Abstract: Hazard-resultant effects to land and buildings are predicted based on various inputs. Hazards may include any appropriate type of hazard (e.g., flood, wildfire, climate-related hazards, or the like). Inputs may include the likelihood that that a specific type of hazard may occur for various scenarios, terrestrial boundaries, property boundaries, census geographies, or the like. Relationships between the inputs are determined and used to quantify parameters pertaining to a specific type of hazard. For example, the depth of flood water may be predicted for a particular terrestrial boundary, a city or town, or a building, for specific climate scenarios. A risk likelihood of the quantified parameter may be determined for a particular period of time and environment. For example, flooding to a building may be determined, broken down by depth threshold and year of annual risk for specific climate scenarios. Economic loss also may be predicted.

Abstract: Hazard-resultant effects to land and buildings are predicted based on various inputs. Hazards may include any appropriate type of hazard (e.g., flood, wildfire, climate-related hazards, or the like). Inputs may include the likelihood that that a specific type of hazard may occur for various scenarios, terrestrial boundaries, property boundaries, census geographies, or the like. Relationships between the inputs are determined and used to quantify parameters pertaining to a specific type of hazard. For example, the depth of flood water may be predicted for a particular terrestrial boundary, a city or town, or a building, for specific climate scenarios. A risk likelihood of the quantified parameter may be determined for a particular period of time and environment. For example, flooding to a building may be determined, broken down by depth threshold and year of annual risk for specific climate scenarios. Economic loss also may be predicted.

Abstract: Hazard-resultant effects to land and buildings are predicted based on various inputs. Hazards may include any appropriate type of hazard (e.g., flood, wildfire, climate-related hazards, or the like). Inputs may include the likelihood that that a specific type of hazard may occur for various scenarios, terrestrial boundaries, property boundaries, census geographies, or the like. Relationships between the inputs are determined and used to quantify parameters pertaining to a specific type of hazard. For example, the depth of flood water may be predicted for a particular terrestrial boundary, a city or town, or a building, for specific climate scenarios. A risk likelihood of the quantified parameter may be determined for a particular period of time and environment. For example, flooding to a building may be determined, broken down by depth threshold and year of annual risk for specific climate scenarios. Economic loss also may be predicted.

Abstract: Hazard-resultant effects to land and buildings are predicted based on various inputs. Hazards may include any appropriate type of hazard (e.g., flood, wildfire, climate-related hazards, or the like). Inputs may include the likelihood that that a specific type of hazard may occur for various scenarios, terrestrial boundaries, property boundaries, census geographies, or the like. Relationships between the inputs are determined and used to quantify parameters pertaining to a specific type of hazard. For example, the depth of flood water may be predicted for a particular terrestrial boundary, a city or town, or a building, for specific climate scenarios. A risk likelihood of the quantified parameter may be determined for a particular period of time and environment. For example, flooding to a building may be determined, broken down by depth threshold and year of annual risk for specific climate scenarios. Economic loss also may be predicted.

Abstract: Ball pivot assemblies for mounting panels to a cable regardless of panel geometry or orientation include a ball pivot. The ball pivot includes geometry configured to enable a panel to pivot about the ball pivot in a plurality of orientations in a plurality of planes with respect to the cable. One or more implementations of the present invention can include a ball socket configured to receive the ball pivot, and provide a secure interface between the ball pivot assembly and the panel. Also, systems of at least one implementation of the present invention include a plurality of panels mounted to one or more cables using one or more ball pivot assemblies. In addition, one or more implementations of the present invention include methods of mounting panels using one or more ball pivot assemblies.

Abstract: A roller door system includes a roller assembly configured to mount directly to a panel and move along a complementary upper guide. In particular, the roller assembly can be coupled to a coupling member embedded in the panel. The roller assembly, when coupled with the panel, can provide a smooth gliding motion for the panel.

