Forum for Science, Industry and Business

Sponsored by:     3M 
Search our Site:

 

Designing Architecture with Solar Building Envelopes

16.01.2017

Among the general public, solar thermal energy is currently associated with dark blue, rectangular collectors on building roofs. Technologies are needed for aesthetically high quality architecture which offer the architect more room for manoeuvre when it comes to low- and plus-energy buildings. With the “ArKol” project, researchers at Fraunhofer ISE together with partners are currently developing two façade collectors for solar thermal energy generation, which permit a high degree of design flexibility: a strip collector for opaque façade sections and a solar thermal blind for transparent sections. The current state of the two developments will be presented at the BAU 2017 trade fair.

As part of the “ArKol – development of architecturally highly integrated façade collectors with heat pipes” project, Fraunhofer ISE together with its partners is developing two new-style façade collectors from the concept through to readiness for application.


Visualization of a façade with a solar thermal blind

©Facade-Lab


Visualization of a façade with strip collectors

©Facade-Lab

Both developments are intended to be much more flexibly integratable into the building envelope than standard collectors currently on the market, and in this way make the architectural integration of solar collectors in façades more attractive. Through the multifunctional nature of the building envelope and the use of mass-produced sub-components, the costs of solar generated heat are however far lower than those of conventional solar thermal collectors.

In recent months, the project team has been able to specify two highly promising approaches to the problem. On the one hand, it is working on a strip collector for which the distance and the material between the strips can be freely selected. On the other, a solar thermal blind is created which can be inserted between glass panels. Both developments use heat pipes with a dry thermal connection to the collection duct, and in so doing enable a flexible design of the solar collector. As a result, the collectors can be optimally integrated into standard building envelopes.

Architectural design diversity: strip collector

The first product concept consists of strip-shaped heat pipe collectors which are variable in length and which can be attached flexibly. The heat pipe concept is designed to enable all alignments, including in the horizontal direction. Due to the particular connection to the heat collector, researchers anticipate that a reduced thermal resistance will be possible.

The collector connection is provided in the form of a heat pipe which engages in a form-fit manner with a corresponding extruded collection duct. It also enables an infinitely variable, flexible distance of the individual heat pipes, thus further contributing to the individualization of the application. “The strip collector combines a high level of efficiency with architectural design diversity”, says Dr.-Ing. Christoph Maurer, Head of Team Solar Thermal Facades, at Fraunhofer ISE. “Classic materials such as wood or plaster, structures and colours can be used in the area between the glazed collector strips.”

Through the use of heat pipes based on string-pressed profiles, the project team anticipates a realization of different collector string lengths at a low production cost. In contrast to collectors through which fluid flows directly, the connection of heat pipes of different lengths to a shared collection duct is hydraulically unproblematic. The modular structure of the collector and the “dry” connection of the heat pipe to the collection duct also lead to simpler maintenance of the collector and to lower installation costs.

Energy efficiency and transparency: solar thermal blind

The second product concept is a solar thermal blind which for the first time enables the energetically optimal regulation of the energy flows through the façade. In order to achieve this effect, blind slats can be used with spectral selective coating. Heat is transported via a heat pipe from the slat to the side collection duct. If external blinds are not required or are not possible, blinds are already now being inserted between two glass panes.

“These blinds reach high temperatures, which increase the cooling requirement of the building. The solar thermal blinds can move just as freely as a normal blinds, but at the same time, they deliver heat and reduce the amount of energy entering the interior of the building”, says Maurer. The switchable connection to the collection duct enables the use to turn and gather up the blind. In this way, the sun protection and heat gain functions can be regulated depending on the position of the sun.

If the connection is opened and the blind is gathered up, the passive solar yields can reduce the heat requirements of the building. Compared to the opaque or semi-transparent collectors used to date, this means switchable energy management. The use of heat pipes for thermal coupling makes the use of movable lamella technically possible for obtaining energy in the first place. Due to the ability to regulate and if necessary the complete removal of shading, together with the design of the collector as a blind, this façade collector is highly suitable for use in ecological multi-storey buildings.

