A solar module and a method for fabricating a solar module comprising a plurality of rear contact solar cells are described. Rear contact solar cells (1) are provided with a large size of e.g. 156×156 mm.sup.2, Soldering pad arrangements (13, 15) applied on emitter contacts (5) and base contacts (7) are provided with one or more soldering pads (9, 11) arranged linearly. The soldering pad arrangements (13, 15) are arranged asymmetrically with respect to a longitudinal axis (17). Each solar cell (1) is then separated into first and second cell portions (19, 21) along a line (23) perpendicular to the longitudinal axis (17). Due to such cell separation and the asymmetrical design of the soldering pad arrangements (13, 15), the first and second cell portions (19, 21) may then be arranged alternately along a line with each second cell portion (21) arranged in a 180°-orientation with respect to the first cell portions (19) and such that emitter soldering pad arrangements (13) of a first cell portion (19) are aligned with base soldering pad arrangements (15) of neighboring second cell portions (21), and vice versa. Simple linear ribbon-type connector strips (25) may be used for interconnecting the cell portions (19, 21) by soldering onto the underlying aligned emitter and base soldering pad arrangements (13, 15). The interconnection approach enables using standard ribbon-type connector strips (25) while reducing any bow as well as reducing series resistance losses.

This solar panel (12) includes a structure (14) and at least two photovoltaic cells (16A, 16B) each defining a lateral contact face (30A, 30B) and including a base element (20A, 20B), a grid of electric conductors (24A, 24B) and a protective element (22A, 22B) made from transparent material, the grid (24A, 24B) including at least one conductive wire extending along the lateral contact face (30A, 30B). The cells (16A, 16B) are arranged on the structure (14) such that at least part of each of the lateral contact faces (30A, 30B) is arranged across from the other part. The solar panel (12) further includes a barrier (18A) made from dielectric material arranged on the structure (14) between the lateral contact faces and extending along the opposite parts of these faces (30A, 30B).

A series-connected solar cell module is provided, which includes multiple solar cell units. each of the multiple solar cell units comprises multiple solar cells. In each of the multiple solar cell units, a back surface of one of two adjacent solar cells is electrically connected to a front surface of the other of the two adjacent solar cells through a conductive material. A first insulating layer and a second insulating layer are provided at positions where the conductive material is in close contact with the two adjacent solar cells. Therefore, adjacent solar cells can be arranged in close contact with each other, to achieve a seamless contact, thereby increasing the effective area of the series-connected solar cell module.

A solar cell and a solar cell module are disclosed. The solar cell module includes a plurality of solar cells each including a semiconductor substrate and first and second electrodes on the semiconductor substrate, the first and second electrodes being alternately positioned in a first direction and extended in a second direction intersecting the first direction, a first conductive line extended in the first direction to intersect the first and second electrodes, connected to the first electrode by a first conductive layer, and insulated from the second electrode by an insulating layer, and a second conductive line positioned in parallel with the first conductive line, connected to the second electrode by the first conductive layer, and insulated from the first electrode by the insulating layer.

A thermoelectric module of the invention includes: first and second thermoelectric elements; a first electrode having a plate-shaped body whose first surface is bonded to a first end surface of the first thermoelectric element and a first end surface of the second thermoelectric element; a second electrode bonded to a second end surface of the first thermoelectric element; and a third electrode bonded to a second end surface of the thermoelectric element. The first electrode includes: a first cutout formed at a first side in a width direction; and a second cutout formed at a second side in the width direction. In the width direction, at least one of the first cutout or the second cutout is present in a section between the first side and the second side of the first electrode.

The invention relates to a method of interconnecting photovoltaic cells into a module by using a tape carrying tabbing wires. The tape makes possible to build modules at a reduced cost. In the tape method individual photovoltaic cells (1) are interconnected into modules by using electrical interconnecting conducting strips (21, 43, 52, 74a, 74b) carried by a tape (51). The strips are laid out on the topsides and backsides of the PV cells. The strips are cut in such a manner that the cells will be interconnected in series after lamination. The present invention concerns an improvement of the tape used in the tape method.

A solar device includes a first string of first solar wafers, wherein a plurality of the first solar wafers each overlap with at least one vertically adjacent solar wafer from the first string. Additionally, the solar device includes a second string of second solar wafers, wherein a plurality of the second solar wafers each overlap with at least one vertically adjacent solar wafer from the second string, wherein a plurality of the first solar wafers overlap with one or more of the plurality of second solar wafers to electrically connect horizontally adjacent solar wafers in parallel.

An interconnection structure used for sequentially bonding at least two cell slices and forming an excellent electrical connection. At least one of a front electrode and a back electrode of the cell slice is in a hollow structure, and the back electrode of the previous back electrode is connected with the front electrode of the next cell slice adjacent thereto through a conductive adhesive, thereby saving a large amount of front and back electrode paste, and reducing the cost of the shingled cell.

An interconnection piece (200) and a solar cell assembly, which relate to the technical field of photovoltaics and which ensure the normal interconnection of cell pieces, while also inhibiting the degree of deformation of back contact cells during welding. The interconnection piece (200) includes a flexible insulation substrate (210) and a plurality of structural welding strips (220) that are spaced apart on the flexible insulation substrate (210). Each structural welding strip (220) is provided with two welding portions and a connecting portion (221) located between the two welding portions. The connecting portions (221) are connected to two welding portions, respectively. At least part of each connecting portion (221) is located in the flexible insulation substrate (210), and the two welding portions extend out of the flexible insulation substrate (210). The solar cell assembly includes the interconnection piece (200) mentioned above.

An interconnecting member of a solar cell panel for connecting a plurality of solar cells, can include a core layer and a solder layer formed on a surface of the core layer, in which the core layer includes a protruding portion having a peak portion extending along a longitudinal direction of the core layer, and a reflection surface having an inclined surface or a rounded portion disposed at opposite sides of the peak portion, and a width of the protruding portion increases from the peak portion towards a center of the core layer.