A bird mister apparatus for attracting and cooling birds includes a base plate, a housing, and a reservoir within a housing inside configured to hold liquid that can be sealed and unsealed. A spout has a spout aperture extending through to the housing inside. A pump is coupled within the housing inside and is in fluid communication with the spout aperture. An inlet tube is coupled to the pump and is in fluid communication with the pump. A CPU is coupled within the housing inside and is in operational communication with the pump. A battery is in operational communication with the CPU and the pump. A power switch is in operational communication with the CPU to activate and alternatively deactivate the pump. A hanger is coupled to the housing to support the apparatus on a tree branch, a fence, or an awning.

A treatment system for spraying treatment fluid onto plants in a field is described. The treatment system includes a highly configurable treatment mechanism including an array of nozzles and valve assemblies coupled into manifolds, and manifold assemblies. The manifolds of the manifold assemblies can be oriented in an open state or a nested state, the open state with no overlap between nozzles of adjacent manifolds and the nested state with overlap between nozzles of adjacent manifolds. The manifolds can have multiple configurations, examples of which include a tube manifold and an offset manifold. The nozzles of the system can have multiple configurations, examples of which include a tri-spray nozzle, a bar nozzle, a fan nozzle, and a deflected fan nozzle. The system can be controlled by a system controller which detects plant material and instructs a nozzle or combination of nozzles to spray treatment fluid.

A motion-activated dispenser includes a housing having a base and top defining a gap sized to receive a human hand. The top portion defining cavity sized to receive a fluid reservoir and an opening extending directly through a lower surface of the top portion to the cavity, a neck of the fluid reservoir extending through the opening. A pressing member is positioned within the cavity and an actuator is coupled to the pressing member and configured to urge the pressing member toward and away from the opening. The pressing member may include, for example, a sliding member positioned opposite a stop face; a roller moved by the actuator toward the opening; a plunger positioned above the opening and driven by an actuator toward the opening; or a pair of rods spanning the cavity and urged by the actuator through the cavity, the rods pressing against sides of the reservoir.

An amusement park attraction effects system includes a dynamic display for viewing by a user traveling through an attraction, a display monitor to provide status data indicative of a status of the dynamic display, a location identification system to determine a location of the user, a thrust-vectoring flow effect generator to generate and direct a fluid flow toward any particular target location of a range of target locations, and an automation controller communicatively coupled to the display monitor, the location identification system, and the thrust-vectoring flow effect generator. The automation controller is configured to receive the status data, receive the location of the user, set a target location based on the location of the user, instruct the thrust-vectoring flow effect generator to direct the fluid flow based on the target location, and instruct the thrust-vectoring flow effect generator to control the fluid flow based on the status data.

A brushless car wash system includes a variable width. The width of the brushless car wash system is adjusted according to a width of a vehicle being washed. By adjusting the width of the brushless car wash system, wash performance of the brushless car wash system is increased.

A brushless car wash system includes a wash unit that washes upper surfaces of the vehicle. The height of the wash unit is adjusted based on the contour of the upper surfaces of the vehicle. Adjusting the height of the wash unit results in increased wash performance of the brushless car wash system.

A coating apparatus and method allow for precise control of the application of a coating material on a substrate and provides a data recording system which is useful for certifying a coating job and assessing when and where any abnormalities occur.

The invention relates to a modular system for weed control for a rail vehicle. The modular system has a control module including a control unit and a control module. The control unit is configured to generate a first set of control signals for controlling valves and mixers in an herbicide and mixing module configured to mix an herbicide mixture and to generate a second set of control signals for controlling valves of a nozzle assembly. The herbicide and mixing module has a plurality of containers for receiving different herbicides. The nozzle assembly has a first set of nozzles for spraying herbicides, and the control module, the herbicide and mixing module, and the nozzle assembly can each be individually fixed to a carrier element in a reversible manner.

In various embodiments, a zero-turn radius robotic base may comprise a substantially rectangular (e.g., rectangular) base portion that comprises a plurality of wheels. In various embodiments, the plurality of wheels are configured to support the robotic base adjacent a support surface (e.g., the ground, a suitable flooring surface within a building, etc.). In some embodiments, the robotic base comprises a first and second driving wheel and a plurality of stability wheels. In some embodiments, an axis of rotation of the first and the second driving wheel are collinear. In various embodiments, the plurality of stability wheels are spaces apart from the axis of rotation of the first and second driving wheels to provide stability to the robotic base.

Various embodiments of the present disclosure are directed to an Unmanned Aerial System (UAS) for applying a liquid to a surface. According to various embodiments, the UAS includes an Unmanned Aerial Vehicle (UAV) including flight control mechanisms. The UAV is configured to receive first control signals and to adjust an operational configuration of the flight control mechanisms in response to the first control signals. The UAS further includes a delivery assembly coupled to the UAV, where the delivery assembly is configured to receive second control signals and to apply the liquid to the surface located proximately to the UAV in response to the second control signals. The UAS further includes a control unit coupled to the UAV and the delivery assembly, the control unit configured to transmit the first and second control signals to the UAV and the delivery assembly, respectively.