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Production engineering --- Marketing --- Production capacity
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Production management --- Industrial capacity --- Management. --- Capacity, Industrial --- Manufacturing capacity --- Production capacity --- Manufactures --- Management --- Industrial capacity - Management.
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Production capacity --- Industrial management --- Production control --- Production management --- Materials handling --- Work measurement
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Brexit’s announcement in June 2016 totally has disrupted the English market and its external relations. Since the referendum, and still now, during the negotiation phase leading up to the United Kingdom’s exit outside the European Union, many parameters have gone uncorrelated. The impact on the country causes the fall in value of its currency and the disruption in the exchange rates that affect the imports and exports in relation to the country. The companies supplying the UK are therefore affected by the phenomenon and must act in order to counter this. Here we are taking an interest in a Belgian construction company, Isosystems AG, for whom the UK market is the most important part of its turnover. We will discuss how it intends to minimize Brexit's consequences on its activities. Otherwise, it could fall into a gear that could lead to the loss of this essential market for the factory. To do this, the company plans to set up a subsidiary in England in partnership with its only British customer. However, it will lead to a transfer of a part of the production on the other side of the Channel, which will have repercussions on the Belgian site. Therefore, we will answer the question of how the company will fill this gap and finance a project of such a magnitude. We will finally analyze the relevance of its choice.
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This study focuses on the design of an energy community in the Hauts-Sarts business park. The current assets in the potential community are 1150 kWp of PV panels, for a total consumption of 22 GWh per year. The main objectives of the community are to offer savings on the energy bill of its members, increase the integration of renewable energy sources into the grid and reduce the CO2 emissions of the community. The design is centered around two main aspects: an internal market model and an optimal sizing model. The internal market model is formulated as a MILP optimization model maximizing the annual profit realized by entities trading in the community and in the wholesale market. The price in the community can be fixed to incentivize investments, or dynamic to redistribute the gains of the community. Two optimization models returning the sizing maximizing the NPV of the community are also developed: one is a MILP optimization problem, returning the exact solution to the problem, and the other is a greedy method returning an optimized realistic sequence of investments in the community. The greedy method leads to a slightly lower PV sizing than the MILP model. The study showed that between 2000 kWp and 3000 kWp of additional PV panels as well as a 2200 kWp wind turbine have to be installed to maximize the NPV of the community, depending on the organizational choices of the community. In general, these choices consist in a trade-off between a fair redistribution of the savings of the community and incentives to increase the production capacity. The fixed costs associated with the operation of the community may sometimes be a barrier for the smallest consumers, but overall the community was able to reduce its costs over 20 years by 20% by installing additional production capacity and operating in a community.
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PETROLEUM PRODUCTS --- PRODUCTION CAPACITY --- BELGIQUE --- DEMAND ECONOMICS --- ATLASES --- COAL DEPOSITS --- GASES --- ELECTRICITY --- MATERIALS HANDLING EQUIPMENT --- MARKETING --- CONSUMPTION --- FUEL CONSUMPTION --- INDUSTRIES --- STATISTICAL DATA --- CONDITIONS ECONOMIQUES --- 20E SIECLE --- ENERGIE
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Does your organization need to improve the way it manages capacity management in SAP? This book dives into an often overlooked area of SAP and provides readers with an understanding of SAP Capacity Management functionality, including capacity planning, sequencing, leveling, and scheduling. Identify quick wins you can implement to improve results and identify opportunities. Learn more about your options for resource leveling and identify how to leverage capacity planning to build a more robust supply chain program at your organization.Explore how to leverage material requirements planning (MRP) and advanced planning systems (APS) in SAP to build a better supply program. Take an indepth look at how to translate planned and customer demand into an effective production program. Walk through standard SAP ERP functionality available for capacity management planning. By using practical examples, tips, and screenshots, the author brings readers quickly up to speed on the fundamentals of SAP Capacity Management.- How to leverage SAP Capacity Management - Capacity planning best practices - Options for capacity scheduling in SAP ERP - Automatic resource and material scheduling with SAP APO
Industrial capacity --- Management&delete& --- Data processing --- SAP ERP. --- E-books --- Capacity, Industrial --- Manufacturing capacity --- Production capacity --- Manufactures --- Systems, applications and products in data processing enterprise resource planning --- SAP Enterprise resource planning --- Management
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PRODUCTION CAPACITY --- TEMPERATURE --- HEATING --- RELIABILITY --- BUILDINGS --- VENTILATION --- COOLING LOAD --- HEAT TRANSFER --- CONVECTION --- CONDUCTION --- MASS TRANSFER --- RADIATION --- HEATING LOAD --- HEAT EXCHANGERS --- WATER STORAGE --- WATER CONSUMPTION --- WATER SUPPLY --- DESIGN --- COMFORT --- ILLUMINATING --- SOUND WAVES --- HUMIDITY --- THERMAL RESPONSE --- WATER RECLAMATION --- TABLES DATA
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COMFORT --- THERMAL ENVIRONMENTS --- VENTILATION --- ILLUMINATING --- SOUND WAVES --- VIBRATION --- WEATHER --- AIR POLLUTION --- THERMODYNAMIC PROPERTIES --- STANDARDS --- PRODUCTION CAPACITY --- BUILDINGS --- HEATING EQUIPMENT --- CONSTRUCTION MATERIALS --- WINDOWS --- HEAT TRANSFER --- CONVECTION --- SOLAR RADIATION --- RADIANT HEATING --- MOISTURE --- CONDENSING --- EVAPORATION --- THERMAL RESISTANCE --- COOLING SYSTEMS --- THERMAL RESPONSE
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