Title of Invention

THIN-FILM PHOTOELECTRIC CONVERTER

Abstract A thin-film photoelectric converter comprising a crystalline silicon photoelectric conversion unit, in particular an integrated thin-film photoelectric converter is disclosed wherein the photoelectric conversion efficiency is improved by preventing decrease in open end voltage and fill factor. The thin-film photoelectric converter comprises at least a transparent electrode film, a crystalline silicon photoelectric conversion unit and backside electrode film sequentially formed on one major surface of a transparent substrate, and the crystalline silicon photoelectric conversion unit is so formed as to partially have a discolored white turbid region in the surface after the formation. The discolored white turbid region is preferably not more than 5% of the photoelectric conversion area. The thin-film photoelectric converter is preferably formed as an integrated thin-film photoelectric converter.
Full Text SPECIFICATION
THIN FILM PHOTOELECTRIC CONVERTER
TECHNICAL FIELD
The present invention relates to improvement in
conversion efficiency of a thin film photoelectric converter,
and more particularly to improvement in conversion efficiency
having a large dimension thin film photoelectric converter
including crystalline silicon photoelectric conversion units
formed by a plasma CVD method.
BACKGROUND ART
[0002]
Today, thin film photoelectric converters have become in
wider use, and crystalline silicon photoelectric converters
including crystalline silicon photoelectric conversion units
have been developed in addition to amorphous silicon
photoelectric converters including conventional amorphous
silicon photoelectric conversion units. And moreover, hybrid
type thin film photoelectric converters having these units
stacked therein have also been put in practical use. A term
"crystalline" as used herein represents also a state including
polycrystalline state and microcrystalline state. Terms
"crystalline" and "microcrystalline" as used herein represent
a state partially including amorphous regions.
A thin film photoelectric converter generally comprises
a transparent electrode film sequentially stacked on a
transparent substrate, one or more semiconductor thin film
photoelectric conversion units, and a back electrode film.
And the one semiconductor thin film photoelectric conversion
unit includes an i type layer sandwiched by a p type layer and
an n type layer.
[0004]
On one hand, an i type layer occupying a great portion
of a thickness of the photoelectric conversion unit is made of
a substantially intrinsic semiconductor layer, photoelectric
conversion is mainly formed within this i type layer, and
therefore the layer is referred to as a photoelectric conversion
layer. For larger absorption of light and larger generation
of photo current, this i type layer preferably has a greater
thickness, but a greater thickness more than needed will result
in increase in cost and time for the film-formation.
On the other hand, a p type layer and an n type layer are
referred to as a conductive layer, and these layers serve to
produce diffusion potential within the semiconductor thin film
photoelectric conversion unit. A magnitude of this diffusion
potential influences a value of an open-circuit voltage as one
of properties of the thin film photoelectric converter.
However, these conductive layers are inactive layers with no
contribution to photoelectric conversion. That is, light
absorbed by impurities doped in the conductive layers does not
contribute to power generation, resulting in a loss of light.
Consequently, the p-type and n-type conductive layers
preferably have a thickness as small as possible in a range for
providing a sufficient diffusion potential.
For this reason, in a semiconductor thin film photoelectric
conversion unit or a thin film photoelectric converter, when
the material of the i type layer occupying a major portion is
made of amorphous silicon, the device will be referred to as
an amorphous silicon thin film photoelectric converter or an
amorphous silicon photoelectric conversion unit. And when the
material of the i type layer is made of crystalline silicon,
it will be referred to as a crystalline silicon photoelectric
converter or a crystalline silicon photoelectric conversion
unit. This expression is not dependent on whether materials
of the conductive layer included are amorphous or crystalline.
[0007]
Known methods of improving conversion efficiency of a thin film
photoelectric converter involve stacking two or more
photoelectric conversion units in tandem. In this method, a
front unit including a photoelectric conversion layer having
a wider energy band gap is disposed closer to a light incident
side of the photoelectric converter, and behind it disposed is
a rear unit including a photoelectric conversion layer (of a
Si-Ge alloy, for example) having a narrower band gap. This
configuration thereby enables photoelectric conversion over a
wide wavelength range of incident light to improve conversion
efficiency of the entire device.
In such tandem type thin film photoelectric converters, a device
including stacked amorphous silicon photoelectric conversion
units and crystalline silicon photoelectric conversion units
are referred to as a hybrid type thin film photoelectric
converter.
For example, wavelengths of light that may be converted into
electricity by an i type amorphous silicon are up to
approximately 800 nm in a longer wavelength side, but an i type
crystalline silicon can convert light with longer wavelengths
of approximately 1100 nm into electricity. Here, on one hand,
in amorphous silicon photoelectric conversion layers
comprising amorphous silicon having a larger light absorption
coefficient, a thickness of not more than 0.3 micrometers is
enough for sufficient light absorption for photoelectric
conversion. On the other hand, however, in a crystalline
silicon photoelectric conversion layer comprising crystalline
silicon having comparatively smaller light absorption
coefficient, it is preferable to have a thickness of not less
than about 2 to 3 micrometers in order to fully absorb light
with longer wavelengths. That is, a crystalline silicon
photoelectric conversion layer usually needs approximately 10
times as large thickness as compared with that for an amorphous
silicon photoelectric conversion layer.
In thin film photoelectric converters, needed are devices
having larger dimension for larger electric generating capacity
and improvement in productive sufficiency. There are various
problems in realizing a large sized device, for example,
Japanese Patent Laid-Open No. 2002-319692 official report
discloses a following technique. When a transparent substrate
having a transparent conducting layer formed, using plasma CVD
device, on one principal surface and having an dimension of not
less than 1200 cm2 is held with a substrate holder, and is made
to face with an electrode to form a crystalline silicon
photoelectric conversion layer with a power flux density of not
less than 100 mW/cm2, the substrate holder and the transparent
conducting layer on a front face of the transparent substrate
are electrically insulated to control abnormal discharge
between the substrate holder and the transparent conducting
layer on the front face of the transparent substrate. It is
assumed that this abnormal discharge occurs, when an amount of
electric charge accumulated in the transparent conducting layer
exceeds a considerable quantity in escaping of the electric
charge held in the transparent conducting layer to the substrate
holder. Since a charge quantity escaping at once to the
substrate holder is dependent on "dimension of substrate /
circumference length of substrate", this value is dependent on
a substrate size. The official report describes that when a
