AU2021102146A4 - Device for generating electricity - Google Patents

Abstract

The present disclosure provides a device for window of a building or structure. The device comprises a panel having an 5 area that is transparent for at least a portion of visible light and having opposite first and second major surfaces. The first major surface is a light receiving surface of the panel. The device further comprises at least one series of solar cells, each solar cell having a light receiving surface which .0 faces the second major surface of the panel and is the directly or indirectly bonded to the panel at the second major surface in a manner such that light can be received by the light receiving surfaces of the solar cells without propagating through a gap between the panel and the light .5 receiving surfaces of the solar cells. The at least one series of solar cells is positioned at and along an edge of the panel and between the edge and the area that is transparent for at least a portion of visible light. Solar cells are only positioned at and along one or more edges of the panel and not .0 in the area that is transparent for at least a portion of visible light. 16 1/3 100 104 102 106 112 110---..---- | | | | | | | | | | | | _ 108 Figure 1 17537899_1 (GHMatters) P114172.AU.2

Description

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17537899_1 (GHMatters) P114172.AU.2

Device for generating electricity

Field of the Invention

The present disclosure relates to a device for generating electricity and relates particularly, though not exclusively, to a panel, such a panel for a window comprising solar cells.

Background of the Invention .0 Buildings such as office towers, high-rise housings and hotels use large amounts of exterior window panelling and/or facades which incorporate glass panelling.

Such glass panelling receives large amounts of sunlight, which .5 results in heating of interior spaces requiring the use of air conditioners. A large amount of energy is globally used to operate air conditioners.

PCT international applications numbers PCT/AU2012/000778, .0 PCT/AU2012/000787 and PCT/AU2014/000814 (owned by the present applicant) disclose a spectrally selective panel that may be used as a windowpane and that is transmissive for visible light, but has solar cell that absorb light, such as infrared radiation, to generate electricity.

The present invention provides further improvement.

Summary of the Invention

The present invention provides in a first aspect a device

for window of a building or structure, the device comprising:

a panel having an area that is transparent for at least a

portion of visible light and having opposite first and second

major surfaces, the first major surface being a light

receiving surface of the panel; and

at least one series of solar cells, each solar cell

.0 having a light receiving surface which faces the second major

surface of the panel and is the directly or indirectly bonded

to the panel at the second major surface in a manner such that

light can be received by the light receiving surfaces of the

solar cells without propagating through a gap between the

.5 panel and the light receiving surfaces of the solar cells;

wherein the at least one series of solar cells is

positioned at and along an edge of the panel and between the

edge and the area that is transparent for at least a portion

of visible light, and .0 wherein solar cells are only positioned at and along one

or more edges of the panel and not in the area that is

transparent for at least a portion of visible light.

As the gap, such as an airgap, between the panel and the

solar cells is avoided, intensity losses of light propagating

from the panel into the solar cell are reduced.

The panel may be a panel of a window of a building or a

vehicle and the device may further comprise a frame structure

for supporting the panel. In one embodiment the device is

provided in the form of a window unit for a building, such as

an integrated glass unit.

The solar cells of the at least one series of solar cells

may be directly or indirectly bonded to the panel using an

adhesive. In one embodiment the adhesive is transmissive for

visible light and may have a refractive index that at least

approximates that of the panel material, which may for example

be glass or a suitable polymeric material. Alternatively, the

solar cells may have an outer layer of a polymeric material,

such as Polyvinyl butyral (PVB) or ethylene-vinyl acetate

(EVA) or another suitable material. The solar cells may in

.0 this embodiment be directly bonded to the second major surface

of the panel. For example, if the solar cells comprise a layer

of EVA or another suitable material, the PVB, EVA or the other

suitable material may be slightly softened and then adhered to

the second major surface of the panel typically without an

.5 additional adhesive (by using the PVB, EVA or the other

material as an adhesive).

