An installation tool and methods for installing a splice kit for a heating cable is provided. The installation tool includes a body, a first channel, and a first cavity. The first channel is defined in the body and configured to retain a first insulating tubing of the splice kit. The first cavity is within the first channel and configured to retain a first connector of the splice kit. The body is configured to retain the first insulating tubing and the first connector in a predetermined formation during installation of the first insulating tubing and the first connector to the heating cable, and the body is further configured to be removed from the first insulating tubing and the first connector following installation of the first insulating tubing and the first connector to the heating cable.

An installation tool and methods for installing a splice kit for a heating cable is provided. The installation tool includes a body, a first channel, and a first cavity. The first channel is defined in the body and configured to retain a first insulating tubing of the splice kit. The first cavity is within the first channel and configured to retain a first connector of the splice kit. The body is configured to retain the first insulating tubing and the first connector in a predetermined formation during installation of the first insulating tubing and the first connector to the heating cable, and the body is further configured to be removed from the first insulating tubing and the first connector following installation of the first insulating tubing and the first connector to the heating cable.

A metal heater includes a metal substrate with a groove, a resistive heater disposed within the groove, and a fill metal disposed over the resistive heater and substantially filling the groove, wherein the fill metal has a lower melting temperature than the metal substrate. The fill metal can be indium and a cover plate can be bonded to the metal substrate and over the indium. A method of manufacturing the metal heater and a method of operating the metal heater are also provided.

A metal heater includes a metal substrate with a groove, a resistive heater disposed within the groove, and a fill metal disposed over the resistive heater and substantially filling the groove, wherein the fill metal has a lower melting temperature than the metal substrate. The fill metal can be indium and a cover plate can be bonded to the metal substrate and over the indium. A method of manufacturing the metal heater and a method of operating the metal heater are also provided.

Some deck or patio areas constructed of pavers mounted on adjustable pedestal supports must remain snow and ice free on their top surfaces. The pedestal-mounted paver heating system is designed to allow easy installation of electric heating cable that is positioned against the bottom surface of pavers so that heat generated by the cable is efficiently transferred up into the pavers to raise their temperature enough to prevent the accumulation of snow and ice on their top surfaces.

Some deck or patio areas constructed of pavers mounted on adjustable pedestal supports must remain snow and ice free on their top surfaces. The pedestal-mounted paver heating system is designed to allow easy installation of electric heating cable that is positioned against the bottom surface of pavers so that heat generated by the cable is efficiently transferred up into the pavers to raise their temperature enough to prevent the accumulation of snow and ice on their top surfaces.

Disclosed is a floor underlayment system and method for radiant heat, comprising: one half inch tile or other floor underlayment board, a series of grooves cut into the tile or other floor underlayment board, electric resistance heating cable inserted into the series of grooves cut into the tile or other floor underlayment board, and sensor wires inserted into the series of grooves cut into the tile or other floor underlayment board.

The invention provides a heating conductive wire-like element comprising a core made from synthetic fibers a plurality of heating conductive wires around said core. The core is twisted in a predetermined direction X and the plurality of heating conductive wires are wound in a predetermined direction Y. The predetermined direction X is different from the predetermined direction Y. A predetermined number of said heating conductive wires are individually covered with a non- electrically conductive material.

The invention provides a heating conductive wire-like element comprising a core made from synthetic fibers a plurality of heating conductive wires around said core. The core is twisted in a predetermined direction X and the plurality of heating conductive wires are wound in a predetermined direction Y. The predetermined direction X is different from the predetermined direction Y. A predetermined number of said heating conductive wires are individually covered with a non- electrically conductive material.

A refrigerating unit including a compartment, a glass door, and a heating arrangement installed in a base profile of the compartment. The refrigerating unit including an elongated gasket profile having a proximal part and a distal part, wherein the proximal part includes a flexible element configured to allow the distal part to be displaced towards the base profile upon closing the glass door. The distal part includes a hollow part with a first side of the hollow part connected to the proximal part and a second side of the hollow part directed towards the glass door. The heating arrangement further includes a heat-conducting material enclosed by the hollow part and arranged with an outer side surface of the heat-conducting material abutting the second side of the hollow part, and a heating element enclosed by the hollow part and arranged for conductive heating of the heat-conducting material.