JP4557622B2 - Solar cell element connection structure and solar cell module including the same - Google Patents

Description

  The present invention relates to a connection structure for connecting electrodes and lead wires for connecting solar cell elements to each other and a solar cell module including the connection structure.

  A solar cell converts incident light energy into electrical energy. Major solar cells are classified into crystalline, amorphous, and compound types depending on the type of materials used. Of these, most of the crystalline silicon solar cells currently on the market are in the market. This crystalline silicon solar cell is further classified into a single crystal type and a polycrystalline type. Single-crystal silicon solar cells have the advantage that the substrate quality is good and the efficiency can be easily increased, but the substrate is expensive to manufacture. On the other hand, the polycrystalline silicon solar cell has the advantage that it can be manufactured at a low cost although it has the disadvantage that it is difficult to increase the efficiency because the quality of the substrate is inferior. Also, recently, conversion efficiency of about 18% has been achieved at the research level due to the improvement of the quality of the polycrystalline silicon substrate and the advancement of element technology.

  On the other hand, mass-produced polycrystalline silicon solar cells have been distributed in the market because of their low cost. However, in recent years, demand has increased further as environmental issues have been addressed, resulting in higher conversion efficiency at lower costs. Is now required.

  In recent years, there has been an increasing demand for further cost reduction. One method for reducing the cost is to increase the area of the solar cell element. The reason is that if the area is increased, the output of the solar cell that can be produced when the same number is produced can be increased. In addition, it has been studied to reduce the cost by thinning the silicon substrate forming the solar cell element and reducing the amount of material used.

  A general configuration of the solar cell element is shown in FIG. 8A is a diagram showing a cross-sectional structure, FIG. 8B is a top view of FIG. 8A, and FIG. 8C is a bottom view.

  As shown in FIG. 8A, P (phosphorus) atoms and the like are diffused at a high concentration on the light incident surface side of the p-type silicon substrate 101 containing B (boron) as a semiconductor impurity. A reverse conductivity type region 102 having a pn junction formed therebetween is formed, and an antireflection film 103 made of a silicon nitride film, a silicon oxide film or the like is further provided. Further, on the opposite side of the light incident surface, a back surface field region 104 containing a large amount of p-type semiconductor impurities such as aluminum is provided. Then, as shown in FIGS. 8B and 8C, a front side electrode 105 (a front side main electrode 105a and a front side collector electrode 105b) mainly composed of silver or the like is provided on the surface side of the solar cell element, and the back side. Are provided with a back side collector electrode 106a made of aluminum or the like and a back side main electrode 106b mainly made of silver or the like. Each of these electrodes is obtained by applying a metal paste containing a predetermined metal powder, an organic solvent, a binder, and the like by screen printing or the like, followed by drying and baking.

In particular, the back-side collector electrode 106a is formed by applying and baking an aluminum paste containing aluminum that acts as a p-type impurity element on the silicon substrate 1, and ap ⁺ region on the back-side surface layer portion of the silicon substrate 1. The back surface electric field region 104 is formed. The back surface field region 104 is also referred to as a BSF (Back Surface Field) region, and serves to reduce the rate of recombination loss when the photogenerated electron carriers reach the back side collector electrode 106a as described above. The current density Jsc is improved. Further, since the minority carrier (electron) density is reduced in the back surface electric field region 104, it functions to reduce the amount of diode current (dark current amount) in the region in contact with the back surface electric field region 104 and the back side collector electrode 106, and is open. The voltage Voc is improved.

  When light enters from the light incident surface, photogenerated carriers are generated in the silicon substrate 1, and an electromotive force is generated between the front side electrode 105 and the back side electrode 106 of the solar cell element. Usually, since a solar cell is a silicon solar cell and has a low voltage of about 600 mV, it is not practical as it is. Therefore, in order to increase the voltage, it is common to increase the voltage by connecting elements in series. For connection, the electrode on the surface and the electrode on the back side of the other solar cell element are connected by a lead wire. In order to connect this lead wire to the solar cell, a main electrode (front side main electrode 105a, back side main electrode 106b) is usually provided where this lead wire passes.

Since the back side collector electrode 106a and the back side main electrode 106b need to be electrically connected to each other, for example, as disclosed in Patent Document 1, silver paste is applied to a region of the back side of the silicon substrate. After drying, a method is used in which an aluminum paste is applied and dried so as to overlap a part of the region, and then fired. Fig.9 (a) is the elements on larger scale of the back side of the solar cell element before baking, FIG.9 (b) is a figure which shows the cross section of this location.
JP-A-5-326990 JP 2000-133826 A

  According to the method described in Patent Document 1 described above, an alloy layer in which aluminum and silver are mutually diffused is formed by firing in a portion where silver and aluminum are overlapped. Specifically, as shown in FIG. 9C, when the aluminum paste and the silver paste are baked, the organic solvent in the paste evaporates as the temperature rises, and then the binder decomposes and evaporates. When the softening point of the glass frit is reached, the glass begins to melt. When the temperature is further increased, aluminum also melts and diffuses to the silver paste side to form an alloy layer.