The solar cells of the at least one series of solar cells

may be positioned parallel to the panel. Adjacent solar cells may be in an at least nearly abutting relationship with each

other. Alternatively, each solar cell may have opposite major

surfaces having opposite electrical polarities and each solar

cell may overlap another one of the solar cells such that a

series of "shingled' solar cells is formed.

The device may comprise a plurality of the series of

solar cells and which may be positioned around (and may

entirely surround) the area that is transparent for at least a

portion of visible light. The plurality of the series of solar

cells may be positioned at edges of the panel such that the

panel is largely transparent for at least a portion of visible

light and the area that is transparent for at least a portion

of visible light is a central area and at 5, 10, 15, 20, 50,

100 or even 500 x larger than an area of the panel at which

the series of the solar cells are positioned.

The panel may have four edges and at least one of the

series of solar cells may be positioned at each edge of the

panel.

The area that is transparent for at least a portion of

visible light may be transmissive for at least 60%, 70%, 80%,

.0 90% or even at least 95% or visible light incident of the

receiving surface at normal incidence.

The panel may be a first panel and the device may

comprise a second panel that may be positioned substantially

.5 parallel the first panel in a manner such that light received

by the light receiving surface of the first panel initially

propagates through the first panel before being received by

the second panel. The second panel may also have an area that

is transparent for at least a portion of visible light and .0 having opposite first and second major surfaces, the first

major surface being a light receiving surface of the second

panel.

In this embodiment each solar cell may have a rear

surface that is directly or indirectly bonded to the second

panel whereby each solar cell may be directly or indirectly

bonded to both the first and the second panels and the solar

cells are sandwiched between the first and second panels. In

this embodiment both the front and also the rear surfaces of

the device are surfaces of the first or second panel (which

may be glass panels), which has the advantage of protecting

the solar cells and also has the advantage of providing

reliable (vacuum) sealing surfaces for window application.

The at least one series of solar cells may be at least

one series of first solar cells and the device may further

comprise at least one series of second solar cells positioned

at the second panel. Each solar cell of the series of second

solar cells may have a light receiving surface which faces the

second panel and is directly or indirectly bonded to the

second panel at the second major surface in a manner such that

light can be received by the light receiving surface of the

second solar cells without propagating through a gap between

.0 the second panel and the light receiving surface of the solar

cells;

wherein the at least one series of solar cells is

positioned at and along an edge of the second panel, and

between the edge and the area that is transparent for at least

.5 a portion of visible light, and wherein solar cells are only

positioned along and in the proximity of one or more edge of

the second panel and not in the area that is transparent for

at least a portion of visible light.

.0 The second panel may have four edges and may comprise at

least one of the series of second solar cells positioned at

each edge of the second panel.

The area that is transparent for at least a portion of

visible light may be transmissive for at least 60%, 70%, 80%,

90% or even at least 95% or visible light incident on the

second panel.

The second panel may further comprise a diffractive

element and/or luminescent material in order to facilitate

redirection of incident infrared light to edges of the second

panel.

Further, the device may comprise at least one series of

third solar cells that is positioned at at least one edge

surface of the second panel and oriented substantially

perpendicular to a major surface of the second panel whereby

the at least one series of third solar cells is positioned

substantially perpendicular to the series of first solar cell

at the first panel and the series of second solar cells at the

second panel. The series of third solar cells is positioned to

receive at least a portion of light redirected by the

.0 diffractive element and/or the luminescent material. The

deflection of infrared radiation by the diffractive element

has the further advantage that transmission of infrared

radiation into buildings (when the panel is used as a window

pane) can be reduced, which consequently reduces overheating

.5 of spaces within the building and can reduce costs for air

conditioning.

The solar cells may be silicon-based solar cells, but may

alternatively also be based on any other suitable material, '.0 such CIGS or CIS, GaAs, CdS or CdTe.

In one specific embodiment the solar cells of the series

of first solar cells and the series of second solar cells are

silicon-based and the solar cells of the series of third solar

cells are CIS- or CIGS-based.

