CASCADED PHOTOVOLTAIC STRUCTURES WITH INTERDIGITATED BACK CONTACTS
A solar module is provided. The solar module includes a number of photovoltaic structures. Each photovoltaic structure has an interdigitated back contact, and the photovoltaic structures are cascaded, wherein any two adjacent structures are electrically coupled by overlapping their edges.
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This relates to solar panel fabrication, including the design of a solar panel having cascaded photovoltaic structures with interdigitated back contacts.
DEFINITIONS“Solar cell” or “cell” is a photovoltaic structure capable of converting light into electricity. A cell may have any size and any shape, and may be created from a variety of materials. For example, a solar cell may be a photovoltaic structure fabricated on a silicon wafer or one or more thin films on a substrate material (e.g., glass, plastic, or any other material capable of supporting the photovoltaic structure), or a combination thereof.
A “solar cell strip,” “photovoltaic strip,” or “strip” is a portion or segment of a photovoltaic structure, such as a solar cell. A solar cell may be divided into a number of strips. A strip may have any shape and any size. The width and length of a strip may be the same or different from each other. Strips may be formed by further dividing a previously divided strip.
A “cascade” is a physical arrangement of solar cells or strips that are electrically coupled via electrodes on or near their edges. There are many ways to physically connect adjacent photovoltaic structures. One way is to physically overlap them at or near the edges (e.g., one edge on the positive side and another edge on the negative side) of adjacent structures. This overlapping process is sometimes referred to as “shingling.” Two or more cascading photovoltaic structures or strips can be referred to as a “cascaded string,” or more simply as a string.
“Finger lines,” “finger electrodes,” and “fingers” refer to elongated, electrically conductive (e.g., metallic) electrodes of a photovoltaic structure for collecting carriers.
A “busbar,” “bus line,” or “bus electrode” refers to an elongated, electrically conductive (e.g., metallic) electrode of a photovoltaic structure for aggregating current collected by two or more finger lines. A busbar is usually wider than a finger line, and can be deposited or otherwise positioned anywhere on or within the photovoltaic structure. A single photovoltaic structure may have one or more busbars.
A “photovoltaic structure” can refer to a solar cell, a segment, or solar cell strip. A photovoltaic structure is not limited to a device fabricated by a particular method. For example, a photovoltaic structure can be a crystalline silicon-based solar cell, a thin film solar cell, an amorphous silicon-based solar cell, a poly-crystalline silicon-based solar cell, or a strip thereof.
A “front side” of a photovoltaic structure refers to the side of the structure that is typically used to absorb direct sunlight.
A “back side” of a photovoltaic structure refers to the side of the structure that is typically facing away from direct sunlight.
An “emitter” refers to a part of a photovoltaic structure that collects carriers, either holes or electrons. An emitter can also be referred to as a surface field (SF) layer, which can be a back surface field (BSF) layer or a front-surface field (FSF) layer, if such an emitter has the same conductivity type as that of the base layer. In general, a P-type emitter collects holes generated by the solar cell (i.e., it “emits” P-type carrier, or holes, to an external circuit) and an N-type emitter collects electrons (i.e., it “emits” N-type carrier, or electrons, to an external circuit). Hence, a P-type emitter may also be called a hole collector, and an N-type emitter may also be called an electron collector.
RELATED ARTAdvances in photovoltaic technology, which are used to make solar panels, have helped solar energy gain mass appeal among those wishing to reduce their carbon footprint and decrease their monthly energy costs. The energy conversion efficiency of photovoltaic structures has always been the focus of solar technology development. The latest photovoltaic structure designs have produced solar cells with efficiencies of 20% or higher, while the pursuit for more efficient devices continues.
A solar module is provided that includes a number of photovoltaic structures. Each structure has an interdigitated back contact. The photovoltaic structures are also cascaded, wherein two adjacent structures are electrically coupled by overlapping their edges.
In the figures, like reference numerals refer to the same figure elements.
DETAILED DESCRIPTIONThe following description is presented to enable any person skilled in the art to make and use the embodiments, and is provided in the context of a particular application and its requirements. Various modifications to the disclosed embodiments will be readily apparent to those skilled in the art, and the general principles defined herein may be applied to other embodiments and applications without departing from the spirit and scope of the present disclosure. Thus, the present invention is not limited to the embodiments shown, but is to be accorded the widest scope consistent with the principles and features disclosed herein.
