JP5870196B2 - Dye-sensitized solar cell element - Google Patents

Description

  The present invention relates to a dye-sensitized solar cell element.

  As a photoelectric conversion element, a dye-sensitized solar cell element has attracted attention because it is inexpensive and can provide high photoelectric conversion efficiency, and various developments have been made on the dye-sensitized solar cell element.

  The dye-sensitized solar cell element generally includes a dye-sensitized solar cell, and the dye-sensitized solar cell includes a working electrode, a counter electrode, and an annular sealing portion that connects the working electrode and the counter electrode. Yes. The working electrode has a transparent substrate and a transparent conductive film formed thereon.

  As such a dye-sensitized solar cell element, for example, an element described in Patent Document 1 below is known. Patent Document 1 below discloses a dye-sensitized solar cell module having a plurality of dye-sensitized solar cells connected in series. In the dye-sensitized solar cell module of Patent Document 1 below, a plurality of dye-sensitized solar cells include a substrate and a conductive film provided on the substrate, and the conductivity included in the plurality of dye-sensitized solar cells. The films are arranged on a substrate via a groove formed by a laser scribing method or the like, and a porous insulating layer containing a carrier transport material containing a redox species enters the groove.

  Moreover, the element of the following patent document 2 is also known as a dye-sensitized solar cell element. Patent Document 2 listed below includes a dye-sensitized solar cell having a pair of electrodes, an electrolyte layer provided between the pair of electrodes, and a sealing material that connects the pair of electrodes around the electrolyte layer, A photoelectric conversion device having a back sheet provided so as to cover one of the electrodes and to be bonded to a sealing material is disclosed.

JP 2010-3557 A JP 2006-100069 A

  However, both of the dye-sensitized solar cell modules described in Patent Documents 1 and 2 have room for improvement in terms of durability.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a dye-sensitized solar cell element having excellent durability.

  The present inventors examined the cause of the above problem in the dye-sensitized solar cell module of Patent Document 1. As a result, when a groove formed between the conductive films is formed on the substrate by a laser scribing method or the like, a crack is formed inside the substrate and below the groove, and the crack reaches the surface of the conductive film. I realized there was a case. Here, when the groove leads to the outside of the sealing portion included in the dye-sensitized solar cell, moisture enters from the outside of the sealing portion through the crack, and this moisture is in the porous insulating layer. The present inventors thought that the durability of the dye-sensitized solar cell module might decrease as a result of contact with the carrier transport material. Therefore, as a result of intensive studies, the present inventors have found that the above problems can be solved by the following invention.

That is, the present invention includes at least one dye-sensitized solar cell, and the dye-sensitized solar cell includes a transparent substrate and a conductive substrate provided on one surface of the transparent substrate, and the conductive material. A counter substrate facing the conductive substrate, the conductive substrate or an oxide semiconductor layer provided on the counter substrate, and an annular sealing portion for bonding the conductive substrate and the counter substrate, The transparent conductive film has a main body portion disposed inside the sealing portion, the groove is formed in the transparent conductive film, and at least a part of the groove is formed along the outer shape of the sealing portion. And the insulating material enters at least part of the first groove and continuously covers the edge of the main body, and the sealing portion is made of resin. said insulating material is made of an inorganic material, color Motozo sensitized solar cell It is a child. Hereinafter, the above invention may be referred to as “first invention”.

  According to this dye-sensitized solar cell element, a groove is formed in the transparent conductive film, and the groove has a first groove formed along the outer shape of the annular sealing portion. And while an insulating material penetrates into at least one part of the 1st groove | channel, this insulating material has also covered the edge part of the main-body part continuously. For this reason, even if a crack is formed along the groove inside the transparent substrate and below the groove, and the crack is connected to the edge of the main body, the outside of the sealing part that has passed through the crack. Intrusion of moisture from the substrate is sufficiently suppressed by the insulating material. For this reason, according to the dye-sensitized solar cell element of this invention, it becomes possible to have the outstanding durability.

  The said dye-sensitized solar cell element WHEREIN: It is preferable that the said insulating material is provided over the perimeter along the external shape of the said sealing part.

  In this case, since the water intrusion route from the outside can be blocked over the entire circumference, it is possible to have more excellent durability.

The present invention also includes at least one dye-sensitized solar cell, wherein the dye-sensitized solar cell has a transparent substrate and a conductive substrate provided on one surface of the transparent substrate, and the conductive material. A transparent substrate including a counter substrate facing the substrate, the conductive substrate or an oxide semiconductor layer provided on the counter substrate, and an annular sealing portion that joins the conductive substrate and the counter substrate. The conductive film has a main body portion disposed inside the sealing portion, a groove is formed in the transparent conductive film, and at least a part of the groove is formed along an outer shape of the sealing portion. A dye-sensitized solar cell element having a first groove, wherein the insulating material enters at least part of the first groove and continuously covers an edge of the main body, At least a part of the first groove is front outside the sealing portion Spaced apart a sealing portion, said at least one on the transparent conductive film of the dye-sensitized solar cell, dye-sensitized with the current collector wire between said sealing portion of the first groove It is a solar cell element.

  In this case, the current generated inside the sealing portion of at least one dye-sensitized solar cell can be taken out of the sealing portion by the current collecting wiring. In addition, the current collecting wiring is generally porous and has air permeability so that a gas such as water vapor can pass therethrough, so that the sealing portion and the first groove outside the sealing portion are connected to each other. By disposing the current collecting wiring therebetween, it is possible to sufficiently suppress gas such as water vapor from entering the sealing portion through the current collecting wiring. For this reason, more excellent durability can be obtained.

  In the case where the dye-sensitized solar cell element further includes a back sheet that covers the dye-sensitized solar cell on the one surface side of the transparent substrate, the groove includes the first groove and the transparent conductive film. A second groove that is formed along an edge of the portion excluding the main body and intersects with a peripheral edge of the backsheet, and the insulating material enters the second groove and the transparent conductive material. It is preferable that the edge part of the film except the main body part is also covered.

  When the second groove intersects with the peripheral edge of the back sheet, moisture can enter the space between the back sheet and the transparent conductive substrate through the second groove. In this case, the insulating material enters the second groove, and the insulating material also covers the edge of the transparent conductive film excluding the main body portion, so that moisture enters from the outside to the inside of the back sheet. Is sufficiently suppressed. For this reason, the water | moisture content which penetrate | invaded into the space between a back sheet | seat and a transparent conductive substrate is fully suppressed that it penetrates into the inside of a sealing part through a sealing part. For this reason, it becomes possible to fully suppress the fall of durability of a dye-sensitized solar cell element.

  The said dye-sensitized solar cell element WHEREIN: It is preferable on the said electroconductive board | substrate, Comprising: The insulating connection part is provided in the peripheral part perimeter of the said back sheet.

  In this case, it is possible to sufficiently prevent moisture from entering the back sheet from the outside of the back sheet.

  The said dye-sensitized solar cell element WHEREIN: It is preferable that the said insulating material and the said connection part consist of the same material, and are integrated.

  In this case, since the insulating material and the connecting portion are made of the same material and are integrated, even if moisture enters the back sheet, no interface is formed between the insulating material and the connecting portion. Can be prevented from entering. For this reason, it becomes possible to have much more excellent durability.

  In the dye-sensitized solar cell element, it is preferable that the insulating material enters all the grooves and covers edges of the transparent conductive film on both sides of all the grooves.

  In this case, since the insulating material enters all the grooves and covers the edges of the transparent conductive film on both sides of all the grooves, moisture cannot penetrate into the groove in the first place, and moisture penetrates into the crack formed in the groove. Since it becomes impossible, it can suppress further that a water | moisture content penetrate | invades through a groove | channel. In addition, since the insulating material covers the edges of the transparent conductive film on both sides of all the grooves, the insulation between the transparent conductive films on both sides of the groove can be sufficiently ensured.

The present invention also includes at least one dye-sensitized solar cell, wherein the dye-sensitized solar cell has a transparent substrate and a conductive substrate provided on one surface of the transparent substrate, and the conductive material. A transparent substrate including a counter substrate facing the substrate, the conductive substrate or an oxide semiconductor layer provided on the counter substrate, and an annular sealing portion that joins the conductive substrate and the counter substrate. The conductive film has a main body portion disposed inside the sealing portion, a groove is formed in the transparent conductive film, and at least a part of the groove is formed along an outer shape of the sealing portion. A dye-sensitized solar cell element having a first groove, wherein the insulating material enters at least part of the first groove and continuously covers an edge of the main body, At least one dye-sensitized solar cell on the transparent substrate In the case of further comprising a back sheet that covers the one surface side, the back sheet has an adhesive part that adheres the back sheet to the conductive substrate, and the adhesive part is separated from the sealing part. This is a dye-sensitized solar cell element.

  According to this dye-sensitized solar cell element, the adhesion part of the back sheet is separated from the sealing part. For this reason, it is sufficiently suppressed that the bonding portion contracts at a low temperature to pull the sealing portion and an excessive stress is applied to the interface between the sealing portion and the conductive substrate or the counter substrate. In addition, even when the temperature is high, it is sufficiently suppressed that the bonding portion expands to push the sealing portion and apply an excessive stress to the interface between the sealing portion and the conductive substrate or the counter substrate. That is, according to the dye-sensitized solar cell element of the present invention, it is sufficiently suppressed that an excessive stress is applied to the interface between the sealing portion and the conductive substrate or the counter substrate even at a high temperature or a low temperature. For this reason, the dye-sensitized solar cell element of the present invention can have excellent durability.

  In the dye-sensitized solar cell element, on the conductive substrate, an insulating connecting portion is provided on the entire periphery of the peripheral portion of the backsheet, and the adhesive portion of the backsheet is connected to the connecting portion. It is preferable that they are adhered.

  In this case, it is possible to sufficiently suppress moisture from entering the inside of the back sheet from the outside of the back sheet.

  In the dye-sensitized solar cell element, the insulating material is provided between the sealing portion and the conductive substrate, the conductive substrate is constituted by a first electrode, and the counter substrate is a second electrode. It is preferable that it is comprised.

  In this case, even if the sealing portion has fluidity at high temperatures, the contact between the conductive substrate constituted by the first electrode and the counter substrate constituted by the second electrode is sufficiently suppressed, and the conductivity is improved. A short circuit between the substrate and the counter substrate can be sufficiently suppressed.

The present invention also includes at least one dye-sensitized solar cell, wherein the dye-sensitized solar cell has a transparent substrate and a conductive substrate provided on one surface of the transparent substrate, and the conductive material. A transparent substrate including a counter substrate facing the substrate, the conductive substrate or an oxide semiconductor layer provided on the counter substrate, and an annular sealing portion that joins the conductive substrate and the counter substrate. The conductive film has a main body portion disposed inside the sealing portion, a groove is formed in the transparent conductive film, and at least a part of the groove is formed along an outer shape of the sealing portion. A dye-sensitized solar cell element having a first groove, wherein an insulating material enters at least a part of the first groove and continuously covers an edge of the main body, A plurality of sensitized solar cells, the plurality of dye-sensitized solar cells A pond is connected in series and electrically, and among the plurality of dye-sensitized solar cells, the dye-sensitized solar cell connected to an adjacent dye-sensitized solar cell is provided on the transparent conductive film. The counter substrate has a metal substrate, and the transparent conductive film protrudes from the main body portion to the outside of the sealing portion, and is connected to the main body portion provided inside the annular sealing portion. A connecting portion in one dye-sensitized solar cell of two adjacent dye-sensitized solar cells, and the metal substrate of the counter substrate in the other dye-sensitized solar cell; Are connected via a conductive material, the connection terminal is connected to the conductive material, and extends along a certain direction outside the sealing portion, and the conductive material outside the sealing portion. Extends along a certain direction from the connection And a material non-connecting portion, the width of the conductive material unconnected portion, a narrow dye-sensitized solar cell element than the width of the conductive material connection.

  When the dye-sensitized solar cell element is placed in an environment with a large temperature change, the wider the connection terminal provided on the protrusion of the transparent conductive film, the more the connection terminal peels from the protrusion of the transparent conductive film. It becomes easy. In that respect, in the dye-sensitized solar cell element of the present invention, the conductive material non-connection portion of the connection terminals has a narrower width than the conductive material connection portion connected to the conductive material. For this reason, a conductive material non-connection part among connection terminals becomes difficult to peel from a projection part of a transparent conductive film. Therefore, even if the conductive material connecting portion is peeled off from the protruding portion of the transparent conductive film, the conductive material non-connecting portion is not peeled off from the protruding portion of the transparent conductive film, and the connection to the protruding portion can be maintained. Further, even when the conductive material connecting portion is separated from the protruding portion of the transparent conductive film, the dye-sensitized solar cell element can operate normally. Therefore, according to the dye-sensitized solar cell element of the present invention, connection reliability can be improved. Moreover, the conductive material connected to the metal substrate of the counter substrate in one dye-sensitized solar cell of two adjacent dye-sensitized solar cells is the conductive material connecting portion on the protrusion in the other dye-sensitized solar cell. The conductive material connecting portion is provided outside the sealing portion on the protruding portion. That is, two adjacent dye-sensitized solar cells are connected to each other outside the sealing portion. For this reason, according to the dye-sensitized solar cell element of this invention, it becomes possible to improve an aperture ratio.