substrate size is large, specifically, when the substrate size
is not less than 1200 cm2, a charge quantity escaping at once
exceeds a certain steady value, and then the abnormal discharge
easily breaks out.
Thin film photoelectric converters with a large dimension
are usually formed as integrated thin film photoelectric
converters. Generally an integrated thin film photoelectric
converter is stacked on a transparent substrate, and the
converter has a structure havincr a plurality of photoelectric
conversion cells comprising a transparent electrode film, one
or more semiconductor thin film photoelectric conversion units,
and a back electrode film, each having a belt-shape connected
in series.
Here, description of an integrated thin film
photoelectric converter will be given referring to/drawings.
Identical referential numerals will be provided with an
identical member in each Figure, and overlapping description
will be omitted.
[0013]
Figure 1 is a schematic plan view showing an integrated
thin film photoelectric converter 1. Still more detailed
description about the integrated thin film photoelectric
converter 1 shown in Figure 1 will be given. Figure 2 is a
schematic sectional view showing the integrated thin film
photoelectric converter 1. The integrated thin film
photoelectric converter 1 shown in Figure 2 is a hybrid type
thin film photoelectric converter, and a photoelectric
conversion cell 10 has a structure wherein a transparent
electrode film 3, an amorphous silicon photoelectric conversion
unit 4a provided with an amorphous silicon photoelectric
conversion layer, a crystalline silicon photoelectric
conversion unit 4b provided with a crystalline silicon
photoelectric conversion layer, and a back electrode film 5,
a sealing resin layer 6, and an organic protective layer 7 are
sequentially stacked on a transparent substrate 2. That is,
this integrated thin film photoelectric converter 1 perform
photoelectric conversion of light entered from a transparent
substrate 2 side by semiconductor thin film photoelectric
conversion units 4a and 4b that form a hybrid type structure.
[0014]
As shown in Figure 2, a first,' and a second isolation
grooves 21 and 22 for dividing the thin film, and a connection
groove 23 are provided in the integrated thin film photoelectric
converter 1. These first and second isolation grooves 21 and
22, and the connection groove 23 are mutually parallel, and
extend in a direction perpendicular to a page space. A boundary
between adjacent photoelectric conversion cells 10 are
specified by the second isolation groove 22.
[0015]
The first isolation groove 21 divides the transparent
electrode film 3 corresponding to each photoelectric conversion
cell 10, and has an opening in an interface between the
transparent electrode film 3 and the amorphous silicon
photoelectric conversion unit 4a, and a surface of the
transparent substrate 2 as a bottom. This first isolation
groove 21 is filled with an amorphous material constituting the
amorphous silicon photoelectric conversion unit 4a, and the
material electrically insulates the. adjacent transparent
electrode films 3 from each other.
[0016]
The second isolation groove 22 is provided in a position
distant from the first isolation groove 21. The second
isolation groove 22 divides the semiconductor thin film
photoelectric conversion units 4a and 4b, and the back electrode
film 5 corresponding to each photoelectric conversion cell 10,
and the groove 22 has an opening in an interface between the
back electrode film 5 and the sealing resin layer 6, and it has
a surface of transparent electrode film 3 as a bottom. This
second isolation groove 22 is filled with a sealing resin layer
6, and the resin electrically insulates the back electrode films
6 from each other between the adjacent photoelectric conversion
cells 10.
[0017]
The connection groove 23 is provided between the first
isolation groove 21 and the second isolation groove 22. This
connection groove 23 divides the semiconductor thin film
photoelectric conversion units 4a and 4b, and has an opening
in an interface between the crystalline silicon photoelectric
conversion unit 4b and the back electrode film 5, and a surface
of the transparent electrode film 3 as a bottom. This
connection groove 23 is filled with a metallic material
constituting the back electrode film 5, and the metallic
material electrically connects one of the back electrode film
5 of the adjacent photoelectric conversion cells 10 with another
transparent electrode film 3. That is, the connection groove
23 and the metallic material charged therein play a role in
connecting in series the photoelectric conversion cells 10
aligned on the substrate 1 with each other.
[0018]
By the way, in such an integrated thin film photoelectric
converter 1, since the photoelectric conversion cells 10 are
connected in series, a current value of whole of the integrated
thin film photoelectric converter 1 during photoelectric
conversion becomes equal to a current value of a photoelectric
conversion cell 10, in a plurality of photoelectric conversion
cells 10, having the minimum photo current generated in
photoelectric conversion. And, as a result, an excessive photo
current in other photoelectric conversion cells 10 makes a loss .
Then, investigations have been made for keeping uniform a
quality of a film in a surface of the crystalline silicon
photoelectric conversion unit 4b. That is, in the integrated
thin film photoelectric converter 1 including the crystalline
silicon photoelectric conversion unit 4b, in order to reduce
the electric current loss mentioned above, efforts have been
made to acquire high photoelectric conversion efficiency by
reducing formation of an area generating only a small photo
current due to difference of crystallinity in the crystalline
silicon photoelectric conversion layer, and furthermore by
making in-plane quality of the film uniform.
[0019]
At this time, areas having a smaller photo current
generated in the crystalline silicon photoelectric conversion
layer may be distinguished from normal areas by visual
observation of a side of the film surface after formation of
the crystalline silicon photoelectric conversion unit 4b, and
it may be observed as a whitish discoloring areas. This
phenomenon is attributed to crystallinity difference in the
crystalline silicon as a material of the crystalline silicon
photoelectric conversion layer. On one hand, sufficient
crystallization was not achieved in whitish discoloring areas,
and the areas include not only crystalline silicon but much
amount of amorphous silicon to give whitish and cloudy
appearance, resulting in small amount of photo current. On the
other hand, since they are fully crystallized, normal areas are
observed as areas having gray appearance without whitish
cloudiness, giving larger amount of photo current generated as
compared with that from the whitish discoloring areas.
[0020]
Japanese Patent Laid-Open No. 11-330520 official report
discloses that in case of comparatively thin film-formation of
an amorphous silicon photoelectric conversion layer, use of a
higher pressure within a reaction chamber not less than 667 Pa
(5 Torr) enables film-formation of a thicker crystalline
silicon photoelectric conversion layer with high quality at a
higher speed, instead of a conventionally used pressure of not
more than 133 Pa (1 Torr) within a plasma reaction chamber, but
the patent fails to provide description about such a whitish
discoloring areas.
[0021]
However, in a hybrid type thin film photoelectric
converter or a crystalline thin film photoelectric converter
having a dimension of not less than 600 cm2, there has been shown
a problem that when the above-mentioned whitish discoloring
areas do not exist in the crystalline silicon photoelectric
