Packaging development process for a wholesale club pack of flea and tick topical treatment for dogs

The Hartz Mountain Packaging Development Department was presented with the challenge of designing a warehouse club package system for the company\u27s One-Spot flea and tick topical treatment product, to take the place of the competitor\u27s flea and tick treatment product sold in some warehouse clubs. In order to properly service the warehouse club market and better understand the reasoning behind the unique package configurations typically sold in that environment, Hartz Packaging Engineering undertook a study of the background, history and current trends of the club market. This information, along with observations gathered from numerous visits to various club locations, was used to design the One-Spot package system described in this thesis. Included is a summary of the information collected during the research, along with a description of the steps involved in the development of the package system

Heat storage in alloy transformations

The feasibility of using metal alloys as thermal energy storage media was determined. The following major elements were studied: (1) identification of congruently transforming alloys and thermochemical property measurements; (2) development of a precise and convenient method for measuring volume change during phase transformation and thermal expansion coefficients; (3) development of a numerical modeling routine for calculating heat flow in cylindrical heat exchangers containing phase change materials; and (4) identification of materials that could be used to contain the metal alloys. Several eutectic alloys and ternary intermetallic phases were determined. A method employing X-ray absorption techniques was developed to determine the coefficients of thermal expansion of both the solid and liquid phases and the volume change during phase transformation from data obtained during one continuous experimental test. The method and apparatus are discussed and the experimental results are presented. The development of the numerical modeling method is presented and results are discussed for both salt and metal alloy phase change media

Grid Expansion, Power-To-Gas and Solar Power Imports - Multi-Scenario Analysis of Large Infrastructure Options for the Decarbonization of the European Energy System

Grid expansion measures, Power-To-Gas and solar power imports are frequently discussed technological options for integrating renewable energies into the energy system. Since this poses enormous economic and social challenges for the development of energy supply infrastructures, potential benefits must be analyzed for a broad spectrum of possible futures. This paper provides a comparative assessment of more than 50 European energy scenarios. Therefore, we vary parameters such as costs, weather data as well as restrictions for modelling interregional power flows. The results show that grid expansion plays an important role in most of scenarios for a cost-efficient and secure power supply

Energy system transition pathways to meet the global electricity demand for ambitious climate targets and cost competitiveness.

This study presents a novel energy system modelling approach for analysis and comparison of global energy transition pathways for decarbonisation of the electricity sector. The results of the International Energy Agency (IEA), and the Teske/DLR scenarios are each reproduced. Additionally, five new energy transition trajectories, called LUT, are presented. The research examines the feasibility of each scenario across nine major regions in 5-year intervals, from 2015 to 2050, under a uniform modelling environment with identical technical and financial assumptions. The main differences between the energy transition paths are identified across: (1) the average electricity generation costs; (2) energy diversity; (3) system flexibility; (4) energy security; and, (5) transition dynamics. All LUT and Teske/DLR scenarios are transitioned to zero CO2 emissions and a 100% renewable energy system by 2050 at the latest. Results reveal that the LUT scenarios are the least-cost pathways, while the Teske/DLR scenarios are centred around energy diversity with slightly higher LCOE of around 10-20%. The IEA shares similarities with the Teske/DLR scenarios in terms of energy diversity yet depends on continued use of fossil fuels with carbon capture and storage, and nuclear power. The IEA scenario based on current governmental policies present a worst-case situation regarding CO2 emissions reduction, climate change and overall system costs

Exploring long-term strategies for the German Energy Transition - A Review of Multi-Sector Energy Scenarios

This article systematically compares 26 different scenarios of climate-friendly energy systems, aiming at a reduction of CO2 emissions of at least 90% for Germany in 2050. Technical strategies in terms of technology or energy carrier mixes in the end-use sectors industry, buildings, and transport as well as in the conversion sectors are examined. In addition, the consequences of those different strategies in terms of electricity demand, installed capacity for electricity generation, demand for synthetic fuels and gases (P2X), etc. are looked at. Furthermore, imports of electricity and P2X are compared. In conclusion, there is a wide range of transformation pathways that are projected for Germany, and there is far from consensus on how to technically achieve a reduction in CO2 emissions of at least 90% by 2050 in comparison to 1990 levels. This, in turn, illustrates that there is still much need for research and discussion to identify feasible and sustainable transformation strategies towards a 'net zero' energy system for Germany

Leitstudie 2010

Strategien zu erarbeiten, die aufzeigen, wie das langfristige Klimaschutzziel 2050 in Deutschland erreicht werden kann, ist das oberste Ziel von Studien, die seit gut einem Jahrzehnt vom DLR-ITT, Abteilung Systemanalyse und Technikbewertung mit wechselnden Projektpartnern für das BMU und das UBA durchgeführt werden. In der Leitstudie 2010 entstanden auf der Basis differenzierter und aktualisierter Potenzialabschätzungen, die technische, strukturelle und ökologische Kriterien berücksichtigen, und detaillierten Technik- und Kostenanalysen zu den Einzeltechnologien der Erneuerbaren verschiedene Szenarien ihres möglichen langfristigen Ausbaus in Wechselwirkung mit den übrigen Teilen der Energieversorgung in Deutschland. Für die Leitstudie 2010 haben die Projektpartner DLR, Stuttgart und Fraunhofer-IWES, Kassel erstmals mittels geeigneter Modelle eine vollständige dynamische und teilweise räumlich aufgegliederte Simulation der Stromversorgung durchgeführt. Außerdem wird der Untersuchungsraum für diese Simulation auf ganz Europa (einschließlich einiger nordafrikanischer Länder) ausgedehnt, um die Wechselwirkungen eines nationalen Umbaus der Energieversorgung mit der Entwicklung in Nachbarregionen erfassen zu können

Effect of Cold Work on the Tensile Properties of 6061, 2024, and 7075 Al Alloys

Aluminum alloys 6061, 2024, and 7075 were heat treated to various tempers and then subjected to a range of plastic strain (stretching) in order to determine their strain limits. Tensile properties, conductivity, hardness, and grain size measurements were evaluated. The effects of the plastic strain on these properties are discussed and strain limits are suggested

A Pathway for the German Energy Sector Compatible with a 1.5°C Carbon Budget

We present an energy transition pathway constrained by a total CO2 budget of 7 Gt allocated to the German energy system after 2020, the Budget Scenario (BS). We apply a normative backcasting approach for scenario building based on historical data and assumptions from existing scenario studies. The modeling approach combines a comprehensive energy system model (ESM) with REMix—a cost optimization model for power and heat that explicitly incorporates sector coupling. To achieve the necessary CO2 reduction, the scenario focuses on electrifying all end use sectors until 2030, adding 1.5–2 million electric vehicles to the road per year. In buildings, 400,000–500,000 heat pumps would be installed annually by 2030, and the share of district heating would double until 2050. In the scenario, coal needs to be phased out by 2030. Wind and Photovoltaic (PV) capacities would need to more than double to 290 GW by 2030 and reach 500 GW by 2050. The BS results indicate that a significant acceleration of the energy transition is necessary before 2030 and that this higher pace must be maintained thereafter until 2050