  In addition, the present inventors have examined the cause of the above problem in the photoelectric conversion device of Patent Document 2. As a result, in the photoelectric conversion device of Patent Document 2 described above, a hot melt resin having a large linear expansion coefficient is used as an adhesive portion included in the back sheet. Therefore, at a low temperature, the hot melt resin contracts. It was thought that the encapsulant was pulled and excessive stress was applied to the interface between the encapsulant and the electrode. Conversely, at high temperatures, the hot melt resin expanded and the sealing material was pushed, and it was thought that excessive stress was applied to the interface between the sealing material and the electrode. As a result, the present inventors thought that the adhesive force between the sealing material and the electrode was weakened, moisture could easily enter, and durability would be easily reduced. Thus, as a result of intensive studies, the present inventors have found that the above-described problems can also be solved by the following invention.

  That is, the present invention has at least one dye-sensitized solar cell and a back sheet disposed to face the at least one dye-sensitized solar cell, and the dye-sensitized solar cell has a conductive substrate. A counter substrate facing the conductive substrate, an oxide semiconductor layer provided on the conductive substrate or the counter substrate, and an annular sealing portion that joins the conductive substrate and the counter substrate. And the backsheet has a bonding portion for bonding the backsheet to the conductive substrate, and the bonding portion is separated from the sealing portion. Hereinafter, the above invention may be referred to as a “second invention”.

  According to this dye-sensitized solar cell element, the adhesion part of the back sheet is separated from the sealing part. For this reason, it is sufficiently suppressed that the bonding portion contracts at a low temperature to pull the sealing portion and an excessive stress is applied to the interface between the sealing portion and the conductive substrate or the counter substrate. In addition, even when the temperature is high, it is sufficiently suppressed that the bonding portion expands to push the sealing portion and apply an excessive stress to the interface between the sealing portion and the conductive substrate or the counter substrate. That is, according to the dye-sensitized solar cell element of the present invention, it is sufficiently suppressed that an excessive stress is applied to the interface between the sealing portion and the conductive substrate or the counter substrate even at a high temperature or a low temperature. For this reason, the dye-sensitized solar cell element of the present invention can have excellent durability.

  In the dye-sensitized solar cell element, on the conductive substrate, an insulating connecting portion is provided on the entire periphery of the peripheral portion of the backsheet, and the adhesive portion of the backsheet is the connecting portion. It is preferable that it is adhered to.

  In this case, it is possible to sufficiently suppress moisture from entering the inside of the back sheet from the outside of the back sheet.

  In the dye-sensitized solar cell element, the conductive substrate is configured by a first electrode, the counter substrate is configured by a second electrode, and an insulating material is provided between the sealing portion and the conductive substrate. It is preferable to be provided.

  In this case, even if the sealing portion has fluidity at high temperatures, the contact between the conductive substrate constituted by the first electrode and the counter substrate constituted by the second electrode is sufficiently suppressed, and the conductivity is improved. A short circuit between the substrate and the counter substrate can be sufficiently suppressed.

  In the said dye-sensitized solar cell element, it is preferable that the said connection part and the said insulating material consist of the same material, and are integrated.

  In this case, since the connecting portion and the insulating material are made of the same material and are integrated, even if moisture enters the back sheet, no interface is formed between the insulating material and the connecting portion. And the connecting portion can be integrated to prevent intrusion of moisture. For this reason, it becomes possible to have much more excellent durability.

  According to the present invention, a dye-sensitized solar cell element having excellent durability is provided.

It is a cut surface end view showing a first embodiment of a dye-sensitized solar cell element of the present invention. It is a top view which shows a part of 1st Embodiment of the dye-sensitized solar cell element of this invention. It is a top view which shows the pattern of the transparent conductive film in the dye-sensitized solar cell element of FIG. It is a top view which shows the 1st integrated sealing part of FIG. It is a top view which shows the 2nd integrated sealing part of FIG. FIG. 3 is a cross-sectional end view taken along line VI-VI in FIG. 2. It is a top view which shows the working electrode which formed the connection part for fixing a back seat | sheet. It is a top view which shows the 1st integrated sealing part formation body for forming the 1st integrated sealing part of FIG. It is a top view which shows a part of 2nd Embodiment of the dye-sensitized solar cell element of this invention. It is a top view which shows a part of 3rd Embodiment of the dye-sensitized solar cell element of this invention. It is a top view which shows a part of 4th Embodiment of the dye-sensitized solar cell element of this invention. It is a cut-plane end view which shows a part of 5th Embodiment of the dye-sensitized solar cell element of this invention. It is a top view which shows a part of 6th Embodiment of the dye-sensitized solar cell element of this invention.

  Hereinafter, a preferred first embodiment of the dye-sensitized solar cell element of the present invention will be described in detail with reference to FIGS. FIG. 1 is a cross-sectional end view showing a first embodiment of the dye-sensitized solar cell element of the present invention, and FIG. 2 is a plan view showing a part of the first embodiment of the dye-sensitized solar cell element of the present invention. 3 is a plan view showing the pattern of the transparent conductive film in the dye-sensitized solar cell module of FIG. 1, FIG. 4 is a plan view showing the first integrated sealing portion of FIG. 1, and FIG. FIG. 6 is a cross-sectional end view taken along line VI-VI in FIG. 2.

  As shown in FIG. 1, a dye-sensitized solar cell module (hereinafter sometimes referred to as “DSC module”) 100 as a dye-sensitized solar cell element includes a plurality of transparent substrates 11 (four in FIG. 1). The dye-sensitized solar cell (hereinafter also referred to as “DSC”) 50 and a back sheet 80 provided so as to cover the DSC 50 on the one surface 11 a side of the transparent substrate 11. An insulating connecting portion 14 is provided on the entire periphery of the peripheral edge portion 80 a of the backsheet 80. As shown in FIG. 2, the plurality of DSCs 50 are connected in series by a conductive material 60P. Hereinafter, for convenience of description, the four DSCs 50 in the DSC module 100 may be referred to as DSCs 50A to 50D.

  As shown in FIG. 1, each of the plurality of DSCs 50 includes a working electrode 10, a counter electrode 20 that faces the working electrode 10, and an annular sealing portion 30 </ b> A that joins the working electrode 10 and the counter electrode 20. A cell space formed by the working electrode 10, the counter electrode 20, and the annular sealing portion 30A is filled with an electrolyte 40.

  The counter electrode 20 includes a metal substrate 21 and a catalyst layer 22 provided on the working electrode 10 side of the metal substrate 21 to promote a catalytic reaction. In two adjacent DSCs 50, the counter electrodes 20 are separated from each other. In the present embodiment, the counter substrate is constituted by the counter electrode 20.

  As shown in FIGS. 1 and 2, the working electrode 10 includes a transparent substrate 11, a transparent conductive film 12 provided on the transparent substrate 11, and a transparent conductive material having an insulating material 33 provided on one surface 11 a of the transparent substrate 11. The substrate 15 includes at least one oxide semiconductor layer 13 provided on the transparent conductive film 12 of the transparent conductive substrate 15, and a connection terminal 16 provided on the transparent conductive film 12. The oxide semiconductor layer 13 is disposed inside the annular sealing portion 30A. The transparent substrate 11 is used as a common transparent substrate for the DSCs 50A to 50D. In the present embodiment, the transparent conductive substrate 15 constitutes a conductive substrate.

  As shown in FIGS. 2 and 3, the transparent conductive film 12 is composed of transparent conductive films 12 </ b> A to 12 </ b> F that are provided in an insulated state. That is, the transparent conductive films 12A to 12F are arranged with the groove 90 interposed therebetween. Here, the transparent conductive films 12A to 12D constitute the plurality of DSCs 50A to 50D, respectively. The transparent conductive film 12E is arranged so as to be bent along the sealing portion 30A. The transparent conductive film 12F is an annular transparent electrode film 12 for fixing the peripheral edge 80a of the back sheet 80 (see FIG. 1).

  As shown in FIG. 3, each of the transparent conductive films 12A to 12D includes a rectangular main body portion 12a having a side edge portion 12b, and a protruding portion 12c protruding sideways from the side edge portion 12b of the main body portion 12a. Have.

  As shown in FIG. 2, the protruding portion 12c of the transparent conductive film 12C among the transparent conductive films 12A to 12D extends from the protruding portion 12d and the protruding portion 12d that protrude laterally with respect to the arrangement direction X of the DSCs 50A to 50D. And a counter part 12e facing the main body part 12a of the adjacent DSC 50D via the groove 90.

  Also in the DSC 50B, the protruding portion 12c of the transparent conductive film 12B has a protruding portion 12d and a facing portion 12e. Also in the DSC 50A, the protruding portion 12c of the transparent conductive film 12A has a protruding portion 12d and a facing portion 12e.

  The DSC 50D is already connected to the DSC 50C, and there is no other DSC 50 to be connected. For this reason, in the DSC 50D, the protruding portion 12c of the transparent conductive film 12D does not have the facing portion 12e. That is, the protruding portion 12c of the transparent conductive film 12D is configured only by the overhang portion 12d.

  However, the transparent conductive film 12D connects the first current extraction part 12f for extracting the current generated in the DSC module 100 to the outside, the first current extraction part 12f, and the main body part 12a, and the transparent conductive films 12A to 12C. And a connecting portion 12g extending along the side edge portion 12b. The first current extraction portion 12f is disposed around the DSC 50A and on the opposite side of the transparent conductive film 12B with respect to the transparent conductive film 12A.

  On the other hand, the transparent conductive film 12E also has a second current extraction portion 12h for extracting the current generated in the DSC module 100 to the outside. The second current extraction portion 12h is around the DSC 50A and is formed of a transparent conductive film. It is arranged on the opposite side to the transparent conductive film 12B with respect to 12A. The transparent conductive film 12E further includes a second connection portion 12i that connects the second current extraction portion 12h and the metal substrate 21 of the counter electrode 20 of the DSC 50A. In the present embodiment, the second connection portion 12i is disposed in an L shape between the annular coupling portion 14 and the main body portion 12a of the transparent conductive film 12A of the DSC 50A. The first current extraction portion 12f and the second current extraction portion 12h are arranged adjacent to each other through the groove 90 around the DSC 50A. Here, the groove 90 is formed along the edge of the first groove 90A formed along the outer shape of the annular sealing portion 30A and the portion of the transparent conductive film 12 excluding the main body portion 12a. The second groove 90 </ b> B intersects with the peripheral edge 80 a of the sheet 80. Since the first groove 90 </ b> A is formed along the outer shape of the annular sealing portion 30 </ b> A, in addition to the groove formed along the edge of the main body portion 12 a of the transparent conductive film 12, A groove formed along the edge of the portion excluding the main body 12a is also included. When the DSC module 100 has the back sheet 80, the first groove 90A is a groove formed inside the inner peripheral edge of the annular connecting portion 14, and the second groove 90B is an annular connecting part. The groove formed outside the inner peripheral edge of the portion 14 is said.

  Moreover, the connection terminal 16 is provided on each protrusion part 12c and transparent conductive film 12E of transparent conductive film 12A-12C. In the present embodiment, in the transparent conductive films 12A to 12C, at least the conductive material connection portion 16A among the connection terminals 16 is provided on the facing portion 12e of the protruding portion 12c, and the main body portion of the adjacent DSC 50 to be connected. 12a. In the transparent conductive film 12E, the conductive material connection portion 16A of the connection terminals 16 faces the main body portion 12a of the adjacent DSC 50A to be connected. Each connection terminal 16 is connected to the conductive material 60P and is connected to the conductive material connection portion 16A extending along the sealing portion 30A outside the sealing portion 30A, and is not connected to the conductive material 60P, and is sealed from the conductive material connection portion 16A. A conductive material non-connecting portion 16B extending along the sealing portion 30A outside the stop portion 30A. The width of the conductive material non-connecting portion 16B is narrower than the width of the conductive material connecting portion 16A. Here, the widths of the conductive material connecting portion 16A and the conductive material non-connecting portion 16B are constant. Note that the width of the conductive material connecting portion 16A is the length in the direction orthogonal to the extending direction of the conductive material connecting portion 16A and means the narrowest width among the widths of the conductive material connecting portion 16A. The width of the portion 16B is the length in a direction orthogonal to the extending direction of the conductive material non-connecting portion 16B and means the narrowest width among the widths of the conductive material non-connecting portion 16B.

  The conductive material connecting portion 16A of the connection terminal 16 provided on the protruding portion 12c of the transparent conductive film 12C in the DSC 50C and the metal substrate 21 of the counter electrode 20 in the adjacent DSC 50D are connected via the conductive material 60P. The conductive material 60P is disposed so as to pass over the sealing portion 30A. Similarly, the conductive material connection portion 16A of the connection terminal 16 in the DSC 50B and the metal substrate 21 of the counter electrode 20 in the adjacent DSC 50C are connected via the conductive material 60P, and adjacent to the conductive material connection portion 16A of the connection terminal 16 in the DSC 50A. The metal substrate 21 of the counter electrode 20 in the DSC 50B is connected via a conductive material 60P, and the conductive material connection portion 16A of the connection terminal 16 on the transparent conductive film 12E and the metal substrate 21 of the counter electrode 20 in the adjacent DSC 50A are conductive material 60P. Connected through.

