This invention provides a tilt angle adjustable combined rat-proof device, relating to the technical field of rat-proof devices. A rat-proof device includes a rat-proof plate body, a fixing mechanism and an adjusting mechanism, wherein the rat-proof plate body is inserted into the fixing mechanism so that the rat-proof plate body is able to be clamped, and an upper end of the fixing mechanism is clamped into the adjusting mechanism and is able to slide along the adjusting mechanism so as to drive the rat-proof plate body to move, thereby realizing adjustment of the tilt angle of rat-proof plate body. The device can adjust the tilt angle based on the user's actual requirements, therefore adapting to the use environment, and it is also extremely convenient in the process of transportation, disassembly and installation.

A system and method of applying a slick surface, such as silicone epoxy, is applied on a vertical wall (on or around the perimeter of a structure), as a means of preventing (bark) scorpions (or other insects/arachnids) from climbing up walls. The system is intended, in part, to keep the Arizona bark scorpions out of homes. Vertical surface areas around the home are treated with a material such as silicone. A clear silicone epoxy, that when dry, prevents scorpions from climbing vertically up into a home or structure. This non-toxic epoxy is applied to the base of a home, including door thresholds, steps or other parts of a home which makes contact with the ground. The epoxy is applied to the area by sprayer.

A mounting bracket surrounding a flexible polymer foam sheet with a protective mesh sheet movably carried on a front side. A mounting flange extending around an exterior perimeter. A front retaining ridge disposed on an interior surface engaging the front side of the flexible polymer foam sheet. An upper retaining flange extending downward from a top portion of the interior surface. A first side retaining flange extending laterally from a first side portion of the interior surface. A second side retaining flange extending laterally from a second side portion of the interior surface opposite the first side portion. A lower retaining flange extending upward from a bottom portion of the interior surface opposite the top portion. A receiving area between the front retaining ridge and the upper, lower and side flanges engaging a rear side of the flexible polymer foam sheet compressed against the receiving area to be releasably carried.

A mounting bracket surrounding a flexible polymer foam sheet with a protective mesh sheet movably carried on a front side. A mounting flange extending around an exterior perimeter. A front retaining ridge disposed on an interior surface engaging the front side of the flexible polymer foam sheet. An upper retaining flange extending downward from a top portion of the interior surface. A first side retaining flange extending laterally from a first side portion of the interior surface. A second side retaining flange extending laterally from a second side portion of the interior surface opposite the first side portion. A lower retaining flange extending upward from a bottom portion of the interior surface opposite the top portion. A receiving area between the front retaining ridge and the upper, lower and side flanges engaging a rear side of the flexible polymer foam sheet compressed against the receiving area to be releasably carried.

An automated system for mitigating risk from a wind turbine includes a plurality of optical imaging sensors. A controller receives and analyzes images from the optical imaging sensors to automatically send a signal to curtail operation of the wind turbine to a predetermined risk mitigating level when the controller determines from images received from the optical imaging sensors that an airborne animal is at risk from the wind turbine.

An automated system for mitigating risk from a wind turbine includes a plurality of optical imaging sensors. A controller receives and analyzes images from the optical imaging sensors to automatically send a signal to curtail operation of the wind turbine to a predetermined risk mitigating level when the controller determines from images received from the optical imaging sensors that an airborne animal is at risk from the wind turbine.

An automated system for mitigating risk from a wind farm. The automated system may include an array of a plurality of image capturing devices independently mounted in a wind farm. The array may include a plurality of low resolution cameras and at least one high resolution camera. The plurality of low resolution cameras may be interconnected and may detect a spherical field surrounding the wind farm. A server is in communication with the array of image capturing devices. The server may automatically analyze images to classify an airborne object captured by the array of image capturing devices in response to receiving the images.

An automated system for mitigating risk from a wind farm. The automated system may include an array of a plurality of image capturing devices independently mounted in a wind farm. The array may include a plurality of low resolution cameras and at least one high resolution camera. The plurality of low resolution cameras may be interconnected and may detect a spherical field surrounding the wind farm. A server is in communication with the array of image capturing devices. The server may automatically analyze images to classify an airborne object captured by the array of image capturing devices in response to receiving the images.

A barrier system includes a substantially vertical structure with a coating layer disposed on and circumscribing a majority of the substantially vertical structure. The coating layer has a height of at least 0.25 inches, has gouge and scratch hardness of at least 2H, and has an average surface roughness (R.sub.a) of less than 10 microns.

A barrier system includes a substantially vertical structure with a coating layer disposed on and circumscribing a majority of the substantially vertical structure. The coating layer has a height of at least 0.25 inches, has gouge and scratch hardness of at least 2H, and has an average surface roughness (R.sub.a) of less than 10 microns.