conversion layer at all, areas giving a smaller photo current
does not exist, and therefore a short circuit current increases
with increase in light sensitivity, but an open-circuit voltage
and fill factor will drop.
[0022]
SUMMARY OF THE INVENTION
In consideration of the above situations, the present
invention aims at providing a thin film photoelectric converter,
in particular, an integrated thin film photoelectric converter
wherein a problem of drop of an open-circuit voltage and a fill
factor is solved and simultaneously photoelectric conversion
efficiency is improved by prevention of drop of a current value
in the thin film photoelectric converter including a
crystalline silicon photoelectric conversion unit.
[0023]
A thin film photoelectric converter by the present
invention is a thin film photoelectric converter having at least
a transparent electrode film, a crystalline silicon
photoelectric conversion unit, and a back electrode film
sequentially formed on one principal surface of a transparent
substrate thereof, and having a whitish discoloring area in a
part of the surface after formation of the crystalline silicon
photoelectric conversion unit.
[0024]
A percentage of the whitish discoloring area is
preferably not more than 5% in an dimension of a photoelectric
conversion area of the thin film photoelectric converter.
[0025]
In the thin film photoelectric converter of the present
invention, the transparent electrode film, crystalline silicon
photoelectric conversion unit, and back electrode film are
isolated with a plurality of isolation grooves so as to form
a plurality of photoelectric conversion cells; the thin film
photoelectric converter may especially preferably have a
constitution of an integrated thin film photoelectric converter
having these plurality of cells electrically connected with
each other in series via grooves for connection.
[0026]
In the integrated thin film photoelectric converter, the
whitish discoloring areas preferably exist with a dimension of
not less than 2 mm and not more than 10 mm to the photoelectric
conversion area side from a boundary parallel to the direction
of series connection of the serially connected photoelectric
conversion areas.
[0027]
A thin film photoelectric converter of the present
invention preferably further comprises an amorphous silicon
photoelectric conversion unit between the transparent
electrode film and the crystalline silicon photoelectric
conversion unit.
[0028]
Furthermore, the thin film photoelectric converter of the
present invention is a thin film photoelectric converter having
at least a transparent electrode film, a crystalline silicon
photoelectric conversion unit, and a back electrode film
sequentially formed on one principal surface of a transparent
substrate, and a difference of a maximum and a minimum values
of an absolute reflectance including diffusion component
measured with monochromatic light, having a wavelength of 800
nm, entered from another principal surface side of the
transparent substrate is not less than 5% in the photoelectric
conversion area.
[0029]
A thin film photoelectric converter of the present
invention especially preferably has a not less than 600 cm2 of
dimension having a semiconductor thin film photoelectric
conversion unit formed on one principal surface of the
transparent substrate.
[0030]
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 is a schematic plan view showing an integrated
thin film photoelectric converter;
Figure 2 is a schematic sectional view showing an
integrated thin film photoelectric converter;
Figure 3 is a schematic sectional view showing a position
of a formed insulated isolation groove;
Figure 4 is a schematic plan view showing
an integrated thin film photoelectric converter having a
substrate of a square measuring 910 mm x 910 mm, and also showing
the converter being divided into portions of two rectangles
measuring 910 mm x 455 mm;
Figure 5 shows a photograph of a film surface, and an
enlarged photograph of whitish discoloring areas after
formation of the crystalline silicon photoelectric conversion
unit in a substrate of square measuring 910 mm x 910 mm;
Figure 6 is view showing measured points of spectral
reflectance of an integrated thin film photoelectric converter
of a rectangular measuring 910 mm x 455 mm;
Figure 7 is a schematic plan view showing an integrated
thin film photoelectric converter of a rectangles measuring 300
mm x 400 mm formed on a substrate of a rectangular measuring
360 mm x 465 mm; and Figure 8 is a view showing measured points
of spectral reflectance of an integrated thin film
photoelectric converter of a rectangular measuring 300 mm x 400
mm.
[0031]
BEST MODE FOR CARRYING-OUT OF THE INVENTION
Hereinafter, more detailed description about embodiments
of the present invention will be given. Description will be
given about each structural element of a thin film photoelectric
converter of the present invention. As a transparent substrate
2, for example, a glass plate, a transparent resin film, etc.
may be used. As a glass plate, glass plates having a large
dimension may be obtained at low price, and float sheet glass
having high transparency and insulative property, having SiO2,
Na2O, and CaO as main components, and furthermore having smooth
principal surfaces may be used.
[0032]
A transparent electrode film 3 may be constituted by a
transparent conductive oxide layer such as an ITO film, a SnO2
film, or a ZnO film etc. The transparent electrode film 3 may
have a single layered structure, or may have a multilayer
structure. The transparent electrode film 3 may be formed using
any known gaseous phase depositing methods, such as a vacuum
deposition method, a CVD method, or a sputtering method. A
surface textured structure including fine unevenness is
preferably formed on a surface of the transparent electrode film
3. Formation of such a textured structure on the surface of
the transparent electrode film 3 may raise incidence efficiency
of light to a semiconductor thin film photoelectric conversion
unit 4.
[0033]
A tandem type thin film photoelectric converter has two
or more semiconductor thin film photoelectric conversion units,
and especially a hybrid type thin film photoelectric converter
has an amorphous silicon photoelectric conversion unit 4a and
a crystalline silicon photoelectric conversion unit 4b.
[0034]
On one hand, the amorphous silicon photoelectric
conversion unit 4a has an amorphous silicon photoelectric
conversion layer, and the layer has a structure wherein a p type
layer, an amorphous silicon photoelectric conversion layer, and
an n type layer are stacked sequentially from the transparent
electrode film 3 side. Each of these p type layer, amorphous
silicon photoelectric conversion layers, and n type layers may
be formed by a plasma CVD method.
[0035]
On the other hand, the crystalline silicon photoelectric
conversion unit 4b has a crystalline silicon photoelectric
conversion layer, and for example, the layer has a structure
wherein a p type layer, a crystalline silicon photoelectric
conversion layer, and an n type layer are stacked sequentially
from the amorphous silicon photoelectric conversion unit 4a
side. Each of these p type layer, crystalline silicon
photoelectric conversion layer, and n type layer may be formed
by a plasma CVD method.
[0036]
The p type layer constituting these semiconductor thin
film photoelectric conversion units 4a and 4b may be formed,
for example, by doping an impurity atom for determining a
conductivity type of p type, such as boron and aluminum, into
silicon alloys, such as silicon, silicon carbide, and silicon
germanium. And the amorphous silicon photoelectric conversion
layer and the crystalline silicon photoelectric conversion
layer may be formed with amorphous silicon based semiconductor