  External connection terminals 18a and 18b are provided on the first current extraction portion 12f and the second current extraction portion 12h, respectively.

  As shown in FIG. 1, the sealing part 30A is provided so as to overlap the first sealing part 31A and the annular first sealing part 31A provided between the transparent conductive substrate 15 and the counter electrode 20, It has the 2nd sealing part 32A which clamps the edge 20a of the counter electrode 20 with 31 A of 1st sealing parts. As shown in FIG. 4, adjacent first sealing portions 31 </ b> A are integrated to form a first integrated sealing portion 31. In other words, the first integrated sealing portion 31 includes an annular portion (hereinafter referred to as “annular portion”) 31 a that is not provided between two adjacent counter electrodes 20 and two adjacent counter electrodes 20. A portion (hereinafter referred to as a “partition portion”) 31 b that is provided between them and partitions the inner opening 31 c of the annular portion 31 a. Further, as shown in FIG. 5, the second sealing portions 32 </ b> A are integrated between the adjacent counter electrodes 20 to constitute a second integrated sealing portion 32. The second integrated sealing portion 32 is provided between an annular portion (hereinafter referred to as “annular portion”) 32 a that is not provided between two adjacent counter electrodes 20 and two adjacent counter electrodes 20. And a portion (hereinafter referred to as “partition portion”) 32b that partitions the inner opening 32c of the annular portion 32a.

  As shown in FIG. 1, between the first sealing portion 31 </ b> A and the groove 90, the groove 90 between the adjacent transparent conductive films 12 </ b> A to 12 </ b> F enters and spans the adjacent transparent conductive film 12. An insulating material 33 is provided on the entire circumference along the outer shape of the annular sealing portion 30A. More specifically, the insulating material 33 is formed in the first groove 90A in the portion of the groove 90 where the first groove 90A formed along the edge of the main body 12a of the transparent conductive film 12 is formed. While entering, the edge part of the main-body part 12a which forms the 1st groove | channel 90A is also covered. On the other hand, the insulating material 33 is also formed on the transparent conductive film 12 between the main body portion 12a where the first groove 90A is not formed and the projecting portion 12c, and the entire periphery along the outer shape of the sealing portion 30A. An insulating material 33 is formed over the entire area. The insulating material 33 also covers the edge of the transparent conductive film 12 on the opposite side of the main body portion 12a across the first groove 90A, and is provided to the outside of the sealing portion 30A. However, in the present embodiment, of the first groove 90A, the groove formed along the edge portion of the transparent conductive film 12 excluding the main body 12a and the second groove 90B are covered with the insulating material 33. Absent.

  As shown in FIG. 6, the width P of the bonding portion between the surface of the counter electrode 20 on the transparent conductive substrate 15 side and the partition portion 31 b of the first integrated sealing portion 31 is the transparent conductive substrate 15 of the counter electrode 20. It is narrower than the width Q of the bonding portion between the side surface and the annular portion 31 a of the first integrated sealing portion 31. Furthermore, the width R of the partition part 31 b of the first integrated sealing part 31 is 100% or more and less than 200% of the width T of the annular part 31 a of the first integrated sealing part 31.

  The second integrated sealing portion 32 includes a main body portion 32 d provided on the opposite side of the counter electrode 20 from the working electrode 10, and an adhesive portion 32 e provided between the adjacent counter electrodes 20. The second integrated sealing portion 32 is bonded to the first integrated sealing portion 31 by an adhesive portion 32e.

  As shown in FIG. 1, a back sheet 80 is provided on the transparent conductive substrate 15. The backsheet 80 includes a laminate 80A including a weather resistant layer and a metal layer, and an adhesive portion that is provided on the opposite side of the laminate 80A from the metal layer and adheres to the transparent conductive substrate 15 via the connecting portion 14. 80B. Here, the bonding portion 80B is for bonding the back sheet 80 to the transparent conductive substrate 15, and as long as it is formed on the peripheral portion of the stacked body 80A as shown in FIG. However, the bonding portion 80B may be provided on the entire surface on the DSC 50 side of the stacked body 80A. The peripheral edge portion 80a of the back sheet 80 is connected to the transparent conductive films 12D, 12E, and 12F of the transparent conductive film 12 through the connecting portion 14 by the bonding portion 80B. Here, the bonding portion 80B is separated from the sealing portion 30A of the DSC 50. The connecting portion 14 is also separated from the sealing portion 30A. Furthermore, the second connection portion 12 i of the transparent conductive film 12 </ b> E is disposed inside the annular coupling portion 14. Further, the transparent conductive film 12F connects the transparent substrate 11 and the connecting portion 14, and surrounds the transparent conductive films 12A to 12D of the DSC 50, and a part of the groove 90 is formed between the transparent conductive films 12A to 12D. It is provided to form. Here, the first groove 90 </ b> A, which is a part of the groove 90, is disposed inside the annular coupling portion 14, and the second groove 90 </ b> B is disposed outside the inner peripheral edge of the annular coupling portion 14. . The space inside the back sheet 80 and outside the sealing portion 30A is not filled with the electrolyte 40.

  In the transparent conductive film 12D, the current collector wiring 17 having a lower resistance than that of the transparent conductive film 12D extends so as to pass through the main body portion 12a, the connection portion 12g, and the current extraction portion 12f. The current collecting wiring 17 is arranged so as not to intersect the connecting portion 14 between the back sheet 80 and the transparent conductive substrate 15. In other words, the current collecting wiring 17 is disposed on the inner side than the connecting portion 14. The current collecting wiring 17 is on the transparent conductive film 12D of the DSC 50D, and the portion of the first groove 90A that is separated from the sealing portion 30A outside the sealing portion 30A and the sealing portion 30A Arranged between.

  As shown in FIG. 2, bypass diodes 70A to 70D are connected in parallel to the DSCs 50A to 50D, respectively. Specifically, the bypass diode 70A is fixed on the partition part 32b of the second integrated sealing part 32 between the DSC 50A and the DSC 50B, and the bypass diode 70B is a second integrated between the DSC 50B and the DSC 50C. The bypass diode 70C is fixed on the partition part 32b of the second integrated sealing part 32 between the DSC 50C and the DSC 50D. The bypass diode 70D is fixed on the sealing portion 30A of the DSC 50D. A conductive material 60Q is fixed to the metal substrate 21 of the counter electrode 20 so as to pass through the bypass diodes 70A to 70D. The conductive material 60P branches from the conductive material 60Q between the bypass diodes 70A and 70B, between the bypass diodes 70B and 70C, and between the bypass diodes 70C and 70D, and the conductive material connecting portion 16A on the transparent conductive film 12A, the transparent conductive film The conductive material connecting portion 16A on 12B and the conductive material connecting portion 16A on the transparent conductive film 12C are connected to each other. A conductive material 60P is also fixed to the metal substrate 21 of the counter electrode 20 of the DSC 50A, and the conductive material 60P connects the bypass diode 70A and the conductive material connection portion 16A of the connection terminal 16 on the transparent conductive film 12E. . Further, the bypass diode 70D is connected to the transparent conductive film 12D through the conductive material 60P.

  Further, as shown in FIG. 1, a desiccant 95 is provided on the counter electrode 20 of each DSC 50.

  The DSC module 100 is provided with a groove 90, and the groove 90 has a first groove 90A formed along the outer shape of the annular sealing portion 30A. Then, the insulating material 33 enters the first groove 90A, and the insulating material 33 continuously covers the edge of the main body 12a. For this reason, even if a crack is formed along the groove 90 in the transparent substrate 11 and below the groove 90, and the crack is connected to the edge of the main body 12 a, the crack is sealed. Intrusion of moisture from the outside of the stop 30A is sufficiently suppressed by the insulating material 33. For this reason, the DSC module 100 can have excellent durability.

  Further, in the DSC module 100, since the insulating material 33 is provided over the entire circumference along the outer shape of the sealing portion 30A, the intrusion path of moisture from the outside can be blocked over the entire circumference. It is possible to have more excellent durability.

  Furthermore, in the DSC module 100, the first groove 90A is provided along the edge of the main body 12a. For this reason, compared with the case where the 1st groove | channel 90A is formed outside the edge part of the main-body part 12a, the area | region enclosed by the 1st groove | channel 90A can be made small, and DSC module 100 is reduced in size. Can do.

  Further, in the DSC module 100, since the insulating connecting portion 14 is provided on the entire periphery of the back sheet 80, it is sufficient to prevent moisture from entering the back sheet 80 from the outside of the back sheet 80. Can be suppressed.

  Further, since the insulating material 33 is also inserted into the first groove 90A between the transparent conductive films 12 of the adjacent DSCs 50 in the DSC module 100, the current flowing between the transparent conductive films 12 can be suppressed. Sufficient sex can be secured. For this reason, a photoelectric conversion characteristic can be improved.

  In the DSC module 100, the sealing portion 30A and the insulating material 33 are arranged so as to overlap each other. For this reason, compared with the case where the insulating material 33 is arrange | positioned so that it may not overlap with 30 A of sealing parts, the area of the part which contributes to electric power generation seen from the light-receiving surface side of the DSC module 100 can be increased more. . For this reason, an aperture ratio can be improved more.

  In the DSC module 100, the first current extraction unit 12f and the second current extraction unit 12h are disposed around the DSC 50A and on the opposite side of the transparent conductive film 12B from the transparent conductive film 12A. The first current extraction portion 12f and the second current extraction portion 12h of the transparent conductive film 12F are arranged adjacent to each other via the groove 90. Therefore, in the DSC module 100, the external connection terminals 18a and 18b can be arranged adjacent to each of the first current extraction unit 12f and the second current extraction unit 12h. Therefore, the number of connectors for taking out current from the external connection terminals 18a and 18b to the outside can be reduced to one. That is, if the first current extraction part 12f is arranged on the opposite side of the transparent conductive film 12C with respect to the transparent conductive film 12D, the first current extraction part 12f and the second current extraction part 12h are arranged greatly apart from each other. Therefore, the external connection terminals 18a and 18b are also arranged far apart. In this case, in order to take out the current from the DSC module 100, two connectors are required: a connector connected to the external connection terminal 18a and a connector connected to the external connection terminal 18b. However, according to the DSC module 100, since the external connection terminals 18a and 18b can be arranged adjacent to each other, only one connector is required. For this reason, according to the DSC module 100, space saving can be achieved. Further, when the DSC module 100 is used under low illuminance, the generated current is small. Specifically, the generated current is 2 mA or less. Therefore, the second current in which a part of the transparent conductive film 12D of the DSC 50D on one end side of the DSCs 50A and 50D at both ends of the DSCs 50A to 50D is electrically connected to the metal substrate 21 of the counter electrode 20 of the DSC 50A on the other end side. Even if it arrange | positions as the 1st electric current extraction part 12f via the groove | channel 90 next to the extraction part 12h, the fall of the photoelectric conversion performance of the DSC module 100 can fully be suppressed.

  In the DSC module 100, the DSCs 50A to 50D are arranged in a line along the X direction, and the DSC 50A and 50D at both ends of the DSCs 50A to 50D include the transparent conductive film 12D of the DSC 50D at one end of the sealing portion 30A. It has a main body part 12a provided on the inner side, a first current extraction part 12f, and a connection part 12g for connecting the main body part 12a and the first current extraction part 12f. Therefore, DSC 50A and DSC 50D, which are a part of DSC 50A to 50D, are folded back halfway, and DSC 50A is used to connect two adjacent DSCs 50 to each other as compared with the case where DSC 50A and DSC 50D are arranged adjacent to each other. It becomes possible to further shorten the installation area of the connection terminals 16 provided along the arrangement direction (X direction in FIG. 2) of ˜50D, and to further reduce the space. Also, according to the DSC module 100, when the DSC module 100 is used in a low illumination environment, the generated current is usually small, so the DSC module 100 connects the main body portion 12a and the first current extraction portion 12f. Even if it has the 1st connection part 12g to perform, the fall of a photoelectric conversion characteristic can fully be suppressed.

  Further, in the DSC module 100, the current collecting wiring 17 is arranged so as not to intersect the connecting portion 14 between the back sheet 80 and the transparent conductive substrate 15. In general, the current collector wiring is porous and has air permeability, and gas such as water vapor can pass through. The current collector wiring 17 is connected to the back sheet 80 and the transparent conductive substrate 15. If it arrange | positions so that it may not cross | intersect the part 14, it can prevent that water vapor | steam etc. penetrate | invade from the exterior into the space between the backsheet 80 and the transparent conductive substrate 15 through the current collection wiring 17. FIG. As a result, the DSC module 100 can have excellent durability. Moreover, since the current collection wiring 17 has resistance lower than transparent conductive film 12D, even if a generated current becomes large, the fall of a photoelectric conversion characteristic can fully be suppressed.

