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Gasdynamik
(2020)
Für kompressible Strömungen werden die Erhaltungssätze für Masse, Impuls und Energie hergeleitet. Die Eigenschaften der Stoßgleichungen wie Rankine-Hugoniot-Relation und Rayleigh-Gerade werden betrachtet. Zur Berechnung der Kräfte auf umströmte Körper werden die Auftriebs- und Widerstandsbeiwerte ermittelt. Auf der Basis der Stromfadentheorie wird die Auslegung von Lavaldüsen behandelt. Das physikalische Verhalten linearer Unter- und Überschallströmungen und transsonischer Profilumströmungen wird analysiert.
Experimental Investigation of the Air Exchange Effectiveness of Push-Pull Ventilation Devices
(2020)
The increasing installation numbers of ventilation units in residential buildings are driven by legal objectives to improve their energy efficiency. The dimensioning of a ventilation system for nearly zero energy buildings is usually based on the air flow rate desired by the clients or requested by technical regulations. However, this does not necessarily lead to a system actually able to renew the air volume of the living space effectively. In recent years decentralised systems with an alternating operation mode and fairly good energy efficiencies entered the market and following question was raised: “Does this operation mode allow an efficient air renewal?” This question can be answered experimentally by performing a tracer gas analysis. In the presented study, a total of 15 preliminary tests are carried out in a climatic chamber representing a single room equipped with two push-pull devices. The tests include summer, winter and isothermal supply air conditions since this parameter variation is missing till now for push-pull devices. Further investigations are dedicated to the effect of thermal convection due to human heat dissipation on the room air flow. In dependence on these boundary conditions, the determined air exchange efficiency varies, lagging behind the expected range 0.5 < εa < 1 in almost all cases, indicating insufficient air exchange including short-circuiting. Local air exchange values suggest inhomogeneous air renewal depending on the distance to the indoor apertures as well as the temperature gradients between in- and outdoor. The tested measurement set-up is applicable for field measurements.
In this paper, we describe the PALM model system 6.0. PALM (formerly an abbreviation for Parallelized Large-eddy Simulation Model and now an independent name) is a Fortran-based code and has been applied for studying a variety of atmospheric and oceanic boundary layers for about 20 years. The model is optimized for use on massively parallel computer architectures. This is a follow-up paper to the PALM 4.0 model description in Maronga et al. (2015). During the last years, PALM has been significantly improved and now offers a variety of new components. In particular, much effort was made to enhance the model with components needed for applications in urban environments, like fully interactive land surface and radiation schemes, chemistry, and an indoor model. This paper serves as an overview paper of the PALM 6.0 model system and we describe its current model core. The individual components for urban applications, case studies, validation runs, and issues with suitable input data are presented and discussed in a series of companion papers in this special issue.
Additive manufacturing is a rapidly growing manufacturing process for which many new processes and materials are currently being developed. The biggest advantage is that almost any shape can be produced, while conventional manufacturing methods reach their limits. Furthermore, a lot of material is saved because the part is created in layers and only as much material is used as necessary. In contrast, in the case of machining processes, it is not uncommon for more than half of the material to be removed and disposed of. Recently, new additive manufacturing processes have been on the market that enables the manufacturing of components using the FDM process with fiber reinforcement. This opens up new possibilities for optimizing components in terms of their strength and at the same time increasing sustainability by reducing materials consumption and waste. Within the scope of this work, different types of test specimens are to be designed, manufactured and examined. The test specimens are tensile specimens, which are used both for standardized tensile tests and for examining a practical component from automotive engineering used in student project. This project is a vehicle designed to compete in the Shell Eco-marathon, one of the world’s largest energy efficiency competitions. The aim is to design a vehicle that covers a certain distance with as little fuel as possible. Accordingly, it is desirable to manufacture the components with the lowest possible weight, while still ensuring the required rigidity. To achieve this, the use of fiber-reinforced 3D-printed parts is particularly suitable due to the high rigidity. In particular, the joining technology for connecting conventionally and additively manufactured components is developed. As a result, the economic efficiency was assessed, and guidelines for the design of components and joining elements were created. In addition, it could be shown that the additive manufacturing of the component could be implemented faster and more sustainably than the previous conventional manufacturing.
