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Vulnerabilitätsanalyse "Hitzestress und menschliche Gesundheit" am Beispiel der Stadt Reutlingen
(2020)
In diesem Modellprojekt wird das Schutzgut "Menschliche Gesundheit" insbesondere unter dem Gesichtspunkt der im Rahmen des globalen Klimawandels zu erwartenden Überhitzung der Städte ("städtische Hitzeinseln") betrachtet.
In der Großstadt Reutlingen ("Tor zur Schwäbischen Alb/112.500 EW) mit ihrer Pfortenlage am Rande der Schwäbischen Alb und der Höhenlage (400-800 m) sowie der Bebauungsdichte werden bis 2050 bzw. 2100 (Strategie zur Anpassung an den Klimawandel Baden-Württemberg - Vulnerabilitäten und Klimaanpassungsmaßnahmen, 2015) die massivsten Auswirkungen bezüglich Aufenthaltsbehaglichkeit und Gesundheitsfolgen in Reutlingen erwartet.
Der Untersuchungsschwerpunkt liegt im Wirkungsbereich Mensch-Siedlung, d.h. in der Betrachtung von empfindlichen Bevölkerungspopulationen (z.B. ältere Menschen) und hitzeempfindlichen Nutzungsstrukturen (z.B. verdichteten städtischen Siedlungsflächen). Insbesondere die bereits in der abgeschlossenen Gesamtstädtischen Klimaanalyse ermittelten überwärmten Areale ("hot spots") und die im Rahmen des Klimawandels für 2020-2050 zukünftig zu erwartende Hitzestressbelastung bei empfindlichen Bevölkerungsgruppen in Stadtquartieren und Funktionsbauten, stehen im Zenit der Untersuchung.
Dabei wird über das Kriterium Empfindlichkeit (Basis sind z.B. quartierbezogene Datenstrukturen von Älteren, Einrichtungen wie Krankenhäuser, Kinderpflegeeinrichtungen, Alten- Behinderten- und Pflegeheime) die zukünftige Hitzestress-Belastung für Reutlingen erarbeitet. Weiteres wichtiges Kriterium ist die Betroffenheit nach Standortsituation (Höhenlage, Durchlüftungsverhältnisse, Bioklima/PMV = Maß für die bioklimatische Behaglichkeit) und die Anzahl hitzestressgeplagter Menschen (Kinder, Kranke, Ältere). Insbesondere für das Szenarium 2020 bis 2050 (s. Strategie zur Anpassung an den Klimawandel Baden-Württemberg - Vulnerabilitäten und Klimaanpassungsmaßnahmen, 2015) werden objekt- bzw. einrichtungsbezogen (z.B. Altenpflegeeinrichtungen) sowie quartiersspezifisch (Stadtstrukturtypen) die Auswirkungen bzw. Verwundbarkeiten erarbeitet. Dieser objektspezifische (bauklimatische) Ansatz, die innovative Indikatorenbildung zur situativen kommunalen Anwendbarkeit auch über Reutlingen hinaus sowie der partizipative Ansatz mit Nichtregierungsorganisationen (NGO´s) begründet den Modellcharakter ("Reutlinger Modell") dieser Untersuchung. Das Modellprojekt bildet das zweite Modul in einem dreiteiligen Klimaanpassungskonzept für die Stadt Reutlingen.
The German Weather Service (DWD) releases a heat warning, when the weather forecast provides a warm, humid, sunny, and windless weather condition during the next days. The heat stress is calculated by the so called Klima-Michel model. If the apparent air temperature exceeds ca. 32°C / 38°C, there is a strong / extreme heat stress. The smallest forecast area is each administrative district. As people (and especially the vulnerable population) stay most of the time indoors, the heat health warning system was extended by the prediction of heat stress in typical rooms. Therewith it is feasible to forecast the heat stress using a combination of the outdoor and indoor heat stress. The prediction for the indoor heat stress is based on the same weather forecast like the Heat Health Warning Systems (HHWS).and calculates the heat stress by the PMV-model (predicted mean vote). Based on a sophisticated data analysis and simulation study, realistic but summer-critical living situations were defined and implemented in the building simulation program ESP-r. As the simulation runs especially for extreme weather conditions, a simplified building model cannot be used. Standardized input/output routines and an adaptive handover of start values provide for short run times for each forecast area. Good building designs and urban planning provide effective measures to reduce heat stress in cities. However, we have to also pay attention to the present building stock under climate change and a higher heat-wave risk. The extended German HHWS provide information for the emergency services to support the social assistants during heat waves.
