CN103000703A - Solar module - Google Patents

Abstract

The invention discloses a solar module. The solar module comprises a first light-transmitting substrate, a photoelectric conversion element and a second light-transmitting substrate, which are stacked in sequence. The solar module is provided with a light-transmitting structure, and an absorbing layer for absorbing incident light is arranged outside the photoelectric conversion element or outside the second light-transmitting substrate.

Description

Solar energy module

Technical field

The present invention is relevant a kind of solar energy module (solar module), and the solar energy module of relevant a kind of light-transmission type particularly.

Background technology

Known solar energy module with various translucent constructions.Schematic diagram when Fig. 1 illustrates 110 use of known a kind of light-transmission type solar energy module.As shown in the figure, the solar energy module 110 that is arranged at building exposed wall comprises the first transparent substrates 112, the first electrode layer 113, photoelectric conversion layer 114, the second electrode lay 116 and the second transparent substrates 118.Wherein, the first electrode layer 113, photoelectric conversion layer 114 consist of photo-electric conversion element with the second electrode lay 116, and they are laminated between the first transparent substrates 112 and the second transparent substrates 118.After incident ray 140 enters the first transparent substrates 112 from outdoor 120, solar energy module 110 can pass through photoelectric conversion layer 114 absorbing light energies, and the second electrode lay 116 can not absorbed incident ray 140 by light reflection to the photoelectric conversion layer 114 that photoelectric conversion layer 114 absorbs again.On the other hand, having a plurality of loopholes 119 between the first transparent substrates 112 and the second transparent substrates 118 can allow part incident ray 140 enter indoor 130 and pass the second transparent substrates 118 and form emergent raies 150.Thus, be positioned at indoor 130 user and can see by loophole 119 outdoor 120 scene.

Fig. 2 illustrates the schematic diagram of known solar energy module 110 when another environment uses of Fig. 1.As shown in the figure, when indoor 130 had light source 160, the second transparent substrates 118 had incident ray 162 and enters, and incident ray 162 can be reflected and form reflection ray 164 to the second electrode lay 116 and passes the second transparent substrates 118.Thus, the user can see emergent ray 150 and reflection ray 164 simultaneously in the second transparent substrates 118, when emergent ray 150 and the luminous power contrast of reflection ray 164 are lower (for example indoor 130 is brighter), the user can see more indoor 130 mirror images and fuzzy outdoor 120 scenes in the second transparent substrates 118, even as looking in the mirror and lose the meaning that loophole 119 is set.

That is to say that the luminous power size of reflection ray 164 can affect the definition of outer 120 scenes of user's interview room.

Summary of the invention

A purpose of the present invention allows indoor light that the definition impact of outdoor scene is reduced for a kind of solar energy module is provided, and the function of performance translucent construction.

According to an embodiment of the present invention, a kind of solar energy module comprises the first transparent substrates, photo-electric conversion element and the second transparent substrates that stacks gradually, described solar energy module has translucent construction, and the outside of the outside of described photo-electric conversion element or described the second transparent substrates is provided with for light-absorbing absorbed layer.

In an embodiment of the present invention, wherein said photo-electric conversion element comprises the first electrode layer, photoelectric conversion layer and the second electrode lay that stacks gradually.

In an embodiment of the present invention, wherein said solar energy module is the translucent thin-film solar module, and described translucent construction is to penetrate a plurality of loopholes of described photo-electric conversion element or arrange the printing opacity groove more, and described translucent construction penetrates this absorbed layer.

In an embodiment of the present invention, wherein said solar energy module is light-transmission type crystal silicon solar module, and described photo-electric conversion element comprises a plurality of solar cell pieces, and described translucent construction is made of the gap between each solar cell piece.

In an embodiment of the present invention, the material of wherein said absorbed layer is titanium nitride, niobium nitride or black silicon.

In an embodiment of the present invention, the outside of wherein said the second transparent substrates is formed with anti-reflecting layer, and described anti-reflecting layer is the printing opacity antireflecting coating.

