An insulation paste for forming a protective layer of a solar cell device includes: a siloxane resin; an organic solvent; and multiple fillers each having a surface covered with an organic coating containing at least one material different from a material of the siloxane resin. A method for producing the insulation paste includes: preparing the multiple fillers; and mixing together a precursor of the siloxane resin, water, a catalyst, an organic solvent, and the multiple fillers. A method for manufacturing a solar cell device includes: applying the insulation paste to the passivation layer; and drying the insulation paste to form the protective layer on the passivation layer. A solar cell device includes: the passivation layer located on a semiconductor region; and the protective layer located on the passivation layer and including a siloxane resin and dimethylpolysiloxane.

An insulation paste for forming a protective layer of a solar cell device includes: a siloxane resin; an organic solvent; and multiple fillers each having a surface covered with an organic coating containing at least one material different from a material of the siloxane resin. A method for producing the insulation paste includes: preparing the multiple fillers; and mixing together a precursor of the siloxane resin, water, a catalyst, an organic solvent, and the multiple fillers. A method for manufacturing a solar cell device includes: applying the insulation paste to the passivation layer; and drying the insulation paste to form the protective layer on the passivation layer. A solar cell device includes: the passivation layer located on a semiconductor region; and the protective layer located on the passivation layer and including a siloxane resin and dimethylpolysiloxane.

An insulator pin for overhead electrical lines has a frangible portion. The pin has an elongate support for attachment to an electrical distribution pole and a body. The body has a connector for an insulator, a frangible portion and an elongate support holding portion from which the elongate support extends. Preferably the elongate support is a bolt. The frangible portion permits the body to break into two pieces for preventing damage to electrical distribution poles from forces transverse to the overhead electrical line. The frangible portion is located between the connector and the elongate support holding portion. The insulator pin may be attached to an electrical distribution pole to protect the pole from forces transverse to an overhead electrical lines supported by the pole. A method of making the insulator pin by molding is disclosed.

An insulator pin for overhead electrical lines has a frangible portion. The pin has an elongate support for attachment to an electrical distribution pole and a body. The body has a connector for an insulator, a frangible portion and an elongate support holding portion from which the elongate support extends. Preferably the elongate support is a bolt. The frangible portion permits the body to break into two pieces for preventing damage to electrical distribution poles from forces transverse to the overhead electrical line. The frangible portion is located between the connector and the elongate support holding portion. The insulator pin may be attached to an electrical distribution pole to protect the pole from forces transverse to an overhead electrical lines supported by the pole. A method of making the insulator pin by molding is disclosed.

A system for the manufacturing of high-fidelity insulated components is described. Per field requirements, components crafted via the process are hermetically sealed, and are configured to employ appropriately matched materials in accordance with their inherent properties of thermal expansion. A pin, glass insulator, and ferule are present. As opposed to conventional insulated components which employ stainless steel as an inefficient conductor, the unique matching process of the system provides for the use of copper and silver alloys to maximize efficiency while maintaining a hermetic seal. Specific glass is selected in accordance with the desired alloy in order to maintain similar degrees of expansion and contraction per temperature variations.

A system for the manufacturing of high-fidelity insulated components is described. Per field requirements, components crafted via the process are hermetically sealed, and are configured to employ appropriately matched materials in accordance with their inherent properties of thermal expansion. A pin, glass insulator, and ferule are present. As opposed to conventional insulated components which employ stainless steel as an inefficient conductor, the unique matching process of the system provides for the use of copper and silver alloys to maximize efficiency while maintaining a hermetic seal. Specific glass is selected in accordance with the desired alloy in order to maintain similar degrees of expansion and contraction per temperature variations.

A thermal sleeve for protecting an electronic member connected to a wiring harness against exposure to heat has a tubular member including an inner layer of insulative material and an outer layer of reflective material. The tubular member extends along a central longitudinal axis between opposite open ends. A plurality of slits extends lengthwise through one of the ends to form a plurality of fingers. The fingers are plastically deformed to extend radially inwardly toward the central longitudinal axis and form an opening for receipt of the wiring harness therethrough.

A thermal sleeve for protecting an electronic member connected to a wiring harness against exposure to heat has a tubular member including an inner layer of insulative material and an outer layer of reflective material. The tubular member extends along a central longitudinal axis between opposite open ends. A plurality of slits extends lengthwise through one of the ends to form a plurality of fingers. The fingers are plastically deformed to extend radially inwardly toward the central longitudinal axis and form an opening for receipt of the wiring harness therethrough.

A tubular cable interconnect unit arranged on an outer periphery of a joint of a power cable, includes a tubular insulating tube, a non-ohmic resistor layer formed from a non-ohmic composition and provided on an inner peripheral surface of the insulating tube, and an inner semiconductive layer provided on the non-ohmic resistor layer, wherein the non-ohmic composition includes a base polymer including at least one of thermoplastic and rubber, and varistor grains having a non-ohmic characteristic in which a volume resistivity varies non-linearly with respect to an applied voltage, and the varistor grains have a maximum grain diameter of 30 m or less.

A tubular cable interconnect unit arranged on an outer periphery of a joint of a power cable, includes a tubular insulating tube, a non-ohmic resistor layer formed from a non-ohmic composition and provided on an inner peripheral surface of the insulating tube, and an inner semiconductive layer provided on the non-ohmic resistor layer, wherein the non-ohmic composition includes a base polymer including at least one of thermoplastic and rubber, and varistor grains having a non-ohmic characteristic in which a volume resistivity varies non-linearly with respect to an applied voltage, and the varistor grains have a maximum grain diameter of 30 m or less.