The Kachina Aholi is a device invented out of three main components. The three components are: a drone or other aerial load lifting apparatus, a air filter (varying in the passage intensity of molecular material, graded filters) and a Super or Ultra hydrophobic spray (e.g. WATERBEADER™). These three components combined make a device that is flown up to clouds that are dense with water molecules and “bead” those molecules up along the air filter and cause premature precipitation. This method of premature precipitation can be used to irrigate farms, prevent flash floods, prevent landslides, wildfire prevention or reduction, increase accessibility in low water/dry areas, and climate control.

An emergency signaling system is disclosed. The system includes a receptacle and a painting device. The painting device is covered in a paint material and stored in the receptacle. The receptacle can be used to launch the painting device onto a surface, such as a roof, in the event that a user needs to signal a search and rescue team or anyone near their present location. The painting device, upon contact with a surface, creates a painted signal. The painted signal can have different shapes according to the shape of the painting device. The painting device can include weight members or flexible frame members to facilitate opening the painting device from a closed or folded configuration to a fully open configuration once the painting device has been launched from the receptacle.

A device for monitoring and identifying a mountain torrent and debris flow and a method for early warning of disasters relate to the technical field of debris flow protection. The device includes a computation device, sensors, an amplifier and an analog-to-digital converter. The sensors convert an acquired impact force signal into a digital signal by the amplifier and the analog-to-digital converter, and transmits the digital signal to the computation device. The computation device utilizes the digital signal to compute an energy coefficient of a liquid impact signal and a solid-liquid impact energy ratio, and a debris flow mode is monitored and identified in combination with a threshold range of the energy coefficient and a threshold range of the solid-liquid impact energy ratio. The device identifies the nature of the mountain torrent and debris flow through time-frequency analysis of an impact force signal generated by the debris flow to sensors.

The system provided allows weather data containing errors to be pre-processed in a way that quickly enhances data integrity which increases the efficiency and effectiveness of warnings. The system further provides a means to selectively distribute messages related to warnings to a group of recipients in a known geographic area. The system further comprises a way to advise recipients of property repair financing to address the needs of underinsured recipients.

An anti-flood device intended to seal an opening, in particular of a building, including at least one parallelepiped panel forming a chamber which can be inflated by injecting a gas, comprising two rectangular main walls joined by a lower edge, an upper edge and two lateral edges. The inner faces of the main walls of the panel are connected to each other by connecting elements formed of threads of equal length, the ends of which are respectively secured to the main walls and which ensure that they are kept parallel when the panel is inflated. The lateral and lower edges of the panel are provided, at least partially, with an elastic deformable seal which is intended to be respectively compressed against the lateral walls of the opening and the base thereof, when the panel is inflated and installed in this opening.

A reinforced building wall includes a foundation and an anchor rod anchored to the foundation; a first stud wall disposed above the foundation; the first stud wall having a first bottom plate, a first top plate and first and second vertical studs operably joined to the first bottom plate and the first top plate; a horizontal first bridge member disposed between the first stud and the second stud, the first bridge member having a first vertical opening; a rod post having one end operably connected to the anchor rod and operably connected to the first bridge member to transfer downward forces from the first bridge member and the second bridge member to the rod post; the anchor rod is attached to an anchor; and the anchor is disposed in an upper portion of the foundation.

A shelter system having a stationary section configured to be positioned below grade and having a plurality of perimeter walls forming a stationary frame. A plurality telescoping sections are nested within the stationary section. A roof panel is attached to a top telescoping section of the plurality telescoping sections. A lift system is configured to provide a vertical force to the top telescoping section such that the plurality of telescoping sections are selectively positionable between an idle configuration below grade and a raised configuration above grade.

Systems and methods are described herein for presenting additional information related to an emergency alert. A media guidance application may detect that a new emergency alert has been received. The media guidance application may then perform a search of various content sources (e.g., program listings, the Internet, etc.) for content related to the emergency alert. The media guidance application may then present the search results in a contextual menu enabling the user to access content of the search results. The media guidance application may also provide more options, such as, recording or pausing media content that the user was in the process of consuming when the emergency alert was generated, and an option to the user not to bring up the contextual menu again if the same emergency alert is repeated.

A method of providing covers over at least a portion of a roof of a storm damaged built structure that includes the steps of: applying a sheet of heat shrinkable film over the portion of the roof, the sheet having a leading edge and a trailing edge and being a film of low density polyethylene including shrinking resins; wrapping portions of the leading edge around a first batten and attaching the first batten to the underside of a first eave or to the facia of the built structure; wrapping portions of the trailing edge around a second batten and attaching the second batten to the underside of a second eave or to the facia of the built structure at a location different than the first batten; and heating the sheet of heat shrinkable film to bring the film into conformity with the portion of the roof, wherein the heating step shrinks the sheet of film tight against the built structure to cover over the portion of the roof.

A column bracket assembly is provided. The column bracket assembly comprises a bottom base bracket and a top base bracket, each including a bracket body adapted to receive an end of support element (e.g. a wooden column) and a mounting bracket/plate pivotally coupled to the bracket body and adapted to be coupled to a structural element (e.g. a footing, pile, header, beam etc.). The column bracket assembly optionally includes mounting brackets for installing cross brace brackets and/or tension rods to the bracket bodies. A method of installing the column bracket assembly, and a method of repairing, resettling, shoring, and/or leveling a structure with the column bracket assembly are also provided, along with structures comprising the column bracket assembly.