Simulação e avaliação de um sistema de aquecimento solar de água utilizando balanço energético / Simulation and evaluation of a system of solar water heating using energy balance

Medeiros, Maurício

17 February 2012

Made available in DSpace on 2017-07-10T15:14:45Z (GMT). No. of bitstreams: 1 Mauricio Medeiros.pdf: 2573107 bytes, checksum: 1e5a17966417b43d576f37b4837c682b (MD5) Previous issue date: 2012-02-17 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / This work was developed at the State University of West of Paraná UNIOESTE, campus de Cascavel and was aimed at developing a computer program to simulate and scale, optimally, a system of solar water heating. To determine the efficiency parameters of the system were installed three solar collectors of 1.05 m2 each, brand Pro Sol, coupled to a thermal reservoir of 200 liters, containing electrical resistances auxiliary 2000 W. The system works by using thermosyphon, and was installed in a metal bracket fixed to the ground, oriented to the north at an angle of 35 degrees from the horizontal. We collected hourly data of solar radiation and water temperatures, and evaluated two scenarios. In the first scenario, it was considered system utilization auxiliary heating controlled by a thermostat, which linked and hang up the electrical resistances as the temperature of water in boiler oscillated around of temperature of consumption (40 º C). In the second scenario, it was considered the system to power auxiliary heating only in timetables of water consumption, when the water temperature in boiler was lower than the temperature of consumption. Coefficients were calculated heat loss in the solar collector and storage tank, the heat removal factor of solar collector and the overall efficiency of the heating system installed. These calculated parameters and other data collected were used in software developed for simulation and design in order to satisfactorily meet the needs of hot water consumption, and minimize the total installation costs and energy consumption. Finally, these system costs solar heating were compared to costs of an electric shower conventional. The results obtained were as follows: coefficient of heat loss in the solar collector (5,45 Wm-2ºC-1), coefficient of heat loss in the thermal reservoir (5,34 Wm-2ºC-1), removal factor heat of the solar collector (0.78) and overall system efficiency (31%). The times of return on capital invested in the solar heating system (compared to a conventional electric shower), for the two scenarios of use, were, respectively, 11.45 years and 7.81 years. / Este trabalho foi desenvolvido na Universidade Estadual do Oeste do Paraná UNIOESTE, campus de Cascavel, e teve por objetivo principal o desenvolvimento de um programa computacional para simular e dimensionar, de forma otimizada, um sistema de aquecimento solar de água. Para determinar os parâmetros de eficiência do sistema, foram instalados três coletores solares de 1,05 m2 cada, da marca Pro Sol, acoplados a um reservatório térmico de 200 litros, contendo resistências elétricas auxiliares de 2000 W. O sistema utilizado funciona por termossifão, e foi instalado em um suporte metálico fixado ao solo, com orientação para o norte, num ângulo de 35º em relação à horizontal. Foram coletados dados horários de radiação solar e temperaturas da água, e avaliados dois cenários. No primeiro cenário, considerou-se a utilização do sistema de aquecimento auxiliar controlado por um termostato, que ligava e desligava as resistências elétricas conforme a temperatura da água no boiler oscilava em torno da temperatura de consumo (40ºC). No segundo cenário, considerou-se o acionamento do sistema de aquecimento auxiliar somente nos horários de consumo de água, quando a temperatura da água no boiler estivesse menor que a temperatura de consumo. Foram calculados os coeficientes de perda de calor no coletor solar e no reservatório térmico, o fator de remoção de calor no coletor solar e a eficiência global do sistema de aquecimento instalado. Esses parâmetros calculados, e os demais dados coletados, foram utilizados no software desenvolvido para simulação e dimensionamento, de maneira a atender satisfatoriamente às necessidades de consumo de água quente, e minimizar os custos totais de instalação e consumo de energia elétrica. Por fim, esses custos do sistema de aquecimento solar foram comparados aos custos de um chuveiro elétrico convencional. Os resultados obtidos foram os seguintes: coeficiente de perda de calor no coletor solar (5,45 Wm-2ºC-1), coeficiente de perda de calor no reservatório térmico (5,34 Wm-2ºC-1), fator de emoção de calor do coletor solar (0,78) e eficiência global do sistema (31%). Os tempos de retorno do capital investido no sistema de aquecimento solar (em comparação a um chuveiro elétrico convencional), para os dois cenários de utilização, foram de, respectivamente, 11,38 anos e 5,73 anos.

Aquecimento solar de água

Dimensionamento e simulação

Solar water heating

sizing and simulation

CNPQ::CIENCIAS EXATAS E DA TERRA

SELF-SUFFICIENT OFF-GRID ENERGY SYSTEM FOR A ROWHOUSE USING PHOTOVOLTAIC PANELS COMBINED WITH HYDROGEN SYSTEM : Master thesis in energy system