In an embodiment of the present invention, the material of wherein said anti-reflecting layer is MgF ₂, SiO ₂, Si ₃N ₄, ZnS or TiO ₂

In an embodiment of the present invention, be formed with the transmittance section corresponding with described translucent construction on the absorbed layer of the arranged outside of wherein said the second transparent substrates.

In an embodiment of the present invention, the material of wherein said absorbed layer is titanium nitride (titanium nitride), niobium nitride (niobium nitride) or black silicon (black silicon).

In an embodiment of the present invention, described photoelectric conversion layer is monocrystalline silicon photoelectric conversion layer, polysilicon photoelectric conversion layer, in conjunction with many knots photoelectric conversion layer of amorphous silicon and microcrystal silicon or in conjunction with many knots photoelectric conversion layer of amorphous silicon and amorphous silicon germanium (a-Si/a-SiGe).

In the above-mentioned execution mode of the present invention, the first transparent substrates is near outdoor, and the second transparent substrates is near indoor.Because solar energy module has translucent construction, therefore being positioned at indoor user can see outdoor scene.When indoor when having light source, though the second transparent substrates has incident ray and enters, but therefore the absorbed layer of solar energy module can reduce the reflectivity of the second transparent substrates incident ray between photo-electric conversion element and the second transparent substrates or on the second transparent substrates outer surface.That is to say that the second transparent substrates incident ray only can not reflected by photo-electric conversion element by the reflection of the second transparent substrates.

Thus, because the reflectivity of the second transparent substrates incident ray can reduce, allow the user be not easy to the mirror image that user oneself and indoor environment (for example table or chair) are seen in the solar energy module back side, therefore when the scene outside user's interview room, can present more clearly scene.On the other hand, the producer more optionally arranges anti-reflecting layer in the second transparent substrates outside (near an indoor side), the second transparent substrates incident ray can be reflected by the second transparent substrates hardly, and can further reduce the reflectivity of solar energy module incident ray.

Compare with known solar energy module, this solar energy module can reduce by absorbed layer and anti-reflecting layer the reflectivity of the second transparent substrates incident ray, allows indoor light that the definition impact of outdoor scene is reduced, and the function of performance translucent construction.

Description of drawings

Schematic diagram when Fig. 1 illustrates known solar energy module use;

Fig. 2 illustrates the schematic diagram of known solar energy module when another environment uses of Fig. 1;

The schematic diagram that Fig. 3 A illustrates according to an embodiment of the present invention solar energy module when using;

Fig. 3 B illustrates the another kind of structural design of the photoelectric conversion layer of Fig. 3 A;

Fig. 3 C illustrates another structural design of the photoelectric conversion layer of Fig. 3 A;

Schematic diagram when the solar energy module that Fig. 4 illustrates another execution mode according to the present invention uses;

Schematic diagram when the solar energy module that Fig. 5 illustrates the another execution mode according to the present invention uses.

[primary clustering symbol description]

110: 112: the first transparent substrates of solar energy module

Electrode layer 114 in 113: the first: photoelectric conversion layer

116: 118: the second transparent substrates of the second electrode lay

119: loophole 120: outdoor

130: indoor 140: incident ray

150: emergent ray 160: light source

162: incident ray 164: reflection ray

210: 211: the second absorbed layers of solar energy module

213: the first electrode layers of 212: the first transparent substrates

214: photoelectric conversion layer 2141: photoelectric conversion material

2142: photoelectric conversion material 2143: oxide

2144: conductive layer 2145: conductive layer

2146: conductive layer 2147: conductive layer

2148: insulating barrier 215: anti-reflecting layer

216: the second electrode lay 217: absorbed layer

Transparent substrates 219 in 218: the second: translucent construction

220: outdoor 222: the transmittance section

230: indoor 240: incident ray

250: emergent ray 260: light source

262: incident ray 264: reflection ray

Embodiment

Below will disclose a plurality of execution mode of the present invention with accompanying drawing, as clearly stated, the details on many practices will be explained in the following description.Yet, should be appreciated that the details on these practices does not use to limit the present invention.That is to say that in part execution mode of the present invention, the details on these practices is non-essential.In addition, for the purpose of simplifying accompanying drawing, some known habitual structures and assembly will illustrate in the mode of simple signal in the accompanying drawings.

