Monitoring of a flat plate solar thermal field supplying process heat

Using solar power for industrial process heat is an increasing trend to fight against climate change thanks to renewable heat. Process heat demand and solar flux can both present intermittency issues in industrial systems, therefore solar systems with storage introduce a degree of freedom on which optimization, on a mathematical basis, can be performed. As the efficiency of solar thermal receivers varies as a function of temperature and solar flux, it seems natural to consider an optimization on the operating temperature of the solar field. In this paper, a Mixed Integer Linear Programming (MILP) algorithm is developed to optimize the operating temperature in a system consisting of a concentrated solar thermal field with storage, hybridized with a boiler. The MILP algorithm optimizes the control trajectory on a time horizon of 48 h in order to minimize boiler use. Objective function corresponds to the boiler use, for completion of the heat from the solar field, whereas the linear constraints are a simplified representation of the system. The solar field mass flow rate is the optimization variable which is directly linked to the outlet temperature of the solar field. The control trajectory consists of the solar field mass flow rate and outlet temperature, along with the auxiliary mass flow rate going directly to the boiler. The control trajectory is then injected in a 0D model of the plant which performs more detailed calculations. For the purpose of the study, a Linear Fresnel system is investigated, with generic heat demand curves and constant temperature demand. The value of the developed algorithm is compared with two other control approaches: one operating at the nominal solar field output temperature, and the other one operating at the actual demand mass flow rate. Finally, a case study and a sensitivity analysis are presented. The MILP’s control shows to be more performant, up to a relative increase of the annual solar fraction of 4% at 350 °C process temperature. Novelty of this work resides in the MILP optimization of temperature levels presenting high non-linearities, applied to a solar thermal system with storage for process heat applications.

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Computational Evolution of Optimal Iceform Shapes Over a Flat Plate

ASME 1991 Computers in Engineering Conference: Volume 1 — Artificial Intelligence; Expert Systems; CAD/CAM/CAE; Computational Fluid/Thermal Engineering ◽

10.1115/cie1991-0075 ◽

1991 ◽

Author(s):

Ronald S. LaFleur

Keyword(s):

Energy Dissipation ◽

Flat Plate ◽

Thermal Field ◽

Fluid Dynamic ◽

Minimum Energy ◽

Thermal Parameter ◽

Thermal Constraints ◽

Ice Water ◽

Nonlinear Geometric ◽

Minimum Energy Dissipation

Abstract This paper presents the computational evolution of minimum energy dissipation iceform contours. The ice/water interface is shaped according to fluid dynamic and heat transfer characteristics of the flow field near the interface. A Couette iceform design model is used to approximate flow and thermal field behavior near the interface. The theory used to calculate the interface shape is based on a wedge model of the ice contour over a cold flat plate. The steady state ice profile is calculated when Reynolds number and the thermal parameter are selected. The generation function, designation function and energy dissipation are related to the nonlinear geometric development. An optimal preprocess criterion is prescribed as zero evolution length. The result is optimal geometries that are adapted to the flow and thermal constraints.

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Aerogel and krypton insulated evacuated flat-plate collector for process heat production

Solar Energy ◽

10.1016/0038-092x(96)00007-2 ◽

1996 ◽

Vol 58 (1-3) ◽

pp. 45-48 ◽

Cited By ~ 7

Author(s):

N. Benz ◽

Th. Beikircher ◽

B. Aghazadeh

Keyword(s):

Flat Plate ◽

Heat Production ◽

Process Heat ◽

Flat Plate Collector

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Aplicaciones del Captador Solar de Placa Plana y del Captador de Tubo de Vacío en la Edificación = Applications of the Flat Plate Solar Collectors and the Vacuum Tube Solar Collectors in Building

Anales de Edificación ◽

10.20868/ade.2018.3797 ◽

2018 ◽

Vol 4 (3) ◽

pp. 25 ◽

Cited By ~ 1

Author(s):

Daniel Ferrández ◽

Carlos Moron ◽

Jorge Pablo Díaz ◽

Pablo Saiz

Keyword(s):

Flat Plate ◽

Solar Collector ◽

Energy Demand ◽

Hot Water ◽

Solar Thermal ◽

Solar Collectors ◽

Thermal Systems ◽

Vacuum Tube ◽

Solar Thermal Collectors ◽

Flat Plate Solar Collector

ResumenEl actual Código Técnico de la Edificación (CTE) pone de manifiesto la necesidad de cubrir parte de la demanda energética requerida para el abastecimiento de agua caliente sanitaria y climatización de piscinas cubiertas mediante sistemas de aprovechamiento de la energía solar térmica. En este artículo se presenta una comparativa entre las dos principales tipologías de captadores solares térmicos que existen en el mercado: el captador de placa plana y el captador de tubo de vacío, atendiendo a criterios de fracción solar, diseño e integración arquitectónica. Todo ello a fin de discernir en qué circunstancias es más favorable el uso de uno u otro sistema, comparando los resultados obtenidos mediante programas de simulación con la toma de medidas in situ.AbstractThe current Technical Building Code (CTE) highlights the need to cover part of the energy demand required for the supply of hot water and heating of indoor swimming pools using solar thermal systems. This article presents a comparison between the two main types of solar thermal collectors that exist in the market: the flat plate solar collector and the vacuum tube solar collector, according to criteria of solar fraction, design and architectural integration. All of this in order to discern in what circumstances the use of one or the other system is more favourable, comparing the results obtained through simulation programs with the taking of measurements in situ.

