A drip edge assembly having an underlying drip edge. A body portion includes first and second ribs extending therealong. The body portion includes an inner edge having a fold and an outer edge that includes a protrusion. A vertical wall extends downward from the body portion and includes a lower kick defining an inwardly-facing channel. An overlying drip edge includes a body portion having first and second ribs extending therealong. The body portion includes an inner edge having a fold and an outer edge that includes a protrusion. A vertical wall extends downward from the body portion and includes a lower kick defining a rearwardly-facing channel. The lower kick of the underlying drip edge is configured to define a pivot axis about which the overlying drip edge rotates during assembly.

The present disclosure includes roof shingle systems. One roof shingle system includes at least two shingles, a shingle clip, a drip edge, and a power collection unit. Each shingle has a semiconductive layer configured to deliver power, electrical current/voltage, and/or control signals to the power collection unit. The shingle clip continues a conductive path between the two shingles. The drip edge is at least partially insulated and partially conductive, and the conductive portion continues the path from the shingle semiconductive layer to the power unit where energy is collected. One method of installing a shingle system includes the steps of positioning a shingle having a transducer in the form of a semiconductive layer, and positioning a shingle clip to engage the semiconductive layer of the shingle.

This invention, in embodiments, relates to a roofing drip edge device that includes a drip edge comprising (i) an upper drip edge that is configured to be installed along an edge of a roofing surface, and (ii) a lower drip edge that is approximately at a right angle to the upper drip edge, a flashing strip member that is secured to the upper drip edge of the drip edge, such that a portion of the flashing strip member overhangs a first side edge of the drip edge, and a connecting member that is secured to the drip edge, such that a portion of the connecting member overhangs a second side edge of the drip edge. This invention, in embodiments, further relates to a method of installing a roofing drip edge device.

This invention, in embodiments, relates to a roofing drip edge device that includes a drip edge comprising (i) an upper drip edge that is configured to be installed along an edge of a roofing surface, and (ii) a lower drip edge that is approximately at a right angle to the upper drip edge, a flashing strip member that is secured to the upper drip edge of the drip edge, such that a portion of the flashing strip member overhangs a first side edge of the drip edge, and a connecting member that is secured to the drip edge, such that a portion of the connecting member overhangs a second side edge of the drip edge. This invention, in embodiments, further relates to a method of installing a roofing drip edge device.

The present disclosure includes roof shingle systems. One roof shingle system includes at least two shingles, a shingle clip, a drip edge, and a power collection unit. Each shingle has a semiconductive layer configured to deliver power, electrical current/voltage, and/or control signals to the power collection unit. The shingle clip continues a conductive path between the two shingles. The drip edge is at least partially insulated and partially conductive, and the conductive portion continues the path from the shingle semiconductive layer to the power unit where energy is collected. One method of installing a shingle system includes the steps of positioning a shingle having a transducer in the form of a semiconductive layer, and positioning a shingle clip to engage the semiconductive layer of the shingle.

A structurally robust roof drip edge system including a tail and an outer section contiguous with the tail. The tail includes a locally thin section nailable to a roof substrate. The outer section includes a bridging member connecting an inner footing and an outer footing. The outer footing includes a drip edge profile for directing the flow of water off of a roof. The inner footing is spaced from the outer footing by a suitable distance and configured to be placed against an eave as a positioning aid such that the drip edge can easily and reliably be installed with sufficient spacing for the installation of a fascia board behind the drip edge profile. The drip edge may be bendable to a user-selectable angle between the tail and the outer section to accommodate a range of roof pitches.

A ridge structure at a roof edge, having a base panel lying on a roof surface and a hollow ridge structure over the base panel. The hollow ridge structure is constructed in a flat spring form along the eaves, and therefore one slope of the ridge faces the roof and the other slope the opposite direction. The slope facing the roof can be lifted to receive and secure roofing materials between the slope and the base panel. When water flows down the roof surface, most water flows over the ridge structure and the rest flows into the hollow space inside the ridge structure and drains through drain holes on the base panel.

A drip edge assembly having an underlying drip edge. A body portion includes first and second ribs extending therealong. The body portion includes an inner edge having a fold and an outer edge that includes a protrusion. A vertical wall extends downward from the body portion and includes a lower kick defining an inwardly-facing channel. An overlying drip edge includes a body portion having first and second ribs extending therealong. The body portion includes an inner edge having a fold and an outer edge that includes a protrusion. A vertical wall extends downward from the body portion and includes a lower kick defining a rearwardly-facing channel. The lower kick of the underlying drip edge is configured to define a pivot axis about which the overlying drip edge rotates during assembly.

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.

Combination drip edge starter strips and methods for using them to prevent wind and moisture damage to the shingles at the edge of a building roof. The devices are used to initiate placement of roofing shingles at the roof edge.