The schematic diagram that Fig. 3 A illustrates according to an embodiment of the present invention solar energy module 210 when using.As shown in the figure, solar energy module 210 comprises the first transparent substrates 212, the first electrode layer 213, photoelectric conversion layer 214, the second electrode lay 216 and the second transparent substrates 218 that stacks gradually.In the present embodiment, the inboard of the second transparent substrates 218 (in the face of a side of the second electrode lay 216) is formed with for light-absorbing absorbed layer 217.

In addition, solar energy module 100 has the translucent construction 219 that penetrates the first electrode layer 213, photoelectric conversion layer 214, the second electrode lay 216 and absorbed layer 217.The first electrode layer 213, photoelectric conversion layer 214 and the second electrode lay 216 consist of so-called photo-electric conversion element.

Wherein, the first electrode layer 213 is positioned on the first transparent substrates 212 and contact photoelectric conversion layer 214.The second electrode lay 216 is between photoelectric conversion layer 214 and absorbed layer 217.Absorbed layer 217 reflects in order to intercept 216 pairs of the second transparent substrates incident raies 262 of the second electrode lay between the second electrode lay 216 and the second transparent substrates 218, and reduces the reflectivity of the second transparent substrates incident ray 262.

Above-mentioned the first transparent substrates 212 is near outdoor 220, and the second transparent substrates 218 is near indoor 230.In addition, translucent construction 219 is between the first transparent substrates 212 and the second transparent substrates 218.Translucent construction 219 is arranged between the first transparent substrates 212 and the second transparent substrates 218 each other almost parallel, and the both ends of translucent construction 219 are approximately perpendicular to respectively the first transparent substrates 212 and the second transparent substrates 218.For the user who is positioned at indoor 230, such set-up mode has better translucent effect, so that outdoor 220 incident ray 240 more easily passes the second transparent substrates 218 and forms emergent ray 250 by translucent construction 219.From the above, this solar energy module 210 is fit to be applied to the exterior wall in building and can for the scene that is positioned at user's interview room outer 220 of indoor 230, has the translucent effect of similar screen window.The error that means to make all " roughly " herein.In addition, translucent construction 219 can or be arranged the printing opacity groove for a plurality of loopholes more.

In the present embodiment, the key property of absorbed layer 217 is antiradar reflectivity and low penetration rate, in brief, exactly high-absorbility to be arranged, this high-absorbility can comprise the black object with high absorptance or have antiradar reflectivity and the column structure of low penetration rate, and the material of absorbed layer 217 can comprise titanium nitride, niobium nitride or black silicon, and black silicon is for example for having the black silicon material of column structure.

Particularly, because solar energy module 210 has translucent construction 219, therefore be positioned at indoor 230 user and can see outdoor 220 scene.When indoor 230 have light source 260, though the second transparent substrates 218 has incident ray 262 and enters, but the absorbed layer 217 of solar energy module 210 is between the second electrode lay 216 and the second transparent substrates 218, therefore can intercept 262 reflections of 216 pairs of the second transparent substrates incident raies of the second electrode lay, and reduce the reflectivity of the second transparent substrates incident ray 262.That is to say that when the reflectivity convergence of absorbed layer 217 was zero, the second transparent substrates incident ray 262 was only reflected by the second transparent substrates 218 and can be by the second electrode lay 216 reflections.

Thus, the reflectivity of the second transparent substrates incident ray 262 can reduce, the user is not easy to the second transparent substrates 218 and sees user oneself and indoor 230 environment (for example table or chair) mirror image, when presenting more clearly scene during 220 scene outside the interview room.