  At this time, the molten glass component erodes silicon, but the erosion speed is high in the alloy layer portion. Therefore, as shown in FIG. 9C, the thickness of the silicon substrate is locally reduced below the alloy layer. Further, stress is generated at the interface with the silicon substrate surface when an alloy of aluminum and silver is formed. After making the solar cell element, the copper foil is connected to the main electrode as a lead wire in order to modularize it normally. However, when mechanical force is applied to the substrate at this time, cracks are caused by the above problems. There was a problem that it was easy to enter. This alloy is more likely to be generated as the amount of the metal melt generated when firing the silver electrode and the aluminum electrode is larger, and as the temperature is higher and the melt is kept longer. As the number of alloys that cause cracks increases, the thickness of the substrate locally decreases and more alloys are generated, so the stress increases and cracks tend to occur. In particular, a silicon substrate that has been thinned for cost reduction is very prone to cracking when it is further thinned by an alloy, resulting in a significant problem such as a decrease in yield. Furthermore, if firing is performed simultaneously with silver and aluminum, an alloy layer is more likely to be formed and cracks are more likely to occur. Therefore, firing must be performed separately, increasing the number of processes and making it difficult to reduce costs. There was also a problem.

  Moreover, in patent document 2, a silver electrode is apply | coated and baked on an aluminum electrode, a lead wire is connected with this with a solder, and the boundary of an aluminum electrode and a silver electrode does not exist with respect to a silicon substrate. Such a structure is described. According to this structure, since the edge portions of the formed electrodes do not exist on the silicon substrate, the stress concentration can be reduced. However, as a result of an investigation by the inventor, although the effect of reducing the erosion to silicon by the alloy layer of aluminum and silver is somewhat seen, since the silver electrode is applied and baked on the aluminum electrode, aluminum and silver are applied to this portion. It was found that an alloy layer diffused with each other was formed, causing problems such as cracking with the aluminum electrode. Since the method described in Patent Document 2 is configured to connect the lead wire to a portion where this crack is likely to occur, when the solar cell elements are connected to each other and modularized, the change over time There is a high possibility of problems.

  In view of the above-described problems, an object of the present invention is to suppress the erosion of a silicon substrate by an alloy layer of silver and aluminum, to prevent damage even to a thin silicon substrate, and to obtain a reliable and highly reliable solar cell. It is providing the connection structure of the solar cell element for connecting elements, and a highly reliable solar cell module using the same.

In order to achieve the above object, a solar cell element connection structure according to claim 1 of the present invention comprises a silicon electrode provided with a collector electrode formed by applying and baking a paste containing aluminum on the non-light-receiving surface side. and the solar cell element to the substrate, in contact with the collector electrode, and silver comprising at fixing means lead wire is fixed by the unrealized said fixing means are entirely apart from the collector electrode .

The solar cell element connection structure according to claim 2 of the present invention is the solar cell element connection structure according to claim 1, wherein the fixing means is provided on the non-light-receiving surface side of the solar cell element. A lead wire holder formed by applying and baking a paste containing silver that can be fired therein.

  The solar cell element connection structure according to claim 3 of the present invention is the solar cell element connection structure according to claim 2, wherein the lead wire is fixed to the lead wire holder by soldering.

A solar cell element connection structure according to a fourth aspect of the present invention is the solar cell element connection structure according to the first aspect, wherein the lead wire is in contact with a peripheral end portion of the collector electrode .

The solar cell element connection structure according to claim 5 of the present invention is the solar cell element connection structure according to any one of claims 1 to 4 , wherein the light receiving surface of the solar cell element is irradiated with light. In this case, the current that flows in the lead wire flows into the lead wire mainly from the point of contact with the collector electrode.

The solar cell module according to claim 6 of the present invention is a solar cell module in which a plurality of solar cell elements are electrically connected, and includes the solar cell element connection structure of the present invention. Moreover, the solar cell module which concerns on Claim 7 of this invention further has the electroconductive sheet which covers the back surface of the said solar cell element from the said lead wire in the solar cell module of Claim 6.

  The solar cell element connection structure of the present invention is provided with a collector electrode formed by applying and baking a paste containing aluminum on the non-light-receiving surface side, a solar cell element using silicon as a substrate, and a contact with the collector electrode In this state, a lead wire fixed so as not to change the relative position with respect to the solar cell element is included. In this way, the current is collected while the collector electrode and the lead wire are in contact with each other, so the influence of the brittleness of the aluminum electrode itself, the stress of the alloy layer of aluminum and silver, the erosion to the silicon substrate, etc. Can be avoided. Therefore, the risk of breakage even with a thin silicon substrate can be reduced, and a reliable and good connection can be obtained.