OverviewEmbodiments of the present invention solve the problem of front-side electrode shading on a solar cell and the presence of gaps between solar cells in a module by providing a tunneling-junction solar cell with interdigitated back contacts (IBC) and cascading such solar cells to reduce the size the gaps space between them.
In particular, solar cells with IBC can be coupled with one another in a cascaded or “shingled” manner, such that little or no gap is present between two adjacent cells. Furthermore, the front side of a string of cascaded IBC cells can be free of electrodes and gaps, which increases the area that can absorb light.
Note that because both N-type and P-type contacts are on the same side (the back side) of an IBC cell, one type of polarity, either N or P, can be coupled to a front electrode contact, which facilitates the shingling of two adjacent cells.
With respect to the structure of solar cells, an IBC solar cell can include a lightly doped base layer with its front and back sides covered with a thin layer of silicon oxide serving as a quantum-tunneling-barrier (QTB) layer. An electron collector region and hole collector region, often formed in finger-like shapes, form an interdigitated pattern on the back side of the solar cell. Electron-collecting and hole-collecting electrodes can then be formed on the electron collector region and hole collector region, respectively. These electrodes can in turn form the interdigitated back contact (IBC) for the solar cell. The electron collector region can include P-type doped hydrogenated a-Si or conductive oxide (CO) the work function of which has an absolute value within a small range (e.g., 0.1-0.3 eV) near or less than the value of the conduction band edge of the base layer (which can be, for example, lightly-doped c-Si). The hole collector region can include N-type doped a-Si or CO the work function of which has an absolute value within a small range (e.g., 0.1-0.3 eV) near or greater than the value of the valence band edge of the base layer (which can be, for example, lightly-doped c-Si). Using conductive oxide materials with properly tuned work functions (as described above with respect to electron collector and hole collector) can obviate the need of using doped a-Si materials as electron and hole collectors, respectively.
Furthermore, instead of using opaque conductive materials, a transparent conductive material (such as transparent conductive oxide, TCO) can be used to form an ohmic contact layer between the semiconductor structure and the electrode. Using transparent instead of opaque conductive layers can allow the solar cell to operate in a bi-facial mode, wherein light can be absorbed from both the front side and back side. More details on the bi-facial configuration of IBC solar cells are provided below in conjunction with the description for
To improve passivation, a thin layer of intrinsic a-Si can be positioned between the back side QTB layer and the electron and hole collector regions. In addition, the electrodes can be based on any conductive material (such as copper or other metallic materials) and formed using electroplating, physical vapor deposition, or a combination thereof. Because all electrical connections are on the back side of the solar cell, and because the back side of the cell can now be transparent, the tunneling junction solar cells with IBCs can absorb light from both front and back sides, which results in higher cell efficiency. Moreover, the IBC configuration can facilitate more efficient module fabrication and modules with a higher packing factor, because it is no longer necessary to weave the connecting tabs from one side of a solar cell to the other side of an adjacent solar cell.
Cascaded IBC Solar CellsAs shown in
Note that using conductive layer 314 to couple back-side busbar 316 to front-side busbar is one of many ways to electrically and mechanically couple the back-side finger lines of a cell to a busbar on the front side. For example,
In addition to the cascading layout shown in
Similarly, conductive layer 424 connects P-type back-side busbar 422 to corresponding front-side busbar 426, which is coupled to N-type back-side busbar 428 of cell 408 by conductive paste 420. Note that the structures shown in
Base layer 502 may include a layer of c-Si that is epitaxially grown, for example, or a c-Si wafer cut from an ingot obtained via the Czochralski (CZ) or floating zone (FZ) process, and is lightly doped with either N-type or P-type dopants. The thickness of base layer 502 can be between 80 and 200 μ. In some embodiments, the thickness of base layer 502 is between 80 and 120 μm, which can be an optimized thickness for reducing carrier recombination rate. The resistivity of base layer 302 can be between 1 ohm-cm and 10 ohm-cm. In one embodiment, the resistivity of base layer 502 is between 1 ohm-cm and 5 ohm-cm, which allows for efficient power extraction and yet provides sufficient physical support for the entire device, and the bulk minority carrier lifetime (MCL) is at least 1 ms. In a further embodiment, base layer 502 can be graded-doped with N-type dopants, and can include a textured surface for reducing light reflection and increasing absorption.