For instance, outdoor 220 incident ray 240 has 200 watts of luminous powers, and incident ray 240 has 20 watts luminous power by the emergent ray 250 of the second transparent substrates 218 via translucent construction 219.Have light source 260 this moment indoor 230, so that the second transparent substrates incident ray 262 has 100 watts luminous power.Yet, because solar energy module 210 has absorbed layer 217, therefore the second transparent substrates incident ray 262 only can by the second electrode lay 216 reflections, not make the reflection ray 264 of the second transparent substrates incident ray 262 only have 4 watts luminous power by 218 reflections of the second transparent substrates.Thus, can define the ratio that a contrast ratio equals emergent ray 250 and the luminous power of reflection ray 264, therefore in the present embodiment contrast ratio is 5, and not being subject to light source 260 during the scene of user's interview room of indoor 230 outer 220 affects definition.

Compare with the known solar energy module 110 of Fig. 2, because the second transparent substrates incident ray 162 of known solar energy module 110 make the reflection ray 164 of the second transparent substrates incident ray 162 may have 90 watts luminous power except by also being reflected by the second electrode lay 116 118 reflections of the second transparent substrates.Similarly, contrast ratio is emergent ray 150 and the ratio of the luminous power of reflection ray 164, and therefore the contrast ratio of known solar energy module 110 is 0.22, and being subject to light source 160 during the scene of user's interview room of indoor 130 outer 120 affects definition.

In the present embodiment, the first transparent substrates 212 and the second transparent substrates 218 can be transparent or semitransparent substrate, for example substrate of light transmittance 50% to 100%.In addition, the first transparent substrates 212 can be glass or thin polymer film, for example PEN film (the polyethylene naphthalate of the film of DuPontTM Teflon, DuPontTM Teonex; PEN), the ST polyester film of DuPontTM Melinex and transparent pi (transparent polyimide).Solar energy module, be commonly called as solar cell, can and form by multiple different material, it can monocrystalline silicon or the solar components of polysilicon, it also can be the thin film solar assembly, the thin film solar assembly generally comprises following this structure: the first electrode layer 213 is transparency conducting layers, and its material can be transparent conductive oxide (transparent conductive oxide; TCO) or other non-oxidized substance, similarly be CNT (carbon nano-tube) (carbon nanotube) or organic conductive macromolecule film (organic conducting polymer).

The material of photoelectric conversion layer 214 can comprise amorphous silicon (amorphous silicon), cadmium sulfide (cadmium diselenide; CdS), cadmium telluride (cadmium telluride; CdTe), indium copper selenide (copper indium selenide; CIS) or Copper Indium Gallium Selenide (copper indium gallium diselenide; CIGS).In detail, the composition structure of photoelectric conversion layer 214 can be the structure of unijunction, namely single kind of material is as photoelectric conversion layer, also can be binode (for example A-Si/ μ c-Si Tandem) or the structure of many knots (for example A-Si/A-SiGe/A-SiGe Multi-junction), namely become photoelectric conversion layer by several identical or different materials stacks.The structure example of unijunction such as amorphous silicon photoelectric conversion layer.On the structural design of binode, might in the middle of two kinds of photoelectric conversion materials 2141/2142, add last layer oxide 2143, shown in Fig. 3 B, might add that also several layers of transparency conducting layer 2144/2145/2146/2147 separately and with insulating barrier 2148 completely cut off the conducting channel of two kinds of photoelectric conversion materials 2141/2142 between two parties, to form the structure of non-series connection, shown in Fig. 3 C.Wherein, transparency conducting layer 2144 can be identical with the first electrode layer 216 materials and forms as one; Transparency conducting layer 2145/2147 can be identical with the first electrode layer 216 materials and forms as one.Photoelectric conversion layer 214 can be by chemical vapour deposition (CVD) (chemical vapor deposition; CVD), physical vapour deposition (PVD) (physical vapor deposition; PVD) or the mode of sputter be formed on the first transparent substrates 212.On the other hand, the material of the second electrode lay 216 can be transparent conductive oxide (transparent conductive oxide; TCO) electrode layer or other metal electrode layer of silver, titanium or aluminium for example.

Should be appreciated that, in the following description, narrated in the above-described embodiment the annexation of each inter-module and the material of assembly and will no longer repeat to give unnecessary details that the structure that only increases with regard to solar energy module 210 is replenished and described in detail.