This study presents some results from a monitoring project with night ventilation and earthto-air heat exchanger. Both techniques refer to air-based low-energy cooling. As these technologies are limited to specific boundary conditions (e.g. moderate summer climate, low temperatures during night, or low ground temperatures, respectively), water-based low-energy cooling may be preferred in many projects. A comparison of the night-ventilated building with a ground-cooled building shows major differences in both concepts.
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.
Variable refrigerant flow (VRF) and variable air volume (VAV) systems are considered among the best heating, ventilation, and air conditioning systems (HVAC) thanks to their ability to provide cooling and heating in different thermal zones of the same building. As well as their ability to recover the heat rejected from spaces requiring cooling and reuse it to heat another space. Nevertheless, at the same time, these systems are considered one of the most energy-consuming systems in the building. So, it is crucial to well size the system according to the building’s cooling and heating needs and the indoor temperature fluctuations. This study aims to compare these two energy systems by conducting an energy model simulation of a real building under a semi-arid climate for cooling and heating periods. The developed building energy model (BEM) was validated and calibrated using measured and simulated indoor air temperature and energy consumption data. The study aims to evaluate the effect of these HVAC systems on energy consumption and the indoor thermal comfort of the building. The numerical model was based on the Energy Plus simulation engine. The approach used in this paper has allowed us to reach significant quantitative energy saving along with a high level of indoor thermal comfort by using the VRF system compared to the VAV system. The findings prove that the VRF system provides 46.18% of the annual total heating energy savings and 6.14% of the annual cooling and ventilation energy savings compared to the VAV system.
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.
This paper presents a framework for numerical building validation enhancement based on detailed building specifications from in-situ measurements and evidence-based validation assessment undertaken on a detached sustainable lightweight building in a semi-arid climate. The validation process has been undergone in a set of controlled experiments – a free-float period, and steady-state internal temperatures. The validation was conducted for a complete year with a 1-min time step for the hourly indoor temperature and the variable refrigerant flow (VRF) energy consumption. The initial baseline model was improved by three series of validation steps per three different field measurements including thermal transmittance, glazing thermal and optical properties, and airtightness. Then, the accurate and validated model was used for building energy efficiency assessment in 12 regions of Morocco. This study aims to assess the effect of accurate building characteristics values on the numerical model enhancement. The initial CV(RMSE) and NMBE have improved respectively from 14.58 % and −11.23 %–7.85 % and 1.86 % for the indoor temperature. Besides, from 31.17 % to 14.37 %–20.57 % and 9.77 % for energy consumption. The findings demonstrate that the lightweight construction with the use of a variable refrigerant flow system could be energy efficient in the southern regions of Morocco.
The variable refrigerant flow system is one of the best heating, ventilation, and air conditioning systems (HVAC) thanks to its ability to provide thermal comfort inside buildings. But, at the same time, these systems are considered one of the most energy-consuming systems in the building sector. Thus, it is crucial to well size the system according to the building’s cooling and heating needs and the indoor temperature fluctuations. Although many researchers have studied the optimization of the building energy performance considering heating or cooling needs, using air handling units, radiant floor heating, and direct expansion valves, few studies have considered the use of multi-objective optimization using only the thermostat setpoints of VRF systems for both cooling and heating needs. Thus, the main aim of this study is to conduct a sensitivity analysis and a multi-objective optimization strategy for a residential building containing a variable refrigerant flow system, to evaluate the effect of the building performance on energy consumption and improve the building energy efficiency. The numerical model was based on the EnergyPlus, jEPlus, and jEPlus+EA simulation engines. The approach used in this paper has allowed us to reach significant quantitative energy saving by varying the cooling and heating setpoints and scheduling scenarios. It should be stressed that this approach could be applied to several HVAC systems to reduce energy-building consumption.
Dieser technische Bericht stellt die Verwendung der Zuwendung und der erzielten Ergebnisse im Einzelnen dar. Die Gegenüberstellung mit den vorgegebenen Zielen erfolgt anhand der Beschreibung des Arbeitspakete. Die Verwendung der Zuwendung und Gegenüberstellung mit den vorgegebenen Zielen wird anhand der Arbeitspakete beschrieben, um den Abgleich zwischen Planung und durchgeführten Arbeiten unmittelbar darstellen zu können.