QTB layers 504 and 506 can be in direct or indirect contact with base layer 502, and can include a dielectric thin film and/or a layer of wide bandgap semiconductor material with low or no doping. Exemplary materials used for the dielectric thin film include, but are not limited to: silicon oxide (SiOx), hydrogenated SiOx, silicon nitride (SiNx), hydrogenated SiNx, silicon oxynitride (SiON), hydrogenated SiON, aluminum oxide (AlOx or Al2O3), and aluminum nitride (AlNx). Examples of the wide bandgap materials include, but are not limited to: amorphous Si (a-Si), hydrogenated a-Si, carbon doped a-Si, and silicon carbide (SiC). In one embodiment, back QTB layer 306 can include SiOx, such as SiO or SiO2, and/or hydrogenated SiOx. Front QTB layer 304 can include one or more of: intrinsic a-Si, amorphous SiO, SiOx, SiNx, and Al2O3. The SiOx or hydrogenated SiOx layer can be formed using various oxidation techniques, such as submerging the wafer in hot deionized water (DIW), low-pressure radical oxidation, ozone oxygen oxidation, atomic oxygen oxidation, thermal oxidation, chemical oxidation, steam or wet oxidation, atomic layer deposition, ozone bubbling in DIW, and plasma-enhanced chemical-vapor deposition (PECVD). The thickness of QTB layers 504 and 506 can be between 1 and 20 angstroms. In general, a thin QTB layer can have a stronger tunneling effect but is less effective at passivation. A thick QTB layer can have better passivation effect but might reduce cell efficiency due to less tunneling effect. In one embodiment, QTB layers 504 and 506 can each include a SiOx layer having a thickness approximately between 8 and 15 angstroms to obtain effective passivation and sufficient tunneling effect. In some embodiments, the Dit of QTB layers 504 and 506 can be less than 5×1011/cm2.
ARC layer 508 can be deposited on front QTB layer 504 to maximize the amount of light absorbed by solar cell 500. In some embodiments, ARC layer 508 can include one or more of: transparent conductive oxide (TCO), SiNx, SiOx, and AlxO3.
Intrinsic a-Si layer 510 can be deposited directly or indirectly on back QTB layer 506. In some embodiments, the thickness of intrinsic a-Si layer 510 can range between 5 Å and 100 Å. In a further embodiment, the thickness of intrinsic a-Si layer 510 can be approximately 10-50 Å, preferably 20-40 Å. Intrinsic a-Si layer 510 can be deposited using a plasma-enhanced chemical-vapor deposition (PECVD) technique. Optional intrinsic a-Si layer 510 can further reduce minority carrier recombination.
Carrier collector layer 512 can include interdigitated-patterned (e.g., interleaved, parallel fingers) P-type emitters and N-type emitters. More specifically, N-type emitters, such as emitter 514, can include P-type doped a-Si, and can be in contact with intrinsic a-Si layer 510. In some embodiments, the N-type emitters can include hydrogenated a-Si with a graded doping profile. If base layer 502 is N-type doped, the N-type emitters can have the opposite electrical conductivity type to base layer 502. The P-type doped a-Si layer, intrinsic a-Si layer 510, QTB layer 506, and base layer 502 together form a hetero tunneling back junction. The doping concentration can determine the contact resistance with the electrode. In addition, a high doping concentration and a thick doped layer can result in higher built-in potential, which in turn can result in stronger tunneling effect. In some embodiments, the N-type emitters (which have an opposite conductivity type to that of N-type doped base layer 502) can have a thickness between 3 and 20 nm and a doping concentration between 1×1015/cm3 and 5×1020/cm3 to obtain desired ohmic contact resistance and built-in potential.