materials and crystalline silicon based semiconductor
materials, respectively. As such materials, intrinsic
semiconductor silicon (hydrogenated silicon etc.) , and silicon
alloys, such as silicon carbide and silicon germanium, etc. may
be mentioned. Moreover, silicon based semiconductor materials
of weak p type or weak n type including a small amount of
conductivity type determination impurities may also be used,
if they have sufficient photoelectric conversion function.
Furthermore, the n type layer may be formed by doping an impurity
atom for determining a conductivity type of n type, such as
phosphorus and nitrogen, into silicon or silicon alloys, such
as silicon carbide and silicon germanium.
[0037]
The amorphous silicon photoelectric conversion unit 4a and the
crystalline silicon photoelectric conversion unit 4b that are
constituted as mentioned above have mutually different
absorption wavelength region. Since a photoelectric
conversion layer of the amorphous silicon photoelectric
conversion unit 4a is constituted by amorphous silicon, and a
photoelectric conversion layer of the crystalline silicon
photoelectric conversion unit 4b is constituted by crystalline
silicon, the former may be expected to absorb an optic element
of approximately 550 nm of wavelength most efficiently, and the
latter may be expected to absorb about an optic element of
approximately 900 nm of wavelength most efficiently.
[0038]
On one hand, a thickness of the amorphous silicon
photoelectric conversion unit 4a is preferably within a range
of 0.01 micrometers to 0.5 micrometers, and more preferably
within a range of 0.1 micrometers to 0.3 micrometers.
[0039]
On the other hand, a thickness of the crystalline silicon
photoelectric conversion unit 4b is preferably within a range
of 0 .1 micrometers to 10 micrometers, and more preferably within
a range of 0.1 micrometers to 5 micrometers.
[0040]
The back electrode film 5 not only has a function as an
electrode, but has a function as a reflecting layer for
reflecting light that entered from the transparent substrate
2 into the semiconductor thin film photoelectric conversion
units 4a and 4b, and that is made to reach the back electrode
film 5, the reflecting layer making the reflected light re-enter
into the semiconductor thin film photoelectric conversion units
4a and 4b. The back electrode film 5 may be formed to have a
thickness of approximately 200 nm to 400 nm by a vacuum
deposition method, a sputtering method, etc. using, for example,
silver, aluminum, etc.
[0041]
Between the back electrode film 5 and the semiconductor
thin film photoelectric conversion units 4, or between the back
electrode film 5 and the crystalline silicon photoelectric
conversion unit 4b in case of a hybrid type thin film
photoelectric converter, maybe formed a transparent conductive
thin film (not shown) comprising nonmetallic substance like ZnO
in order to improve, for example, adhesive property between both
of the films.
[0042]
Each photoelectric conversion cell 10 formed on the
transparent substrate 2 of the integrated thin film
photoelectric converter 1 is sealed with an organic protective
layer 7 via a sealing resin layer 6. As this sealing resin layer
6, resins enabling adhesion of the organic protective layer onto
these cells 10 are used. As such resins, for example, EVA
(ethylene vinyl acetate copolymer), PVB (polyvinyl butyral),
PIB (polyisobutylene), silicone resins, etc. may be used. As
organic protective layer 7, may be used fluororesin films like
polyvinyl fluoride films (for example, Tedlar film (registered
trademark)) or insulative films excellent in moisture
resistance and water resisting property like PET film. The
organic protective layer may have a single layered structure,
and may have a stacked structure having the single layers
stacked therein. Furthermore, the organic protective layer
may have a structure wherein a metallic foil comprising aluminum
etc. is sandwiched with these films. Since metallic foils like
aluminum foil have a function for improving moisture resistance
and water resisting property, the organic protective layer
having such a structure enables more effective protection of
the photoelectric conversion cell 10 from moisture. These
sealing resin layer 6 / organic protective layer 7 may be
simultaneously attached to a back face side of the integrated
thin film photoelectric converter 1 by a vacuum laminating
method.
[0043]
When a substrate holder 31 as shown in Figure 3 is used
at the time of formation of the crystalline silicon thin film
photoelectric conversion unit 4b, as shown in Figure 3, one or
more insulated isolation grooves 14 are formed in parallel with
an integration direction 50 that is a direction of series
connection of the photoelectric conversion cell 10 shown in
Figure 1 on the transparent electrode film 2.
[0044]
By the way, the whitish discoloring area is visually
observable from a film side after formation of the crystalline
silicon thin film photoelectric conversion unit 4b. The
whitish discoloring area has a certain amount of uncertainty
under completely same conditions. Especially in case of a
larger dimension, temperature distribution, plasma density
distribution, spatial relationship with the substrate holder,
etc. make the uncertainty much more remarkable. This
phenomenon increases necessity for control of whitish
discoloring area, but the necessity may not be taken into
consideration in case of a smaller dimension. Suitable amount
of whitish discoloring areas need to exist in suitable areas.
[0045]
A percentage of a dimension to whole of the photoelectric
conversion area of the whitish discoloring area is preferably
not more than 5%. If a percentage of the whitish discoloring
area exists not less than the percentage mentioned above, drop
of short circuit current will exceed improvement in
open-circuit voltage and fill factor. In case of an integrated
thin film photoelectric converter 1 with a structure integrated
in series, the whitish discoloring areas preferably exist on
both ends or one end of a side parallel to the integration
direction 50 with respect to each photoelectric conversion cell
10 of the integrated thin film photoelectric converter 1. In
that case drop of a short circuit current will exceed
improvement in an open-circuit voltage and fill factor, when
the whitish discoloring areas exist within a range of not less
than 2 mm to not more than 10 mm in an inward direction of the
photoelectric conversion cell 10 from boundary of the
photoelectric conversion cell 10 of parallel side with respect
to a direction where photoelectric conversion cell 10 is
connected in series, that is an integration direction. In an
area of the photoelectric conversion area 52 and a circumference
area of the non-photoelectric conversion area on one principal
surface of the transparent substrate 2, when the transparent
electrode film 2 is divided parallel to the integration
direction 50 with borders of the insulated isolation grooves
14, by forming the insulated isolation grooves 14, the whitish
discoloring areas tend to appear in a long and slender shape
along the boundary in the integration direction 50.
[0046]
Conversely, when the whitish discoloring areas exist in
a side perpendicular to the integration direction, and when only
one of a plurality of photoelectric conversion cells 10 is
wholly the whitish discoloring area, light sensitivity of the
photoelectric conversion cell 10 becomes very low, and short
circuit current will become small. Therefore, in this case,
even if a percentage of a dimension of whitish discoloring area
is not more than 5%, a short circuit current of an integrated
thin film photoelectric converter 1 as a whole will become
extremely small, due to serial integration structure thereof,
causing decrease in photoelectric conversion efficiency.