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Evaluating the Performance of Two Solar Domestic Hot Water Systems of the Archetype Sustainable Houses

10.32920/ryerson.14646924.v1 ◽

2021 ◽

Author(s):

Kamyar Tanha

Keyword(s):

Flat Plate ◽

Hot Water ◽

Experimental Results ◽

Solar Thermal ◽

Energy Output ◽

Evacuated Tube Collector ◽

Solar Thermal Collector ◽

Solar Thermal Collectors ◽

Evacuated Tube Collectors ◽

Evacuated Tube

This thesis is focused on the performance of the two SDHW systems of the sustainable Archetype houses in Vaughan, Ontario with daily hot water consumption of 225 litres. The first system consists of a flat plate solar thermal collector in conjunction with a gas boiler and a DWHR. The second SDHW system consists of an evacuated tube collector, an electric tank and a DWHR. The experimental results showed that the DWHRs were capable of an annual heat recovery of 789 kWh. The flat plate and evacuated tube collectors had an annual thermal energy output of 2038 kWh and 1383 kWh. The systems were also modeled in TRNSYS and validated with the experimental results. The simulated results showed that Edmonton has the highest annual energy consumption of 3763.4 kWh and 2852.9 kWh by gas boiler and electric tank and that the solar thermal collectors and DWHRs are most beneficial in Edmonton.

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A New Approach on the Protection Against Overheating of Flat Plate Solar-Thermal Collectors

Springer Proceedings in Energy - Nearly Zero Energy Communities ◽

10.1007/978-3-319-63215-5_21 ◽

2017 ◽

pp. 283-295

Author(s):

Mircea Neagoe ◽

Ion Visa ◽

Anca Duta ◽

Nadia Cretescu

Keyword(s):

Flat Plate ◽

Solar Thermal ◽

New Approach ◽

Solar Thermal Collectors

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Real Time Experimental Performance Assessment of a Photovoltaic Thermal System Cascaded with Flat Plate and Heat Pipe Evacuated Tube Collector

Journal of Solar Energy Engineering ◽

10.1115/1.4051861 ◽

2021 ◽

pp. 1-28

Author(s):

Laveet Kumar ◽

Md Hasanuzzaman ◽

Nasrudin Abd Rahim

Keyword(s):

Performance Assessment ◽

Flat Plate ◽

Heat Pipe ◽

Large Scale ◽

Industrial Process ◽

Simulation Models ◽

Solar Thermal ◽

Evacuated Tube Collector ◽

Flat Plate Collector ◽

Evacuated Tube

Abstract In response to the global quest for a sustainable and environmentally friendly source of energy most scientists' discretion is solar energy, especially solar thermal. However, successful deployment of solar thermal technologies such as solar assisted process heating (SAPH) systems in medium- to large-scale industries is still in quandary due to their inefficacy in raising ample temperatures. Cascaded SAPH system, which is essentially a series combination of two same or different types of thermal collectors, may provide a worthwhile solution to this problem. In this article, performance assessment and comparison of two cascaded SAPH systems have been presented: photovoltaic thermal (PVT) cascaded with flat-plate collector (PVT-FPC) and PVT coupled with heat-pipe evacuated tube collector (PVT-HPETC). Simulation models have been presented for individual FPC, HPETC and PVT as well as PVT cascaded with FPC and HPETC systems in TRNSYS and validated through outdoor experimentation. Both the first and the second laws of thermodynamics have been employed to reveal veritable performance of the systems. Results show that PVT-HPETC delivers better performance with 1625 W thermal energy, 81% energy efficiency and 13.22% exergy efficiency. It cuts 1.37 kg of CO2 on an hourly basis. Cascaded systems can be effective in sustaining industrial process heat requirements.

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Greenhouse Solar Thermal Application

Handbook of Research on Solar Energy Systems and Technologies ◽

10.4018/978-1-4666-1996-8.ch017 ◽

2013 ◽

pp. 462-479

Author(s):

Tribeni Das ◽

Ganesh C Bora

Keyword(s):

Flat Plate ◽

Crop Production ◽

Research Work ◽

Agricultural Products ◽

Photovoltaic System ◽

Solar Thermal ◽

Basic Knowledge ◽

Solar Thermal Applications ◽

Flat Plate Collector ◽

Work Done

This chapter includes brief description of different solar thermal applications of greenhouse structure based on the different research work done in this area. It provides the basic knowledge of the use of solar energy to increase the production of different agricultural products using greenhouse system, e.g., crop production and drying of agricultural products. The chapter includes the introduction of greenhouse system, the definition, the concept, and the importance of greenhouse technology. The uses of various solar thermal applications in different greenhouse systems such as flat plate collector in greenhouse fish pond system and application of photovoltaic system in greenhouse drying are covered in this chapter.

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