  Further, in the DSC module 100, the current collector wiring 17 is on the transparent conductive film 12D of the DSC 50D, and the portion of the first groove 90A that is separated from the sealing portion 30A outside the sealing portion 30A; It arrange | positions between 30A of sealing parts. For this reason, the electric current which generate | occur | produced inside 30 A of sealing parts of DSC50 can be taken out outside 30 A of sealing parts with the current collection wiring 17. FIG. Further, the current collecting wiring 17 is generally porous and has air permeability so that gas such as water vapor can pass therethrough. The sealing portion 30A and the first outside of the sealing portion 30A are provided. By disposing the current collecting wiring 17 between the groove 90A, the gas such as water vapor is sufficiently prevented from entering the sealing portion 30A through the current collecting wiring 17. For this reason, more excellent durability can be obtained.

  Furthermore, when the DSC module 100 is placed in an environment where the temperature change is large, the connection terminal 16 is less likely to be peeled off from the protruding portion 12 c of the transparent conductive film 12 as the connection terminal 16 is narrower. In that respect, in the DSC module 100, the conductive material non-connecting portion 16B of the connection terminals 16 has a narrower width than the conductive material connecting portion 16A connected to the conductive material 60P. For this reason, the conductive material non-connecting portion 16 </ b> B of the connection terminal 16 is difficult to peel off from the protruding portion 12 c of the transparent conductive film 12. Therefore, even if the conductive material connecting portion 16A is peeled off from the protruding portion 12c of the transparent conductive film 12, the conductive material non-connecting portion 16B is not peeled off from the transparent conductive film 12 and can maintain the connection to the transparent conductive film 12. It becomes. Even if the conductive material connecting portion 16A is peeled off from the protruding portion 12c of the transparent conductive film 12, the DSC module 100 can operate normally. Therefore, according to the DSC module 100, connection reliability can be improved. In addition, the conductive material 60P connected to the metal substrate 21 of the counter electrode 20 in one of the two adjacent DSCs 50 is connected to the conductive material connection portion 16A on the protruding portion 12c in the other DSC 50, and the conductive material connection portion. 16A is provided outside the sealing portion 30A on the protruding portion 12c. That is, two adjacent DSCs 50 are connected to each other outside the sealing portion 30A. For this reason, according to the DSC module 100, it is possible to improve the aperture ratio.

  Further, in the DSC module 100, in the DSC 50 connected to the adjacent DSC 50 among the DSCs 50A to 50D, the projecting portion 12c extends from the main body portion 12a to the side and extends from the protruding portion 12d to the adjacent DSC 50. Of the connection terminal 16 and at least the conductive material connection portion 16A is provided on the facing portion 12e.

  In this case, since at least the conductive material connection portion 16A of the connection terminals 16 is provided on the facing portion 12e facing the main body portion 12a of the adjacent DSC 50, at least the conductive material connection portion 16A of the connection terminals 16 is Unlike the case where it is not provided on the facing portion 12e facing the main body portion 12a of the adjacent DSC 50, the conductive material 60P connected to the conductive material connecting portion 16A crosses the metal substrate 21 of the counter electrode 20 of the adjacent DSC 50. Can be sufficiently prevented. As a result, it is possible to sufficiently prevent a short circuit between adjacent DSCs 50.

  In the DSC module 100, the conductive material connecting portion 16A and the conductive material non-connecting portion 16B are both arranged along the sealing portion 30A. For this reason, compared with the case where the electrically conductive material connection part 16A and the electrically conductive material non-connection part 16B are arranged along the direction away from the sealing part 30A, the space required for the connection terminal 16 can be omitted.

  Furthermore, in the DSC module 100, the adhesive portion 80B of the back sheet 80 is separated from the sealing portion 30A of the DSC 50. For this reason, it is sufficiently suppressed that the adhesive portion 80B contracts at a low temperature to pull the sealing portion 30A and an excessive stress is applied to the interface between the sealing portion 30A and the transparent conductive substrate 15 or the counter electrode 20. Is done. In addition, even when the temperature is high, the adhesive portion 80B sufficiently expands and pushes the sealing portion 30A to apply an excessive stress to the interface between the sealing portion 30A and the transparent conductive substrate 15 or the counter electrode 20. Is done. That is, excessive stress is sufficiently suppressed from being applied to the interface between the sealing portion 30 </ b> A and the transparent conductive substrate 15 or the counter electrode 20 at both high and low temperatures. For this reason, the DSC module 100 can have excellent durability.

  Further, in the DSC module 100, the width P of the bonding portion between the surface of the counter electrode 20 on the transparent conductive substrate 15 side and the partition portion 31 b of the first integrated sealing portion 31 is the transparent conductive substrate 15 of the counter electrode 20. It is narrower than the width Q of the bonding portion between the side surface and the annular portion 31 a of the first integrated sealing portion 31. For this reason, the aperture ratio in the DSC module 100 can be improved more sufficiently. In the DSC module 100, the adjacent first sealing portions 31 </ b> A and the adjacent second sealing portions 32 </ b> A are integrated between the adjacent counter electrodes 20. Here, if the adjacent first sealing portions 31 </ b> A are not integrated, two adjacent sealing portions are exposed to the atmosphere between the adjacent DSCs 50. On the other hand, in the DSC module 100, since the adjacent first sealing portions 31A are integrated, there is one sealing portion exposed to the atmosphere between the adjacent DSCs 50. That is, since the 1st integrated sealing part 31 is comprised by the annular part 31a and the partition part 31b, the sealing part exposed with respect to air | atmosphere between adjacent DSC50 is the partition part 31b. There is only one place. Further, since the first sealing portions 31A are integrated with each other, the penetration distance of moisture and the like from the atmosphere to the electrolyte 40 is extended. For this reason, it is possible to sufficiently reduce the amount of moisture and air entering from the outside of the DSC 50 between the adjacent DSCs 50. That is, the sealing ability of the DSC module 100 can be sufficiently improved. Further, according to the DSC module 100, the adjacent first sealing portions 31A are integrated. Therefore, the width P of the bonding portion between the surface of the counter electrode 20 on the transparent conductive substrate 15 side and the partition portion 31b of the first integrated sealing portion 31 is the same as the surface of the counter electrode 20 on the transparent conductive substrate 15 side. Even if it is narrower than the width Q of the bonding portion between the first integrated sealing portion 31 and the annular portion 31a, a sufficient sealing width can be secured in the partition portion 31b. That is, according to the DSC module 100, the adhesive strength between the first sealing portion 31A and the transparent conductive substrate 15 and the adhesive strength between the first sealing portion 31A and the counter electrode 20 are sufficiently increased while improving the aperture ratio. It is possible to make it larger. As a result, the aperture ratio can be improved, and when the DSC module 100 is used at a high temperature, the electrolyte 40 expands and an excessive stress is applied from the inside to the outside of the first sealing portion 31A. In addition, peeling of the first sealing portion 31A from the transparent conductive substrate 15 and the counter electrode 20 can be sufficiently suppressed, and excellent durability can be achieved.

  Furthermore, in the DSC module 100, the width R of the counter electrode 20 and the partition portion 31b of the first integrated sealing portion 31 is 100% or more and less than 200% of the width T of the annular portion 31a of the first integrated sealing portion 31. It has become. In this case, in the partition part 31b of the first integrated sealing part 31, the width of the partition part 31b is 100% or more of the width T of the annular part 31a. In comparison with the case where the width R of the partition portion 31b is less than 100% of the width T of the annular portion 31a, the penetration distance of moisture and the like from the atmosphere to the electrolyte 40 is further extended. For this reason, it can suppress more fully that a water | moisture content penetrate | invades from the exterior through the partition part 31b between adjacent DSC50. On the other hand, compared with the case where the width R of the partition part 31b exceeds 200% of the width T of the annular part 31a, the aperture ratio can be further improved.

  In the DSC module 100, the second sealing portion 32A is bonded to the first sealing portion 31A, and the edge portion 20a of the counter electrode 20 is sandwiched between the first sealing portion 31A and the second sealing portion 32A. Has been. For this reason, even if the stress in the direction away from the working electrode 10 acts on the counter electrode 20, the separation is sufficiently suppressed by the second sealing portion 32A. Further, since the partition portion 32b of the second integrated sealing portion 32 is bonded to the first sealing portion 31A through the gap S between the adjacent counter electrodes 20, the counter electrodes 20 of the adjacent DSCs 50 are in contact with each other. Is reliably prevented.

  Next, the working electrode 10, the connecting portion 14, the photosensitizing dye, the counter electrode 20, the sealing portion 30A, the electrolyte 40, the conductive materials 60P and 60Q, the back sheet 80, and the desiccant 95 will be described in detail.

(Working electrode)
The material which comprises the transparent substrate 11 should just be a transparent material, for example, As such a transparent material, glass, such as borosilicate glass, soda lime glass, white plate glass, quartz glass, polyethylene terephthalate (PET), for example , Polyethylene naphthalate (PEN), polycarbonate (PC), and polyethersulfone (PES). The thickness of the transparent substrate 11 is appropriately determined according to the size of the DSC module 100 and is not particularly limited, but may be in the range of 50 to 10,000 μm, for example.

Examples of materials included in the transparent conductive film 12 include tin-doped indium oxide (Indium-Tin-Oxide: ITO), tin oxide (SnO ₂ ), and fluorine-doped tin oxide (Fluorine-doped-Tin-Oxide: FTO). Examples include conductive metal oxides. The transparent conductive film 12 may be a single layer or a laminate of a plurality of layers containing different conductive metal oxides. When the transparent conductive film 12 is composed of a single layer, the transparent conductive film 12 preferably includes FTO because it has high heat resistance and chemical resistance. The transparent conductive film 12 may further include glass frit. The thickness of the transparent conductive film 12 may be in the range of 0.01 to 2 μm, for example.

Moreover, the resistance value of the connection part 12g of transparent conductive film 12D among the transparent conductive films 12 is not particularly limited, but is preferably equal to or less than the resistance value represented by the following formula (1).
Resistance value = number of DSCs 50 connected in series × 120Ω (1)

  In this case, compared with the case where the resistance value of the connection part 12g exceeds the resistance value represented by said Formula (1), the performance fall of the DSC module 100 can fully be suppressed. In the present embodiment, since the number of DSCs 50 is 4, the resistance value represented by the above formula (1) is 480Ω, and thus the resistance value of the connecting portion 12g is preferably 480Ω or less.

  As the insulating material 33, an inorganic material such as glass frit or a resin can be used. Especially, it is preferable that the insulating material 33 is a glass frit. Since the glass frit has a higher sealing ability than the resin material, it is possible to effectively suppress intrusion of moisture and the like from the first groove 90A. The thickness of the insulating material 33 is 10-30 micrometers normally, Preferably it is 15-25 micrometers. Moreover, it is preferable that the width | variety which the insulating material 33 covers the edge part of the transparent conductive film 12 is 0.2 mm or more, and it is more preferable that it is 0.5 mm or more. By setting the width covering the edge of the transparent conductive film 12 to be 0.2 mm or more, sufficient insulation between the transparent conductive films 12 of the adjacent DSCs 50 can be secured.

  The connection terminal 16 includes a metal material. Examples of the metal material include silver, copper, and indium. You may use these individually or in combination of 2 or more types.

  Moreover, although the connection terminal 16 may be comprised with the material same as the electrically conductive material 60P, or may be comprised with a different material, it is preferable that it is comprised with the same material.

  In this case, since the connection terminal 16 and the conductive material 60P are made of the same material, the adhesion between the connection terminal 16 and the conductive material 60P can be more sufficiently improved. For this reason, the connection reliability in the DSC module 100 can be further improved.

  In the connection terminal 16, the width of the conductive material non-connecting portion 16B is not particularly limited as long as it is smaller than the width of the conductive material connecting portion 16A, but is preferably 1/2 or less of the width of the conductive material connecting portion 16A.

  In this case, the connection reliability in the DSC module 100 can be further improved as compared with the case where the width of the conductive material non-connecting portion 16B exceeds 1/2 of the width of the conductive material connecting portion 16A.

  The width of the conductive material connecting portion 16A is not particularly limited, but is preferably 0.5 to 5 mm, and more preferably 0.8 to 2 mm.

  The oxide semiconductor layer 13 is composed of oxide semiconductor particles. The oxide semiconductor particles are, for example, titanium oxide (TiO₂), Silicon oxide (SiO₂), Zinc oxide (ZnO), tungsten oxide (WO₃), Niobium oxide (Nb)₂O₅), Strontium titanate (SrTiO)₃), Tin oxide (SnO)₂), Indium oxide (In₃O₃), Zirconium oxide (ZrO) ₂), Thallium oxide (Ta₂O₅), Lanthanum oxide (La₂O₃), Yttrium oxide (Y₂O₃), Holmium oxide (Ho)₂O₃), Bismuth oxide (Bi₂O₃), Cerium oxide (CeO)₂), Aluminum oxide (Al₂O₃) Or two or more of these.

  The oxide semiconductor layer 13 is usually composed of an absorption layer for absorbing light, but may be composed of an absorption layer and a reflective layer that reflects light transmitted through the absorption layer and returns it to the absorption layer.

  The thickness of the oxide semiconductor layer 13 may be, for example, 0.5 to 50 μm.

(Connecting part)
The material constituting the connecting portion 14 is not particularly limited as long as the back sheet 80 and the transparent conductive film 12 can be bonded. Examples of the material constituting the connecting portion 14 include a glass frit and a sealing portion. A resin material similar to the resin material used for 31A can be used. Especially, it is preferable that the connection part 14 is a glass frit. Since the glass frit has a higher sealing ability than the resin material, it is possible to effectively suppress intrusion of moisture and the like from the outside of the back sheet 80.