  In addition, another solar cell element connection structure of the present invention includes a solar cell element having a silicon substrate provided with a collector electrode formed by applying and baking a paste containing aluminum on the non-light-receiving surface side, And a lead wire electrically connected to the collector electrode by soldering. In this way, the lead wire is soldered directly to the collector electrode, thereby collecting current, so that the influence of the stress due to the alloy layer of aluminum and silver is avoided, and the collector electrode efficiently leads to the lead wire. Can collect current.

  The solar cell module of the present invention is a solar cell module in which a plurality of solar cell elements are electrically connected, and includes the connection structure of the solar cell elements of the present invention. Overcoming problems such as stress caused by alloy formation with the electrode and erosion of the silicon substrate, a highly reliable solar cell module with little secular change can be obtained.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

  FIG. 2 is a schematic sectional view of a solar cell element according to the solar cell element connection structure of the present invention. FIG. 3A is a diagram showing an example of the electrode shape on the light incident surface side (light receiving surface side, surface side), and FIGS. 3B and 3C show the non-light incident surface side (non-light incident surface side). It is a figure which shows an example of the electrode shape of a light-receiving surface side and a back surface side. In the figure, 1 is a silicon substrate, 2 is a reverse conductivity type region on the light receiving surface side, 3 is an antireflection film, 4 is a back surface field region (BSF region), 5 is a front side electrode (5a is a front side main electrode 5a, 5b is a front side) (Collector electrode), 6 is a back side collector electrode, 7 (7a, 7b) is a lead wire holder as a fixing means, and 10 is a solar cell element.

  The structure of the solar cell element 10 according to the solar cell element connection structure of the present invention will be briefly described. As shown in FIG. 2, P (phosphorus) atoms and the like are diffused at a high concentration on the light receiving surface side of a p-type silicon substrate 1 containing B (boron) as a semiconductor impurity, and a pn junction is formed between the p-type silicon substrate and the p-type silicon substrate. A reverse conductivity type region 2 is formed, and an antireflection film 3 made of a silicon nitride film or a silicon oxide film is further provided. Further, on the opposite side of the light receiving surface, a back surface electric field region 4 containing a high concentration of p-type semiconductor impurities such as aluminum is provided. Then, as shown in FIGS. 3A and 3B, on the light receiving surface side of the solar cell element 10, a front side electrode 5 (a front side main electrode 5a, a front side collector electrode 5b) mainly composed of a metal material such as silver is provided. ) And a back side collector electrode 6 mainly composed of aluminum is provided on the non-light-receiving surface side.

  When light is incident from the side of the antireflection film 3 that is the light receiving surface side of the solar cell element 10, it is absorbed and photoelectrically converted in the region of the silicon substrate 1 that is a p-type semiconductor, and electron-hole pairs (electron carriers). And hole carriers). Due to the photo-excited electron carriers and hole carriers (photogenerated carriers), between the front-side electrode 5 provided on the light-receiving surface side of the solar cell element 10 and the back-side collector electrode 6 provided on the non-light-receiving surface side. Photoelectromotive force is generated, and the generated photogenerated carriers are collected by these electrodes and guided to the output terminal.

  As shown in FIG. 3A, the front side electrode 5 is generally a front side main electrode having a large line width to which a front side collector electrode 5b (branch electrode) having a narrow line width and at least one end of the front side collector electrode 5b are connected. It consists of an electrode 5a (stem electrode). In order to reduce the power loss at the front electrode 5 as much as possible, a metal material is usually used, and in particular, silver having a low resistivity is generally the main component. For example, a silver paste is produced by screen printing or the like. Etc. are applied and then baked.

Further, as shown in FIG. 3B and FIG. 3C, a back side collector electrode 6 is provided on the back side of the solar cell element 10. The backside collector electrode 6 is formed on the silicon substrate 1 by applying an aluminum paste containing aluminum that acts as a p-type impurity element by screen printing or the like, and then baking it. A back surface electric field region 4 as a p ⁺ region is formed in the side surface layer portion. The back surface field region 4 is also called a BSF (Back Surface Field) region, and serves to reduce the rate of recombination loss when the photogenerated electron carriers reach the back side collector electrode 6 as described above. The current density Jsc is improved. Further, since the minority carrier (electron) density is reduced in this back surface electric field region 4, it functions to reduce the amount of diode current (dark current amount) in the region in contact with this back surface electric field region 4 and back side collector electrode 6. The voltage Voc is improved.

  Furthermore, the solar cell element 10 according to the present invention is provided with a lead wire holder 7 (7a, 7b) as a fixing means on the back surface side, and when this solar cell element 10 is electrically connected by a lead wire, The lead wire is fixed so as not to change the relative position with respect to the solar cell element.

