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.

The embodiments are apparatuses, systems and methods of water management and icicle prevention for solar carports, and are designed to catch drips between rows of, and water run-off from, the low side of inclined photovoltaic modules arranged to form the roof of the solar carport or canopy.

The embodiments are apparatuses, systems and methods of water management and icicle prevention for solar carports, and are designed to catch drips between rows of, and water run-off from, the low side of inclined photovoltaic modules arranged to form the roof of the solar carport or canopy.

A debris guard for installation on an eavestrough is disclosed. The debris guard includes a frame having a back side, a front side, a length, two ends, a top surface, a bottom surface opposite the top surface, and a water collection portion extending from the front side to the back side and along the length of the frame between the two ends. The water collection portion includes a plurality of holes to allow rainwater to pass through. The water collection portion also includes a plurality of drip legs coupled to the plurality of holes, the plurality of drip legs extending below the bottom surface to provide improved water flow through the eavestrough debris guard. Each of the plurality of holes includes at least one drip leg that provide improved flow through the debris guard.

A fluid deposition system is provided. The system comprises one or more electronic processors, and one or more electronic memories each electrically connected to at least one of the one or more processors and having instructions stored therein. The processor(s) is/are configured to access the memory or memories and execute the instructions stored therein such that the processor(s) is/are configured to: determine whether one or more predetermined criteria are met for initiating deposition of fluid onto an area of interest; when it is determined that the criteria is/are met, determine one or more operating parameters of the fluid deposition system to use in the deposition of the fluid onto the area of interest; and following the determination of the operating parameter(s), generate one or more electrical signals to cause the fluid to be deposited onto the area of interest in accordance with the determined parameter(s).

A heat panel system for preventing ice formation about a roof or gutter includes at least two heat panels that are connected using a fastener. The heat panels each include a body including at least one channel configured to accept a heating element. Tongues and grooves or other mating arrangements on the panels and the fastener permit two panels to be joined by a fastener so as to inhibit relative lateral movement and enhance heat transfer between panels. A single panel or a multi-panel system can be mounted directly on the roof, and/or a single panel system can be mounted in a gutter. By using these heat panels and fasteners, heat panel systems of varying widths can be made using the same supplies.

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.

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.

The present invention includes a cover for use with a heat element and gutter debris preclusion devices. The cover includes a body, a front member, and a middle portion disposed between the body and the front member. The body includes a lip being operably configured to extend beyond an outer edge of the gutter when the cover is in use. The cover also includes a channel defined by the middle portion and at least the front member, wherein the channel is operably configured to receive the heat element. The cover is operably configured to hold the heat element to the gutter debris preclusion device. When the heat element is energized it will generate heat. The cover will enable the generated heat to transfer to the gutter debris preclusion device and to a gutter to which it is attached.

The present invention includes a cover for use with a heat element and gutter debris preclusion devices. The cover includes a body, a front member, and a middle portion disposed between the body and the front member. The body includes a lip being operably configured to extend beyond an outer edge of the gutter when the cover is in use. The cover also includes a channel defined by the middle portion and at least the front member, wherein the channel is operably configured to receive the heat element. The cover is operably configured to hold the heat element to the gutter debris preclusion device. When the heat element is energized it will generate heat. The cover will enable the generated heat to transfer to the gutter debris preclusion device and to a gutter to which it is attached.