(Photosensitizing dye)
Examples of the photosensitizing dye include a ruthenium complex having a ligand containing a bipyridine structure, a terpyridine structure, and the like, and organic dyes such as porphyrin, eosin, rhodamine, and merocyanine.

(Counter electrode)
As described above, the counter electrode 20 includes the metal substrate 21 and the conductive catalyst layer 22 that is provided on the working electrode 10 side of the metal substrate 21 and promotes the reduction reaction on the surface of the counter electrode 20.

  The metal substrate 21 is made of a corrosion-resistant metal material such as titanium, nickel, platinum, molybdenum, tungsten, aluminum, and stainless steel. The thickness of the metal substrate 21 is appropriately determined according to the size of the DSC module 100 and is not particularly limited, but may be, for example, 0.005 to 0.1 mm.

  The catalyst layer 22 is composed of platinum, a carbon-based material, a conductive polymer, or the like. Here, carbon nanotubes are suitably used as the carbon-based material.

(Sealing part)
The sealing unit 30A includes a first sealing unit 31A and a second sealing unit 32A.

  Examples of the material constituting the first sealing portion 31A include a modified polyolefin resin containing, for example, an ionomer, an ethylene-vinyl acetic anhydride copolymer, an ethylene-methacrylic acid copolymer, an ethylene-vinyl alcohol copolymer, and ultraviolet curing. Examples thereof include resins and resins such as vinyl alcohol polymers.

  The thickness of 31A of 1st sealing parts is 40-90 micrometers normally, Preferably it is 60-80 micrometers.

  The width P of the bonded portion between the counter electrode 20 and the partition portion 31b is preferably 25% or more and less than 100% of the width Q of the bonded portion between the counter electrode 20 and the annular portion 31a of the first integrated sealing portion 31. In this case, compared with the case where the width | variety P of an adhesion part is less than 25% of the width | variety Q of an adhesion part, it becomes possible to have more outstanding durability. The width P of the bonding portion is more preferably 30% or more of the width Q of the bonding portion, and further preferably 40% or more.

  In the DSC module 100, the width R of the partition part 31b of the first integrated sealing part 31 is preferably 100% or more and less than 200% of the width T of the annular part 31a of the first integrated sealing part 31. 120 to 180% is more preferable.

  In this case, a large aperture ratio and excellent durability can be balanced.

  As the material constituting the second sealing portion 32A, for example, an ionomer, an ethylene-vinyl acetic anhydride copolymer, an ethylene-methacrylic acid copolymer, an ethylene-vinyl alcohol copolymer, as in the first sealing portion 31A. Examples thereof include resins such as modified polyolefin resins, UV curable resins, and vinyl alcohol polymers.

  The thickness of the second sealing portion 32A is usually 20 to 45 μm, preferably 30 to 40 μm.

(Electrolytes)
The electrolyte 40 contains a redox couple such as I ⁻ / I ₃ ^— and an organic solvent. As an organic solvent, acetonitrile, methoxyacetonitrile, methoxypropionitrile, propionitrile, ethylene carbonate, propylene carbonate, diethyl carbonate, γ-butyrolactone, valeronitrile, pivalonitrile, glutaronitrile, methacrylonitrile, isobutyronitrile, Phenylacetonitrile, acrylonitrile, succinonitrile, oxalonitrile, pentanitrile, adiponitrile and the like can be used. Examples of the redox pair include I ⁻ / I ₃ ^— and redox pairs such as bromine / bromide ions, zinc complexes, iron complexes, and cobalt complexes. The electrolyte 40 may use an ionic liquid instead of the organic solvent. As the ionic liquid, for example, a known iodine salt such as a pyridinium salt, an imidazolium salt, or a triazolium salt, and a room temperature molten salt that is in a molten state near room temperature is used. Examples of such room temperature molten salts include 1-hexyl-3-methylimidazolium iodide, 1-ethyl-3-propylimidazolium iodide, dimethylimidazolium iodide, ethylmethylimidazolium iodide, and dimethylpropyl. Imidazolium iodide, butylmethylimidazolium iodide, or methylpropyl imidazolium iodide is preferably used.

  In addition, the electrolyte 40 may use a mixture of the ionic liquid and the organic solvent instead of the organic solvent.

An additive can be added to the electrolyte 40. As the _{additive, LiI, I 2, 4-} t- butylpyridine, guanidinium thiocyanate, 1-methylbenzimidazole, 1-butyl-benzimidazole and the like.

Further, as the electrolyte 40, a nano-composite gel electrolyte, which is a pseudo-solid electrolyte formed by kneading nanoparticles such as SiO ₂ , TiO ₂ , carbon nanotubes, etc. into the electrolyte, may be used, and polyvinylidene fluoride may be used. Alternatively, an electrolyte gelled with an organic gelling agent such as a polyethylene oxide derivative or an amino acid derivative may be used.

The electrolyte 40 includes an oxidation-reduction pair consisting of I ⁻ / I ₃ ^—, and the concentration of I ₃ ⁻ is preferably 0.006 mol / liter or less, and is 0 to 6 × 10 ⁻⁶ mol / liter. More preferably, it is more preferably 0-6 × 10 ⁻⁸ mol / liter. In this case, since the concentration of I ₃ ⁻ carrying electrons is low, the leakage current can be further reduced. For this reason, since an open circuit voltage can be increased more, a photoelectric conversion characteristic can be improved more.

(Conductive material)
For example, metal films are used as the conductive materials 60P and 60Q. As a metal material constituting the metal film, for example, silver or copper can be used.

(Back sheet)
As described above, the back sheet 80 is provided on the surface of the laminate 80A including the weather resistant layer and the metal layer, and the DSC 50 side of the laminate 80A, and bonds the laminate 80A and the connecting portion 14 together. 80B.

  The weather resistant layer may be made of, for example, polyethylene terephthalate or polybutylene terephthalate.

  The thickness of the weather resistant layer may be, for example, 50 to 300 μm.

  The metal layer should just be comprised with the metal material containing aluminum, for example. The metal material is usually composed of aluminum alone, but may be an alloy of aluminum and another metal. Examples of other metals include copper, manganese, zinc, magnesium, lead, and bismuth. Specifically, 1000 series aluminum obtained by adding a trace amount of other metals to 98% or more pure aluminum is desirable. This is because the 1000 series aluminum is cheaper and more workable than other aluminum alloys.

  Although the thickness of a metal layer is not specifically limited, For example, what is necessary is just 12-30 micrometers.

  The stacked body 80A may further include a resin layer. Examples of the material constituting the resin layer include butyl rubber, nitrile rubber, thermoplastic resin, and the like. These can be used alone or in combination of two or more. The resin layer may be formed on the entire surface of the metal layer opposite to the weather-resistant layer, or may be formed only on the peripheral edge.

  Examples of the material constituting the bonding portion 80B include butyl rubber, nitrile rubber, and thermoplastic resin. These can be used alone or in combination of two or more. The thickness of the bonding portion 80B is not particularly limited, but may be, for example, 300 to 1000 μm.

(desiccant)
The desiccant 95 may be a sheet or a granule. The desiccant 95 only needs to absorb moisture, for example, and examples of the desiccant 95 include silica gel, alumina, and zeolite.

  Next, a method for manufacturing the DSC module 100 will be described with reference to FIGS. 3, 7, and 8. 7 is a plan view showing a working electrode in which a connecting portion for fixing the backsheet is formed, and FIG. 8 is a first integrated sealing portion formation for forming the first integrated sealing portion of FIG. It is a top view which shows a body.

  First, a laminate in which a transparent conductive film is formed on one transparent substrate 11 is prepared.

  As a method for forming the transparent conductive film, a sputtering method, a vapor deposition method, a spray pyrolysis (SPD) method, a CVD method, or the like is used.

  Next, as shown in FIG. 3, grooves 90 are formed in the transparent conductive film, and transparent conductive films 12 </ b> A to 12 </ b> F that are disposed in an insulating state with the grooves 90 interposed therebetween are formed. Specifically, the four transparent conductive films 12A to 12D corresponding to the DSCs 50A to 50D are formed so as to have a rectangular main body 12a and a protrusion 12c. At this time, for the transparent conductive films 12A to 12C corresponding to the DSCs 50A to 50C, the protruding part 12c extends not only from the overhanging part 12d but also from the overhanging part 12d, and the opposing part 12e facing the main body part 12a of the adjacent DSC 50 is provided. It is formed so that it also has. The transparent conductive film 12D includes not only the rectangular main body 12a and the overhanging portion 12d, but also the first current extraction portion 12f and a connection portion 12g that connects the first current extraction portion 12f and the main body portion 12a. To form. At this time, the first current extraction portion 12f is formed to be disposed on the opposite side of the transparent conductive film 12B with respect to the transparent conductive film 12A. Further, the transparent conductive film 12E is formed so that the second current extraction portion 12h is formed. At this time, the second current extraction portion 12h is disposed on the opposite side of the transparent conductive film 12A with respect to the transparent conductive film 12A, and is disposed adjacent to the first current extraction portion 12f via the groove 90. Form.

The groove 90 can be formed by a laser scribing method using, for example, a YAG laser or a CO ₂ laser as a light source.

  Thus, a transparent conductive substrate 15 formed by forming the transparent conductive film 12 on the transparent substrate 11 is obtained.

  Next, a precursor of the connection terminal 16 composed of the conductive material connection portion 16A and the conductive material non-connection portion 16B is formed on the protruding portion 12c of the transparent conductive films 12A to 12C. Specifically, the precursor of the connection terminal 16 is formed so that the conductive material connection portion 16A is provided on the facing portion 12e. Also, the precursor of the connection terminal 16 is formed on the transparent conductive film 12E. The precursor of the conductive material non-connecting portion 16B is formed to be narrower than the width of the conductive material connecting portion 16A. The precursor of the connection terminal 16 can be formed, for example, by applying a silver paste and drying it.

  Furthermore, the precursor of the current collection wiring 17 is formed on the connection part 12g of transparent conductive film 12D. The precursor of the current collecting wiring 17 can be formed, for example, by applying a silver paste and drying it.

  Also, precursors for external connection terminals 18a and 18b for taking out current to the outside are formed on the first current extraction part 12f and the second current extraction part 12h of the transparent conductive film 12A, respectively. The precursor of the terminal for external connection can be formed, for example, by applying a silver paste and drying it.

  Further, the precursor of the insulating material 33 is formed so as to enter the first groove 90A formed along the edge of the main body 12a in the first groove 90A and also cover the edge of the main body 12a. . The insulating material 33 can be formed, for example, by applying and drying a paste containing glass frit.

  Further, in order to fix the back sheet 80, the annular connecting portion 14 is surrounded by the annular conductive portion 14 so as to surround the insulating material 33 and pass through the transparent conductive film 12D, the transparent conductive film 12E, and the transparent conductive film 12F. A precursor is formed.

  Furthermore, the precursor of the oxide semiconductor layer 13 is formed on each main body part 12a of the transparent conductive films 12A to 12D. The precursor of the oxide semiconductor layer 13 can be formed by printing a porous oxide semiconductor layer forming paste containing oxide semiconductor particles and then drying the paste.

  The oxide semiconductor layer forming paste contains a resin such as polyethylene glycol and a solvent such as terpineol in addition to the oxide semiconductor particles.

  As a method for printing the oxide semiconductor layer forming paste, for example, a screen printing method, a doctor blade method, a bar coating method, or the like can be used.

  Then, the precursor of the connection terminal 16, the precursor of the insulating material 33, the precursor of the connecting portion 14, and the precursor of the oxide semiconductor layer 13 are baked together, and the connecting terminal 16, the insulating material 33, the connecting portion 14, Then, the oxide semiconductor layer 13 is formed.

  At this time, the firing temperature varies depending on the types of oxide semiconductor particles and glass frit, but is usually 350 to 600 ° C., and the firing time also varies depending on the types of oxide semiconductor particles and glass frit, but usually 1 to 5 times. It's time.

  In this way, as shown in FIG. 7, the working electrode 10 in which the connecting portion 14 for fixing the back sheet 80 is formed is obtained.

  Next, a photosensitizing dye is supported on the oxide semiconductor layer 13 of the working electrode 10. For this purpose, the working electrode 10 is immersed in a solution containing a photosensitizing dye, the photosensitizing dye is adsorbed on the oxide semiconductor layer 13, and then the excess photosensitizer is added with the solvent component of the solution. The photosensitizing dye may be adsorbed to the oxide semiconductor layer 13 by washing away the dye and drying it. However, even if the photosensitizing dye is adsorbed to the oxide semiconductor layer 13 by applying a solution containing the photosensitizing dye to the oxide semiconductor layer 13 and then drying the solution, the photosensitizing dye can be absorbed into the oxide semiconductor layer 13. 13 can be carried.

  Next, the electrolyte 40 is disposed on the oxide semiconductor layer 13.