Similarly, P-type emitters, such as emitter 516, can include N-type doped a-Si, and be in contact with intrinsic a-Si layer 510. In some embodiments, the P-type emitters can include hydrogenated a-Si with a graded doping profile. If base layer 502 is N-type doped, the P-type emitters have the same electrical conductivity type to base layer 502. In some embodiments, the P-type emitters can have a thickness between 1 and 30 nm and a doping concentration between 1×1015/cm3 and 5×1020/cm3 to obtain esired ohmic contact resistance and built-in potential. The interdigitated pattern can facilitate multiple P-type emitter contacts to the underlying intrinsic a-Si layer 510 and QTB layer 506. The interdigitated pattern of both the N-type and P-type emitters allows adjacent emitters have opposite conductivity doping types. Forming the emitters can involve epitaxially growing doped Si over one or more patterned masks, and hence carefully designed masks can ensure gaps of appropriate size are maintained between the emitters of opposite doping types. This prevents the formation of a short circuit between electrodes of opposite polarities.
Electrodes deposited on the P-type and N-type emitters, such as electrodes 518 and 520, provide electrical coupling to the emitters. The electrodes can be made of metallic or non-metallic materials. As shown in
In some embodiments, conductive oxide (CO) layer 522 can be formed between carrier collector layer 512 and the electrode metallic layer. CO layer 522 can facilitate the formation of good ohmic contact to the P-type and N-type emitters. In some embodiments, CO layer 522 can include one or more transparent conductive oxide (TCO) materials. As a result, the back side of solar cell 500 can be transparent, either entirely or partially, in areas not covered by the electrodes. Using TCO allows solar cell 500 to receive and absorb light incident on its back side, which in turn allows solar cell 500 to operate in a bi-facial mode.
CO layer 522 can be deposited, for example, using one or more of the following techniques: plasma vapor deposition, thermal evaporation, ion plating, and remote plasma deposition. The electrode layer can be deposited on CO layer 522 or directly on the P-type or N-type doped a-Si. In some embodiments, the electrode layer is electrically conductive, and can include one or more layers of metal, such as Cu, Ag, Ni, etc. Various techniques, including but not limited to: physical vapor deposition (PVD), screen printing, evaporating, inkjet printing, aerosol printing, electro- or electroless plating with patterning can be used to deposit the one or more metallic layers. In one embodiment, the metallic electrodes can include copper, and can be formed using an electroplating technique. In a further embodiment, a seed layer of copper can be deposited using a PVD process, and bulk copper can be formed on the seed layer using an electroplating process. More details on how to form an electroplated metal grid on a photovoltaic structure can be found in U.S. patent application Ser. No. 13/220,532, entitled “SOLAR CELL WITH ELECTROPLATED METAL GRID,” by inventors Jianming Fu, Zheng Xu, Chentao Yu, and Jiunn Benjamin Heng, the disclosure of which is hereby incorporated by reference in its entirety herein.
Instead of using a-Si based emitters the N-type or P-type emitters can be formed using CO materials (which can be transparent or opaque), without using any doped a-Si material.
Base layer 602, front and back QTB layers 604 and 606, ARC layer 608, and intrinsic a-Si layer 610 can be similar to base layer 502, front and back QTB layers 504 and 506, ARC layer 508, and intrinsic a-Si layer 510, respectively. However, instead of graded doped a-Si, CO layer 612 (which can include two types of CO materials deposited in two or more steps) can be deposited onto and in direct contact with intrinsic a-Si layer 610 or back QTB layer 606 (if a-Si layer 610 is not present). As shown in
As mentioned above, to collect holes, instead of using N-type doped a-Si, a high work function CO material can be used. Ideally, this high work function CO material has a work function whose absolute value is within a small range (e.g., 0.3 eV) near or greater than the value of the valence band edge, Ev, of the c-Si (lightly doped or intrinsic) used in base layer 602, which is approximately 5.17 eV, for example. When interfaced with c-Si base layer 602, this high work function CO region (such as CO region 616) can create a built-in electrical field that can draw the holes away from base layer 602 where carriers (i.e., both electrons and holes) are generated. Because the CO material's work function is relatively large, the potential difference at this interface is large enough to cause the holes to tunnel through back side QTB layer 606. If base layer 602 is N-type doped, this high work function CO layer can function as a surface field region, because it attracts minority carriers (e.g., holes). If base layer 603 is P-type doped, this high work function CO layer can function as an emitter region, because it attracts majority carriers (e.g., holes).
