A collapsible umbrella with automatic closing structure has an extendable rod automatically retracting toward a runner away from its users by pressing of a button. The extendable rod includes an outer tube, an intermediate tube, an inner tube and a first spring. The tubes respectively have one, two, and three groove sections along outer peripheries thereof. A runner of the collapsible umbrella has axial protrusion to release a resilient section of a first clip from a first slot hole, thereby retracting a first spring for the intermediate tube being retracted into the outer tube; then a resilient section of a second clip is released from a second slot hole, thereby retracting the inner tube into the intermediate tube. The structure enables the users to close and fold the collapsible umbrella with single hand and has the extendable rod closing in a direction away from the users, so as to prevent from splashes of the rain and potential injuries during the retracting and folding.

The present invention discloses an intelligent outdoor umbrella, comprising an umbrella body, an angle adjustment mechanism configured to adjust an angle in a vertical direction, a rotation mechanism configured to adjust an angle in a horizontal direction, a lifting mechanism, an environment monitoring mechanism and a main controller. An angle of an outdoor umbrella is automatically adjusted to follow the change in the sun angle and better achieve the purpose of shading. The lifting mechanism enables the outdoor umbrella to fold and unfold automatically. The environment monitoring mechanism comprises a solar assembly and a wind speed measurement device, the direction of sunlight and the wind speed are monitored and the measured related data is transmitted to the main controller. The present invention is simple and convenient without manual operation.

An automatic umbrella comprises: a shaft (221), a handle, an upper runner (31, 131, 231), a lower runner (30, 130, 230), first ribs (13) having an inner end connected to the upper runner (31, 131, 231), second ribs (15) having two ends respectively connected to the lower runner (30, 130, 230) and one of the first ribs (13), and an automatic opening-closing device. The automatic opening-closing device comprises: an opening draw cord (24), a closing draw cord (45, 145, 245), a first reel (81) and a second reel (82) provided in an internal cavity of the handle, and a drive member (85). One end of the opening draw cord (24) is connected to the lower runner (30, 130, 230), and the opening draw cord (24) passes around a top portion of the shaft (221) to enter an internal cavity of the shaft (221). The other end of the opening draw cord (24) is connected to the first reel (81). The closing draw cord (45, 145, 245) has one end connected to the second reel (82) and the other end led outward and passing through an upper side wall of the shaft (221) to be connected to one of the first ribs (13). The drive member (85) provides a rotational force to both or a selected one of the first reel (81) and the second reel (82). The automatic umbrella has a simple structure, significantly reduces the torque requirement of the drive member (85), and lowers power consumption, thus reducing costs and enabling convenient and safe use.

The formation of dynamic, micro-climate groups consisting of passive and active weather collecting devices is provided. Such devices may collect weather information in real-time. The collected information may be distributed weather information and or forecasts to individuals in a particular geographical area or to other subscribers.

An automatic non-collapsible umbrella includes a handle, a control mechanism, a center post, a detent mechanism, a runner assembly, and a skeleton. A cylindrical main seat of the control mechanism includes a spring biased open button for opening the umbrella, and a spring biased collapse button adjacent to the collapse button for closing the umbrella.

A shading object includes a base unit, a support unit coupled to the base unit, and a rotation hub assembly, the rotation hub assembly coupled to the support unit and rotatable in a circular direction about the rotation hub assembly. The shading object also includes a control housing, the control housing coupled to the rotation hub assembly, the control housing having one or more motor assemblies installed therein. The shading object includes a pivot assembly, a shading element frame, and one or more shading elements, the shading element frame coupled to the pivot assembly, the pivot assembly to rotate the shading element frame and the one or more shading elements about the pivot assembly axis.

An intelligent umbrella includes a light sensor to generate a light intensity measurement, a motor to move the light sensor about an azimuth axis, the light sensor generating a plurality of light intensity measurements and associated locations. The intelligent umbrella also includes a controller to receive the plurality of light intensity measurements from the light sensor, and to identify a highest light sensor measurement of the plurality of light sensor measurements and an associated location. The controller generates and communicates a command including the associated location to a motor, which receives the command and moves the light sensor to the associated location. The controller moves a light sensor about an elevation axis, determines a peak intensity value and corresponding elevation location, and moves the light sensor to the corresponding elevation location.

An umbrella includes a base assembly, an umbrella support assembly connected to the base assembly, a processor, one or more memory devices, a motor assembly to rotate the umbrella support assembly about a vertical axis, the motor assembly comprising a controller and a motor and computer-readable instructions executable by the processor to communicate signals, commands or instructions to the controller in the motor assembly, wherein the controller to communicate signals or commands to the motor to assist in rotating the umbrella support assembly about a vertical axis.

An umbrella system includes a support pole connected to a rotating tube positioned around a center tube that extends between the support pole and a center support that is connected to an umbrella frame. The rotating tube has one or more helical grooves therein that are engaged by teeth of a hub which is connected to the umbrella frame. As the rotating tube is rotated, the hub is driven along the length of the rotating tube thereby opening and closing the umbrella frame. In one arrangement system includes a motor housing assembly including a plurality of batteries and a motor that includes a driven gear that meshes with a stationary gear which causes rotation of the rotating tube. The system also includes a counterbalance assembly positioned within the rotating tube. The counterbalance assembly includes at least one spring positioned within the rotating tube that provides a counterbalance force.

An intelligent umbrella includes a wireless transceiver to receive commands or messages from a mobile computing device and an integrated computing device, the integrated computing device including one or more memory devices, one or more processors and computer-readable instructions stored in the one or more memory devices. The computer-readable instructions are executable by the one or more processors to receive the commands or messages, via the wireless transceiver from the mobile computing device and to generate instructions, signals, commands and/or messages, based, at least in part on the received commands or messages from the mobile computing device. The computer-readable instructions are executable by the one or more processors to communicate the generated instructions, signals, commands or messages to one or more assemblies of the intelligent umbrella to cause the one or more assemblies of the intelligent umbrella to move in a specified manner.