  Next, as shown in FIG. 8, a first integrated sealing portion forming body 131 for forming the first integrated sealing portion 31 is prepared. The first integrated sealing portion forming body 131 prepares one sealing resin film made of the material constituting the first integrated sealing portion 31, and the sealing resin film according to the number of DSCs 50. It can be obtained by forming a rectangular opening 131a. The first integrated sealing portion forming body 131 has a structure in which a plurality of first sealing portion forming bodies 131A are integrated.

  Then, the first integrated sealing portion forming body 131 is adhered on the working electrode 10. At this time, the first integrated sealing portion forming body 131 is bonded to the working electrode 10 so as to overlap the insulating material 33. The first integrated sealing portion forming body 131 can be adhered to the working electrode 10 by heating and melting the first integrated sealing portion forming body 131. The first integrated sealing portion forming body 131 is adhered to the working electrode 10 so that the main body portion 12 a of the transparent conductive film 12 is disposed inside the first integrated sealing portion forming body 131.

  On the other hand, the same number of counter electrodes 20 as the number of DSCs 50 are prepared.

  The counter electrode 20 can be obtained by forming a conductive catalyst layer 22 that promotes the reduction reaction on the surface of the counter electrode 20 on the metal substrate 21.

  Next, another first integrated sealing portion forming body 131 described above is prepared. And each of the some counter electrode 20 is bonded together so that each opening 131a of the 1st integrated sealing part formation body 131 may be plugged up.

  Next, the first integrated sealing portion forming body 131 bonded to the counter electrode 20 and the first integrated sealing portion forming body 131 bonded to the working electrode 10 are superposed to form a first integrated sealing portion forming body. 131 is heated and melted under pressure. Thus, the first integrated sealing portion 31 is formed between the working electrode 10 and the counter electrode 20. At this time, the width P of the bonding portion between the surface of the counter electrode 20 on the transparent conductive substrate 15 side and the partition portion 31b of the first integrated sealing portion 31 is equal to the surface of the counter electrode 20 on the transparent conductive substrate 15 side. The first integrated sealing portion 31 is formed so as to be narrower than the width Q of the bonding portion between the first integrated sealing portion 31 and the annular portion 31a. Further, the first integrated sealing is performed such that the width R of the partition portion 31b of the first integrated sealing portion 31 is not less than 100% and less than 200% of the width T of the annular portion 31a of the first integrated sealing portion 31. A portion 31 is formed. The formation of the first integrated sealing portion 31 may be performed under atmospheric pressure or under reduced pressure, but is preferably performed under reduced pressure.

  Next, the 2nd integrated sealing part 32 is prepared (refer FIG. 5). The second integrated sealing portion 32 has a structure formed by integrating a plurality of first sealing portions 32A. The second integrated sealing portion 32 can be obtained by preparing a single sealing resin film and forming the rectangular openings 32c corresponding to the number of DSCs 50 in the sealing resin film. The second integrated sealing portion 32 is bonded to the counter electrode 20 so as to sandwich the edge portion 20 a of the counter electrode 20 together with the first integrated sealing portion 31. The adhesion of the second integrated sealing portion 32 to the counter electrode 20 can be performed by heating and melting the second integrated sealing portion 32.

  Examples of the sealing resin film include ionomers, ethylene-vinyl acetic anhydride copolymers, modified polyolefin resins containing ethylene-methacrylic acid copolymers, ethylene-vinyl alcohol copolymers, ultraviolet curable resins, and vinyls. Examples thereof include resins such as alcohol polymers. The constituent material of the sealing resin film for forming the second integrated sealing portion 32 has a higher melting point than the constituent material of the sealing resin film for forming the first integrated sealing portion 31. It is preferable. In this case, since the second sealing portion 32A is harder than the first sealing portion 31A, it is possible to effectively prevent contact between the counter electrodes 20 of the adjacent DSCs 50. In addition, since the first sealing portion 31A is softer than the second sealing portion 32A, the stress applied to the sealing portion 30A can be effectively relieved.

  Next, the bypass diodes 70 </ b> A, 70 </ b> B, and 70 </ b> C are fixed to the partition part 32 b of the second sealing part 32. The bypass diode 70D is also fixed on the sealing portion 30A of the DSC 50D.

  Then, the conductive material 60Q is fixed to the metal substrate 21 of the counter electrode 20 of the DSCs 50B to 50C so as to pass through the bypass diodes 70A to 70D. Furthermore, each conductive material 60Q between the bypass diodes 70A and 70B, between the bypass diodes 70B and 70C, between the bypass diodes 70C and 70D, the conductive material connection portion 16A on the transparent conductive film 12A, and the conductive material connection portion on the transparent conductive film 12B. A conductive material 60P is formed so as to connect 16A and the conductive material connecting portion 16A on the transparent conductive film 12C. Further, the conductive material 60P is fixed to the metal substrate 21 of the counter electrode 20 of the DSC 50A so as to connect the conductive material connecting portion 16A on the transparent conductive film 12E and the bypass diode 70A. Further, the transparent conductive film 12D and the bypass diode 70A are connected by the conductive material 60P.

  At this time, as the conductive material 60P, a paste containing a metal material constituting the conductive material 60P is prepared, and this paste is applied from the counter electrode 20 to the conductive material connection portion 16A of the connection terminal 16 of the adjacent DSC 50 and cured. . For the conductive material 60Q, a paste containing a metal material constituting the conductive material 60Q is prepared, and this paste is applied on each counter electrode 20 so as to connect adjacent bypass diodes, and is cured. At this time, as the paste, it is preferable to use a low-temperature curable paste that can be cured at a temperature of 90 ° C. or less from the viewpoint of avoiding an adverse effect on the photosensitizing dye.

  Finally, a back sheet 80 is prepared, and the peripheral edge 80 a of the back sheet 80 is bonded to the connecting portion 14. At this time, the back sheet 80 is disposed so that the adhesive portion 80B of the back sheet 80 and the sealing portion 30A of the DSC 50 are separated from each other.

  The DSC module 100 is obtained as described above.

  In the above description, in order to form the connection terminal 16, the insulating material 33, the connecting portion 14, and the oxide semiconductor layer 13, the precursor of the connecting terminal 16, the precursor of the insulating material 33, and the precursor of the connecting portion 14. Body, the precursor of the oxide semiconductor layer 13 is baked in a lump, but the connection terminal 16, the insulating material 33, the connecting portion 14, and the oxide semiconductor layer 13 are separately fired. May be formed.

  The present invention is not limited to the above embodiment. For example, in the above-described embodiment, the DSCs 50A to 50D are arranged in a line along the X direction in FIG. 2, but like the DSC module 200 shown in FIG. The DSC 50A and the DSC 50D may be arranged so that they are adjacent to each other. In FIG. 9, the back sheet 80 is omitted. In this case, unlike the DSC module 100, the transparent conductive film 12D does not require the connection portion 12g to be provided between the main body portion 12a and the first current extraction portion 12f. For this reason, it is not necessary to provide the current collection wiring 17 either.

  Moreover, in the said embodiment, the groove | channel formed along the edge part of the part except the main-body part 12a of the transparent conductive film 12 among 90 A of 1st groove | channels, and the connection part of the back sheet 80 and the transparent conductive substrate 15 14 is not covered with the insulating material 33, but at least the second groove 90B is covered with the insulating material 33 as in the DSC module 300 shown in FIG. preferable. In FIG. 10, the back sheet 80 is omitted. As shown in FIG. 10, when at least the second groove 90 </ b> B intersects the connecting portion 14, moisture enters the space between the back sheet 80 and the transparent conductive substrate 15 through the second groove 90 </ b> B. It becomes possible. In this case, the insulating material 33 enters at least the second groove 90B, and covers the portion of the transparent conductive film 12 except the main body 12a and the edge of the second groove 90B in the first groove 90A. Thus, the penetration of moisture from the outside to the inside of the back sheet 80 is sufficiently suppressed. For this reason, the moisture that has entered the space between the back sheet 80 and the transparent conductive substrate 15 is sufficiently suppressed from entering the inside of the sealing portion 30A through the sealing portion 30A. For this reason, it is possible to sufficiently suppress a decrease in durability of the DSC module 300.

  Further, in the above-described embodiment, a part of the groove 90 is not covered with the insulating material 33. However, as in the DSC module 300 shown in FIG. It is preferable to cover the edges of the transparent conductive films 12 on both sides. In this case, since the insulating material 33 enters all the grooves 90 and covers the edges of the transparent conductive film 12 on both sides of all the grooves 90, moisture cannot enter the grooves 90 in the first place, and is formed in the grooves 90. Since moisture cannot enter the cracks, it is possible to further prevent moisture from entering through the grooves 90. In addition, since the insulating material 33 covers the edges of the transparent conductive film 12 on both sides of all the grooves 90, sufficient insulation can be ensured between the transparent conductive films 12 on both sides of the groove 90. In addition, since the insulating material 33 enters all of the first grooves 90A between the transparent conductive films 12 of the adjacent DSCs 50, the DSC module 100 further suppresses the current flowing between the transparent conductive films 12. And sufficient insulation can be ensured. For this reason, a photoelectric conversion characteristic can be improved more.

In the above embodiment, the first current extraction unit 12f and the second current extraction unit 12h are arranged around the DSC 50A side. However, as shown in the DSC module 400 shown in FIG. And the 2nd electric current extraction part 12h may be arrange | positioned around the DSC50D side. In this case, the 1st electric current extraction part 12f is provided so that it may protrude to the outer side of 30 A of sealing parts on the opposite side to DSC50C with respect to the main-body part 12a of transparent conductive film 12D. On the other hand, the second current extraction portion 12h is provided on the opposite side of the DSC 50C with respect to the main body portion 12a of the transparent conductive film 12D. A connecting portion 12i as a second connecting portion extends along the transparent conductive films 12A to 12D, and the connecting portion 12i connects the second current extraction portion 12f and the metal substrate 21 of the counter electrode 20 of the DSC 50A. Yes. Specifically, the current collection wiring 417 is provided on the connection portion 12i along the connection portion 12i, and the current collection wiring 417 and the conductive material 60P extending from the bypass diode 70A are connected. The DSC module 400 can also save space while having excellent photoelectric conversion characteristics. In this case, the resistance value of the connection portion 12i is preferably equal to or less than the resistance value represented by the following formula (1), as in the above embodiment.
Resistance value = number of DSCs 50 connected in series × 120Ω (1)

  Furthermore, in the said embodiment, although 90 A of 1st grooves are formed along the edge of the main-body part 12a of the transparent conductive film 12, as shown in FIG. 12, it follows the external shape of 30 A of cyclic | annular sealing parts. As long as it is sufficient, it does not have to be formed along the edge of the main body 12a of the transparent conductive film 12. Specifically, the first groove 90 </ b> A is formed at a position away from the annular sealing portion 30 </ b> A on the transparent conductive film 12. Even in this case, the insulating material 33 enters the first groove 90A formed along the outer shape of the annular sealing portion 30A and continuously covers the edge of the main body portion 12a.

  Moreover, in the said embodiment, although the insulating material 33 and the connection part 14 were spaced apart, as shown in FIG. 12, it is preferable that it is comprised with the same material and is integrated. In this case, the insulating material 33 and the connecting portion 14 are made of the same material and integrated. For this reason, even if moisture enters the back sheet 80, no interface is formed between the connecting portion 14 and the insulating layer 33, so that moisture can be prevented from entering in an integrated manner. Therefore, it becomes possible to have much more excellent durability.

  Moreover, in the said embodiment, although the groove | channel 90 has the 2nd groove | channel 90B, the 2nd groove | channel 90B does not necessarily need to be formed.

  Moreover, in the said embodiment, although the width | variety of the conductive material connection part 16A and the conductive material non-connection part 16B of the connection terminal 16 is made constant, the width | variety of the conductive material connection part 16A and the conductive material non-connection part 16B is respectively connected. It may change along the extending direction of the terminal 16. For example, the width of the conductive material non-connecting portion 16B monotonically increases from the end farthest from the conductive material connecting portion 16A toward the end closest to the conductive material connecting portion 16A. The width may monotonously increase from the end portion on the 16B side toward the end portion farthest from the conductive member non-connecting portion 16B. However, when the widths of the conductive material non-connecting portion 16B and the conductive material connecting portion 16A are constant, the width of the connection terminal 16 changes abruptly at the boundary between the conductive material non-connecting portion 16B and the conductive material connecting portion 16A. Therefore, the conductive material non-connecting portion 16B becomes more difficult to peel off.

  Moreover, in the said embodiment, although the electrically-conductive material connection part 16A and the electrically-conductive material non-connection part 16B are provided along the sealing part 30A, respectively, these are formed so that it may extend in the direction away from the sealing part 30A. May be. However, in this case, it is preferable that the conductive material connecting portion 16A is disposed at a position closer to the sealing portion 30A than the conductive material non-connecting portion 16B. In this case, the conductive material 60P can be made shorter.

  Alternatively, in the connection terminals 16 formed on the transparent conductive films 12A to 12C, the conductive material non-connecting portion 16B may be disposed so as to be orthogonal to the conductive material connecting portion 16A.

  Furthermore, when the object of the present invention is achieved by the first invention and the second invention, the width of the conductive material non-connecting portion 16B may be equal to or larger than the width of the conductive material connecting portion 16A.

  In the above embodiment, the second sealing portion 32A is bonded to the first sealing portion 31A. However, the second sealing portion 32A may not be bonded to the first sealing portion 31A.