Ecological concerns on the climatic effects of the emissions from electricity production stipulate the remuneration of electricity grids to accept growing amounts of intermittent regenerative electricity feed-in from wind and solar power. Germany’s eager political target to double regenerative electricity production by 2030 puts pressure on grid operators to adapt and restructure their transmission and distribution grids. The ability of local distribution grids to operate autonomous of transmission grid supply is essential to stabilize electricity supply at the level of German federal states. Although congestion management and collaboration at the distribution system operator (DSO) level are promising approaches, relatively few studies address this issue. This study presents a methodology to assess the electric energy balance for the low-voltage grids in the German federal state of Baden-Württemberg, assuming the typical load curves and the interchange potential among local distribution grids by means of linear programming of the supply function and for typical seasonal electricity demands. The model can make a statement about the performance and development requirements for grid architecture for scenarios in 2035 and 2050 when regenerative energies will—according to present legislation—account for more than half of Germany’s electricity supply. The study details the amendment to Baden-Württemberg’s electricity grid required to fit the system to the requirements of regenerative electricity production. The suggested model for grid analysis can be used in further German regions and internationally to systematically remunerate electricity grids for the acceptance of larger amounts of regenerative electricity inflows. This empirical study closes the research gap of assessing the interchange potential among DSO and considers usual power loads and simultaneously usual electricity inflows.
Short-term load forecasting (STLF) has been playing a key role in the electricity sector for several decades, due to the need for aligning energy generation with the demand and the financial risk connected with forecasting errors. Following the top-down approach, forecasts are calculated for aggregated load profiles, meaning the sum of singular loads from consumers belonging to a balancing group. Due to the emerging flexible loads, there is an increasing relevance for STLF of individual factories. These load profiles are typically more stochastic compared to aggregated ones, which imposes new requirements to forecasting methods and tools with a bottom-up approach. The increasing digitalization in industry with enhanced data availability as well as smart metering are enablers for improved load forecasts. There is a need for STLF tools processing live data with a high temporal resolution in the minute range. Furthermore, behin-the-meter (BTM) data from various sources like submetering and production planning data should be integrated in the models. In this case, STLF is becoming a big data problem so that machine learning (ML) methods are required. The research project “GaIN” investigates the improvement of the STLF quality of an energy utility using BTM data and innovative ML models. This paper describes the project scope, proposes a detailed definition for a benchmark and evaluates the readiness of existing STLF methods to fulfil the described requirements as a reviewing paper.
The review highlights that recent STLF investigations focus on ML methods. Especially hybrid models gain more and more importance. ML can outperform classical methods in terms of automation degree and forecasting accuracy. Nevertheless, the potential for improving forecasting accuracy by the use of ML models depends on the underlying data and the types of input variables. The described methods in the analyzed publications only partially fulfil the tool requirements for STLF on company level. There is still a need to develop suitable ML methods to integrate the expanded data base in order to improve load forecasts on company level.
Interaction and capturing information from the surrounding is dominated by vision and hearing. Haptics on the other side, widens the bandwidth and could also replace senses (sense switching) for impaired. Haptic technologies are often limited to point-wise actuation. Here, we show that actuation in two-dimensional matrices instead creates a richer input. We describe the construction of a full-body garment for haptic communication with a distributed actuating network. The garment is divided into attachable-detachable panels or add-ons that each can carry a two dimensional matrix of actuating haptic elements. Each panel adds to an enhanced sensoric capability of the human- garment system so that together a 720° system is formed. The spatial separation of the panels on different body locations supports semantic and theme-wise separation of conversations conveyed by haptics. It also achieves directional faithfulness, which is maintaining any directional information about a distal stimulus in the haptic input.
Das Projekt „Tilty“ befässt sich mit der Konstruktion eines Speed- Pedelecs. Dieses verfügt über eine Vorderachse mit 2 Rädern und Neigemechanismus. Hinten besitzt es ein Rad. Der Sitz dieses Fahrzeuges sollte ein Fahren in aufrechter Sitzhaltung ermöglichen. Dabei ist der Sitz auf derselben Höhe wie bei einem Auto, um im Straßenverkehr besser wahrgenommen werden zu können als bei einem Liegefahrrad. Ein Ziel dieser Arbeit war es, einen Sitz unter Berücksichtigung der Physiologie eines Menschen zu konstruieren. Die Position der Kurbel war ebenso ein zentrales Thema dieser Arbeit. Dabei spielte der sogenannte runde Tritt eine wichtige Rolle. Beide Komponenten mussten ebenfalls gemeinsam betrachtet werden um eine Aussage treffen zu können. Die Lenkung und damit die Position der Arme sind auch von Bedeutung. Die Konstruktion dieser Lenkung übernimmt eine Masterstudentin, daher ist die Lenkung nur ein Randthema. Eine Aussage über die Position der Arme konnte ebenfalls aufgrund der physiologischen Parameter getroffen werden.