Similarly, to collect electrons, instead of using P-type doped a-Si, a low work function CO material can be used. Ideally, this low work function CO material has a work function whose absolute value is within a small range (e.g., 0.1 eV to 0.3 eV) near or less than the value of the conduction band edge of the c-Si (lightly doped or intrinsic) used in base layer 602. When interfaced with c-Si base layer 602, this low work function CO region (such as CO region 614) can create a built-in electrical field that can draw the electrons away from base layer 602. Because the CO material's work function is small enough, the potential difference at this interface is large enough to cause the electrons to tunnel through back side QTB layer 606. If base layer 602 is N-type doped, this low work function CO layer can function as an emitter, because it attracts majority carriers (e.g., electrons). If base layer 602 is P-type doped, this low work function CO layer can function as a surface field region, because it attracts minority carriers (e.g., electrons).
Furthermore, because of the passivation effect of intrinsic a-Si layer 610, the CO film can be formed with a low interface defect density. In one embodiment, the interface defect density (Dit) can be less than 1e11/cm2, which makes it possible to eliminate the Fermi-level pinning effect at the CO-semiconductor interface. The Fermi-level pinning effect can be caused by the surface states associated with the defects and would make energy band bending nearly impossible on the semiconductor side. As a result of Fermi-level pinning, the Schottky barrier height can be insensitive to the conductor's (which in this case is the CO material) work function. Because of the low interface defect density resulting from intrinsic a-Si layer 610, the carrier transportation property can now be manipulated based on Fermi level of the CO layer. Consequently, the degenerated carrier distribution in the CO layer with an appropriate work function and the low Dit make it possible to have a strong tunneling effect when the CO/intrinsic a-Si/QTB structure is in contact with a lightly doped c-Si base. The tunneling process can depend on the available carrier concentration at the starting side (the c-Si side) and the density of states at the receiving side (the CO side), according to the Wentzel-Kramers-Brillouin (WKB) approximation.
In one embodiment, when CO materials with different work functions are used as electron and hole collectors instead of P-type and N-type doped a-Si, the CO materials can be transparent, opaque, or partially transparent. In one embodiment, the high work function and low work function CO materials are transparent (i.e., both are TCO materials). As a result, the solar cell can absorb light from both the front and back sides. Such solar cells can then be used to build bi-facial solar panels, which can produce more energy than conventional single-sided solar panels.
Although the exemplary device structures shown in
In a further embodiment, the electron collector and hole collector can be formed using opaque CO materials with different work functions. Alternatively, the electron collector and hole collector can be formed using P-type doped a-Si and N-type doped a-Si, respectively. These two regions can then be covered by the same transparent or opaque CO material.
Now assuming that the open circuit voltage (Voc) across a standard 6-inch solar cell is Voc_cell, then the Voc of each string is m×n×Voc_cell, wherein m is the number of smaller strips as the result of dividing a conventional square shaped cell, and n is the number of conventional cells included in each string. On the other hand, assuming that the short circuit current (Isc) for the standard 6-inch solar cell is Isc_cell, then the Isc of each string is Isc_cell/m. Hence, when m such strings are connected in parallel in a new panel configuration, the Voc for the entire panel can be the same as the Voc for each string, and the Isc for the entire panel will be the sum of the Isc of all strings. More specifically, with such an arrangement, one can achieve: Voc-panel=m×n×Voc_cell and Isc_panel=Isc_cell. This means that the output voltage and current of this new solar panel will be comparable to the output voltage and current of a more conventional solar panel of a similar size but with undivided solar cells all connected in series. The similar voltage and current outputs make this new panel compatible with other devices, such as inverters, that are used by a conventional solar panel with all its undivided cells connected in series. Although having similar current and voltage output, the new solar panel can extract more output power to external load because of the reduced total internal resistance.
In the example shown in
Furthermore, the total internal resistance of panel 1000 is significantly reduced. Assume that the internal resistance of a conventional cell is Rcell. The internal resistance of a smaller strip is Rsmall_cell=Rcell/3. In a conventional panel with 72 conventional cells connected in series, the total internal resistance is 72Rcell. In panel 1000 as illustrated in
In the example shown in
Other configurations of the strip size and number of strings can also be used. For example, each strip can be ⅓, ¼, ⅕, or other fraction of a conventional-sized solar cell. Correspondingly, a solar cell can be scribed and cleaved into the properly sized strips with an automated tool. The strips can then be shingled into strings.