Schematic diagram when the solar energy module 210 that Fig. 4 illustrates another execution mode according to the present invention uses.As shown in the figure, solar energy module 210 comprises the first transparent substrates 212, the second transparent substrates 218, photoelectric conversion layer 214, the second electrode lay 216, absorbed layer 217 and translucent construction 219.Place different from the embodiment described above is the outside (sides near indoor 230) that solar energy module 210 also comprises the second anti-reflecting layer 215 and is positioned at the second transparent substrates 218, namely is positioned on the second transparent substrates 218 side back to absorbed layer 217.Wherein anti-reflecting layer 215 can be the printing opacity antireflecting coating.The material of anti-reflecting layer 215 can be MgF ₂, SiO ₂, Si ₃N ₄, ZnS or TiO ₂ Solar energy module 210 in the present embodiment can more reduce the reflectivity of the second transparent substrates incident ray 262 because having anti-reflecting layer.

Particularly, outdoor 220 incident ray 240 has 200 watts of luminous powers, and incident ray 240 has 20 watts luminous power by the emergent ray 250 of the second transparent substrates 218 via translucent construction 219.Have light source 260 this moment indoor 230, so that the second transparent substrates incident ray 262 has 100 watts luminous power.Yet, because solar energy module 210 has absorbed layer 217 and anti-reflecting layer 215, therefore the second transparent substrates incident ray 262 can by 218 reflections of the second transparent substrates, make the reflection ray 264 of the second transparent substrates incident ray 262 only have 1 watt luminous power hardly.Thus, contrast ratio equals the ratio of emergent ray 250 and the luminous power of reflection ray 264, and therefore in the present embodiment contrast ratio is 20, and more not being subject to light source 260 during the scene of user's interview room of indoor 230 outer 220 affects definition.

In above narration, the contrast ratio of the known solar energy module 110 of known Fig. 2 is 0.22, and solar energy module 210 its contrast ratios that therefore have absorbed layer 217 and anti-reflecting layer 215 are about 90 times of known solar energy module 110.

Schematic diagram when the solar energy module 210 that Fig. 5 illustrates the another execution mode according to the present invention uses.As shown in the figure, solar energy module 210 comprises the first transparent substrates 212, the first electrode layer 213, photoelectric conversion layer 214, the second electrode lay 216, the second transparent substrates 218 and translucent construction 219.Place different from the embodiment described above is that solar energy module 210 does not have absorbed layer 217 and anti-reflecting layer 215, but the outside of the second transparent substrates 218 (sides near indoor 230) are provided with the second absorbed layer 211.The second absorbed layer 211 is consistent with the effect of absorbed layer 217 both structures and performance, and wherein, " second " only is for the convenience on the appellation.That is to say that the second absorbed layer 211 is positioned on the second transparent substrates 218 side back to the second electrode lay 216.In addition, the second absorbed layer 211 is provided with the transmittance section 222 corresponding with translucent construction 219.In the embodiment shown in fig. 5, translucent construction 219 is a plurality of loopholes, and this transmittance section 222 correspondingly is loophole.The second absorbed layer 211 can or have the column structure of antiradar reflectivity for the black object of high absorptance, and the material of the second absorbed layer 211 can comprise titanium nitride, niobium nitride or black silicon, and black silicon is for example for having the black silicon material of column structure.

Particularly, outdoor 220 incident ray 240 has 200 watts of luminous powers, and incident ray 240 enters indoor 230 emergent ray 250 via translucent construction 219 and transmittance section 222 and has 20 watts luminous power.Have light source 260 this moment indoor 230, so that the second transparent substrates incident ray 262 has 100 watts luminous power.Yet, because solar energy module 210 has anti-reflecting layer 211, the second transparent substrates incident ray 262 can be stopped by the second absorbed layer 211 and can be reflected by the second transparent substrates 218 hardly that therefore the reflection ray 264 of the second transparent substrates incident ray 262 only has 0.5 watt luminous power.Thus, contrast ratio equals the ratio of emergent ray 250 and the luminous power of reflection ray 264, and therefore in the present embodiment contrast ratio is 40, and more not being subject to light source 260 during the scene of user's interview room of indoor 230 outer 220 affects definition.