  The lead wire holder according to the present invention will be described with reference to FIG. 4. First, the lead wire 11 will be described. The lead wire 11 electrically connects the solar cell elements to each other to form a solar cell module described later. In order to improve the characteristics of the solar cell module, a copper foil is usually used because it is necessary to use a low electric resistance. It is desirable to coat the copper foil with solder beforehand. There are various types of solder having different melting points, but the present invention is not limited to this type, and any necessary one may be used.

  FIG. 4 is a partially enlarged view of the lead wire holding body 7 according to the present invention, and FIGS. 4A and 4B show examples of the embodiment. The lead wire holding body 7a shown in FIG. 4A is an example formed in a line shape, and the lead wire holding body 7a and the backside collector electrode 6 of aluminum are separated from each other. 4B is an example in which the lead wire holding body 7b is formed in a dot shape, and the lead wire holding body 7b and the aluminum back side collecting electrode 6 are separated from each other.

  FIG. 5 is a schematic diagram showing a method of configuring the connection structure for solar cell elements of the present invention. FIG. 5 is a diagram in which two solar cell elements are arranged side by side with the back side facing forward, FIG. 5 (a) is before connection by the lead wire 11, and FIG. 5 (b) is a lead wire. 11 shows after connection. In FIG. 5A, the left side of the two solar cell elements is seen through the front main electrode 5a of the front side electrode 5, and the right side is the back side collecting electrode. 6 and the line-shaped lead wire holding body 7a are visible. 1A is a cross-sectional view taken along the line Aa in FIG. 5A, and FIG. 1B is a cross-sectional view taken along the line BB in FIG. 5B.

  As shown in FIG. 1B, the lead wire 11 is fixed to the lead wire holding body 7a while being in contact with and electrically connected to the back side collector electrode 6 mainly composed of aluminum. And the relative position with respect to the solar cell element 10 is not changed. The reason why the effect according to the configuration according to the present invention is obtained is considered as follows.

  First, the baked aluminum paste has a fast oxidation of the surface of the aluminum powder contained therein, so it is difficult to bond with the adjacent aluminum powder, and the aluminum powder is in a state of being laminated without bonding. . Even if the aluminum sintered electrode in such a state is connected via a silver electrode as described in Patent Document 2, the strength is low and the aluminum portion is easily peeled off. In particular, when firing in a state where aluminum and silver are spread in contact with the interface as in Patent Document 2, the interface portion is easily cracked due to shrinkage of the interdiffused alloy layer, and a highly reliable connection is obtained. I can't. In the configuration of the present invention, the lead wire 11 is fixed by the lead wire holding body 7 in a state where the aluminum electrode and the lead wire are in physical contact, and is fixed so as not to be displaced with respect to the solar cell element 10. The current can be collected in a stable state, avoiding the influence of the brittleness of the aluminum electrode itself, the stress of the alloy layer of aluminum and silver, the erosion to the silicon substrate 1, and the risk of breaking even with a thin silicon substrate A good connection with high reliability can be obtained.

  The lead wire holder 7 is preferably formed by applying and baking a paste containing a metal other than aluminum that can be fired in the air. Examples of such metals include gold, platinum, silver, silver-palladium alloy, nickel, and the like. Since such a metal paste sinters each other when fired in the air, and has sufficient mechanical strength, it adheres well to the non-light-receiving surface of the solar cell element. The battery element and the lead wire 11 can have sufficient strength.

  Further, the lead wire holder 7 and the lead wire 11 are preferably connected by soldering. This is because a highly reliable fixing strength can be obtained by a simple method.

  Furthermore, among metals other than aluminum that can be fired in the atmosphere, it is desirable to use silver. The reason is that it is relatively low cost among noble metals and has a low resistance, so that the lead wire holder 7 and the back side collector electrode 6 are partially in contact with each other, and the back side collector electrode 6 is connected to the lead wire holder 7 one by one. Even if a partial current flows, the substantial electric resistance can be reduced by increasing the current path with respect to the lead wire 11, and the flowing current can be effectively taken out to the lead wire 11. It is.

  In the configuration according to the present invention described in FIG. 1A and FIG. 1B described above, even when the lead wire holding body 7 is formed using silver, it does not contact the back side collector electrode 6 made of aluminum. Unlike the prior art described in Patent Document 1 and Patent Document 2, the metal melt generated when firing silver and aluminum forms an alloy with silicon, It is possible to avoid reducing the thickness of silicon.

  However, in the solar cell element connection structure according to the present invention, the lead wire holder 7 made of silver and the back side collector electrode 6 made of aluminum may be in contact with each other as long as cracks are not generated. In particular, when the thickness of the silicon substrate 1 is large (for example, 350 μm or more, etc.), the possibility of cracking due to handling in a later process is reduced, so that they are in contact with each other in terms of reducing the series resistance of the solar cell element 10. This is advantageous because the resistance between the back-side collector electrode 6 and the lead wire 11 becomes smaller.