[0047]
The whitish discoloring area does not actually formed
with a same dimension in all of the photoelectric conversion
cells 10, and therefore if they are formed on both ends with
a width of approximately 6 mm on an average, and if the whitish
discoloring areas are not formed in a direction perpendicular
to the integration direction 50, a percentage of the whitish
discoloring areas becomes not more than 5%, when a length of
direction perpendicular to the integration direction 50 of the
photoelectric conversion cell is not less than 240 mm. In fact,
not only on both ends of a direction parallel to the integration
direction of the integrated thin film photoelectric converter
1, but on both ends of a direction perpendicular to the
integration direction, the whitish discoloring areas of an
almost same percentage will be formed. For this reason, when
integration of the converter is to be performed so as to exclude
the cloudy portion in this direction perpendicular to the
integration direction, a size of the integrated thin film
photoelectric converter 1 needs to be not less than 600 cm2,
that is , not less than 240 mm x 250 mm, in order to realize
an integrated thin film photoelectric converter 1 having not
more than 5% of whitish discoloring areas, and having a width
from a boundary parallel to the integration direction of not
less than 2 mm and not more than 10 mm.
[0048]
Although the whitish discoloring areas can be easily
distinguished from a film side also after formation of the back
electrode film 5, the areas may hardly be distinguished by
visual inspection from a surface on which the semiconductor thin
film photoelectric conversion unit 4 of the transparent
substrate 2 is not formed, after sealing by resins etc. However,
these areas may be distinguished from a surface of the
transparent substrate 2 on which the semiconductor thin film
photoelectric conversion unit is not formed by spectral
reflectance measurement using a spectrum reflectometer. In
spectrum reflective measurement, measured is a reflection
including diffusion components with an incident angle of 10
degrees using an integrating sphere, determining a value on the
basis of barium sulfate board. The whitish discoloring area
may be determined by a definition that the whitish discoloring
area has a spectral reflectance in 800 nm in spectral
reflectance measurement on the conditions not less than 5% as
large as a spectral reflectance of areas without whitish
discoloring.
[0049]
EXAMPLE
(Example 1)
A glass substrate 2 having a SnO2 film 3 formed on one principal
surface and having a size measuring 910 mm x 910 mm was prepared.
Isolation grooves 21 and insulated isolation grooves 14 were
formed by a laser scriber in an SnO2 film 3 formed on a surface
of this glass substrate, as shown in Figure 1. As shown in
Figure 3, at the time of installation to a substrate holder 31
of the plasma CVD device, a first insulation isolation groove
14a having a width of approximately 100 micrometers was formed
approximately 1 mm spaced apart from an inner circumference of
the substrate holder 31. Furthermore, a second insulation
isolation groove 14b having a width of approximately 100
micrometers was formed in a position having approximately 0.7
mm apart inside from the first insulation isolation groove 14a.
[0050]
In case of formation of a crystalline silicon
photoelectric conversion unit 4b with a high power density of
not less than 100 mW/cm2 by a plasma CVD method on a substrate
having a large dimension of not less than 1200 cm2, these
insulation isolation grooves 14 insulate the substrate holder
31 from a transparent conducting layers 2 on a surface of the
substrate to prevent abnormal discharge.
[0051]
The glass substrate 2 having one sheet of SnO2 film 3 to which
the above-mentioned laser scribe was given was held in the
substrate holder 31. Allowing for a shift of a position of the
glass substrate 2 at this time, a distance from an inner
circumference of the substrate holder 31 to the first insulation
isolation groove 14a would be in a range of 3+2 mm. A substrate
holder 31 holding the glass substrate 2 was carried in within
a CVD system with an electrode (115 cm x 118 cm) installed. A
silane, hydrogen, methane, and diborane were introduced as
reactive gases. After formation of a p type layer, the silane
was introduced as a reactive gas to form an amorphous silicon
photoelectric conversion layer. After that, the silane,
hydrogen, and phosphine were introduced to form an n type layer
as reactive gases. An amorphous silicon photoelectric
conversion unit 4a was thus formed.
[0052]
Then, the silane, hydrogen, and diborane were introduced
as reactive gases to form a p type layer, and subsequently
hydrogen and the silane were introduced as reactive gases under
flow rate conditions shown in Example 1 of Table 1 to form a
crystalline silicon photoelectric conversion layer. After
that, the silane, hydrogen, and phosphine were introduced as
reactive gases to form an n type layer. A crystalline silicon
photoelectric conversion unit 4b was thus formed.
[0053]
After formation of the crystalline silicon photoelectric
conversion unit 4b, the amorphous silicon photoelectric
conversion unit 4a and the crystalline silicon photoelectric
conversion unit 4b were laser scribed to form a connection
groove 23. And furthermore, a back electrode film 5 as a double
layer film of a ZnO film and an Ag film as a back electrode film
was formed by a sputtering method. Then, the amorphous silicon
photoelectric conversion unit 4a, the crystalline silicon
photoelectric conversion unit 4b, and the back electrode film
5 were laser scribed to form an isolation groove 22.
Furthermore, the circumference insulation grooves 42a and 42b
shown in Fig. 4 were formed by laser scribing of the SnO2 film
3, the amorphous silicon photoelectric conversion unit 4a, the
crystalline silicon photoelectric conversion unit 4b, and the
back face electrode film 5. Before attachment of lead wires
12, as shown in Figure 4, the substrate was divided into a half
size along with a cutting line 41 in a direction parallel to
the integration direction 50. Thus a hybrid type integrated
thin film photoelectric converter 1 with a size of 910 mm x 455
mm wherein 100 of photoelectric conversion cells 10 having a
size of 8. 9 mm x 430 mm were connected in series was produced.
Here, the circumference insulation grooves 42a were formed on
the insulated isolation grooves 14 beforehand formed on the SnO2
film 3.
[0054]
A surface of the crystalline silicon photoelectric
conversion unit 4b of this hybrid type integrated thin film
photoelectric converter 1 was observed after formation of the
conversion unit 4b, and whitish discoloring areas 51 discolored
in white were observed on both ends of the photoelectric
conversion cell 10, as schematically shown in Figure 4. Figure
5 shows a visual appearance photograph of the whitish
discoloring areas. In case of a hybrid type integrated thin
film photoelectric converter 1 with a size measuring 910 mm x
455 mm, this whitish discoloring area 51 existed within a width
of not less than 5 mm and not more than 10 mm from one of the
circumference insulation isolation grooves 42a parallel to the
integration direction 50. When an area surrounded with the
circumference insulation isolation grooves 42a and 42b is
defined as a photoelectric conversion area 52 here, the whitish
discoloring area 51 occupied an area of approximately 2% to a
gross dimension of the photoelectric conversion area 52.
[0055]
Measured was a sample wherein the hybrid type integrated
thin film photoelectric converter 1 having the whitish
discoloring area 51 for a spectral reflectance using a light
entered from a glass surface 2 side. Measurement of the
spectral reflectance was carried out by measuring a reflection