  Furthermore, in the said embodiment, although 30 A of sealing parts are comprised by 31 A of 1st sealing parts and 32 A of 2nd sealing parts, 32 A of 2nd sealing parts may be abbreviate | omitted.

  Moreover, in the said embodiment, the width P of the adhesion part of the counter electrode 20 and the partition part 31b of the 1st integrated sealing part 31 is the adhesion part of the counter electrode 20 and the annular part 31a of the 1st integrated sealing part 31. Although it is narrower than the width Q, the width P of the bonding portion may be equal to or greater than the width Q of the bonding portion.

  Furthermore, in the said embodiment, the width | variety R of the partition part 31b of the 1st integrated sealing part 31 is 100% or more of the width | variety T of the annular part 31a of the 1st integrated sealing part 31, and less than 200%. However, the width R of the partition part 31b may be less than 100% of the width T of the annular part 31a of the first integrated sealing part 31, or 200% or more.

  Furthermore, in the said embodiment, although cyclic | annular 1st sealing part 31A of adjacent DSC50 is integrated, cyclic | annular 1st sealing part 31A of adjacent DSC50 is not necessarily integrated. Good. That is, the annular first sealing portions 31A may be separated from each other.

  Further, in the above-described embodiment, the back sheet 80 is provided. However, when the object of the present invention is achieved by the first invention, the back sheet 80 is not necessarily provided.

  Moreover, in the said embodiment, although the back sheet 80 and the transparent conductive film 12 are adhere | attached via the connection part 14, the back sheet 80 and the transparent conductive film 12 are not necessarily adhere | attached via the connection part 14. There is no need to be.

  Furthermore, in the said embodiment, although several DSC50 is connected in series, you may connect in parallel.

  Further, in the above embodiment, a plurality of DSCs 50 are used. However, in the present invention, only one DSC 50 may be used like the dye-sensitized solar cell element 600 shown in FIG. In the dye-sensitized solar cell element 600 shown in FIG. 13, DSC 50A to DSC 50C are omitted, and the connection terminal 16 provided on the second connection portion 12i and the metal substrate 21 of the counter electrode 20 of the DSC 50D are electrically conductive material 60P. It is electrically connected via. Further, in the dye-sensitized solar cell element 600, the connection terminal 16 includes only the conductive material connection portion 16A, and the conductive material connection portion 16A is disposed between the sealing portion 30A and the coupling portion 14. That is, the conductive material connecting portion 16A is not disposed at a position facing the side edge portion 12b of the main body portion 12a in the transparent conductive film 12D of the DSC 50D. For this reason, in the DSC module 100 of the first embodiment, the oxide semiconductor layer 13 can be expanded to the space where the conductive material connecting portion 16A is disposed. In this case, a useless space is effectively used and the power generation area can be expanded.

  Moreover, in the said embodiment, although the counter electrode 20 comprises the counter substrate, it may replace with the counter electrode 20 and may use an insulating substrate as a counter substrate. In this case, a structure including an oxide semiconductor layer, a porous insulating layer, and a counter electrode is disposed in a space between the insulating substrate, the sealing portion 30A, and the transparent conductive substrate 15. The structure can be provided on the surface of the transparent conductive substrate 15 on the counter substrate side. The structure includes an oxide semiconductor layer, a porous insulating layer, and a counter electrode in order from the transparent conductive substrate 15 side. An electrolyte is disposed in the space. The electrolyte is impregnated into the oxide semiconductor layer and the porous insulating layer. Here, as the insulating substrate, for example, a glass substrate or a resin film can be used. As the counter electrode, the same electrode as the counter electrode 20 of the above embodiment can be used. Alternatively, the counter electrode may be composed of a single porous layer containing, for example, carbon. The porous insulating layer is mainly for preventing physical contact between the porous oxide semiconductor layer and the counter electrode, and impregnating the electrolyte inside. As such a porous insulating layer, for example, an oxide fired body can be used.

  Furthermore, when the object of the present invention is achieved by the second invention, it is only necessary to satisfy the constituent requirements of the second invention, and the insulating material 33 enters the first groove 90 and continuously enters the main body 12a. There is no need to cover the edges of the.

  Hereinafter, the content of the present invention will be described more specifically with reference to examples. However, the present invention is not limited to the following examples.

Example 1
First, a laminate was prepared by forming a transparent conductive film made of FTO having a thickness of 1 μm on a transparent substrate made of glass having a thickness of 1 mm. Next, as shown in FIG. 3, CO ₂ to form a groove 90 on the transparent conductive film 12 by a laser (Universal System Co. V-460), to form a transparent conductive film 12A-12F. At this time, the width of the groove 90 was 1 mm. Each of the transparent conductive films 12A to 12C was formed so as to have a rectangular main body portion of 4.6 cm × 2.0 cm and a protruding portion protruding from one side edge portion of the main body portion. The transparent conductive film 12D was formed to have a 4.6 cm × 2.1 cm rectangular main body portion and a protruding portion protruding from one side edge of the main body portion. Further, of the transparent conductive films 12A to 12D, the projecting portions 12c of the three transparent conductive films 12A to 12C extend from the one side edge portion 12b of the main body portion 12a and the projecting portion 12d, and are adjacent to each other. The conductive film 12 is constituted by a facing portion 12e facing the main body portion 12a. Further, the projecting portion 12c of the transparent conductive film 12D is configured only by the overhanging portion 12d protruding from the one side edge portion 12b of the main body portion 12a. At this time, the length of the overhang portion 12d in the overhang direction (direction orthogonal to the X direction in FIG. 2) was 2.1 mm, and the width of the overhang portion 12d was 9.8 mm. The width of the facing portion 12e was 2.1 mm, and the length of the facing portion 12e in the extending direction was 9.8 mm.

  Further, the transparent conductive film 12D is formed to have not only the main body portion 12a and the protruding portion 12c, but also the first current extraction portion 12f and a connection portion 12g that connects the first current extraction portion 12f and the main body portion 12a. did. The transparent conductive film 12E was formed to have the second current extraction part 12h. At this time, the width of the connecting portion 12g was 1.3 mm, and the length was 59 mm. Further, the resistance value of the connecting portion 12g was measured by a four-terminal method and found to be 100Ω.

  Next, the precursor of the connection terminal 16 composed of the conductive material connection portion 16A and the conductive material non-connection portion 16B was formed on the protruding portion 12c of the transparent conductive films 12A to 12C. Specifically, the precursor of the connection terminal 16 is provided such that the precursor of the conductive material non-connecting portion 16B is provided on the overhanging portion 12d so that the precursor of the conductive material connecting portion 16A is provided on the facing portion 12e. Formed. At this time, the precursor of the conductive material non-connecting portion 16B was formed to be narrower than the width of the conductive material connecting portion 16A. The precursor of the connection terminal 16 was formed by applying and drying a silver paste (“GL-6000X16” manufactured by Fukuda Metal Foil Powder Industry Co., Ltd.) by screen printing.

  Furthermore, the precursor of the current collection wiring 17 was formed on the connection part 12g of transparent conductive film 12D. The precursor of the current collector wiring 17 was formed by applying a silver paste by screen printing and drying.

  In addition, precursors of external connection terminals 18a and 18b for taking out current to the outside were formed on the first current extraction portion 12f and the second current extraction portion 12h of the transparent conductive film 12A, respectively. The precursor of the terminal for external connection was formed by applying a silver paste by screen printing and drying.

  Further, the precursor of the insulating material 33 was formed so as to enter the first groove 90A and cover the edges of the transparent conductive film on both sides of the first groove 90A. The insulating material 33 was formed by applying and drying a paste containing glass frit by screen printing. At this time, the width of the edge of the transparent conductive film covered with the insulating material 33 was 0.2 mm from the groove 90.

  Further, in order to fix the back sheet 80, in the same manner as the insulating material 33, an annular ring made of glass frit is formed so as to surround the insulating material 33 and pass through the transparent conductive film 12D, the transparent conductive film 12E, and the transparent conductive film 12F. The precursor of the connection part 14 was formed. At this time, the precursor of the connecting portion 14 was formed so that the precursor of the current collecting wiring 17 was disposed inside thereof. Moreover, the connection part 14 was formed so that the 1st electric current extraction part and the 2nd electric current extraction part may be arrange | positioned on the outer side. The connecting part 14 was formed by applying and drying a paste containing glass frit by screen printing.

  Furthermore, the precursor of the oxide semiconductor layer 13 was formed on each main body part 12a of the transparent conductive films 12A to 12D. The precursor of the oxide semiconductor layer 13 is a porous oxide semiconductor layer forming paste containing titania (“PST-21NR” manufactured by JGC Catalysts & Chemicals Co., Ltd.) three times by screen printing, dried, and further titania. It was formed by applying a porous oxide semiconductor layer forming paste (“PST-400C” manufactured by JGC Catalysts & Chemicals Co., Ltd.) by screen printing, followed by drying.

Next, a precursor of the connection terminal 16, a precursor of the current collector wiring 17, a precursor of the external connection terminals 18a and 18b, a precursor of the insulating material 33, a precursor of the connecting portion 14, a precursor of the insulating material 33, The precursor of the oxide semiconductor layer 13 was baked at 500 ° C. for 15 minutes to form the connection terminal 16, the current collector wiring 17, the external connection terminals 18 a and 18 b, the connecting portion 14, the insulating material 33, and the oxide semiconductor layer 13. . At this time, the width of the conductive material connection portion of the connection terminal 16 was 1.0 mm, and the width of the conductive material non-connection portion was 0.3 mm. Further, the length along the extending direction of the conductive material connecting portion was 7.0 mm, and the length along the extending direction of the conductive material non-connecting portion was 7.0 mm. The dimensions of the current collector wiring 17, the external connection terminals 18 a and 18 b, the connecting portion 14, and the oxide semiconductor layer 13 were as follows.

Current collecting wiring 17: thickness 4 μm, width 200 μm, length 79 mm along the X direction in FIG. 2, length 21 mm along the direction orthogonal to the X direction in FIG.
External connection terminals 18a and 18b: thickness 20 μm, width 2 mm, length 7 mm
Connecting part 14: 50 μm, width 3 mm
Oxide semiconductor layer 13: 13 μm thick, 17 mm length in the X direction in FIG. 2, 42.1 mm length in the direction orthogonal to the X direction in FIG.

  Next, the working electrode is immersed overnight in a dye solution containing 0.2 mM of a photosensitizing dye composed of N719 and a solvent in which acetonitrile and tert-butanol are mixed at a volume ratio of 1: 1. Then, it was taken out and dried, and a photosensitizing dye was supported on the oxide semiconductor layer.

  Next, on the oxide semiconductor layer, in a solvent composed of 3-methoxypropionitrile, hexylmethylimidazolium iodide 2M, n-methylbenzimidazole 0.3M, and guanidinium thiocyanate 0.1M are formed. The electrolyte was applied and dried to place the electrolyte.

  Next, a first integrated sealing portion forming body for forming the first sealing portion was prepared. The first integrated sealing portion forming body prepares one sealing resin film made of maleic anhydride-modified polyethylene (trade name: Binnel, manufactured by DuPont) of 8.0 cm × 4.6 cm × 50 μm, It was obtained by forming four rectangular openings in the sealing resin film. At this time, each opening has a size of 1.7 cm × 4.4 cm × 50 μm, the width of the annular portion is 2 mm, and the width of the partition portion that partitions the inner opening of the annular portion is 2.6 mm. The 1st integrated sealing part formation body was produced.

  Then, after the first integrated sealing portion forming body is overlaid on the insulating material 33 of the working electrode, the first integrated sealing portion forming body is bonded to the insulating material 33 of the working electrode by heating and melting. It was.

  Next, four counter electrodes were prepared. Of the four counter electrodes, two counter electrodes were prepared by forming a catalyst layer of platinum having a thickness of 5 nm on a 4.6 cm × 1.9 cm × 40 μm titanium foil by sputtering. The remaining two counter electrodes among the four counter electrodes were prepared by forming a catalyst layer made of platinum having a thickness of 5 nm on a 4.6 cm × 2.0 cm × 40 μm titanium foil by sputtering. In addition, another first integrated sealing portion forming body was prepared, and this first integrated sealing portion forming body was adhered to the surface of the counter electrode facing the working electrode in the same manner as described above. .

Then, the first integrated sealing portion forming body bonded to the working electrode and the first integrated sealing portion forming body bonded to the counter electrode are opposed to each other, and the first integrated sealing portion forming bodies are overlapped with each other. Combined. In this state, the first integrated sealing portion forming body was heated and melted while pressurizing the first integrated sealing portion forming body. Thus, the first sealing portion was formed between the working electrode and the counter electrode. At this time, the width P of the bonded portion between the partition portion of the first integrated sealing portion and the surface on the transparent conductive substrate side of the counter electrode, and the transparent conductive portion of the annular portion and the counter electrode of the first integrated sealing portion. The width Q of the bonded portion with the surface on the conductive substrate side, the width R of the partition portion of the first integrated sealing portion, and the width T of the annular portion were as follows.