  Further, in the present invention, the current flowing into the lead wire 11 flows into the lead wire 11 mainly from the point of contact with the back-side collector electrode 6 when the light receiving surface of the solar cell element 10 is irradiated with light. It is desirable to make it. This has the meaning described below. First, as shown in FIG. 1, the back side collector electrode 6 formed of aluminum forms the back surface electric field region 4 between the silicon substrate 1, and therefore when such a solar cell element is irradiated with light. Most of the carriers to be generated are collected by the back side collector electrode 6 and hardly reach the lead wire holder 7a or the like where the back surface electric field region 4 is not formed. However, as described above, when the back side collector electrode 6 made of aluminum is in contact with the lead wire holding body 7 made of silver, the lead wire from the back side collector electrode 6 once out of the current flowing into the lead wire 11. Since there is a portion that flows into the lead wire 11 via the holding body 7, the ratio of flowing directly from the back side collector electrode 6 decreases. Even if the lead wire holding body 7 made of silver and the back side current collecting electrode 6 made of aluminum are in contact with each other by suppressing the ratio of flowing from the back side collecting electrode 6 to the lead wire 11 via the lead wire holding body 7, cracks Can be suppressed to a level at which no occurrence occurs.

  Whether the current flowing from the solar cell element 10 to the lead wire 11 is mainly derived from the back side collector electrode 6 is as follows. The front and back lead wires 11 are connected to the output terminal, and the light receiving surface of the solar cell element 10 The output characteristics when the light is irradiated and an insulator is interposed between the lead wire 11 and the back side collector electrode 6, the front and back lead wires 11 are connected to the output terminal again, and light is applied to the light receiving surface of the solar cell element 10. Can be confirmed by the significant reduction of FF (fill factor) of 0.05 or more.

  Next, another embodiment of the solar cell element connection structure according to the present invention will be described. This is a configuration in which a lead wire 11 is electrically connected by soldering to a back-side collector electrode 6 formed by applying and baking a paste containing aluminum provided on the non-light-receiving surface side. Since aluminum has an oxide film on the surface, it is usually difficult to connect by soldering. However, a flux (for example, SP-20 made by Nippon Almit) is applied to the aluminum electrode side, and a copper foil with solder is applied to this. Soldering can be performed by welding the lead wire 11 at a temperature of about 150 to 300 ° C. As the copper foil solder, so-called lead-free solder (solder containing no lead) containing Sn as a main component may be used, or solder containing Sn—Pb as a main component. Moreover, it is also possible to use the copper foil to which the solder is not applied as the lead wire 11. In addition, since it will cause a corrosion of an electrode if flux remains, it is preferable to wash and remove sufficiently using a predetermined solvent after soldering.

  Next, a process for forming the solar cell element according to the present invention will be described.

The silicon substrate 1 is a single crystal or polycrystalline semiconductor substrate. This substrate may be either p-type or n-type. In the case of monocrystalline silicon, it is formed by a pulling method or the like, and in the case of polycrystalline silicon, it is formed by a casting method or the like. Since polycrystalline silicon can be mass-produced and is much more advantageous than monocrystalline silicon in terms of manufacturing cost, this example will be described using an example using a p-type polycrystalline silicon substrate, which is the most common solar cell. It is desirable to use B (boron) as the p-type doping element, the concentration is about 1 × 10 ¹⁶ to 1 × 10 ¹⁷ / cm ^3, and the specific resistance value of the substrate is about 0.2 to 2 Ω · cm at this time. It becomes.

  A polycrystalline silicon ingot formed by a pulling method or a casting method is cut into a size of about 15 cm × 15 cm and sliced to a thickness of about 300 μm to form the silicon substrate 1. In addition, according to the structure of this invention, even if it is a thin silicon substrate of 300 micrometers or less, the connection structure of a solar cell element can be formed favorably. In addition, in order to remove the mechanical damage layer of the substrate surface layer portion due to the slicing of the substrate, the surface layer portion on the front surface side and the back surface side of this substrate is about 10 to 20 μm each with NaOH, KOH, hydrofluoric acid, hydrofluoric acid, or the like. Etching and then cleaning with pure water or the like.

  Thereafter, it is preferable to form a concavo-convex structure having a light reflectivity reduction function on the substrate surface side which becomes the light receiving surface (not shown). In forming the concavo-convex structure, an anisotropic wet etching method using an alkaline solution such as NaOH used for removing the substrate surface layer portion described above can be applied, but the silicon substrate is a polycrystalline silicon substrate formed by a cast method or the like. In this case, since the crystal plane orientation in the substrate plane varies randomly for each crystal grain, it is very difficult to uniformly form a good concavo-convex structure that can effectively reduce the light reflectance over the entire substrate. It is. In this case, for example, by performing gas etching by the RIE (Reactive Ion Etching) method or the like, a good concavo-convex structure can be formed over the entire substrate relatively easily.

