Vacuum enclosures for solar thermal panels Part 1: Fabrication and hot-box testing

Farid Arya, Trevor Hyde, Paul Henshall, Roger Moss, Stan Shire, P. C Eames

Research output: Contribution to journalArticle

2 Citations (Scopus)

Abstract

Non-concentrating solar thermal collectors are generally available in two forms, flat plate or evacuated tube. Recently a third configuration, the evacuated flat plate, has attracted interest due to enhanced performance and aesthetic characteristics. By isolating a solar absorber in a vacuum space (<1 Pa) heat loss from the absorber can be minimized resulting in improved efficiency. In addition the improved thermal insulation performance of evacuated panels over conventional glazing systems makes them attractive solutions for integration into energy efficient building facades. This two part paper describes the design, construction techniques and thermal performance of two vacuum enclosures, fabricated at Ulster University, as prototype components for evacuated flat solar collectors. The first enclosure consists of two glass panes sealed to an edge spacer and separated by an array of support pillars on a regular square grid to form a narrow evacuated space. The second enclosure incorporates an uncooled copper sheet to represent a solar thermal absorber. The enclosures were tested at three conditions i.e. with an internal pressure of high vacuum (0.0021 Pa), low vacuum (8.4 Pa) and no vacuum (atmospheric pressure). Part 1 of this paper describes the fabrication process for the vacuum enclosures and the measurement of their thermal insulation properties using a hot box calorimeter. The theory of heat transfer through an enclosure with support pillars is discussed; experimental results are compared with mathematical models predictions. A fabrication methodology has been successfully established and a U-value of 1.35 W/m2 K for an enclosure with an internal pressure of 0.0021 Pa has been demonstrated. The experimental results are in good agreement with the predictions. Part 2 of this paper describes solar simulator testing of the enclosure containing a copper plate. The highest stagnation temperature (121.8 °C) was reached under steady-state conditions in the high vacuum test and was in good agreement with predictions. The transient plate and glass surface temperatures were measured and found to be consistent with the predicted curves.
LanguageEnglish
Pages1212-1223
Number of pages12
JournalSolar Energy
Volume174
DOIs
Publication statusPublished - 9 Nov 2018

Fingerprint

Enclosures
Vacuum
Fabrication
Testing
Thermal insulation
Copper
Solar absorbers
Glass
Facades
Hot Temperature
Solar collectors
Calorimeters
Heat losses
Atmospheric pressure
Simulators
Mathematical models
Heat transfer
Temperature

Keywords

  • Vacuum enclosure
  • Vacuum glazing
  • Solar absorber
  • Vacuum insulation
  • Evacuated flat plate solar collector
  • Ultrasonic soldering
  • Hot box calorimeter

Cite this

Arya, Farid ; Hyde, Trevor ; Henshall, Paul ; Moss, Roger ; Shire, Stan ; Eames, P. C. / Vacuum enclosures for solar thermal panels Part 1: Fabrication and hot-box testing. 2018 ; Vol. 174. pp. 1212-1223.
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abstract = "Non-concentrating solar thermal collectors are generally available in two forms, flat plate or evacuated tube. Recently a third configuration, the evacuated flat plate, has attracted interest due to enhanced performance and aesthetic characteristics. By isolating a solar absorber in a vacuum space (<1 Pa) heat loss from the absorber can be minimized resulting in improved efficiency. In addition the improved thermal insulation performance of evacuated panels over conventional glazing systems makes them attractive solutions for integration into energy efficient building facades. This two part paper describes the design, construction techniques and thermal performance of two vacuum enclosures, fabricated at Ulster University, as prototype components for evacuated flat solar collectors. The first enclosure consists of two glass panes sealed to an edge spacer and separated by an array of support pillars on a regular square grid to form a narrow evacuated space. The second enclosure incorporates an uncooled copper sheet to represent a solar thermal absorber. The enclosures were tested at three conditions i.e. with an internal pressure of high vacuum (0.0021 Pa), low vacuum (8.4 Pa) and no vacuum (atmospheric pressure). Part 1 of this paper describes the fabrication process for the vacuum enclosures and the measurement of their thermal insulation properties using a hot box calorimeter. The theory of heat transfer through an enclosure with support pillars is discussed; experimental results are compared with mathematical models predictions. A fabrication methodology has been successfully established and a U-value of 1.35 W/m2 K for an enclosure with an internal pressure of 0.0021 Pa has been demonstrated. The experimental results are in good agreement with the predictions. Part 2 of this paper describes solar simulator testing of the enclosure containing a copper plate. The highest stagnation temperature (121.8 °C) was reached under steady-state conditions in the high vacuum test and was in good agreement with predictions. The transient plate and glass surface temperatures were measured and found to be consistent with the predicted curves.",
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Vacuum enclosures for solar thermal panels Part 1: Fabrication and hot-box testing. / Arya, Farid; Hyde, Trevor; Henshall, Paul; Moss, Roger; Shire, Stan; Eames, P. C.

Vol. 174, 09.11.2018, p. 1212-1223.

Research output: Contribution to journalArticle

TY - JOUR

T1 - Vacuum enclosures for solar thermal panels Part 1: Fabrication and hot-box testing

AU - Arya, Farid

AU - Hyde, Trevor

AU - Henshall, Paul

AU - Moss, Roger

AU - Shire, Stan

AU - Eames, P. C

PY - 2018/11/9

Y1 - 2018/11/9

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AB - Non-concentrating solar thermal collectors are generally available in two forms, flat plate or evacuated tube. Recently a third configuration, the evacuated flat plate, has attracted interest due to enhanced performance and aesthetic characteristics. By isolating a solar absorber in a vacuum space (<1 Pa) heat loss from the absorber can be minimized resulting in improved efficiency. In addition the improved thermal insulation performance of evacuated panels over conventional glazing systems makes them attractive solutions for integration into energy efficient building facades. This two part paper describes the design, construction techniques and thermal performance of two vacuum enclosures, fabricated at Ulster University, as prototype components for evacuated flat solar collectors. The first enclosure consists of two glass panes sealed to an edge spacer and separated by an array of support pillars on a regular square grid to form a narrow evacuated space. The second enclosure incorporates an uncooled copper sheet to represent a solar thermal absorber. The enclosures were tested at three conditions i.e. with an internal pressure of high vacuum (0.0021 Pa), low vacuum (8.4 Pa) and no vacuum (atmospheric pressure). Part 1 of this paper describes the fabrication process for the vacuum enclosures and the measurement of their thermal insulation properties using a hot box calorimeter. The theory of heat transfer through an enclosure with support pillars is discussed; experimental results are compared with mathematical models predictions. A fabrication methodology has been successfully established and a U-value of 1.35 W/m2 K for an enclosure with an internal pressure of 0.0021 Pa has been demonstrated. The experimental results are in good agreement with the predictions. Part 2 of this paper describes solar simulator testing of the enclosure containing a copper plate. The highest stagnation temperature (121.8 °C) was reached under steady-state conditions in the high vacuum test and was in good agreement with predictions. The transient plate and glass surface temperatures were measured and found to be consistent with the predicted curves.

KW - Vacuum enclosure

KW - Vacuum glazing

KW - Solar absorber

KW - Vacuum insulation

KW - Evacuated flat plate solar collector

KW - Ultrasonic soldering

KW - Hot box calorimeter

U2 - 10.1016/j.solener.2018.10.064

DO - 10.1016/j.solener.2018.10.064

M3 - Article

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