PV/THERMAL COLLECTORS

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PV/THERMAL COLLECTORS Yiannis TRIPANAGNOSTOPOULOS Assoc. Professor in Physics Department University of Patras, Greece Tel: +30 2610 997472, e-mail: yiantrip@physics.upatras.gr


Thessaloniki VERGINA

DODONI

DELPHI

Patra OLYMPIA

MYCENES

Athens

DELOS

Patra: The gate of Greece to Europe

THIRA

KNOSSOS


Solar Energy Laboratory Is established at the Physics Department and has an experience in education and research for 35 years Activities:

Solar collectors Photovoltaics small wind turbines energy and building greenhouses


ICS Type solar water heaters Simple and low cost solar water heaters Efficient in water heating Satisfactory preservation of hot water temperature Aesthetical integration on buildings

Booster reflectors to improve energy performance The reflectors increase the solar input achieving higher thermal output at higher operating temperatures.


Solar collectors with colored absorbers Solar collectors with absorbers of different color than black could be an interesting solution for the wider application of solar energy systems These collectors are of lower thermal efficiency than that of the usual black collectors because of the lower absorptance

Stationary concentrating CPC solar collectors


Hybrid PV/T Systems

CROSS SECTION OF STUDIED PV/T SYSTEMS


Fresnel lenses for illumination and temperature control Fresnel lenses are solar radiation concentrators with low volume and weight and low cost. They can separate the direct from the diffuse solar radiation and it makes them suitable for illumination control in the building interior space, providing light without sharp contrasts.

The surplus solar energy can be extracted and used to cover building electrical and thermal needs.


Solar Thermal Domestic Hot Water


Installed solar thermal collectors per capita


Flat plate collector, vacuum collector, thermosiphonic collector, parabolic trough, Fresnel reflector and Fresnel lens concentrating collector.

@@@


Solar Thermal systems

Application examples of solar thermal collectors


Solar Thermal systems Application examples of solar thermal collectors


Concentrating solar thermal Συγκεντρωτικά ηλιακάsystems θερμικά


Concentrating solar thermal systems for roof integration


solar tower


Photovoltaic effect and silicon cells

Photons are absorbed by the semiconducting material of solar cells, resulting to the producion of voltage/current


Photovoltaics

Greece: 600 MW-Europe: 50.000 MW-World 67.500 MW

PV installed Power


Photovoltaics

Photovoltaic park



Photovoltaics . .


Photovoltaics for Semitransparent building faรงades


Hybrid Photovoltaic/Thermal solar systems


The hybrid Photovoltaic/Thermal (PV/T) solar collectors are consisted of mounted together photovoltaic panels and thermal units that extract the heat and provide simultaneously electricity and heat.


Thermal collectors and Photovoltaics separately installed on building roof


Concept of Hybrid Photovoltaic/Thermal solar systems Photovoltaics convert 5%-15% (depending on the technology) of the solar radiation into electricity and the rest is converted into heat. The heat inctreses the temperature of PV modules and this results to electrical efficiency drop. This effect can be partially avoided by applying a suitable heat extraction mode The PV modules combined with thermal units consist the hybrid Photovoltaic/Thermal (PV/T) systems providing electrical and thermal output.

PV/T systems provide simultaneously electricity (5%-15%) and heat (50%-70%).


Hybrid Photovoltaic/Thermal Solar Energy Systems

PVT/WATER

PVT/AIR


PVT COLLECTOR


Hybrid Photovoltaic/Thermal Solar Energy Systems


Hybrid Photovoltaic/Thermal Solar Energy Systems installed on buildings


Aspects for Hybrid Photovoltaic/Thermal systems Air-cooled PV modules (PVT/AIR systems) can cover building heating and ventilation needs. Water-cooled PV modules (PVT/WATER systems) are used for water heating, space heating, etc. PV/T solar collectors integrated on buildings can replace the thermal collectors and photovoltaics In PV/T collectors the electrical and thermal efficiencies depend on PV temperature



SOLAR WALL PV/T SYSTEM

Solar Wall PVT collector


Arontis CPVT collector


Heliodynamics Fresnel reflector PV/T collector


Hybrid Photovoltaic/Thermal solar collectors with Fresnel reflectors (Menova system)


UPatras developed PV/T collectors

CROSS SECTION OF STUDIED PV/T SYSTEMS


Diffuse reflectors between the parallel rows of the installed PV/T collectors on horizontal roof.

A performance improvement can be achieved by using diffuse reflectors between the parallel rows of the installed PV/T collectors on horizontal roof.