Next, an n-type reverse conductivity type region 2 is formed. As the n-type doping element, P (phosphorus) is preferably used, the doping concentration is about 1 × 10 ^{18 to} 5 × 10 ²¹ / cm ³ , and the sheet resistance is an n ⁺ type having a sheet resistance of about 30 to 300 Ω / □. . As a result, a pn junction is formed with the p-type semiconductor silicon substrate 1.

As a manufacturing method, it is formed by diffusing a doping element in the surface layer portion of the silicon substrate 1 at a temperature of about 700 to 1000 ° C. using a thermal diffusion method using POCl ₃ (phosphorus oxychloride) as a diffusion source. At this time, the thickness of the diffusion layer is about 0.2 to 0.5 μm, and this can be set to a desired thickness by adjusting the diffusion temperature and the diffusion time.

  In a normal diffusion method, a diffusion region is also formed on the surface opposite to the target surface, but this portion may be removed later by etching. At this time, the reverse conductivity type region 2 other than the surface side of the substrate is removed by applying a resist film to the surface side of the silicon substrate, removing the resist film by etching using a mixed solution of hydrofluoric acid and nitric acid. To do. Further, as will be described later, in the present invention, the back surface electric field region 4 (BSF region) on the back surface is formed of aluminum paste, so that aluminum as a p-type dopant can be diffused to a sufficient depth at a sufficient concentration. The influence of the n-type diffusion layer in the shallow region that has already been diffused can be ignored, and it is not necessary to remove the n-type diffusion layer formed on the back side.

  The method of forming the reverse conductivity type region 2 is not limited to the thermal diffusion method. For example, using a thin film technique and conditions, a crystalline silicon film including a hydrogenated amorphous silicon film or a microcrystalline silicon layer is used as a substrate temperature. You may form at about 400 degrees C or less. However, when forming using thin film technology, it is necessary to consider the temperature of each process described below and to determine the order of formation so that the process temperature is as low as the subsequent process.

Next, the antireflection film 3 is formed. As a material of the antireflection film 3, a Si ₃ N ₄ film, a TiO ₂ film, a SiO ₂ film, a MgO film, an ITO film, a SnO ₂ film, a ZnO film, or the like can be used. The thickness is appropriately selected depending on the material, and realizes the non-reflection condition for incident light (if the refractive index of the material is n and the wavelength of the spectral region to be non-reflection is λ, (λ / n) / 4 = d is (This is the optimum film thickness for the antireflection film). For example, in the case of a commonly used Si ₃ N ₄ film (n = about 2), if the non-reflection target wavelength is 600 nm, the film thickness may be about 75 nm.

As a manufacturing method, a PECVD method, a vapor deposition method, a sputtering method, or the like is used, and the film is formed at a temperature of about 400 to 500 ° C. The antireflection film 3 is patterned in a predetermined pattern in order to form the front side electrode 5. As a patterning method, an etching method (wet or dry) used for a mask such as a resist, or a method in which a mask is formed in advance when the antireflection film 3 is formed, and then removed after the antireflection film 3 is formed can be used. As another method, a so-called fire-through method in which the front electrode 5 and the reverse conductivity type region 2 are brought into contact with each other by applying and baking an electrode material directly on the antireflection film 3 is also common. There is no need. This Si ₃ N ₄ film has a surface passivation effect during formation and a bulk passivation effect during subsequent heat treatment, and has the effect of improving the electrical characteristics of the solar cell element together with the antireflection function. is there.

Next, a silver paste is applied to a predetermined position on the front surface of the silicon substrate 1 and an aluminum paste is applied to a predetermined position on the back surface by screen printing or the like, followed by firing, whereby the front side electrode 5 (the front side main electrode 5a, the front side collector electrode 5b). ) And the back side collector electrode 6 are formed. First, according to the present invention on the back side, as the back side collecting electrode 6, an aluminum paste made into a paste by adding 10 to 30 parts by weight of an organic vehicle and 0.1 to 5 parts by weight of glass frit to 100 parts by weight of aluminum powder Is printed and dried in a predetermined shape by, for example, a screen printing method.

  Further, the front electrode 5 and the lead wire holder 7 (if necessary) are formed. These include, for example, a silver paste prepared by adding 10 to 30 parts by weight of an organic vehicle and 0.1 to 5 parts by weight of a glass frit to 100 parts by weight of silver powder. Print in shape and dry.