The invention will be more fully understood from the

following description of specific embodiments of the

invention. The description is provided with reference to the

accompanying drawings.

Brief Description of the Drawings

Figure 1 is a schematic top view of a device for

generating electricity in accordance with an embodiment of the

present invention; and

Figures 2 and 3 are schematic cross-sectional

representation of a portion of the device in accordance with

an embodiment of the present invention.

.0

Detailed Description of Embodiments

Referring initially to Figure 1, there is shown a

schematic top view of a device for generating electricity 100

.5 in accordance with an embodiment of the present invention. The

device 100 comprises a panel 102 and in this embodiment four

series of solar cells 104 106, 108,110 are positioned at

respective edges of the panel 102. The four series of solar

cells 104 106, 108, 110 face a light receiving surface of the .0 panel and together surround an area of the panel that is at

least largely transmissive for light. The panel 102 may for

example form a panel of a window of a building or another

structure and the four series of solar cells 104 106, 108,110

may be positioned at a frame structure that supports the panel

102 and one or more other panels to for a window unit.

The panel 102 is transmissive for at least 70% of

incident visible light (limited by the transmissivity of the

panel material, such as glass). The solar cells are only

positioned at edges of the panel 102 such that only at edges

of the panel 102 the transmission of incident light is

obstructed by the solar cells.

The solar cells of the series 104 106, 108, 110 each have

light receiving surfaces facing the panel 100 and are adhered

to the panel 102 such that no air gap is present between the

solar cells and the panel 102. In this example the solar cells

112 comprise outer ETA layers. Prior to adhering the solar

cells 112 to the panel 102, the ETA is slightly softened (by

the careful application of heat) and then the solar cells 112

are pressed against the panel 102. Once the softened ETA has

hardened again, the solar cells are adhered to the panel 102

.0 without the need of an additional adhesive.

The panel 102 may have any shape, but in one specific

embodiment is rectangular and may be square. The panel 102 may

be formed from suitable glass or polymeric materials.

.5

The solar cells 104 106, 108,110 are in this embodiment

arranged in an overlapping relationship and electrically

coupled using a conductive adhesive. The solar cells 112, have

opposite major surfaces and which have different polarities .0 and are oriented such that only surfaces of the same

polarities face the panel 102. The conductive adhesive couples

a back face of one of the solar cells 112 with a front face of

an adjacent solar cell 112. Consequently, the solar cells of

the series of solar cells are electrically series connected.

Alternatively, the solar cells may be arranged in an

abutting relationship.

Turning now to Figure 2, there is shown a cross-sectional

view of a portion of a window unit 200 in accordance with an

embodiment of the present invention. The window unit 200

comprises the panel 102 with the series of (shingled) solar

first cells 104, 106, 108 and 110, which are encapsulated by a

layer of ETA 109. The panel 102 has a light receiving surface

103. In this embodiment the panel 102 is a first panel and the

window unit 200 also comprises a second panel 202, which is

positioned parallel, and spaced apart from, the first panel

102. The second panel 202 has series of solar cells 204

adhered to it in the same manner as illustrated above for the

first panel 102 and with reference to Figures 1. In this

embodiment the panels 102 and 202 are rectangular and each

comprise four series of solar cells that are adhered at edge

portions of the panels 102, 204 and positioned as illustrated

.0 in Figure 1.

Similar to the panel 102 illustrated in Figure 1, the

second panel 202 is transmissive for at least 70% of incident

visible light (limited by the transmissivity of the panel

.5 material, such as glass). The solar cells are only positioned

at edges of the panel 202 such that only at edges of the panel

202 the transmission of incident light is obstructed by the

solar cells.

The window unit 200 also comprises a frame structure 205

that is arranged to hold the panels 102 and 202 and the series

of solar cells in position.