P = 1.0mm
Q = 2.0mm
R = 2.6mm
T = 2.2mm

  Next, a second integrated sealing part was prepared. The second integrated sealing portion is prepared by preparing a sealing resin film made of maleic anhydride-modified polyethylene (trade name: Binnel, manufactured by DuPont) of 8.0 cm × 4.6 cm × 50 μm. It was obtained by forming four rectangular openings in the stopping resin film. At this time, each opening has a size of 1.7 cm × 4.4 cm × 50 μm, the width of the annular portion is 2 mm, and the width of the partition portion that partitions the inner opening of the annular portion is 2.6 mm. A second integrated sealing portion was prepared. The second integrated sealing portion was bonded to the counter electrode so as to sandwich the edge of the counter electrode together with the first integrated sealing portion. At this time, the first integrated sealing portion and the second integrated sealing portion were bonded to the counter electrode and the first integrated sealing portion by heating and melting while pressing the second integrated sealing portion against the counter electrode.

  Next, the desiccant sheet was affixed with the double-sided tape on the metal substrate of each counter electrode. The dimensions of the desiccant sheet were 1 mm thick × 3 cm long × 1 cm wide, and a zeo sheet (trade name, manufactured by Shinagawa Kasei Co., Ltd.) was used as the desiccant sheet.

  Next, as shown in FIG. 2, bypass diodes 70 </ b> A to 70 </ b> C are respectively provided in the three partition portions of the second integrated sealing portion, and a low-temperature curing type silver paste (Dotite D500 manufactured by Fujikura Kasei Co., Ltd.) is used. It fixed by apply | coating so that it might connect with the metal substrate 21 of the counter electrode 20 from the terminal of both ends. Further, among the four DSCs 50A to 50D, the bypass diode 70D is connected to the annular part of the second integrated sealing part of the DSC 50D, and the low-temperature curing type silver paste is connected to the counter electrode from one of the terminals at both ends of the diode. It was fixed by applying as follows. Thus, the conductive material 60Q was formed so as to connect the two adjacent bypass diodes to the four bypass diodes 70A to 70D. At this time, the conductive material 60Q was formed by curing the low temperature curable silver paste at 30 ° C. for 12 hours. As the bypass diode, RB751V-40 manufactured by ROHM was used.

  Further, a low temperature curing type silver paste (Dotite D-500, manufactured by Fujikura Kasei Co., Ltd.) is used so as to connect each conductive material 60Q between the bypass diodes and the conductive material connecting portions on the three transparent conductive films 12A to 12C. The conductive material 60P was formed by applying and curing. Further, with respect to the bypass diode 70A, the conductive material 60P was formed by applying and curing the low-temperature curable silver paste so as to be connected to the conductive material connecting portion on the transparent conductive film 12E. At this time, the conductive material 60P was formed by curing the low temperature curable silver paste at 30 ° C. for 12 hours.

  Next, butyl rubber (“Aikamelt” manufactured by Aika Kogyo Co., Ltd.) was applied onto the connecting portion 14 with a dispenser while heating at 200 ° C. to form a precursor of the bonded portion. On the other hand, a laminate is prepared by laminating a film (thickness 50 μm) made of polybutylene terephthalate (PBT) resin film (thickness 50 μm), aluminum foil (thickness 25 μm), and binel (trade name, manufactured by DuPont) in this order. did. And it piled up on the peripheral part of this laminated body 80A, and the precursor of the adhesion part 80B, and pressurized for 10 seconds. In this way, a back sheet 80 composed of the bonding portion 80B and the laminated body 80A was obtained at the connecting portion 14. A DSC module was obtained as described above.

(Example 2)
The DSC module is the same as in Example 1 except that the insulating material 33 made of glass frit enters the second groove 90B and covers the edge of the transparent conductive film 12 forming the second groove 90B. Was made. The edge of the transparent conductive film covered with the insulating material 33 was a portion 0.2 mm from the groove.

(Example 3)
A DSC module was produced in the same manner as in Example 2 except that the width of the edge of the transparent conductive film 12 covered with the insulating material 33 was 0.5 mm from the groove 90.

(Comparative Example 1)
A DSC module was produced in the same manner as in Example 1 except that the insulating material 33 was not formed.

Example 4
After forming the connection terminal 16, the current collector wiring 17, the external connection terminals 18 a and 18 b, the coupling portion 14, and the oxide semiconductor layer 13, before the photosensitizing dye is supported on the oxide semiconductor layer, the insulating material 33 A DSC module was produced in the same manner as in Example 1 except that a paste containing a polyimide resin was printed and baked at 350 ° C. for 1 hour.

(Example 5)
A DSC module was produced in the same manner as in Example 1 except that the connecting portion was not formed.

(Example 6)
A DSC module was produced in the same manner as in Example 1 except that the insulating material was not formed.

(Example 7)
A DSC module was produced in the same manner as in Example 1 except that the width of the conductive material non-connection portion was set to 1/3 times the width of the conductive material connection portion.

(Example 8)
A DSC module was produced in the same manner as in Example 1 except that the width of the conductive member non-connecting portion 16 was the same as the width of the conductive member connecting portion 16.

(Characteristic evaluation)
(Durability 1)
For the DSC modules obtained in Examples 1 and 2 and Comparative Example 1, the output (η ₀ ) was measured. Then, about the DSC module obtained in Examples 1-2 and the comparative example 1, the output ((eta)) after performing the heat cycle test according to JISC8938 was also measured. And the following formula:
Retention rate of photoelectric conversion efficiency (%) = η / η ₀ × 100
Based on the above, the output retention rate (output retention rate) was calculated. The results are shown in Table 1.

(Durability 2)
About the DSC module obtained in Examples 4-6, the photoelectric conversion efficiency ((eta) ₀ ) was measured. Then, about the DSC module obtained in Examples 4-6, the photoelectric conversion efficiency ((eta)) after performing the heat cycle test according to JISC8938 was also measured. And the following formula:
Retention rate of photoelectric conversion efficiency (%) = η / η ₀ × 100
Based on the above, the retention rate of photoelectric conversion efficiency (photoelectric conversion retention rate) was calculated. The results are shown in Table 2.

(Connection reliability)
The connection reliability was evaluated by conducting a heat cycle test according to JIS C 8938 on the DSC modules obtained in Examples 7 to 8 and examining the presence or absence of peeling of the connection terminals from the transparent conductive film. The results are shown in Table 3. In addition, the heat cycle test 1 was performed 200 cycles when the cycle which raises or falls environmental temperature from -40 degreeC to 90 degreeC was made into 1 cycle.

  As shown in Table 1, it was found that the DSC modules of Examples 1 to 3 showed a higher output retention rate than the DSC module of Comparative Example 1. Moreover, it turned out that the DSC module of Examples 1-3 shows a high output compared with the DSC module of the comparative example 1.

  From the above, it was confirmed that the DSC element of the present invention has excellent durability.

DESCRIPTION OF SYMBOLS 11 ... Transparent substrate 12 ... Transparent electrically conductive film 12a ... Main-body part 12c ... Protrusion part 12e ... Opposite part 13 ... Oxide semiconductor layer 14 ... Connection part 15 ... Transparent conductive substrate (conductive substrate)
DESCRIPTION OF SYMBOLS 16 ... Connection terminal 16A ... Conductive material connection part 16B ... Conductive material non-connection part 20 ... Counter electrode (opposite substrate)
DESCRIPTION OF SYMBOLS 21 ... Metal substrate 30A ... Sealing part 33 ... Insulating material 50, 50A-50D ... Dye-sensitized solar cell 60P, 60Q ... Conductive material 80 ... Back sheet 80B ... Adhesive part 90 ... Groove 90A ... First groove 90B ... First Two grooves 100, 200, 300, 400, 500 ... Dye-sensitized solar cell module (dye-sensitized solar cell element)
600 ... Dye-sensitized solar cell element

Claims (11)

Having at least one dye-sensitized solar cell;
The dye-sensitized solar cell is
A conductive substrate having a transparent conductive film provided on one surface of the transparent substrate and the transparent substrate;
A counter substrate facing the conductive substrate;
An oxide semiconductor layer provided on the conductive substrate or the counter substrate;
An annular sealing portion that joins the conductive substrate and the counter substrate;
The transparent conductive film has a main body portion disposed inside the sealing portion,
A groove is formed in the transparent conductive film, and at least a part of the groove has a first groove formed along the outer shape of the sealing portion,
The insulating material enters at least a part of the first groove and continuously covers the edge of the main body ,
The sealing portion is made of resin;
It said insulating material is made of an inorganic material, color Motozo sensitized solar cell element.   The dye-sensitized solar cell element according to claim 1, wherein the insulating material is provided over the entire circumference along the outer shape of the sealing portion. Having at least one dye-sensitized solar cell;
The dye-sensitized solar cell is
A conductive substrate having a transparent conductive film provided on one surface of the transparent substrate and the transparent substrate;
A counter substrate facing the conductive substrate;
An oxide semiconductor layer provided on the conductive substrate or the counter substrate;
An annular sealing portion that joins the conductive substrate and the counter substrate;
The transparent conductive film has a main body portion disposed inside the sealing portion,
A groove is formed in the transparent conductive film, and at least a part of the groove has a first groove formed along the outer shape of the sealing portion,
The insulating material enters at least a part of the first groove and continuously covers the edge of the main body, and the dye-sensitized solar cell element,
At least a portion of the first groove is separated from the sealing portion outside the sealing portion;
Wherein A on the transparent conductive film of at least one of the dye-sensitized solar cell, said that having a current collector wire between the sealing portion and the first groove, the color Motozo sensitized solar cell element. A back sheet that covers the dye-sensitized solar cell on the one surface side of the transparent substrate;
The groove is
The first groove;
A second groove that is formed along an edge of the transparent conductive film excluding the main body and intersects with a peripheral edge of the backsheet;
The dye sensitization according to any one of claims 1 to 3, wherein the insulating material enters the second groove and covers an edge portion of the transparent conductive film excluding the main body portion. Solar cell element.   5. The dye-sensitized solar cell element according to claim 4, wherein an insulating connecting portion is provided on the entire periphery of the peripheral portion of the back sheet on the conductive substrate.   The dye-sensitized solar cell element according to claim 5, wherein the insulating material and the connecting portion are made of the same material and integrated.   The dye-sensitized solar cell element according to any one of claims 1 to 6, wherein the insulating material enters all the grooves and covers edges of the transparent conductive film on both sides of all the grooves. Having at least one dye-sensitized solar cell;
The dye-sensitized solar cell is
A conductive substrate having a transparent conductive film provided on one surface of the transparent substrate and the transparent substrate;
A counter substrate facing the conductive substrate;
An oxide semiconductor layer provided on the conductive substrate or the counter substrate;
An annular sealing portion that joins the conductive substrate and the counter substrate;
The transparent conductive film has a main body portion disposed inside the sealing portion,
A groove is formed in the transparent conductive film, and at least a part of the groove has a first groove formed along the outer shape of the sealing portion,
The insulating material enters at least a part of the first groove and continuously covers the edge of the main body, and the dye-sensitized solar cell element,
A backsheet that covers the at least one dye-sensitized solar cell on the one surface side of the transparent substrate;
The back sheet has an adhesive portion that bonds the back sheet to the conductive substrate;
The adhesive portion that are spaced apart from the sealing portion, the color Motozo sensitized solar cell element.   The insulating connection part is provided on the conductive substrate on the entire periphery of the back sheet, and the adhesion part of the back sheet is bonded to the connection part. Dye-sensitized solar cell element. The insulating material is provided between the sealing portion and the conductive substrate;
The conductive substrate comprises a first electrode;
The dye-sensitized solar cell element according to claim 9, wherein the counter substrate is constituted by a second electrode. Having at least one dye-sensitized solar cell;
The dye-sensitized solar cell is
A conductive substrate having a transparent conductive film provided on one surface of the transparent substrate and the transparent substrate;
A counter substrate facing the conductive substrate;
An oxide semiconductor layer provided on the conductive substrate or the counter substrate;
An annular sealing portion that joins the conductive substrate and the counter substrate;
The transparent conductive film has a main body portion disposed inside the sealing portion,
A groove is formed in the transparent conductive film, and at least a part of the groove has a first groove formed along the outer shape of the sealing portion,
The insulating material enters at least a part of the first groove and continuously covers the edge of the main body, and the dye-sensitized solar cell element,
Having a plurality of the dye-sensitized solar cells, the plurality of dye-sensitized solar cells are connected in series and electrically,
Among the plurality of dye-sensitized solar cells, the dye-sensitized solar cell connected to an adjacent dye-sensitized solar cell is
A connection terminal provided on the transparent conductive film;
The counter substrate has a metal substrate;
The transparent conductive film is
A main body provided inside the annular sealing portion;
Projecting from the main body part to the outside of the sealing part, and having a projecting part provided with the connection terminal
The connection terminal in one dye-sensitized solar cell of two adjacent dye-sensitized solar cells and the metal substrate of the counter substrate in the other dye-sensitized solar cell are connected via a conductive material,
The connection terminal is
A conductive material connecting portion connected to the conductive material and extending along a certain direction outside the sealing portion;
A conductive material non-connecting portion extending along a certain direction from the conductive material connecting portion outside the sealing portion;
The width of the conductive material unconnected portion, the conductive material connecting unit width than not narrow, color Motozo sensitized solar cell element.

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