After the metal paste is applied and dried on the silicon substrate 1 as described above, it is baked by baking at 600 to 850 ° C. for about 1 to 30 minutes. At this time, the back side of the surface of the silicon substrate 1 at the same time diffused aluminum and to form a backside collector electrode 6, p ⁺ the back surface field region 4 to prevent the carriers generated in the back surface recombination (BSF region ) Is formed. The aluminum dope concentration in the p ⁺ region is about 1 × 10 ^{18 to} 5 × 10 ²¹ / cm ³ . Of the metal component in the paste, the metal component that is not used for forming the back surface field region 4 but remains on the back surface field region 4 is used as a part of the back side collector electrode 6 as it is. The back side collector electrode 6 is desirably formed on substantially the entire back surface of the substrate in order to increase the reflectance of the long wavelength light reaching the back surface.

As an electrode material for forming the front-side electrode 5, it is desirable to use a material containing at least one low-resistance metal such as silver, Cu, or aluminum, but silver is most preferable in terms of resistivity. In addition, the metal-containing paste to be the front electrode 5 is directly printed on the antireflection film 3 and baked without patterning the antireflection film 3 by a so-called fire-through method. Electrical contact can be made with the region 2, which is very effective in reducing manufacturing costs. The formation of the front electrode 5 may be performed prior to the formation of the back surface electric field region 4 on the back surface side. Furthermore, in order to particularly increase the adhesive strength between the electrode and the semiconductor region, an oxide component such as TiO ₂ may be slightly included in the paste.

  As described above, the solar cell element according to the present invention can be realized.

  Next, the solar cell module according to the present invention will be described. FIG. 7 is a schematic cross-sectional structure diagram for illustrating a manufacturing process of the solar cell module 18 of the present invention. As shown in the figure, a transparent member 12 made of glass or the like, a front side filler 13 made of a transparent ethylene vinyl acetate copolymer (EVA) or the like, a front electrode and a back electrode of the solar cell element 10 adjacent by the lead wire 11 A plurality of solar cell elements 10 alternately connected to each other, a back side filler 14 made of white EVA, etc., and a back surface protective material 15 in which polyethylene terephthalate (PET) or metal foil is sandwiched between polyvinyl fluoride resins (PVF) By laminating, degassing in a laminator, heating and pressing, EVA is cured and polymerized, and each member is integrated to form a solar cell module. Then, if necessary, a frame (not shown) such as aluminum is fitted around the periphery. Furthermore, one end of the electrodes of the first element and the last element of the plurality of elements connected in series is connected to a terminal box 17 which is an output extraction portion by an output extraction wiring 16.

  In this solar cell module, the connection structure between the back electrode of the solar cell element 10 and the lead wire 11 is the above-described solar cell element connection structure of the present invention, so that the reliability is high. In the solar cell module of the present invention, at least one of the solar cell modules may have the solar cell element connection structure of the present invention. However, if all have the solar cell element connection structure of the present invention, the solar cell module is most favorable. Since the effects of the invention can be obtained, it is preferable.

  As described above, the solar cell element connection structure of the present invention and the solar cell module using the same can be realized.

  It should be noted that the embodiment of the present invention is not limited to the above-described example, and it is needless to say that various modifications can be made without departing from the gist of the present invention. In addition, the configurations described in the claims and clarified in the above-described embodiment can be used in combination of two or more unless a contradiction arises. Examples of embodiments belonging to the scope of the present invention will be described below.

  For example, as shown in FIG. 6, as the fixing means, an inorganic or organic adhesive 8 or a thermosetting resin may be used to join the lead wire 11 and the solar cell element 10 together. Such an adhesive 8 does not erode the silicon substrate 1 because it forms a metal melt with the aluminum backside collector electrode 6 and does not form an alloy layer with silicon. There is no problem whether such an adhesive 8 is in contact with the back side collector electrode 6 or not. Moreover, since it shrink | contracts when adhere | attaching, the effect that the contact property between the lead wire 11 and the back side collector electrode 6 of aluminum improves is also acquired.

  In particular, when a thermosetting resin is used as a fixing means, an ethylene vinyl acetate copolymer (EVA) serving as a module member is used as a thermosetting resin, and thus the solar cell module 18 is manufactured at the time of manufacturing the solar cell module 18 described above. The module 18 is sealed, and the lead wire 11 may be fixed while being in contact with the aluminum electrode at the same time. In this case, in order to further improve the reliability, it is preferable to seal with EVA with a conductive sheet (aluminum foil or the like) covered from the top of the lead wire 11 so as to cover the entire back surface of the solar cell. In the case of FIG. 1 (b), the copper foil of the lead wire 11 and the aluminum electrode are in contact with each other at the peripheral edge of the aluminum, but the conductive sheet is covered with the aluminum electrode and the aluminum sheet. This is because it comes into contact with the copper foil and the conductivity is improved. In addition, this conductive sheet plays the role of a wedge, urges the copper foil of the lead wire 11 against the aluminum electrode, and improves the mutual adhesion, thereby improving the reliability of the solar cell module, It becomes possible to take a good continuity.

