Design and fabrication of a hydroformed absorber for an evacuated flat plate solar collector.

Moss, R.W., Shire, G.S.F., Henshall, P., Eames, P.C., Arya, Farid and Hyde, T. (2018) Design and fabrication of a hydroformed absorber for an evacuated flat plate solar collector. Applied Thermal Engineering, 138. pp. 456-464. ISSN 13594311

Full text not available from this repository. (Request a copy)

Abstract

The concept of an evacuated flat plate collector was proposed over 40 years ago but, despite its professed advantages, very few manufacturers have developed commercial versions. The absorber is a key component of a flat plate collector: in the context of an evacuated panel, absorber design poses a number of technical challenges. A flooded panel absorber has been designed for use in evacuated flat plate solar collectors. The aim was to obtain higher efficiency, in a low out-gassing material, than would be possible using a conventional serpentine tube design. Initial plans for a micro-channel plate were modified when optimisation analysis showed that a flooded panel could achieve as good performance with easier fabrication. The absorber plate is made from hydroformed stainless steel sheets welded together and features an array of through-holes for the glass-supporting pillars with the square panel subdivided into two rectangles connected in series for ease of fabrication and better flow distribution. The coolant flow was modelled in Star-CCM+. FEM simulations based on tensile test data informed the choice of sheet thickness and weld radius around the holes to withstand the 1 bar pressure differential. Hydroforming is an effective method for producing sheet metal components, e.g. plates for heat exchangers or solar absorbers. As a thermal engineering experimental technique, the tooling is significantly cheaper than press tools since the mould does not need a matching die. In a research context, the ability to form plates in-house and explore profile and tooling options at low cost is very useful and might find application in other fields such as experimental heat exchangers. A hydroforming facility was built using 85 mm thick steel sheet and a 25 MPa hydraulic pump. This proved highly effective at forming 0.7 mm stainless steel sheet. A total of eight absorbers were fabricated and successfully leak tested using helium. Two variants were made: one kind for use in enclosures with a metallic rear tray, the other for enclosures with glass on both sides. The collector efficiency factor is estimated to be 3% higher than for commercial tube-on-plate designs.

Item Type: Article
Keywords: Solar collector, Evacuated, Vacuum, Hydroform, Flow distribution
Depositing User: RED Unit Admin
Date Deposited: 11 Nov 2019 13:53
Last Modified: 13 Nov 2019 09:40
URI: https://bnu.repository.guildhe.ac.uk/id/eprint/17899

Actions (login required)

Edit Item Edit Item