The panels 102 and 204 comprise in this embodiment

respective panes of glass that are each largely transmissive

for visible light. In an embodiment the glass panes that form

the panels 102 and 204 are formed of low iron ultra-clear

glass pane, with the panel 204 additionally having a low-E

coating.

In the embodiment shown in Figure 2 the panel 204 is a

laminate structure having three sub-panes 204a, 204b and 204c.

The sub-pane 204a is formed of low iron ultra-clear glass

having a thickness of 4 mm, and second and third panes 204b and 204c are each formed from ultra-clear glass having a thickness of 4 mm. The sub-panes 204a, 204b and 204c mate with each other to form a stack of the sub-panes substantially parallel to one another. Disbursed between panes 204a and 204b is an interlayer 210 of polyvinyl butyral (PVB). A PVB interlayer 212 is also located between sub-pane 204b and 404c, but PVB interlayer 212 also includes a light scattering element. In this embodiment the light scattering element comprises a luminescent scattering powder embedded in the PVB,

.0 which also an epoxy that provides adhesive. The panel 204 also

includes a diffraction grating that is arranged to facilitate

redirection of light towards edge region of the panel 204

(i.e. towards the frame 205) and guiding of the light by total

internal reflection.

.5

It should be appreciated that the panel 204 could have

any number of panes with any number of interlayers. In some

embodiments the panel 204 may comprise a single piece of

optically transmissive material such as glass. -O

The panel 204 has an edge 211 that has a plane which is

transverse to the light receiving surface 103. In the

embodiment of Figure 2, the angle between the edge 211 and the

light receiving surface 103 is 90°.

The window unit 200 also has series of third solar cells

114. The series of third solar cells 114 face the edge 211 and

a cavity between the first panel 102 and the second panel 204.

The series of third solar cells 114 substantially surround the

second panel 204 and are positioned to receive light that is

redirected by the scattering material and/or the diffractive

element (not shown) to the edges (such as edge 211) of the

second panel 204. Further, the series of third solar cells 214 also receives light at an area which faces the cavity between the first panel 102 and the second panel 204.

In the present embodiment, the series of first and second

solar cells 104, 106, 108, 110, 208 may be silicon-based solar

cells, but can alternatively also be based on any other

suitable material such CdS, CdTe, GaAs, CIS or CIGS. The

series of third solar cells 214 may be CIS or CIGS-based, but

may alternatively also be based on any other suitable material

.0 such SI, CdS, CdTe, or GaAs.

Figure 3 shows a device for generating electricity in

accordance with a further embodiment of the present invention.

Figure 3 shows the device 300 having a first panel 302 and a

.5 second panel 304. The first and second panels 302, 304 are

transmissive for at least 70% of incident visible light

(limited by the transmissivity of the panel material, such as

glass).

The device 300 comprises solar cells 306 which each have

a light receiving surface facing the panel 302 and adhered to

the panel 302 such that no air gap is present between the

solar cells 306 and the first panel 302. Further, the solar

cells 306 each have a rear surface facing the panel 304 and

adhered to the panel 304. In this example the solar cells 306

comprise outer ethylene-vinyl acetate (EVA) or Polyvinyl

butyral (PVB) layers at the front surfaces. A sheet of

excluded-volume-branched-polymers (EVB), Polyvinyl butyral

(PVB)or Ethylene tetrafluoroethylene (ETFE) is placed between

the panels 302 and 304 such that the sheet is also positioned

between the rear surfaces of the solar cells 306 and panel

304. Prior to adhering the solar cells 306 to the panels 302,

304 (and the panels 302, 304 to each other) the ETA, EVB or

ETFE is slightly softened (by the careful application of heat)

11 17537895_1 (GHMatters) P114172.AU.2 and then the panel 302, 304 are pressed together such that the solar cells 306 are positioned between the panels 302, 304.

Once the softened ETA, EVB or ETFE has hardened again, the

solar cells are sandwiched between, and adhered to, the panels

302, 304 without the need of an additional adhesive whereby a

laminated structure is formed. The panels 302, 304 protect the

solar cells 306 and also provide reliable sealing surfaces at

both front and rear sides of the device, which is advantageous

for window applications.

