduction of the size of the company or even closure. Besides the hesitation from the top management of textile companies to focus on new developments,middle management level is also reluctant to evaluate and implement developments in new products and processes. One of the reasons for this reluctance is that many processes in the textile industry are notfully explored or known. From this lack of knowledge, it is easy to explain that there is hesitation for change, since not all consequences of a change in processing or production can be predicted. Often new developments cannot be fully tested and evaluated on the laboratory- or pilot-scale level.This is caused by the impossibility of mimicking industrial-scale production in a laboratory.Additionally, pilot-scale equipment is very expensive and for many companies it is not realistic to invest in this type of equipment. Fortunately an increasing number of textile companies have realized that they have to invest in new products and processes for their future survival and prosperity. New developments are decisive for future successes. If such companies decide to invest in new developments, it is clear that with the scarcity of capital for product and process developments, the chance of failure should be minimized. For successful process and product development, it is necessary to organize the development process with external partners because it is clear that it is almost impossible for individual textile companies to control the process from idea generation to academic research, implementation research, and development and industrial testing. These issues are especially characteristic for small- and medium-sized enterprises (SMEs). Herein, the collaboration has been organized on two research levels. The first research level is knowledge and know-how based. The universities and chemical suppliers worked closely together to investigate the new process.The aim was to explore the influence of process conditions and interactions of chemicals in sub-process steps as a result of the treatment.The second level is that of the industrial implementation of the new process. The universities and chemical suppliers worked closely together with different industries to implement the newly developed process. The focus in this part of the research was the interaction between the chemistry of the new process, equipment, and fabrics. A co-operation between the beneficiaries of the new process was established.The selection criterion for the co-peration was “who will earn something with the new process”. To answer this question, the value chain has been drawn as the simplified scheme shown in Fig. 1 [2].
MULTIFILE
In this proposal, a consortium of knowledge institutes (wo, hbo) and industry aims to carry out the chemical re/upcycling of polyamides and polyurethanes by means of an ammonolysis, a depolymerisation reaction using ammonia (NH3). The products obtained are then purified from impurities and by-products, and in the case of polyurethanes, the amines obtained are reused for resynthesis of the polymer. In the depolymerisation of polyamides, the purified amides are converted to the corresponding amines by (in situ) hydrogenation or a Hofmann rearrangement, thereby forming new sources of amine. Alternatively, the amides are hydrolysed toward the corresponding carboxylic acids and reused in the repolymerisation towards polyamides. The above cycles are particularly suitable for end-of-life plastic streams from sorting installations that are not suitable for mechanical/chemical recycling. Any loss of material is compensated for by synthesis of amines from (mixtures of) end-of-life plastics and biomass (organic waste streams) and from end-of-life polyesters (ammonolysis). The ammonia required for depolymerisation can be synthesised from green hydrogen (Haber-Bosch process).By closing carbon cycles (high carbon efficiency) and supplementing the amines needed for the chain from biomass and end-of-life plastics, a significant CO2 saving is achieved as well as reduction in material input and waste. The research will focus on a number of specific industrially relevant cases/chains and will result in economically, ecologically (including safety) and socially acceptable routes for recycling polyamides and polyurethanes. Commercialisation of the results obtained are foreseen by the companies involved (a.o. Teijin and Covestro). Furthermore, as our project will result in a wide variety of new and drop-in (di)amines from sustainable sources, it will increase the attractiveness to use these sustainable monomers for currently prepared and new polyamides and polyurethanes. Also other market applications (pharma, fine chemicals, coatings, electronics, etc.) are foreseen for the sustainable amines synthesized within our proposition.
Size measurement plays an essential role for micro-/nanoparticle characterization and property evaluation. Due to high costs, complex operation or resolution limit, conventional characterization techniques cannot satisfy the growing demand of routine size measurements in various industry sectors and research departments, e.g., pharmaceuticals, nanomaterials and food industry etc. Together with start-up SeeNano and other partners, we will develop a portable compact device to measure particle size based on particle-impact electrochemical sensing technology. The main task in this project is to extend the measurement range for particles with diameters ranging from 20 nm to 20 um and to validate this technology with realistic samples from various application areas. In this project a new electrode chip will be designed and fabricated. It will result in a workable prototype including new UMEs (ultra-micro electrode), showing that particle sizing can be achieved on a compact portable device with full measuring range. Following experimental testing with calibrated particles, a reliable calibration model will be built up for full range measurement. In a further step, samples from partners or potential customers will be tested on the device to evaluate the application feasibility. The results will be validated by high-resolution and mainstream sizing techniques such as scanning electron microscopy (SEM), dynamic light scattering (DLS) and Coulter counter.
Currently, many novel innovative materials and manufacturing methods are developed in order to help businesses for improving their performance, developing new products, and also implement more sustainability into their current processes. For this purpose, additive manufacturing (AM) technology has been very successful in the fabrication of complex shape products, that cannot be manufactured by conventional approaches, and also using novel high-performance materials with more sustainable aspects. The application of bioplastics and biopolymers is growing fast in the 3D printing industry. Since they are good alternatives to petrochemical products that have negative impacts on environments, therefore, many research studies have been exploring and developing new biopolymers and 3D printing techniques for the fabrication of fully biobased products. In particular, 3D printing of smart biopolymers has attracted much attention due to the specific functionalities of the fabricated products. They have a unique ability to recover their original shape from a significant plastic deformation when a particular stimulus, like temperature, is applied. Therefore, the application of smart biopolymers in the 3D printing process gives an additional dimension (time) to this technology, called four-dimensional (4D) printing, and it highlights the promise for further development of 4D printing in the design and fabrication of smart structures and products. This performance in combination with specific complex designs, such as sandwich structures, allows the production of for example impact-resistant, stress-absorber panels, lightweight products for sporting goods, automotive, or many other applications. In this study, an experimental approach will be applied to fabricate a suitable biopolymer with a shape memory behavior and also investigate the impact of design and operational parameters on the functionality of 4D printed sandwich structures, especially, stress absorption rate and shape recovery behavior.