  In addition, an example in which solder is used when electrically connecting the aluminum backside collector electrode 6 and the copper foil of the lead wire 11 or connecting the lead wire holding body 7 and the lead wire has been described. However, the present invention is not limited to this, and ultrasonic welding may be performed. This is a general method for performing physical welding and is called an ultrasonic welder. In this method, the amplitude of the horn tip is amplified by a horn coupled to an ultrasonic transducer, and the object to be welded is brought into contact with the horn tip to change the vibration into heat and weld. When this method is used, it is desirable to increase the amount of aluminum paste applied. This is because if the coating amount is small, ultrasonic vibrations may be transmitted to a brittle silicon substrate and cracked.

  The front-side electrode 5 on the light-receiving surface side may be printed and baked simultaneously with the back-side collector electrode 6, or may be printed and baked by changing the order of the front and rear. In the present invention, the method of applying the aluminum paste first and then applying the silver paste is shown, but the reverse is also possible. In addition, although the case where two of aluminum and silver are fired simultaneously has been described as an example, the present invention is effective even when fired separately.

It is sectional structure drawing of the connection structure of the solar cell element of this invention, (a) is arrow sectional drawing of the Aa line of Fig.5 (a), (b) is B- of Fig.5 (b). It is arrow sectional drawing of a b line. It is a schematic sectional drawing of the solar cell element which concerns on the connection structure of the solar cell element of this invention. The solar cell element which concerns on the connection structure of the solar cell element of this invention WHEREIN: (a) is a figure which shows an example of the electrode shape of the light-incidence surface side (light-receiving surface side, surface side), (b) and (c) These are figures which show an example of the electrode shape of the non-light-incident surface side (non-light-receiving surface side, back surface side). It is the elements on larger scale of the lead wire holder 7 concerning the present invention, and (a) and (b) all show the example of an embodiment. It is a schematic diagram which shows the method of comprising the connection structure of the solar cell element of this invention, (a) is before connecting with a lead wire, (b) shows after connecting with a lead wire. It is sectional drawing which shows another example of the connection structure of the solar cell element of this invention. It is typical sectional structure drawing for showing the manufacturing process of the solar cell module of this invention. It is a figure which shows the general structure of a solar cell element, (a) is sectional structure, (b) is a top view of (a), (c) is a bottom view. The position of the collector electrode which consists of aluminum, and the position of the silver main electrode is shown, (a) is the elements on larger scale of the back side of the solar cell element before baking, (b) is before baking of the (a) part. (C) shows the cross section after firing of part (a).

Explanation of symbols

1: Silicon substrate 2: Reverse conductivity type region 3: Antireflection film 4: Back surface electric field region 5: Front side electrode 5a: Front side main electrode 5b: Front side collector electrode 6: Back side collector electrode 6a: Back side collector electrodes 7, 7a, 7b: Lead wire holder (an example of fixing means)
8: Adhesive (an example of fixing means)
10: Solar cell element 11: Lead wire 12: Transparent member 13: Front side filler 14: Back side filler 15: Back side protective material 16: Output extraction wiring 17: Terminal box 18: Solar cell module 101: Silicon substrate 102: Reverse conductivity Type region 103: Antireflection film 104: Back surface electric field region 105: Front side electrode 105a: Front side main electrode 105b: Front side collector electrode 106: Back side collector electrode 106a: Back side collector electrode 106b: Back side main electrode

Claims (7)

A solar cell element having a silicon substrate, provided with a collector electrode formed by applying and baking a paste containing aluminum on the non-light-receiving surface side,
In contact with the collector electrode, unrealized and lead wire is fixed by fixing means comprising silver,
The fixing means is a connection structure of solar cell elements , the entirety of which is separated from the collector electrode . 2. The sun according to claim 1, wherein the fixing means is a lead wire holder formed by applying and baking a paste containing silver that can be baked in the atmosphere, provided on the non-light-receiving surface side of the solar cell element. Battery element connection structure.   The solar cell element connection structure according to claim 2, wherein the lead wire is fixed to the lead wire holder by soldering. The solar cell element connection structure according to any one of claims 1 to 3, wherein the lead wire is in contact with a peripheral end portion of the collector electrode. 5. The current flowing in the lead wire when light is applied to the light receiving surface of the solar cell element flows into the lead wire mainly from a position in contact with the collector electrode. 6. Connection structure of the solar cell element as described in any one . A solar cell module in which a plurality of solar cell elements are electrically connected, and includes the solar cell element connection structure according to any one of claims 1 to 5 . The solar cell module according to claim 6, further comprising a conductive sheet covering the back surface of the solar cell element from above the lead wire.

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