Integrated pest management | EPFL Graph Search

Integrated pest management (IPM), also known as integrated pest control (IPC) is a broad-based approach that integrates both chemical and non-chemical practices for economic control of pests. IPM aims to suppress pest populations below the economic injury level (EIL). The UN's Food and Agriculture Organization defines IPM as "the careful consideration of all available pest control techniques and subsequent integration of appropriate measures that discourage the development of pest populations and keep pesticides and other interventions to levels that are economically justified and reduce or minimize risks to human health and the environment. IPM emphasizes the growth of a healthy crop with the least possible disruption to agro-ecosystems and encourages natural pest control mechanisms." Entomologists and ecologists have urged the adoption of IPM pest control since the 1970s. IPM allows for safer pest control. The introduction and spread of invasive species can also be managed with IPM

Optimisation du système d’assainissement des eaux urbaines Réseau-STEP-Milieu récepteur par une approche de gestion intégrée

Jean-Baptiste Razurel

Water management is a recurring problem that has occupied mankind for years. Nowadays, the multiple stakeholders involved in this management have the willingness to cooperate to make it more integrated and take into consideration all social, economic and environmental components across an ideal functional unit which is the hydrological watershed. The urban wastewater system plays a central role because of its triple dimension Sewer, Wastewater treatment plant, Receiving water and well often determines the quality of the water on which depend many other sectors. Insurance that the system is in a good health allows having a functional and efficient water resources management. This work explores the possibilities of optimization of the urban wastewater system by the establishment of an integrated management which takes into account the three subsystems. For this, an understanding of the process of optimization and the knowledge about the conventionally used algorithms is deepened. Furthermore the importance of modeling and real time control for the improvement of knowledge and decision making is emphasized by a review of the available tools involved in concrete examples. An approach of integrated management of the urban wastewater system is proposed, focusing on two aspects : the identification of the critical points of the system by analyzing performance indicators and the implementation of the optimization process. This approach is applied to a case study and allows highlighting the presence of important overflows at a pumping station due to the infiltration of parasitic clean water. At this problematic station the optimization process is applied with the help of CVX tool on matlab. This optimization reduces spills using existing infrastructure while following sizing, economic and environmental constraints established by the system. This study shows that improvement of the urban wastewater system performance by following an integrated management approach exists and can be considered in Switzerland.

2016

Opportunities for Switzerland to Contribute to the Production of Algal Biofuels: the Hydrothermal Pathway to Bio-Methane

Mariluz Bagnoud, Christian Ludwig, Dominik Refardt, François Richard Vuille

Microalgae have a significant potential to be a sustainable source of fuel and thus are of interest in the transition to a sustainable energy system, in particular for resource-dependent countries such as Switzerland. Independence of fossil fuels, considerable reduction of CO2 emissions, and abandoning nuclear energy may be possible with an integrated system approach including the sourcing of biofuels from different types of biomass. Today, a full carbon-to-fuel conversion is possible, and has been recently demonstrated with an advanced hydrothermal technology. The potential to develop algal biofuels is viewed as high thanks to the possibility they offer to uncouple bioenergy from food production. Nevertheless, technological breakthroughs must take place before commercial production becomes a reality, especially to meet the necessary cost savings and efficiency gains in the algae cultivation structure. In addition, an integrated management of waste resources to promote the nutrient recovery appears today as imperative to further improve the economic viability and the environmental sustainability of algal production. We provide here a review that includes the global technological status of both algae production and their conversion into biofuels in order to understand first the added value of algal energy in general before we focus on the potential of algae to contribute specifically to the Swiss energy system to the horizon 2050. In this respect, the hydrothermal conversion pathway of microalgal biomass into synthetic natural gas (SNG) is emphasized, as research into this technology has received considerable attention in Switzerland during the last decade. In addition, SNG is a particularly relevant fuel in the Swiss context due to the existing gas grid and to the opportunity it offers to cover a wide spectrum of energy applications, in particular cogeneration of heat and electricity or use as a transport fuel in the growing gas car fleet.

Swiss Chemical Soc2015

Opportunities for Switzerland to Contribute to the Production of Algal Biofuels: the Hydrothermal Pathway to Bio-Methane

Mariluz Bagnoud, Christian Ludwig, Dominik Refardt, François Richard Vuille

Swiss Chemical Soc2015

Optimisation du système d’assainissement des eaux urbaines Réseau-STEP-Milieu récepteur par une approche de gestion intégrée

Jean-Baptiste Razurel

2016