In some aspects, deicer systems to distribute a deicing fluid along a roof of a building to limit ice dam formation can include: a pre-pressurized water source that provides pressurized water; a deicer solution source containing a deicer solution; a passive mixing system in fluid communication with the pre-pressurized water source and the deicer solution source, the passive mixing system being configured to combine the pressurized water and the deicer solution to form a deicer fluid; and one or more emitters configured to be disposed along the roof, the emitters being in fluid communication with the passive mixing system to receive the deicer fluid and dispense the deicer fluid along the roof. In addition, certain systems described herein can be run with an electric pump.

A system for securing one or more heating cables to a roof and having one or more apparatuses, each apparatus including a metal base panel and a continuous metal C-shaped channel integrally-formed with the base panel. The channel includes a pair of opposing continuous channel walls creating and surrounding a continuous cavity having a cross-sectional cavity shape substantially identical for at least a majority thereof to the cross-sectional shape of the cable. The channel walls are resiliently flexible to enable receipt of a continuous length of the heating cable within the cavity such that the heating cable is in snug continuous contact with the channel to enhance heat conductance from the heating cable to the base panel.

An apparatus for heating structure or areas adjacent such structure, such as a roof on a building for example, exposed to varying weather conditions and methods of making and use of the apparatus. The heating apparatus can include a heating element and heat supplying components. In one embodiment, the heating apparatus also includes a heatable cover panel and fasteners or other fastening components or materials for securing the heating element and cover panel to the structure. The heat supplying components may include one or more heater cable or heater cable sections penetrating one or more heater cable channels in the heating element. The apparatus may also utilize various insulating and other materials, including paint on exposed surfaces of the apparatus.

A thin light-transmitting substrate showing high thermal conduction efficiency, and having a function of raising surface temperature thereof is provided. The light-transmitting substrate of the present invention comprises a substrate that transmits at least a light of a predetermined wavelength, and a conductor pattern that is disposed on the substrate, and generates heat to raise temperature of the surface of the substrate when it is supplied with an electric current. The conductor pattern is directly disposed on the substrate without any adhesive layer.

A roofing product can include a substrate and a heater. The roofing product may be placed along portions of a roof where heat can help to reduce the likelihood of water freezing into ice while along a roof. In an embodiment, a hinge can be used in a roofing product to aid in folding of the roofing product or to retain a non-planar shape of the roofing product. The roofing product may or may not include a self-adhesive backing. A roofing product can include plurality of heaters that can provide sufficient heating should a particular heater fail. Method of fabricating the roofing product can be adapted for a fabrication line that can operate continuously.

Structure heating systems and methods of making and use. One embodiment has a unitary or integral roof edge heating element with a single heating cable mounted in a heating cable channel running laterally through the heating element and a roof edge heating panel extending from the portion of the heating element bearing the heating cable. Another embodiment includes a single heating cable mounted in a heating element surrounded by a heating element cover. Some embodiments can reduce the amount of heat transfer contact with supporting roof or adjacent structure, reducing heat transfer to the supporting roof or other adjacent structure.

Apparatuses, systems, and methods are disclosed for efficient control of a heating element. A sensor is configured to detect a state of water in proximity to a heating element. A switch device is configured to control a supply of power to the heating element. A hardware controller device is in communication with the sensor and the switch. The hardware controller device is configured to adjust the supply of power to the heating element using the switch device based on the state of water in proximity to the heating element.

A snow-melting roof tile according to an embodiment of the present invention comprises: a metal roof tile including a main cover part, a first bending part bent vertically and located at a first edge in a first direction of the main cover part and, and a second bending part bent vertically and located at a second edge in the first direction, opposite to the first edge of the main cover part; a heat generation part located an upper portion or lower portion of the metal roof tile; and a fixing part for fixing the heat generation part to the metal roof tile, wherein the heat generation part can generate heat to heat the metal roof tile, thereby melting snow on the metal roof tile.

A roofing system of the present disclosure has a first shingle layer and an overlaid layer a portion of which overlays the first shingle layer. Additionally, the roofing system has a first shingle in the first shingle layer, the first shingle having a first channel and a first protrusion in an upward-facing surface and the channel is contiguous with the protrusion, the channel and the protrusion formed on an interlocking end of the first shingle. Further, the roofing system has a second shingle in the overlaid layer, the second shingle having a second channel and a second protrusion in a downward-facing surface and the second channel is contiguous with the second protrusion such that the first channel is configured for receiving the second protrusion and the second channel is configured for receiving the first protrusion.

Rooftop photovoltaic solar systems and methods for installing interconnection wiring for photovoltaic solar systems. Cabling systems can include cable support stands secured underneath shingles. Cabling systems can include molded rubber raceways mounted using raceway clips secured underneath shingles.