Konstrukteure im Maschinenbau stehen häufig vor der Problemstellung, hochfest vorgespannte Schraubenverbindungen und einen durchgehenden Korrosionsschutz zu vereinen. Die Normen und Richtlinien bieten hierzu Stand heute keine ausreichenden Antworten. Die Hochschule Offenburg befasst sich im Rahmen einer industriellen Gemeinschaftsforschung mit der Fragestellung, welchen Einfluss organische Beschichtungen auf die Vorspannkraft insbesondere bei erhöhten Umgebungstemperaturen haben. In dieser Arbeit werden die ersten Ergebnisse zum Einfluss der Einzelschichtstärke des Beschichtungssystems präsentiert.
Die Physik des Fahrrades
(2020)
Jeder kann Fahrradfahren, keiner weiß,warum es klappt: Anders als beim Reiten, Laufen oder Skifahren muss man sich mit dem Fahrrad immer vorwärtsbewegen, um nicht umzufallen. Prof. Giel von der Hochschule Offenburg erklärt dieses und andere Geheimnisse des Radfahrens. Zum Beispiel, ob man mit der Fahrradpumpe auch Autoreifen aufpumpen kann, warum normale Fahrradfahrer die Marathon-Distanz schneller als die weltbesten Läufer zurücklegen und welche legalen Tuning-Methoden das eigene Fahrrad noch schneller machen.
Power systems are increasingly built from distributed generation units and smart consumers that are able to react to grid conditions. Managing this large number of decentralized electricity sources and flexible loads represent a very huge optimization problem. Both from the regulatory and the computational perspective, no one central coordinator can optimize this overall system. Decentralized control mechanisms can, however, distribute the optimization task through price signals or market-based mechanisms. This chapter presents the concepts that enable a decentralized control of demand and supply while enhancing overall efficiency of the electricity system. It highlights both technological and business challenges that result from the realization of these concepts, and presents the state-of-the-art in the respective domains.
Ziel und Tempo der Energiewende sind gesetzt. Der Ausstieg aus der Stromproduktion in Kernkraftwerken soll bis 2022 geschafft sein. Eine Elektrizitätserzeugung, die auf erneuerbaren Energien beruht, soll die bisherige Erzeugung auf der Grundlage von Kohle, Kernbrennstoffen und Erdgas bis 2050 stufenweise weitgehend ablösen und damit maßgeblich zu den Klimaschutzzielen der Bundesregierung beitragen. Der Weg zu diesen Zielen ist für die Beteiligten hingegen noch nicht deutlich einsehbar. Viele offene Fragestellungen technischer, ökonomischer, legislativer und gesellschaftlicher Natur verstellen den Blick auf eine klare Strategie zur Erreichung der energiepolitischen Ziele. Vielschichtige Aufgaben und immense Herausforderungen kommen mit der Mammutaufgabe „Energiewende“ auf Politik, Wirtschaft, Wissenschaft und Bevölkerung zu. Ein wichtiger Enabler für die erfolgreiche Integration von Wind- und Sonnenenergie sowie für neue Prozesse, Marktrollen und Technologien ist die Informations- und Kommunikationstechnologie (IKT). An diesem Punkt setzt die hier vorliegende Studie an.
The PHOTOPUR project aims to develop a photocatalytic process as a type of AOPs (Advanced Oxidation Processes) for the elimination of plant protection products (PPP) of the cleaning water used to wash sprayers. At INES a PV based energy supply for the photocatalytic cleaning system was developed within the framework of two bachelor theses and assembled as a demonstration unit. Then the system was step by step extended with further process automation features and pushed to a remote operating device. The final system is now available as a mobile unit mounted on a lab table. The latest step was the photocatalytic reactor module which completed the first PHOTOPUR prototype. The system is actually undergoing an intensive testing phase with performance checks at the consortium partners. First results give an overview about the successful operation.
Optimisation based economic despatch of real-world complex energy systems demands reduced order and continuously differentiable component models that can represent their part-load behaviour and dynamic responses. A literature study of existing modelling methods and the necessary characteristics the models should meet for their successful application in model predictive control of a polygeneration system are presented. Deriving from that, a rational modelling procedure using engineering principles and assumptions to develop simplified component models is applied. The models are quantitatively and qualitatively evaluated against experimental data and their efficacy for application in a building automation and control architecture is established.