.0

Whilst a number of specific embodiments have been

described, it should be appreciated that the disclosed unit

200 maybe embodied in many other forms. For example, the unit

200 may not necessarily be rectangular, but may alternatively

.5 have any other suitable shape (such as for example round or

rounded). Further, the panel 204 may comprise any suitable

number of sub-panels. Further, the window unit may comprise a

third panel such that a triple glazing unit is formed.

.0 Any discussion of the background art throughout this

specification should in no way be considered as an admission

that such background art is prior art, nor that such

background art is widely known or forms part of the common

general knowledge in the field in Australia or worldwide.

Claims (5)

Claims

1. A device for window of a building or structure, the device comprising: a panel having an area that is transparent for at least a portion of visible light and having opposite first and second major surfaces, the first major surface being a light receiving surface of the panel; and at least one series of solar cells, each solar cell .0 having a light receiving surface which faces the second major surface of the panel and is the directly or indirectly bonded to the panel at the second major surface in a manner such that light can be received by the light receiving surface of the solar cell without propagating through a gap between the panel .5 and the light receiving surface of the solar cell; wherein the at least one series of solar cells is positioned at and along an edge of the panel and between the edge and the area that is transparent for at least a portion of visible light, and .0 wherein solar cells are only positioned at and along and one or more edges of the panel and not in the area that is transparent for at least a portion of visible light.

2. The device of any one of the preceding claims wherein the device comprises a plurality of the series of solar cells which are positioned around the area that is transparent for at least a portion of visible light, and wherein the plurality of the series of solar cells are positioned at edges of the panel such that the panel is largely transparent for at least a portion of visible light and the area that is transparent for at least a portion of visible light is a central area and at 10 larger than an area of the panel at which the series of the solar cells are positioned.

3. The device of any one of the preceding claims wherein the

panel is a first panel and the device comprises a second panel

that is positioned substantially parallel to the first panel

in a manner such that light received by the light receiving

surface of the first panel initially propagates through the

first panel before being received by the second panel, wherein

the second panel also has an area that is transparent for at

least a portion of visible light and having opposite first and

second major surfaces, the first major surface being a light

.0 receiving surface of the second panel and wherein each solar

cell has a rear surface that is directly or indirectly bonded

to the second panel such that each solar is sandwiched between

the first and second panel and each solar cell is directly or

indirectly bonded to both the first and the second panel.

.5

4. The device of any one of the preceding claims wherein the

at least one series of solar cells is at least one series of

first solar cells and the device further comprises at least

one series of second solar cells positioned at the second panel;

wherein each solar cell of the series of second solar

cells has a light receiving surface which faces the second

panel and is directly or indirectly bonded to the second panel

at the second major surface in a manner such that light can be

received by the light receiving surface of the solar cell

without propagating through a gap between the second panel and

the light receiving surface of the solar cell;

wherein the at least one series of solar cells is

positioned at and along an edge of the second panel, and

between the edge and the area that is transparent for at least

a portion of visible light, and wherein solar cells are only

positioned along and in the proximity of one or more edge of

the second panel and not in the area that is transparent for

at least a portion of visible light.

5. The device of any one of claims 3 or 4 when dependent on

claim 3 wherein the second panel further comprises a

diffractive element and/or luminescent material in order to

facilitate redirection of incident infrared light to edges of

the second panel; wherein the device comprises at least one

series of third solar cells that is positioned at at least one

edge surface of the second panel and oriented substantially

perpendicular to a major surface of the second panel whereby

.0 the at least one series of third solar cells is positioned

substantially perpendicular to the series of first solar cell

at the first panel and the series of second solar cells at the

second panel; wherein the series of third solar cells is

positioned to receive at least a portion light redirected by

.5 the diffractive element and/or the luminescent material.