Solar energy module of the present invention can be the translucent thin-film solar module, as mentioned above.Yet solar energy module of the present invention also can be light-transmission type crystal silicon solar module.Be in the situation of light-transmission type crystal silicon solar module at solar energy module of the present invention, described photo-electric conversion element comprises a plurality of solar cell pieces, described translucent construction is made of the gap between each solar cell piece, and the structure shown in accompanying drawing 1 among the Chinese patent literature CN101533873A is such.

The above-mentioned execution mode of the present invention and prior art are compared, and have the following advantages at least:

(1) when indoor when having light source, though the second transparent substrates has incident ray and enters, but solar energy module has the absorbed layer in the outside (for example between the second electrode lay and the second transparent substrates) that is positioned at photo-electric conversion element, therefore can intercept the second electrode lay the second transparent substrates incident ray is reflected.

(2) producer optionally the side in the second transparent substrates back to absorbed layer (near the i.e. outside of an indoor side) anti-reflecting layer is set, just can reduce again the reflectivity of the second transparent substrates incident ray.

(3) this solar energy module can reduce by absorbed layer and anti-reflecting layer the reflectivity of the second transparent substrates incident ray, allows indoor light that the definition impact of outdoor scene is reduced.

(4) this solar energy module can reduce separately the reflectivity of the second transparent substrates incident ray by the second absorbed layer that is positioned at the second transparent substrates outside, allows indoor light that the definition impact of outdoor scene is reduced.

Although the present invention discloses as above with execution mode; so it is not to limit the present invention; anyly be familiar with this skill person; without departing from the spirit and scope of the present invention; when can being used for a variety of modifications and variations, so protection scope of the present invention is as the criterion when looking the scope that appending claims defines.

Claims (10)

1. solar energy module, it is characterized in that, comprise the first transparent substrates, photo-electric conversion element and the second transparent substrates that stack gradually, described solar energy module has translucent construction, and the outside of the outside of described photo-electric conversion element or described the second transparent substrates is provided with for light-absorbing absorbed layer.

2. solar energy module according to claim 1 is characterized in that, described photo-electric conversion element comprises the first electrode layer, photoelectric conversion layer and the second electrode lay that stacks gradually.

3. solar energy module according to claim 2, it is characterized in that, described solar energy module is the translucent thin-film solar module, and described translucent construction is to penetrate a plurality of loopholes of described photo-electric conversion element or arrange the printing opacity groove more, and described translucent construction penetrates this absorbed layer.

4. solar energy module according to claim 1 is characterized in that, described solar energy module is light-transmission type crystal silicon solar module, and described photo-electric conversion element comprises a plurality of solar cell pieces, and described translucent construction is made of the gap between each solar cell piece.

5. according to claim 3 or 4 described solar energy modules, it is characterized in that the material of described absorbed layer is titanium nitride, niobium nitride or black silicon.

6. solar energy module according to claim 5 is characterized in that, the outside of described the second transparent substrates is formed with anti-reflecting layer, and described anti-reflecting layer is the printing opacity antireflecting coating.

7. solar energy module according to claim 6 is characterized in that, the material of described anti-reflecting layer is MgF ₂, SiO ₂, Si ₃N ₄, ZnS or TiO ₂

8. solar energy module according to claim 1 is characterized in that, is formed with the transmittance section corresponding with described translucent construction on the absorbed layer of the arranged outside of described the second transparent substrates.

9. solar energy module according to claim 8 is characterized in that, the material of described absorbed layer is titanium nitride, niobium nitride or black silicon.

10. solar energy module according to claim 1, it is characterized in that described photoelectric conversion layer is monocrystalline silicon photoelectric conversion layer, polysilicon photoelectric conversion layer, in conjunction with many knots photoelectric conversion layer of amorphous silicon and microcrystal silicon or in conjunction with many knots photoelectric conversion layer of amorphous silicon and amorphous silicon germanium.

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