including diffusion components with an incident angle of 10
degrees using an integrating sphere on the basis of barium
sulfate board. Measured result showed that the whitish
discoloring area 51 had a value not less than 5% larger than
a value in a normal area in spectral reflectance in 800 nm. That
is, a test result of spectral reflectance for 9 points shown
in Figure 6 as shown in Example 1 of Table 2 gave a difference
of the absolute values of 12.1%. Here, points of measurement
of 1, 4, and 7 correspond to the whitish discoloring areas 51,
and points of measurement of 2, 3, 5, 6, 8, and 9 correspond
to the normal areas.
[0056]
An initial output as an output before photodegradation
by optical exposure of this hybrid type integrated thin film
photoelectric converter 1 may be obtained from a an electrical
property of a light of a solar simulator of AM 1.5 using a xenon
and a halogen lamp as a light source having an irradiance of
100 mW/cm2 being entered from a glass surface side. A
measurement temperature was set at 25 degrees C. As shown in
Example 1 of Table 3, the initial output gave 42.8 W. At this
time, a short circuit current, an open-circuit voltage, and a
fill factor gave 0.456 A, 135.5 V, and 0.692, respectively.
[0057]
Table 1 shows relationship between film-formation flow
rate conditions of the crystalline silicon photoelectric
conversion layers, and the whitish discoloring areas in the
hybrid type integrated thin film photoelectric converters of
each of Examples and Comparative Examples.
[0058]
Table 2 shows spectral reflectances at 800 nm of the
hybrid type integrated thin film photoelectric converters in
each of Examples and Comparative Examples.
[0059]
Table 3 shows photoelectric transfer characteristics of
the hybrid type integrated thin film photoelectric converter
in each of Examples and Comparative Examples.
[0060]
(Comparative Example 1)
Except for having formed a crystalline silicon
photoelectric conversion layer under a flow rate conditions
shown in Comparative Example 1 of Table 1, a hybrid type
integrated thin film photoelectric converter 1 of Comparative
Example 1 was produced in a same manner as in Example 1. In
the hybrid type integrated thin film photoelectric converter
1 of Comparative Example 1, obtained was a hybrid type
integrated thin film photoelectric converter 1 having a size
measuring 910 mm x 455 mm in which whitish discoloring area 51
was not recognized by film side observation before sealing. As
in Example 1, measurement of an initial output and a spectral
reflectance of the hybrid type integrated thin film
photoelectric converter 1 of Comparative Example 1 gave results
of Comparative Example 1 in Table 3, and Comparative Example
1 in Table 2, respectively. A difference of absolute values
of spectral reflectance at 800 nm gave not more than 5%, the
initial output gave 40.1 W, and the short circuit current, the
open-circuit voltage, and the fill factor gave 0.455 A, 129.5
V, and 0.681, respectively. The Comparative Example 1 gave
obviously a lower open-circuit voltage and a fill factor as
compared with those in Example 1, and also gave a low value for
the initial output.
[0061]
[0063]
(Example 2)
Except for having formed a crystalline silicon
photoelectric conversion layer under a flow rate condition
shown in Example 2 of Table 1, a hybrid type integrated thin
film photoelectric converter 1 of Example 2 was produced in a
same manner as in Example 1. In the hybrid type integrated thin
film photoelectric converter 1 of Example 2, by a film side
observation before sealing, whitish discoloring areas 51
discolored white were identified on both ends of the
photoelectric conversion cell 10 as shown in Figure 4. In case
of the hybrid type integrated thin film photoelectric converter
1 having a size measuring 910 mm x 455 mm, this whitish
discoloring area 51 existed in a range of not less than 15 mm
and not more than 30 mm from one of the two circumference
insulation isolation grooves 42a parallel to the integration
direction 50. The whitish discoloring areas 51 occupied
approximately 5.5% to a gross dimension of the photoelectric
conversion area 52.
[0064]
The hybrid type integrated thin film photoelectric
converter 1 of Example 2 was measured for spectral reflectances
at 9 points as shown in Figure 6 in a same manner as in Example
1. As shown in Example 2 in Table 2, a difference of absolute
values of spectral reflectances at 800 nm gave 11.7%. Here,
points of measurement 1, 4, and 7 correspond to whitish
discoloring areas 51, and points of measurement 2, 3, 5, 6, 8,
and 9 correspond to normal areas.
[0065]
Measurement in a same manner as in Example 1 of an initial
output of the hybrid type integrated thin film photoelectric
converter 1 of Example 2 gave 41.2 W, as shown in Example 2 in
Table 3. A short circuit current, an open-circuit voltage, and
a fill factor gave 0.441 A, 136.7 V, and 0.683, respectively.
Example 2 gave a higher open-circuit voltage and a higher fill
factor as compared with those in Comparative Example 1, and also
gave a higher initial output. And it gave a little lower value
of a short circuit current and also a little low initial output
as compared with those in Example 1.
[0066]
(Example 3)
A glass substrate 2 having an SnO2 film 3 formed on one
principal surface thereof and having a size measuring 365 mm
x 465 mm was prepared, and isolation grooves 21 were formed on
this substrate, as shown in Figure 7.
[0067]
Without using a substrate holder, the glass substrate 2
was moved in a position having an electrode size measuring 400
mm x 500 mm of a single wafer processing plasma CVD device
enabling conveyance of the glass substrate 2 with a conveying
fork, and an amorphous silicon photoelectric conversion unit
4a and a crystalline silicon photoelectric conversion unit 4b
were formed using a same gas composition as in Example 1. This
time, a crystalline silicon photoelectric conversion layer was
formed under flow rate conditions shown in Example 3 in Table
1. After formation of the crystalline silicon photoelectric
conversion unit 4b, connection grooves 23 were formed by a laser
scribe method, and then a back electrode film 5 as a double layer
film of a ZnO film and an Ag film was formed as a back electrode
film by a sputtering method. Then, isolation grooves 22, and
circumference insulation grooves 42a and 42b as shown in Figure
4 were formed by a laser scribe method. And subsequently, lead
wires 12 was attached to produce a hybrid type integrated thin
film photoelectric converter 1 having a size measuring 300 mm
x 400 mm wherein 28 pieces of photoelectric conversion cells
10 with a size measuring 8. 9 mm x 380 mm were connected in series
together.
[0068]
As schematically shown in Figure 7, whitish discoloring
areas 51 colored white on both ends of the photoelectric
conversion cell 10 were identified by observation from a film
side before sealing of this hybrid type integrated thin film
photoelectric converter 1. The whitish discoloring areas 51
were observed in a range of not less than 2 mm and not more than
6 mm from both of the circumference insulation isolation grooves
42a parallel to the integration direction 50, and a percentage
of the whitish discoloring areas 51 gave approximately 3% to
a gross dimension of the photoelectric conversion area 52.
[0069]
The hybrid type integrated thin film photoelectric converter
1 of Example 3 was measured for a spectral reflectance in 9 points
as shown in Figure 8 in a same manner as in Example 1. As shown
in Example 3 in Table 2, a difference of absolute values of the
spectral reflectance at 800 nm gave 9.9%. Here, points of
measurement 1, 3, 4, 6, 7, and 9 correspond to the whitish
discoloring area 51, and points of measurement 2, 5, and 8
correspond to normal areas.
[0070]