Abstract: A twisted resin panel of typically several feet in length can be twisted after being subject to heat, pressure, and a rotation assembly. In one implementation, a manufacturer can clamp opposing ends of a heated resin panel, such as a panel comprising a one or more layers (e.g., tie/EVA layer, image layer(s), etc.) thermoformed within opposing resin sheet layers. The manufacturer can then elevate the resin panel, and then twist at least one end of the resin panel to a specified degree to achieve a desired aesthetic. Upper securing means (e.g., vertical clamps, rig hardware) at the upper end of the resin panel can be configured to move up or down during the twist of the resin panel in order to accommodate length variations thereof. Upon twisting, the resin panel will then cool into the desired position, and thus be used for any number of decorative architectural purposes.

Abstract: A roller door system includes one or more sets of rollers configured to mount to a panel frame member on an upper end of a panel, and move through a complementary upper guide. A lower side of the panel frame can also be guided through one or more bottom tracks. These components, when coupled with the resin panel, can provide the ability to provide a smooth gliding motion for the resin panel door. In addition, the frame in which the panel is mounted can be configured with one or more components to accommodate the unique expansion and contraction properties of resin materials, and thus allow a stable, long term mounting solution. The upper guide and the lower track can also be configured with one or more components or mechanisms for pitch adjustment, as well as to adjust for uneven or irregular mounting surfaces.

Abstract: A roller door system includes one or more sets of rollers configured to mount to a panel frame member on an upper end of a panel, and move through a complementary upper guide. A lower side of the panel frame can also be guided through one or more bottom tracks. These components, when coupled with the resin panel, can provide the ability to provide a smooth gliding motion for the resin panel door. In addition, the frame in which the panel is mounted can be configured with one or more components to accommodate the unique expansion and contraction properties of resin materials, and thus allow a stable, long term mounting solution. The upper guide and the lower track can also be configured with one or more components or mechanisms for pitch adjustment, as well as to adjust for uneven or irregular mounting surfaces.

Abstract: A variable length standoff assembly is configured to mount one or more portions of one or more panels to a frame or support structure, regardless of curvature or angling in the given panel or frame. The variable length standoff assembly includes a connector bar to which one or more variable length standoffs can be attached. Each variable length standoff includes a standoff barrel and adjustable extender to which a manufacturer can attach a portion of a given panel via a mounting cap. Each variable length standoff can be rotated about the connector bar, and can be extended or shortened to a wide range of lengths. In one implementation, a variable length standoff can also be configured to rotate with respect to the connector bar in at least two planes, thereby providing additional degrees of freedom for attaching variously curved and/or differentially orientated panels to a support structure.

Abstract: A twisted resin panel includes resin material that has been heated and twisted after being subject to heat and/or pressure. In one implementation, a manufacturer can clamp opposing ends of a resin panel, such as a panel comprising a one or more layers thermoformed together. The manufacturer can then elevate the resin panel, and twist at least one end of the resin panel to achieve a desired aesthetic. Upper securing means (e.g., vertical clamps, rig hardware) at the upper end of the resin panel can be configured to move up or down during the twist of the resin panel in order to accommodate length variations thereof. Upon twisting, the resin panel will then cool into the desired position, and thus be used for any number of decorative architectural purposes. Implementations of the invention further include means to mount a twisted panel to upper and lower support surfaces.

Abstract: Finished envelopes are conveyed in a feed line of an envelope forming machine aligned in spaced apart relation to a spiral delivery mechanism that transfers the envelopes on edge to the surface of a delivery table. A conveyor on the delivery table sequentially advances the envelopes in a stacked relation from a receiving end portion to a discharge end portion where a predetermined quantity of stacked envelopes are periodically removed from the table as envelopes are added to the stack at the receiving end portion of the table. The envelopes are maintained in a compact stack by a stop member which is normally biased toward the receiving end portion of the table by an actuator mechanism. The stop member exerts pressure on the stack as it advances upon the addition of envelopes from the receiving end portion to the discharge end portion.