A snow melting system and method for operating a snow sensor is provided. The snow melting system includes a controller, a heating system, and a snow sensor. The snow sensor comprises a support structure and a cap. The support structure includes a proximal end and a distal end, where a first plane defined by the distal end is angled with respect to a second plane defined by the proximal end. The cap is disposed at the distal end of the support structure and comprises a top surface, a side surface arranged orthogonal to the top surface, and a chamfer that extends between the side surface and the top surface.

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.

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.

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.

This application discloses a heated roofing underlayment placed between roof sheathing and the roofing surface. Building structures in climates that experience freezing temperatures and snowfall may develop problems associated with freezing moisture on the surface of a roof. This freezing moisture may lead to problems that result in moisture penetration into the structure, structural damage, rot, and other damage. The heated roofing underlayment may cause the ice and snow on a roof to melt.

A system is provided for preventing the buildup of ice dams on a roof system of a building. The system includes a heating cable configured to generate heat, and a fastening system configured to hold the heating cable in place. The fastening system further includes at least one adhesive clip which is configured to adhere to smooth flat surfaces present on the building. The adhesive clip includes a cable cradle and a base portion with a bottom surface on which an adhesive layer is arranged.

A roofing product can include a heater. In an embodiment, the heater can have different areas that have different heat flux capacities, different portions having heater elements of different lengths or a combination thereof. The roofing product can be installed so that an area of the roof that has a higher heat load, such as near an eave and a valley of the roof, can receive more heat. In another embodiment, the roofing product includes an overhang section that includes at least a portion of the heater. The roofing product can be installed, and the overhang section can be coupled to an object that extends beyond an edge of the roof or over a plane defined by a roof. Many different manufacturing techniques can be used to form the heaters.

A snow melting system for greenhouse comprises sensors for measuring an accumulation of snow on or at the greenhouse. A snow melting processor unit comprises an accumulation rate calculator for calculating an accumulation rate of the snow from the measured accumulation, and a heating prioritizer for actuating at least one of at least two different heating systems of the greenhouse as a function of at least the accumulation rate. A rooftop greenhouse system comprises a greenhouse adapted to be mounted to a rooftop surface. Two or more different heating systems mounted to the greenhouse to heat a roof of the greenhouse, and controlled by the snow melting system.

Air supported structures forming an enclosure via internal pressurized air, and methods of making same, are disclosed. The structures include an outer membrane defining an outer surface of the structure. The structures include an inner liner blanket coupled to the outer membrane via a plurality of spaced baffles extending from the outer membrane into the enclosure, the inner liner blanket and the inner surface of the outer membrane forming a heating pocket therebetween within the enclosure extending along a first portion of the outer membrane. The structures also include at least one input channel in communication with the heating pocket, and at least one heated air system configured to selectively direct a flow of heated air through the at least one input channel and into the heating pocket to heat the first portion of the outer membrane to remove and/or prevent frozen precipitation accumulation on the outer surface thereof.

A snow guard assembly heated within one or more snow guard tubes. Heating of the snow guard tube prevents excessive accumulation of snow and helps prevent snow build up and spill over above the top of the snow guard. The tubes can be length-wise separable to place and service the heating elements. The heating element can be standard heat tape or infrared LEDs. The snow guard tubes can optionally have a non-uniform cross-sectional thickness to direct the heat more efficiently in a desired orientation. The interior of the snow guard tubes can be selectively coated with infrared absorbing or reflective material to direct the heat in a desired orientation when infrared LEDs are used as a heat source. The snow guard can be attached to many types of roof surfaces including tile roofs, metal roofs with or without standing seams, and shingle roofs.