Cooling towers or recoolers are one of the major consumers of electricity in a HVAC plant. The implementation and analysis of advanced control methods in a practical application and its comparison with conventional controllers is necessary to establish a framework for their feasibility especially in the field of decentralised energy systems. A standard industrial controller, a PID and a model based controller were developed and tested in an experimental set-up using market-ready components. The characteristics of these controllers such as settling time, control difference, and frequency of control actions are compared based on the monitoring data. Modern controllers demonstrated clear advantages in terms of energy savings and higher accuracy and a model based controller was easier to set-up than a PID.
Passive hybridization refers to a parallel connection of photovoltaic and battery cells on the direct current level without any active controllers or inverters. We present the first study of a lithium-ion battery cell connected in parallel to a string of four or five serially-connected photovoltaic cells. Experimental investigations were performed using a modified commercial photovoltaic module and a lithium titanate battery pouch cell, representing an overall 41.7 W-peak (photovoltaic)/36.8 W-hour (battery) passive hybrid system. Systematic and detailed monitoring of this system over periods of several days with different load scenarios was carried out. A scaled dynamic synthetic load representing a typical profile of a single-family house was successfully supplied with 100 % self-sufficiency over a period of two days. The system shows dynamic, fully passive self-regulation without maximum power point tracking and without battery management system. The feasibility of a photovoltaic/lithium-ion battery passive hybrid system could therefore be demonstrated.
Skispringen ist aus biomechanischer sowie sportlicher Sicht eine hoch komplexe Sportart, bei der Koordination und Timing exakt abgestimmt sein müssen. Der Skisprung setzt sich dabei aus verschiedenen Phasen zusammen, die häufig getrennt voneinander trainiert werden. Grund hierfür ist vor allem der organisatorische Aufwand sowie das hohe Verletzungsrisiko bei einem echten Schanzensprung. Dass dies zwar als Basis für das Training ausreicht, aber einen ganzheitlichen Sprung nicht ersetzten kann, ist offensichtlich. Darum soll eine Möglichkeit gefunden werden, die Realsituation nachempfinden zu können und den ganzen Ablauf, dabei vor allem den Flug, trainieren zu können. Eine mögliche Lösung stellen sogenannte Windanlagen dar. Solche Systeme werden bereits eingesetzt, um sich auf Wettkämpfe vorzubereiten. Die meisten werden dabei allerdings nur als Trainingskanal umfunktioniert und haben eigentlich eine andere Bestimmung. Kaum eine der auf dem Markt befindlichen Anlagen bietet die Möglichkeit die Flugphase so nachzubilden, dass zum einen die Körperposition der realen entspricht, aber auch die Windbedingungen, denen auf der Schanze nahekommen. In Kooperation mit dem Olympiastützpunkt Freiburg soll im Rahmen dieser Arbeit erörtert werden, welche Voraussetzungen notwendig sind und wie die entsprechende Umsetzung aussehen kann, um einen für Skisprungzwecke geeigneten Trainingskanal zu konzipieren. Der Fokus dieser Arbeit liegt hierbei auf der Positionierung des Springers/der Springerin und der Gestaltung der dafür notwendigen Umgebung. Die technischen Gegebenheiten wie das Strömungsprofil werden hier nahezu ganz ausgelassen und anderweitig erarbeitet. Durch eine Analyse der umzusetzenden Situation sowie der gegebenen Bedingungen wird ein ganzheitliches Konzept zur Umsetzung entwickelt. Dabei soll eine Verbindung zwischen Athleten/in und Aufhängungsprofil geschaffen werden, die vor allem realitätsnah, sicher und flexibel ist. Unterteilen lässt sich die Fragestellung in Gurt, Aufhängungssystem und Rahmenprofil, was getrennt voneinander konzipiert wird. Zusätzlich werden Messtechniken, die dem Training sowie der Forschung dienen, erörtert.
In dieser Bachelorarbeit wird mit Hilfe der Software RecurDyn ein generisches Simulationsmodell eines Trikes mit Neigemechanismus entwickelt. Dabei wird besonderes Augenmerk auf die Vorderachse des Trikes gelegt, diese wird zunächst in einem zweidimensionalen Modell erstellt und anschließend ins Dreidimensionale Modell übertragen. Die Parametrisierung erfolgt nach aktuellen Standards der Fahrzeugtechnik.
Zur Simulation sind Funktionen für den einstellbaren Neigewinkel, die Geschwindigkeit des Fahrzeugs und für den Lenkwinkel hinterlegt.
Außerdem werden Konzepte entwickelt, um bei Parameterstudien die Auslenkung des Federsystems in der Vorderachse, sowie den erreichbaren Lenkwinkel zu quantifizieren.