The hybrid type integrated thin film photoelectric
converter 1 of this Example 3 was measured for an initial output
in a same manner as in Example 1 to obtain 12.3 W as shown in
Example 3 in Table 3. At this time, a short circuit current,
an open-circuit voltage, and a fill factor gave 0.439 A, 37.8
V, and 0.741, respectively.
[0071]
(Comparative Example 2)
Except for having formed a crystalline silicon
photoelectric conversion layer under flow rate conditions shown
in Comparative Example 2 in Table 1, a hybrid type integrated
thin film photoelectric converter 1 of Comparative Example 2
was produced in a same manner as in Example 3. In the hybrid
type integrated thin film photoelectric converter 1 of
Comparative Example 2, obtained was a hybrid type integrated
thin film photoelectric converter 1 having a size measuring 300
mm x 400 mm wherein whitish discoloring areas 51 were not
recognized by observation from a film side before sealing. The
hybrid type integrated thin film photoelectric converter 1 of
Comparative Example 2 was measured for an initial output and
spectral reflectance in a same manner as in Example 1 to obtain
results for Comparative Example 2 in Table 2, and for
Comparative Example 2 in Table 3, respectively. A difference
of absolute values of the spectral reflectance at 800 nm gave
not more than 5%, and an initial output gave 11.8 W. A short
circuit current, an open-circuit voltage, and a fill factor gave
0.441 A, 37.0 V, and 0.681, respectively. The Comparative
Example 2 showed obviously lower open-circuit voltage and fill
factor as compared with those in Example 3, and also showed a
lower initial output.
[0072]
(Example 4)
A crystalline silicon photoelectric conversion layer formed
under flow rate conditions shown in Example 4 in Table 1 gave
whitish discoloring areas 51 discolored white on both ends of
a photoelectric conversion cell 10, as schematically shown in
Figure 7. In case of the obtained layer used for a hybrid type
integrated thin film photoelectric converter 1 having a size
measuring 300 mm x 400 mm, this whitish discoloring area 51
existed in a range of not less than 5 mm and not more than 16
mm from one of two circumference insulation isolation grooves
42a parallel to the integration direction 50. A percentage of
the whitish discoloring area 51 to a gross dimension of the
photoelectric conversion area 52 gave approximately 5.2%.
Measurement, in a same manner as in Example 1, of spectral
reflectance in 9 points as shown in Figure 8 gave 9.6% of
difference of absolute values of spectral reflectance in 800
nm as shown in Example 4 of Table 2.
[0073]
A same measurement as in Example 1 gave 12.1 W for initial
output, as shown in Example 4 in Table 3. A short circuit
current, an open-circuit voltage, and a fill factor gave 0.435
A, 38.1 V, and 0.728, respectively. Example 4 gave a higher
open-circuit voltage and a higher fill factor, and also a higher
initial output as compared with that in Comparative Example 2.
And it gave a little lower short circuit current and a little
lower initial output as compared with those in Example 2.
[0074]
DESCRIPTION OF NOTATIONS
1 Integrated thin film photoelectric converter
2 Transparent substrate
3 Transparent electrode film
4a and 4b Semiconductor thin film photoelectric conversion unit
5 Back electrode film
6 Sealing resin layer
7 Organic protective layer
10 Photoelectric conversion cell
12 Lead wire
14a, 14b, and 14c Insulated isolation groove
21 and 22 Isolation groove
23 Connection groove
31 Substrate holder
32 Back plate
41 Cutting line
42a, 42b Circumference insulation isolation groove
50 Integration direction
51 Cloudy discoloring area
52 Photoelectric conversion area
61 Point of measurement for spectral reflectance 1
62 Point of measurement for spectral reflectance 2
63 Point of measurement for spectral reflectance 3
64 Point of measurement for spectral reflectance 4
65 Point of measurement for spectral reflectance 5
66 Point of measurement for spectral reflectance 6
67 Point of measurement for spectral reflectance 7
68 Point of measurement for spectral reflectance 8
69 Point of measurement for spectral reflectance 9
[0075]
INDUSTRIAL APPLICABILITY
As described in full detail above, a thin film
photoelectric converter of the present invention is a thin film
photoelectric converter including a crystalline silicon
photoelectric conversion unit, it has a whitish discoloring
areas in a crystalline silicon photoelectric conversion layer,
and it may solve problems of obtaining a small open-circuit
voltage and a fill factor, and as a result it may provide a thin
film photoelectric converter having an improved photoelectric
conversion efficiency. Furthermore, the present invention
enables discrimination of quality of the photoelectric
conversion characteristic of the obtained thin film
photoelectric converter immediately after completion of
formation of the crystalline silicon photoelectric conversion
unit.
We claim :
1. A thin film photoelectric converter comprising at
least a transparent electrode film (3), a crystalline
silicon photoelectric conversion unit (4b) formed by a
plasma CVD method, and a back electrode film (5)
sequentially formed on one principal surface of a
transparent substrate (2) , wherein the thin film
photoelectric converter comprises a whitish discoloring
area on a part of a surface thereof after formation of
the crystalline silicon photoelectric conversion unit
(4b) wherein in said whitish discoloring area
sufficient crystallization was not achieved.
2. The thin film photoelectric converter as claimed
in Claim 1, wherein a percentage of the whitish
discoloring area is not more than 5% of a photoelectric
conversion area of the thin film photoelectric
converter.
3. The thin film photoelectric converter as claimed
in Claim 1 or Claim 2, wherein the transparent
electrode film, crystalline silicon photoelectric
conversion unit, and back electrode film are isolated
by a plurality of isolation grooves so as to form a
plurality of photoelectric conversion cells, and the
plurality of cells are electrically connected mutually
in series via grooves for connection.
4. The thin film photoelectric converter as claimed
in Claim 3, wherein the whitish discoloring area exists
in a range of not less than 2 mm and not more than 10
mm to a side of the photoelectric conversion area from
a boundary parallel to a direction of the photoelectric
conversion area connected in series.
5. The thin film photoelectric converter as claimed
in Claims 1 to 4, wherein the thin film photoelectric
converter further comprises an amorphous silicon
photoelectric conversion unit between the transparent
electrode film and the crystalline silicon
photoelectric conversion unit.
6. The thin film photoelectric converter as claimed
in Claims 1 to 5, wherein a dimension having the
semiconductor thin film photoelectric conversion unit
formed therein is not less than 600 cm2.
A thin-film photoelectric converter comprising a crystalline silicon photoelectric conversion unit, in particular an
integrated thin-film photoelectric converter is disclosed wherein the photoelectric conversion efficiency is improved by preventing
decrease in open end voltage and fill factor. The thin-film photoelectric converter comprises at least a transparent electrode film, a
crystalline silicon photoelectric conversion unit and backside electrode film sequentially formed on one major surface of a transparent
substrate, and the crystalline silicon photoelectric conversion unit is so formed as to partially have a discolored white turbid region
in the surface after the formation. The discolored white turbid region is preferably not more than 5% of the photoelectric conversion
area. The thin-film photoelectric converter is preferably formed as an integrated thin-film photoelectric converter.