Maxamhud, Mahamed, Shanshal, Arkam

January 2020

It is known that Sweden is categorised by being one of the regions that experience low solar radiation because it is located in the northern hemisphere that has a low potential of solar radiation during the colder seasons. The government of Sweden aim to promote a more sustainable future by applying more renewable initiative in the energy sector. One of the initiatives is by applying more renewable energy where PV panels will play a greater role in our society and in the energy sector. However, the produced energy from the PV panels is unpredictable due to changes in radiation throughout the day. One great way to tackle this issue is by combining PV panels with different energy storage system. This thesis evaluates an off-grid rowhouse in Eskilstuna Sweden where the PV panels are combined with a heat pump, thermal storage tank, including batteries and hydrogen system. The yearly electrical demand is met by utilizing PV panels, battery system for short term usage and hydrogen system for long-term usage during the colder seasons. The yearly thermal demand is met by the thermal storage tank. The thermal storage tank is charged by heat losses from the hydrogen system and thermal energy from heat pump.The calculations were simulated in Excel and MATLAB where OPTI-CE is composed with different components in the energy system. Furthermore, the off-grid household was evaluated from an economic outlook with respect to today’s market including the potential price decrease in 2030.The results indicated that the selected household is technically practicable to produce enough energy. The PV panels produces 13 560 kWh annually where the total electrical demand reaches 6 125 kWh yearly (including required electricity for the heat pump). The annual energy demand in terms of electricity and thermal heat reaches 12 500 kWh which is covered by the simulated energy system. The overproduction is stored in the batteries and hydrogen storage for later use. The back-up diesel generator does not need to operate, indicating that energy system supplies enough energy for the off-grid household. The thermal storage tank stores enough thermal energy regarding to the thermal load and stores most of the heat during the summer when there are high heat losses due to the charge of the hydrogen system. The simulated energy system has a life cycle cost reaching approximately k$318 with a total lifetime of 25 years. A similar off-grid system has the potential to reduce the life cycle cost to k$195 if the energy system is built in 2030 with a similar lifespan. The reduction occurs due to the potential price reduction for different components utilized in the energy system.

Off-grid

PV panels

hydrogen system

battery system

thermal storage tank

heat pump

life cycle cost

electrical load

thermal load

OPTI-CE

Engineering and Technology

Teknik och teknologier

Analysis of a novel thermoelectric generator in the built environment

Lozano, Adolfo

05 October 2011

This study centered on a novel thermoelectric generator (TEG) integrated into the built environment. Designed by Watts Thermoelectric LLC, the TEG is essentially a novel assembly of thermoelectric modules whose required temperature differential is supplied by hot and cold streams of water flowing through the TEG. Per its recommended operating conditions, the TEG nominally generates 83 Watts of electrical power. In its default configuration in the built environment, solar-thermal energy serves as the TEG’s hot stream source and geothermal energy serves as its cold stream source. Two systems-level, thermodynamic analyses were performed, which were based on the TEG’s upcoming characterization testing, scheduled to occur later in 2011 in Detroit, Michigan. The first analysis considered the TEG coupled with a solar collector system. A numerical model of the coupled system was constructed in order to estimate the system’s annual energetic performance. It was determined numerically that over the course of a sample year, the solar collector system could deliver 39.73 megawatt-hours (MWh) of thermal energy to the TEG. The TEG converted that thermal energy into a net of 266.5 kilowatt-hours of electricity in that year. The second analysis focused on the TEG itself during operation with the purpose of providing a preliminary thermodynamic characterization of the TEG. Using experimental data, this analysis found the TEG’s operating efficiency to be 1.72%. Next, the annual emissions that would be avoided by implementing the zero-emission TEG were considered. The emission factor of Michigan’s electric grid, RFCM, was calculated to be 0.830 tons of carbon dioxide-equivalent (CO2e) per MWh, and with the TEG’s annual energy output, it was concluded that 0.221 tons CO2e would be avoided each year with the TEG. It is important to note that the TEG can be linearly scaled up by including additional modules. Thus, these benefits can be multiplied through the incorporation of more TEG units. Finally, the levelized cost of electricity (LCOE) of the TEG integrated into the built environment with the solar-thermal hot source and passive ground-based cold source was considered. The LCOE of the system was estimated to be approximately $8,404/MWh, which is substantially greater than current generation technologies. Note that this calculation was based on one particular configuration with a particular and narrow set of assumptions, and is not intended to be a general conclusion about TEG systems overall. It was concluded that while solar-thermal energy systems can sustain the TEG, they are capital-intensive and therefore not economically suitable for the TEG given the assumptions of this analysis. In the end, because of the large costs associated with the solar-thermal system, waste heat recovery is proposed as a potentially more cost-effective provider of the TEG’s hot stream source. / text

Thermoelectric generator

TEG

Novel thermoelectric generator

Thermoelectrics

Thermoelectric effect

Thermoelectric modules

Thermoelectric device

Patent application

Hot stream source

Cold stream source

EIA

EERE

Systems-level analysis

Energy balance

Control volume analysis

Thermodynamic analysis

Insolation data

Insolation incident on a panel

Incident insolation

Extraterrestrial insolation

NREL

Ambient temperature data

NOAA

Renewable energy sources

Energy generation technology

Electricity generation technology

Thermal energy

Coupled system

Emissions

Greenhouse gas

GHG

Emissions analysis

Zero-emission

Emissions avoided

Emission factor

EF

Reliability First Corporation

RFC

Built environment

Integrated into the built environment

Solar-thermal energy

Solar collector system

Photovoltaic thermal

PVT panel

Thermal storage tank

Geothermal energy

Geothermal heat pump

GHP

Ground source heat pump

GSHP

Numerical analysis

Numerical model

MATLAB

Finite-difference

Euler explicit

Electric grid

Annual energetic performance

Annual electricity generation

Operating efficiency

System efficiency

Thermodynamic characterization

Economic analysis

Levelized cost of energy

LCOE

Waste heat recovery

Carbon dioxide equivalent

CO2e

Capital costs

Installed costs

Operating and maintenance costs