A building monitoring computer system for monitoring building integrity may be provided. Various types of sensors may be embedded throughout or within certain portions of different types of building or construction material making up the building, such as within roofing, foundation, or structural materials. The sensors may be in wireless communication with a home controller. The sensors may be water, moisture, temperature, vibration, or other types of sensors, and may detect unexpected or abnormal conditions within the home. The sensors and/or home controller may transmit alerts to a mobile device of the home owner associated with the unexpected condition, and/or that remedial actions may be required to repair the home or mitigate further damage to the home. The sensor data may also be communicated to an insurance provider remote server to facilitate the insurance provider communicating insurance-related recommendations, updating insurance policies, or preparing insurance claims for review for home owners.

A building monitoring computer system for monitoring building integrity may be provided. Various types of sensors may be embedded throughout or within certain portions of different types of building or construction material making up the building, such as within roofing, foundation, or structural materials. The sensors may be in wireless communication with a home controller. The sensors may be water, moisture, temperature, vibration, or other types of sensors, and may detect unexpected or abnormal conditions within the home. The sensors and/or home controller may transmit alerts to a mobile device of the home owner associated with the unexpected condition, and/or that remedial actions may be required to repair the home or mitigate further damage to the home. The sensor data may also be communicated to an insurance provider remote server to facilitate the insurance provider communicating insurance-related recommendations, updating insurance policies, or preparing insurance claims for review for home owners.

An assembly having a longitudinal webbed base plate, upright webbed diverter (e.g. “V”-shaped) and coupling stabilizer and brace arms that assemble to extend from a roof above typical snow cover depths to protect downstream appliances protruding from the roof from snow/ice slide damage. The base plate and/or stabilizer arm includes surfaces shaped to promote the scoring and shearing of a snow/ice slide prior to the sheared sections of the snow/ice being laterally displaced away from a downstream appliance via the upright diverter. Alternative serrated, saw tooth, pointed, spiked and wedged shear surfaces are formed into the base plate and/or a single or multi-section stabilizer arm. An appliance cover piece can be fitted to the upright diverter and suspended above the downstream appliance.

An assembly having a longitudinal webbed base plate, upright webbed diverter (e.g. “V”-shaped) and coupling stabilizer and brace arms that assemble to extend from a roof above typical snow cover depths to protect downstream appliances protruding from the roof from snow/ice slide damage. The base plate and/or stabilizer arm includes surfaces shaped to promote the scoring and shearing of a snow/ice slide prior to the sheared sections of the snow/ice being laterally displaced away from a downstream appliance via the upright diverter. Alternative serrated, saw tooth, pointed, spiked and wedged shear surfaces are formed into the base plate and/or a single or multi-section stabilizer arm. An appliance cover piece can be fitted to the upright diverter and suspended above the downstream appliance.

Disclosed herein is a method for constructing a joint between thin flexible sheets of electromagnetic shielding material. The method includes adhering first sides of multiple first sheets of shielding material to a wall and adhering first sides of multiple second sheets of shielding material to second sides of the multiple first sheets of shielding material. A conductive adhesive or a conductive double-sided adhesive tape may be applied to the first side of each of the first sheets of shielding material and the second sheets of shielding material, the first sheets of shielding material may be arranged to abut each other along at least one first seam, and the second sheets of shielding material may be arranged to abut each other along at least one second seam.

Disclosed herein is a method for constructing a joint between thin flexible sheets of electromagnetic shielding material. The method includes adhering first sides of multiple first sheets of shielding material to a wall and adhering first sides of multiple second sheets of shielding material to second sides of the multiple first sheets of shielding material. A conductive adhesive or a conductive double-sided adhesive tape may be applied to the first side of each of the first sheets of shielding material and the second sheets of shielding material, the first sheets of shielding material may be arranged to abut each other along at least one first seam, and the second sheets of shielding material may be arranged to abut each other along at least one second seam.

A gutter debris preclusion device for use with a gutter attached to a building, comprising a screen having a plurality of manipulations, which cause resting debris to be elevated off the surface of the screen. The elevated debris resultingly become more rapidly dried and more easily removed by the wind.

A gutter debris preclusion device for use with a gutter attached to a building, comprising a screen having a plurality of manipulations, which cause resting debris to be elevated off the surface of the screen. The elevated debris resultingly become more rapidly dried and more easily removed by the wind.

A soil stabilization system for a structure can include a stem wall and floor slab disposed within a perimeter of the stem wall. An aggregate base course (ABC) layer can be disposed within a perimeter of the stem wall and below the floor slab. A ventilation opening can extend to the ABC layer, and an air exhaust system can extend between the ABC layer and an exterior of the structure. A method of soil stabilization for a structure can include measuring a moisture content of an expansive soil below a structure, drawing dry air through the ABC layer and over a surface of an expansive soil. Moisture can be removed from the expansive soil into the dry air by evaporation to create moist air, and moist air can be evacuated at an exterior of the structure.

A soil stabilization system for a structure can include a stem wall and floor slab disposed within a perimeter of the stem wall. An aggregate base course (ABC) layer can be disposed within a perimeter of the stem wall and below the floor slab. A ventilation opening can extend to the ABC layer, and an air exhaust system can extend between the ABC layer and an exterior of the structure. A method of soil stabilization for a structure can include measuring a moisture content of an expansive soil below a structure, drawing dry air through the ABC layer and over a surface of an expansive soil. Moisture can be removed from the expansive soil into the dry air by evaporation to create moist air, and moist air can be evacuated at an exterior of the structure.