It is of utmost importance to collect organic waste from households as a separate waste stream. If collected separately, it could be used optimally to produce compost and biogas, it would not pollute fractions of materials that can be recovered from residual waste streams and it would not deteriorate the quality of some materials in residual waste (e.g. paper). In rural areas with separate organic waste collection systems, large quantities of organic waste are recovered. However, in the larger cities, only a small fraction of organic waste is recovered. In general, citizens dot not have space to store organic waste without nuisances of smell and/or flies. As this has been the cause of low organic waste collection rates, collection schemes have been cut, which created a further negative impact. Hence, additional efforts are required. There are some options to improve the organic waste recovery within the current system. Collection schemes might be improved, waste containers might be adapted to better suit the needs, and additional underground organic waste containers might be installed in residential neighbourhoods. There are persistent stories that separate organic waste collection makes no sense as the collectors just mix all municipal solid waste after collection, and incinerate it. Such stories might be fuelled by the practice that batches of contaminated organic waste are indeed incinerated. Trust in the system is important. Food waste is often regarded as unrein. Users might hate to store food waste in their kitchen that could attract insects, or the household pets. Hence, there is a challenge for socio-psychological research. This might also be supported by technology, e.g. organic waste storage devices and measures to improve waste separation in apartment buildings, such as separate chutes for waste fractions. Several cities have experimented with systems that collect organic wastes by the sewage system. By using a grinder, kitchen waste can be flushed into the sewage system, which in general produces biogas by the fermentation of sewage sludge. This is only a good option if the sewage is separated from the city drainage system, otherwise it might create water pollution. Another option might be to use grinders, that store the organic waste in a tank. This tank could be emptied regularly by a collection truck. Clearly, the preferred option depends on local conditions and culture. Besides, the density of the area, the type of sewage system and its biogas production, and the facilities that are already in place for organic waste collection are important parameters. In the paper, we will discuss the costs and benefits of future organic waste options and by discussing The Hague as an example.
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Over the past 20 years, water quality in Indonesia has deteriorated due to an increase of water pollution. Research and analysis is needed to identify pollution sources and assess contamination in Indonesian water resources. Water quality management is not yet sufficiently integrated in river basin management in Indonesia, which mainly focuses on water quantity. Women are comparatively highly impacted by failing water resources management, but theirinvolvement in decision making processes is limited. Water quality deterioration continues to increase socio-economic inequality, as it are the most poor communities who live on and along the river. The uneven water quality related disease burden in Brantas River Basin widens the socio-economic gap between societal groups. In the Brantas region, cooperation and intention between stakeholders to tackle these issues is growing, but is fragile as well due to overlapping institutional mandates, poor status of water quality monitoring networks, and limited commitment of industries to treat their waste water streams. The existing group of Indonesian change makers will be supported by this project. Three Indonesian and three Dutch organisations have teamed up to support negotiation platforms in order to deal with institutional challenges, to increase water quality monitoring capacity, to build an enabling environment facilitating sustainable industrial change, and to develop an enabling environment in support of community concerns and civil society initiatives. The project builds on integrated water quality monitoring and modelling within a framework of social learning. The strong consortium will be able to build links with civil society groups (including women, farmer and fisher unions) in close cooperation with local, regional and national Indonesian governmentinstitutions to clean the Brantas river and secure income and health for East Java’s population, in particular the most vulnerable groups.
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The textile industry is one of the largest environmental polluters, primarily due to its water-intensive dyeing processes and the waste-water release of synthetic colorants which are harmful to the environment and human health. While there are efforts to improve sustainability, few solutions address both water usage and the need for renewable alternatives to synthetic dyes. FuntureTex presents an innovative solution by implementing fungal-based colorants with the doping dyeing process. Fungal colorants are renewable and biodegradable, providing a sustainable alternative to synthetic dyes. The doping process is a water-saving technique where colorants are integrated directly into textile fibers during their production, eliminating the need for traditional water-dependent dyeing steps. This method reduces water use by up to 90% compared to conventional dyeing, as no water is required to rinse or fix the dye. Til date, although efforts have been made on incorporating biobased substances in dope dyeing, the use of natural, especially fungal colorants, has not yet been done. In this project, the consortium will combine forces to improve dope dyeing by using fungal colorants. Key technologies including fermentation and green chemistry will be applied throughout the project. Firstly, the colorants will be produced via fermentation and treated with sustainable downstream processing methods. Afterwards, the colorants will be integrated into polymers and yarned as textile materials by using the dope dyeing method. The project results will be disseminated to professional fields to gain insights in business potentials. Students will be involved through the project to broaden the impact. The FuntureTex consortium is made by experts in areas of fungal colorants, dope dyeing and business outlook, ensuring a proper execution of the project. In line with the EU’s goal of circular and sustainable economy, the research result will bring a potential dual solution to the environmental challenges of textile industries.
Living walls are increasingly becoming tools for green climate adaptation in the urban context, but distribution efforts are dampened by high investment and operational costs. Those costs are derived mainly from designing and manufacturing unique equipment for such new projects. A system using wastewater could relieve some of these costs by decreasing their irrigation and fertigation needs. Muuras is developing helophyte filters integrated into living wall systems that can readily be attached to any wall surface, with the ultimate purpose of local water recycling. Additionally, based on the fact that Muuras is a pre-engineered company, their product is modular, which means that a considerable advantage is recognized regarding the decreased capital cost. To realize scalable implementation of such a system, research with regards to the purification capabilities of lightweight substrates and small wetland plant species is imperative. In SoW & FloW, the NHL Stenden Water Technology Professorship proposes a collaboration between two SME’s (Muuras, Greenwave Systems) and a company (DeSaH), to evaluate a selection of substrates and endemic plant species based on their capability to use domestic wastewater as an irrigation source.
This research is a collaborative project between Water Future, Looop, and MNEXT to address the valorisation of a residual stream that remain after valorisation of whey towards food and feed applications: whey permeate. This permeate is a high-volume but low-quality stream, which is currently used as a filler for mainly animal feed, but with the large amounts produced in NW-Europe it is essential to valorise whey permeate higher in the value chain, for example into a biobased resource which replace fossil-based resources in the chemical industry. To accomplish this, pre-processing steps are necessary to remove minerals. Electrodialysis (ED) can remove unwanted minerals from whey permeate by applying an electric field across its membranes. Using ED, whey permeate is expected to demineralize into a liquid which is suitable for application as biobased resource for various applications. Moreover, the extracted mineral stream can also be reused. This one-year project aims to quantify and optimize the demineralisation of whey permeates using a lab-scale ED setup to make the whey permeate stream suitable for re-use and thus reduce the environmental impact of this stream. The project involves setting up an ED setup provided by Water Future to treat whey permeates supplied by Looop, assessing the suitability of treated permeate as a biobased resource in the chemical industry and processing the produced mineral streams into new biobased resources. The result of this research will demonstrate the use of ED as a valorisation technique for whey permeates and the integration of multiple processes into a valorisation pathway to transform costly whey permeates into value-added products. MNEXT leads the research development, aiming to potentially establish a recycle strategy for resource recovery in the dairy industry. The results will be presented through educational activities, reports, digital platforms, and conferences to transfer knowledge to a broader audience.
