The present invention relates to a photovoltaic device (1). The device comprises a solar cell unit (2) comprising a porous light-absorbing layer (3) at a top side (2a), of a porous first conducting layer (4), a porous substrate (5) of an insulating material. The solar cell unit comprises a conducting medium. The photovoltaic device comprises a first conductor (7) in electrical contact with the first conducting layer (4), a second conductor (8) in electrical contact with the second conducting layer (6), and an encapsulation (9) encapsulating the solar cell unit. The encapsulation comprises a top sheet (9a) and a bottom sheet (9b). The first and second conductors (7, 8) are arranged between the encapsulation (9) and the solar cell unit (2) at the bottom side (2b) of the solar cell unit (2). The second conductor (8) is arranged between the second conducting layer (6) and the bottom sheet (9b) of the encapsulation (9), and the first conductor (7) is arranged between the porous substrate (5) and the bottom sheet (9b). The first conductor (7) is electrically insulated from the second conducting layer (6). A part (14) of the porous substrate (5) comprises conducting material (12) disposed between the first conductor (7) and the first conducting layer (4) to provide electrical contact between the first conductor and the first conducting layer.

The dye-sensitized solar cell comprises a first electrode including a porous semiconductor layer supporting a dye; and a second electrode serving as a counter electrode of the first electrode. The second electrode includes a counter electrode conductive layer containing an absorbent supporting a dye that is the same as or different from the dye supported by the porous semiconductor layer.

Composites comprising an exfoliated graphite support material having a degree of graphitization g in an range of 50 to 93%, obtained by XRD Rietveld analysis, which is coated with ZnO nanoparticles. These composites are produced by three different methods: A) (syn) the method comprises the following consecutive steps: i) a Zn(II)salt is dissolved in a solvent ii) graphite and a base are added simultaneously iii) the mixture is stirred under impact of ultrasound iv) the solvent is removed from the suspension or B) (pre) the method comprises the following consecutive steps: i) graphite is suspended in a solvent and exfoliated via impact of ultrasound ii) a Zn(II)salt and a base are added simultaneously forming nano-ZnO particles iii) the mixture is stirred iv) the solvent is removed from the suspension or C) (post) the method comprises the following steps: i) a Zn(II)salt and a base are mixed in a solvent in a first reactor forming nano-ZnO particles ii) graphite is exfoliated via impact of ultrasound in a second reactor iii) both suspensions of i) and ii) are mixed together iv) after step iii) the solvent is removed from the suspension. These coated composites may be tempered in a further step and again coated and again tempered.

Methods and devices for forming painted circuits using multiple layers of electrically conductive paint. In one aspect, a painted circuit includes a substrate (111) and one or more paint layer (106, 108, 110, 112, 114, 116, 120, 122) applied to the substrate, where the one or more paint layers each form an electrical component of the painted circuit. A given paint layer of the one or more paint layers includes a conductive paint formulation having a resistance that is defined by a concentration of conductive material that is included in the conductive paint formulation and a thickness of the given paint layer, and lower concentrations of the conductive material included in the conductive paint formulation provide a higher resistance than higher concentrations of conductive material.

A solar cell module (100) includes: one or more cells that are enclosed by a barrier packaging material (13A, 13B) and that include first and second base plates (3, 7) and a functional layer; and first and second lead-out electrodes (11A, 11B) that are respectively connected to electrodes (2, 6) disposed at the sides of the respective base plates (3, 7) via electrical connectors (12A, 12B). The electrical connectors (12A, 12B) are separated from the functional layer in a base plate surface direction. The lead-out electrodes (11A, 11B) are disposed on an outer surface of the barrier packaging material (13A, 13B). Gaps between the barrier packaging material (13A, 13B) and the lead-out electrodes (11A, 11B) are sealed by a lead-out electrode seal (15).

The present invention relates to a dye-sensitized solar cell unit (1) comprising:—a working electrode comprising a porous light-absorbing layer (10),—a porous first conductive layer (12) including conductive material for extracting photo-generated electrons In from the light-absorbing layer (10),—a porous insulating layer (105) made of an insulating material,—a counter electrode comprising a porous catalytic conductive layer (106) formed on the opposite side of the porous insulating layer (105), and—an ionic based electrolyte for transferring electrons from the counter electrode to the working electrode and arranged in pores of the porous first conductive layer (12), the porous catalytic conductive layer (106), and the porous insulating layer (105), wherein the first conductive layer (12) comprises an insulating oxide layer (109) formed on the surfaces of the conductive material, and the porous catalytic conductive layer (106) comprises conductive material (107′) and catalytic particles (107″) distributed in the conductive material for improving the transfer of electrons from the conductive material (107″) to the electrolyte.

Disclosed is a bus stop using a large-scale perovskite solar cell in which a perovskite solar cell is prepared using a hybrid structure including a graphene-carbon nanotube. The bus stop includes a body unit fixed to the ground to maintain the overall shape, a solar cell unit for producing electrical energy from sunlight, and an energy storage system (ESS) for storing the electrical energy produced by the solar cell part.

The quantum dot-sensitized solar cell (QDSSC) includes a photoelectrode, a counter electrode, and an electrolyte sandwiched between the photoelectrode and the counter electrode. The photoelectrode is formed from a titanium dioxide (TiO.sub.2) layer, a cadmium sulfide (CdS) quantum dot sensitizer layer, and a tin dioxide (SnO.sub.2) nanograss layer sandwiched between the titanium dioxide (TiO.sub.2) layer and the cadmium sulfide (CdS) quantum dot sensitizer layer.

A method for manufacturing a photoelectric conversion device, that includes: forming a laminate structure of a substrate, a transparent electrode, an active layer produced by wet-coating, and a counter electrode, stacked in this order; and thereafter forming a cavity by: (a) pressing an adhesive material just against a defect formed on the surface of said counter electrode, and then peeling off said adhesive material together with said defect and the peripheral part thereof; or (b) sucking a defect formed on the surface of said counter electrode, so as to remove said defect and the peripheral part thereof, where said cavity penetrates through the counter electrode and unreached to the transparent electrode.

The present invention provides a hybrid ferroelectric discotic liquid crystal solar cell by incorporating an electrolyte composition for improving power conversion efficiency of the solar cell. The hybrid ferroelectric (FE) discotic liquid crystal solar cell comprises a first layer of n-type inorganic semiconductor deposited on conductive fluorine doped tin oxide (FTO) glass plate 101, a second thin layer of light absorbing inorganic sensitizer 103; wherein the inorganic sensitizer strained titania FTO glass-plate acts as a photo anode, a third layer of ferroelectric discotic liquid crystal electrolyte 104 applied between the photo anode and a photo cathode and a fourth layer of reflective platinum deposited FTO glass-plate 105 configured to act as the photo cathode. The ferroelectric discotic liquid crystal electrolyte composition comprises of an achiral HAT6 discotic molecule (2,3,6,7,10,11-Hexakis-hexyloxy triphenylene) and at least two additives, wherein the additives includes tertiary butyl pyridine (t-bPy) and lithium bis(trifluoromethylsulphonyl)imide Li[CF3SO2]2N.