The “ArKol” project started work at the beginning of 2016, and is funded by the Federal Ministry for Economic Affairs and Energy (Bundesministerium für Wirtschaft und Energie). During the first 18 months, the project partners are in the process of developing detailed cost-optimal sub-functions for the façade collectors. In 2017, the sample collectors will undergo the first laboratory tests at Fraunhofer ISE.

In 2018, the simulation models will be measured and calibrated. On their basis, it will be possible to precisely forecast the advantages of the technology. By the project completion date in 2019, a demonstration façade will be completed for each of the two technologies. A follow-up project immediately afterwards is already planned for 2020, with which the technologies will first be realized on a commercial basis. Interested architects, building owners and planners are welcome to contact Dr.-Ing. Christoph Maurer now.

At the BAU trade fair from 16 to 21 January 2017 in Munich, the Fraunhofer ISE will present its new developments within the scope of the “ArKol” project. Visit us at the Fraunhofer-Allianz BAU stand in Hall C2, stand 538.

Weitere Informationen:

https://www.ise.fraunhofer.de/en
https://arkol.de/en

Karin Schneider | Fraunhofer-Institut für Solare Energiesysteme ISE

More articles from Architecture and Construction:

nachricht New Generation of Cleaning Tools for CSP Plants Reduces the Water Consumption
09.11.2018 | Steinbeis-Europa-Zentrum

nachricht memory-steel - a new material for the strengthening of buildings
23.10.2018 | Empa - Eidgenössische Materialprüfungs- und Forschungsanstalt

All articles from Architecture and Construction >>>

The most recent press releases about innovation >>>

Die letzten 5 Focus-News des innovations-reports im Überblick:

Im Focus: Data use draining your battery? Tiny device to speed up memory while also saving power

The more objects we make "smart," from watches to entire buildings, the greater the need for these devices to store and retrieve massive amounts of data quickly without consuming too much power.

Millions of new memory cells could be part of a computer chip and provide that speed and energy savings, thanks to the discovery of a previously unobserved...

Im Focus: An energy-efficient way to stay warm: Sew high-tech heating patches to your clothes

Personal patches could reduce energy waste in buildings, Rutgers-led study says

What if, instead of turning up the thermostat, you could warm up with high-tech, flexible patches sewn into your clothes - while significantly reducing your...

Im Focus: Lethal combination: Drug cocktail turns off the juice to cancer cells

A widely used diabetes medication combined with an antihypertensive drug specifically inhibits tumor growth – this was discovered by researchers from the University of Basel’s Biozentrum two years ago. In a follow-up study, recently published in “Cell Reports”, the scientists report that this drug cocktail induces cancer cell death by switching off their energy supply.

The widely used anti-diabetes drug metformin not only reduces blood sugar but also has an anti-cancer effect. However, the metformin dose commonly used in the...

Im Focus: New Foldable Drone Flies through Narrow Holes in Rescue Missions

A research team from the University of Zurich has developed a new drone that can retract its propeller arms in flight and make itself small to fit through narrow gaps and holes. This is particularly useful when searching for victims of natural disasters.

Inspecting a damaged building after an earthquake or during a fire is exactly the kind of job that human rescuers would like drones to do for them. A flying...

Im Focus: Topological material switched off and on for the first time

Key advance for future topological transistors

Over the last decade, there has been much excitement about the discovery, recognised by the Nobel Prize in Physics only two years ago, that there are two types...

All Focus news of the innovation-report >>>

Anzeige

Anzeige

VideoLinks
Industry & Economy
Event News

ICTM Conference 2019: Digitization emerges as an engineering trend for turbomachinery construction

12.12.2018 | Event News

New Plastics Economy Investor Forum - Meeting Point for Innovations

10.12.2018 | Event News

EGU 2019 meeting: Media registration now open

06.12.2018 | Event News

 
Latest News

Data use draining your battery? Tiny device to speed up memory while also saving power

14.12.2018 | Power and Electrical Engineering

Tangled magnetic fields power cosmic particle accelerators

14.12.2018 | Physics and Astronomy

In search of missing worlds, Hubble finds a fast evaporating exoplanet

14.12.2018 | Physics and Astronomy

VideoLinks
Science & Research
Overview of more VideoLinks >>>