Documents:

1281-KOLNP-2005-CORRESPONDENCE.pdf

1281-KOLNP-2005-FORM 27.pdf

1281-KOLNP-2005-FORM-27.pdf

1281-kolnp-2005-granted-abstract.pdf

1281-kolnp-2005-granted-assignment.pdf

1281-kolnp-2005-granted-claims.pdf

1281-kolnp-2005-granted-correspondence.pdf

1281-kolnp-2005-granted-description (complete).pdf

1281-kolnp-2005-granted-drawings.pdf

1281-kolnp-2005-granted-examination report.pdf

1281-kolnp-2005-granted-form 1.pdf

1281-kolnp-2005-granted-form 18.pdf

1281-kolnp-2005-granted-form 3.pdf

1281-kolnp-2005-granted-form 5.pdf

1281-kolnp-2005-granted-gpa.pdf

1281-kolnp-2005-granted-reply to examination report.pdf

1281-kolnp-2005-granted-specification.pdf

1281-kolnp-2005-granted-translated copy of priority document.pdf


Patent Number 222872
Indian Patent Application Number 1281/KOLNP/2005
PG Journal Number 35/2008
Publication Date 29-Aug-2008
Grant Date 27-Aug-2008
Date of Filing 01-Jul-2005
Name of Patentee KANEKA CORPORATION
Applicant Address 2-4, NAKANOSHIMA 3-CHOME, KITA-KU, OSAKA-SHI OSAKA
Inventors:
# Inventor's Name Inventor's Address
1 TAWADA YUKO 8-28-304, TORIKAI-WADO 1-CHOME, SETTSU-SHI OSAKA-566-0073
2 YAMAMOTO KENJI 2-W1406, MIKATA-DAI 1-CHOME, NISHI-KU, KOBE-SHI HYOGO 651-2277
3 SUEZAKI TAKASHI 18-52-405, YOSHIMI 3-CHOME, MORIYAMA-SHI SHIGA 524-0021
4 YOSHIMI MASASHI 6-6-4, IBUKIDAI-NISHIMACHI, NISHI-KU, KOBE-SHI HYOGO 651-2243
5 SASAKI TOSHIAKI 2-1-2-131, HIEITSUJI, OHTSU-SHI SHIGA 520-0104
PCT International Classification Number H01L 31/04
PCT International Application Number PCT/JP2004/007803
PCT International Filing date 2004-05-28
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 2003-174423 2003-06-19 Japan