An embodiment converter includes a magnetic material, a first circuit including a first winding surrounding the magnetic material and a clamp circuit configured to reset a power conversion operation, the first circuit being configured to convert power received from a first input voltage source to provide the converted power to a load, and a second circuit including a second winding surrounding the magnetic material, the second circuit being configured to convert power received from a second input voltage source to provide the converted power to the load and to perform the power conversion operation being reset by the clamp circuit.

An embodiment converter includes a magnetic material, a first circuit including a first winding surrounding the magnetic material and a clamp circuit configured to reset a power conversion operation, the first circuit being configured to convert power received from a first input voltage source to provide the converted power to a load, and a second circuit including a second winding surrounding the magnetic material, the second circuit being configured to convert power received from a second input voltage source to provide the converted power to the load and to perform the power conversion operation being reset by the clamp circuit.

A method includes providing a mandrel having an electrical conduit electroformed in the mandrel. The second side of the electrical conduit is blackened while in the mandrel to create a black layer on the electrical conduit. The mandrel is aligned in a flatness fixture such that the mandrel is substantially flat. The mandrel remains flat and in a fixed relationship to the flatness fixture throughout the method. A beam of a laser is controlled toward the black layer. The beam has laser parameters including a power output, a frequency and a mark speed, and selected by setting the power output and the mark speed then determining the frequency. The beam removes a plurality of the portions of the black layer. Each removed portion of the plurality of the portions has a thickness equal to the black layer thickness, and a portion area of 9 mm.sup.2 to 18 mm.sup.2.

A method includes providing a mandrel having an electrical conduit electroformed in the mandrel. The second side of the electrical conduit is blackened while in the mandrel to create a black layer on the electrical conduit. The mandrel is aligned in a flatness fixture such that the mandrel is substantially flat. The mandrel remains flat and in a fixed relationship to the flatness fixture throughout the method. A beam of a laser is controlled toward the black layer. The beam has laser parameters including a power output, a frequency and a mark speed, and selected by setting the power output and the mark speed then determining the frequency. The beam removes a plurality of the portions of the black layer. Each removed portion of the plurality of the portions has a thickness equal to the black layer thickness, and a portion area of 9 mm.sup.2 to 18 mm.sup.2.

A system includes a plurality of photovoltaic modules installed on a roof deck in an array and at least one jumper module electrically connecting a first subarray to a second subarray of the array. The jumper module includes at least one electrical bussing and an encapsulant encapsulating the at least one electrical bussing. The jumper module includes a frontsheet juxtaposed with the encapsulant. The frontsheet includes a first layer and a polymer layer attached to the first layer.

A high efficiency configuration for a string of solar cells comprises series-connected solar cells arranged in an overlapping shingle pattern. Front and back surface metallization patterns may provide further increases in efficiency.

A high efficiency configuration for a string of solar cells comprises series-connected solar cells arranged in an overlapping shingle pattern. Front and back surface metallization patterns may provide further increases in efficiency.

There is a dynamically adjustable photovoltaic (PV) system for transforming solar energy into electrical energy. The dynamically adjustable PV system includes a first PV fold including a first set of PV cells for generating electrical energy, and a first laminating film that encapsulates the first set of PV cells; a second PV fold including a second set of PV cells for generating electrical energy, and a second laminating film that encapsulates the second set of PV cells; and a connecting mechanism that connects the first laminating film to the second laminating film. The connecting mechanism includes a chamber.

A panel connected body includes a plurality of flat panels arranged in a matrix of m rows and n columns, where m≥3 and n≥3; and a plurality of row-direction connection portions and column-direction connection portions which connect together panels that are adjacent in a row direction and column direction, respectively. A first type row satisfying relationships D.sub.1≥2L and D.sub.y≥D.sub.y−1−2L and a second type row satisfying relationships D.sub.n≥2L and D.sub.y≥D.sub.y+1+2L are alternately included, where D.sub.y is a length along the column direction of the column-direction connection portions in a y-th column, and L is a thickness of the panels. The relationship E≤W.sub.C−L is satisfied, where W.sub.C is a length along the column direction of the panels and E is a length along the column direction of the row-direction connection portions.

Provided is a photovoltaic module, including a first intermediate busbar having a first lead-out terminal provided at an end thereof; a second intermediate busbar having a second lead-out terminal provided at an end thereof; and a first jumper wire arranged on a first isolation bar; the first lead-out terminal and the second lead-out terminal are located on two opposite sides of the first jumper wire, and the first lead-out terminal and the second lead-out terminal abut against two opposite side surfaces of the first isolation bar or overlap a top surface of the first isolation bar. Compared with the related art, the first isolation bar where the first jumper wire is located is clamped or pressed by the first lead-out terminal and the second lead-out terminal, to prevent short circuit or shielding of the cell caused by free movement of the first jumper wire, the first and second intermediate busbars.