Electrical efficiency for pc-Si PV/T + REF hybrid solar energy systems 0.18

Electrical efficiency η

el

0.17 0.16 0.15

C=1.0

C=1.1

C=1.2

C=1.3

C=1.4

C=1.5

0.14 0.13 0.12 0.11 0.10 0.09 35

40

45

50

55

PV Temperature ( °C )

60

65

70


Thermal efficiency n

th

Test results of Thermal efficiency for pc-Si PV/T water system 1.0

PV / WATER

0.9

PV / WATER + GL

0.8

PV / WATER + REF

0.7

PV / WATER + GL + REF

0.6 0.5 0.4 0.3 0.2 0.1

0.0 -0.02 -0.01 0.00 0.01 0.02 0.03 0.04 0.05 0.06 0.07 0.08 0.09 0.10 -1

2

ΔΤ / G ( KW m )


Test results of Thermal efficiency for pc-Si PV/T air system

1.0

PV / AIR

Thermal efficiency η

th

0.9

PV / AIR + GL

0.8

PV / AIR + REF

0.7

PV / AIR + GL + REF

0.6 0.5 0.4 0.3 0.2 0.1 0.0 0.00

0.01

0.02

0.03

0.04

0.05

0.06 -1

2

ΔΤ / G ( KW m )

0.07

0.08

0.09

0.10


Test results of electrical efficiency for pc-Si PV/T water system

PV / WATER

0.18

PV / WATER + GL

Electrical efficiency η

el

0.16

PV / WATER + REF

0.14

PV / WATER + GL + REF

0.12 0.10 0.08 0.06 0.04 0.02

0.00 -0.02 -0.01 0.00 0.01 0.02 0.03 0.04 0.05 0.06 0.07 0.08 0.09 0.10 -1

2

ΔΤ / G ( KW m )


Test results of electrical efficiency for pc-Si PV/T air system

0.18

PV / AIR

Electrical efficiency η

el

0.16

PV / AIR + GL

0.14

PV / AIR + REF

0.12

PV / AIR + GL + REF

0.10 0.08 0.06 0.04 0.02 0.00 0.00

0.01

0.02

0.03

0.04

0.05

0.06 -1

2

ΔT / G ( KW m )

0.07

0.08

0.09

0.10


TMS air heat exchanger

We increase the heat exchanging surface area inside the air channel by using a thin flat metallic sheet (TMS) suspended in the middle of the cavity to improve air heat extraction and prevent building overheating


Hybrid Photovoltaic/Thermal solar systems with air heat extraction

PV/T with air heat extraction PV/T of glazed and unglazed type PV/T systems with improvements

0.14 UNGL Electrical efficiency

0.12

GL

0.10 0.08 0.06 0.04 0.02 0.00 20

30

40

50 60 70 PV temperature (oC)

80

90

100


The PVT/DUAL system concept

TMS

FIN

TMS/RIB

This system can operate either with water or with air heat extraction, according the weather conditions and the energy demand of the building


PVT/AIR faรงade integration

PV modules integrated on the faรงade with air gap contribute to a heat flow of circulating air out of the building. Fresh air enters into the building through open windows and doors or infiltration and achieve natural ventilation.


PVT/AIR Roof integration PV module mounted on the roof operates as a roof solar collector. Fresh air enters into building through open (or infiltration) windows and doors and achieves natural ventilation.

PV/T system can be used as “ventilation driver” for natural ventilation of building creating substantial ventilation rate with air velocity about 1 ms-1.

TMS “shields’’ the back wall up to about 3oC below that of REF system and reduces building heat load in summer.


Energy Pay Back Time results 4

EPBT (12)

3.5

EPBT (6)

EPBT (6+6)

EPBT ( Years )

)

3

2.5

*

2

1.5

1

0.5

0

PV

F RE + PV

L F LT LT G RE TI N TI + U L L T/ G PV G V N N P U U T/ T/ V V P P

G T/ V P

L G T/ V P

SYSTEMS

EF R L+

G T/ V P

LT TI L

T S EF IL M R F T + T S S T/ M M V F F P T T T/ T/ V V P P


Thermosiphonic PVT/WATER collectors

Multi Solar System, MSS Millenium Electric, Israel


HYBRID PHOTOVOLTAIC/THERMAL SOLAR SYSTEMS

Improved performance with separated thermal collector and PV/T system


PV/T systems combined with Fresnel lenses The direct incident solar radiation can be concentrated on an absorber strip, located at the focal position and can be taken away to achieve lower illumination level and also to avoid the overheating of the space.

In low intensity irradiance, the absorber can be out of focus leaving the light to come in the interior space and keep the illumination at an acceptable level.


The operation concept of the fresnel lenses with tracking absorbers

Absorbers out of focus

Absorbers at focus

To control the illumination and the temperature of the transparently covered internal spaces of buildings (atria, sunspaces) the tracking absorbers play a significant role.


Application of fresnel lenses in buildings

atrium

room

sunspace

industry


CPC reflectors combined with linear PV and PVT absorbers Stationary CPC reflectors with flat bifacial absorber (a) can be combined with PV strips that track the converged solar radiation and absorb the concentrated solar radiation.

a

b

c

The non-absorbed beam solar radiation and the diffuse solar radiation are absorbed by the flat bifacial thermal absorber and can be taken away by the circulation of a heat removal fluid. In asymmetric CPC reflector, the PV strip is moving in front of the thermal absorber, tracking the converged solar radiation. The parabola axis is directed to: (b) the higher altitude of sun (summer) or to (c) the lower sun altitude (winter).






Architectural design of CPC-PVT building integration



Booster Diffuse Reflectors




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HYBRID PV/T COLLECTORS ON CYCLADIC HOUSE ROOF





UPatras architectural design for cycladic island houses


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