In the example shown in
Furthermore, the total internal resistance of panel 1100 is significantly reduced. Assume that the internal resistance of a conventional cell is Rcell. The internal resistance of a smaller strip is Rsmall_cell=Rcell/5. In a conventional panel with 72 conventional cells connected in series, the total internal resistance is 72Rcell. In panel 1100, each string has a total internal resistance Rstring=72 Rsmall_cell=14.4 Rcell. Since panel 1100 has 5 U-shaped strings connected in parallel, the total internal resistance for panel 1100 is Rstring/5=2.88 Rcell, which is 1/25 of the total internal resistance of a conventional panel. As a result, the amount of power that can be extracted to external load can be significantly increased.
The foregoing descriptions of various embodiments have been presented only for purposes of illustration and description. They are not intended to be exhaustive or to limit the present invention to the forms disclosed. Accordingly, many modifications and variations will be apparent to practitioners skilled in the art. Additionally, the above disclosure is not intended to limit the present invention.
Claims
1. A solar module, comprising:
- a plurality of photovoltaic structures, each having a front side, a back side, and an interdigitated back contact;
- wherein each photovoltaic structure comprises a first edge and a second edge opposite to the first edge;
- wherein the plurality of photovoltaic structures include first, second, and third structures, wherein the second structure is adjacent to and positioned between the first and third structures;
- wherein each of the first and third structures comprises: first and second front edge busbars positioned on the first and second edges, respectively, of the front side of the structure, and first and second back edge busbars positioned on the first and second edges, respectively, of the back side of the structure; and
- wherein the first and second edges of the second structure are coupled with and positioned above the second edge of the first structure and first edge of the third structure, respectively.
2. (canceled)
3. The solar module of claim 1, wherein the first front edge busbar is electrically coupled to the first back edge busbar; and
- wherein the second front edge busbar is electrically coupled to the second back busbar.
4. The solar module of claim 3, wherein the first front edge busbar is electrically coupled the first back edge busbar using a via or a heavily doped region internal to the first or third structure.
5. (canceled)
6. (canceled)
7. The solar module of claim 1, wherein the first and second structures are electrically and mechanically coupled by a conductive paste.
8-14. (canceled)
15. A solar cell, comprising:
- a semiconductor structure having a front side and a back side;
- a back contact located on the back side of the structure, wherein the contact comprises: a first plurality of finger lines having a first polarity; a second plurality of finger lines having a second polarity that is opposite the first polarity, wherein the first and second pluralities of finger lines are interdigitated; a first back edge busbar positioned on a first edge of the back side of the structure and electrically connected to the first plurality of finger lines; and a second back edge busbar positioned on a second edge of the back side of the structure and electrically connected to the second plurality of finger lines;
- a first front edge busbar located on the first edge of the front side of the structure, wherein the first front edge busbar is electrically coupled to the first back edge busbar; and
- a second front busbar located on the second edge of the front side of the structure, wherein the second front edge busbar is electrically coupled to the second back edge busbar.
16. (canceled)
17. The solar cell of claim 15, wherein the first or second front edge busbar is coupled to the first or second back edge busbar, respectively, using one or more vias.
18. The solar cell of claim 15, wherein the first or second front edge busbar is coupled to the first or second back edge busbar, respectively, using one or more heavily doped regions internal to the semiconductor structure.
19. (canceled)
20. (canceled)
21. (canceled)
22. The solar module of claim 1,
- wherein the second photovoltaic structure comprises a first edge busbar near the first edge of the back side and a second edge busbar near the second edge of the back side.
23. The solar module of claim 22, wherein the first structure and second structure are electrically coupled to each other by overlapping the second front edge busbar of the first structure with the first edge busbar of the second structure.
24. (canceled)
25. The solar module of claim 22, wherein the third structure and second structure are electrically coupled to each other by overlapping the first front edge busbar of the third structure with the second edge busbar of the second structure.
26. The solar module of claim 1, wherein the third and second structures are electrically and mechanically coupled by a conductive paste.
Type: Application
Filed: Oct 18, 2016
Publication Date: Apr 19, 2018
Applicant: SolarCity Corporation (San Mateo, CA)
Inventors: Jiunn Benjamin Heng (Los Altos Hills, CA), Peter J. Rive (San Mateo, CA), Zhigang Xie (San Jose, CA), Bobby Yang (Los Altos Hills, CA)
Application Number: 15/297,039