An umbrella is formed of an elongated shaft having a first end and an opposite second end and a runner slidably disposed about the elongated shaft. The umbrella includes a rib assembly including a plurality of ribs that are attached to the runner by a plurality of struts that move between open and closed positions. In accordance with the present invention, the elongated shaft has a cross-sectional shape defined by a plurality of curved sections and a plurality of planar sections interspersed between the plurality of curved sections for providing increased torsional strength to the elongated shaft. At least one of the ribs can have a cross-sectional shape defined by a plurality of curved sections and a plurality of planar sections interspersed between the plurality of curved sections for providing increased torsional strength to the at least one rib.

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 base unit, a central support unit, a shading element projection mechanism, one or more shading elements; and a GPS/GNSS receiver, the GPS/GNSS receiver to capture a latitude and/or longitude of the intelligent umbrella. The intelligent umbrella includes a controller, the controller to receive the latitude and the longitude measurement of the intelligent umbrella and to calculate an associated azimuth angle for the intelligent umbrella. The intelligent umbrella also includes a first motor, the controller to communicate the associated azimuth angle to the first motor to cause the intelligent umbrella to move to the associated azimuth angle. The controller receives an altitude measurement from the GPS receiver and calculates an elevation angle. The intelligent umbrella also includes a second motor, the controller to communicate the associated elevation angle to the second motor to cause the umbrella to the associated elevation angle.

An automated hands-free umbrella, having a controller unit integration module with a motor assembly. The motor assembly has a shaft and a directional propeller. A power module has a housing. The housing has a gas container module. The gas container module has a container having gas. Further having an umbrella canopy module, a handle assembly, and a data coordinator system module. The automated hands-free umbrella sustains itself in the air by controlling the umbrella's buoyancy or floatability with an incorporated gas, such as helium. Also has means to hover over a user, even as the user is stationary or while moving.

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 electric umbrella having roller sets contains: a first stick section, a second stick section, a third stick section, and a transmission mechanism. The second stick section is fitted in the third stick section, and the third stick section is fitted in the first stick section, a lower portion of the second stick section is in connection with a handle. The first stick section includes an upper runner disposed on a top including a first roller set disposed therein, and two ends of the driving rope are fixed on two sides of the lower runner, the driving rope rolls across the first roller set and slides between a top of the third stick section and the first roller set, and the transmission mechanism in the second stick section and drives the third stick section through a driving source in the handle drives the umbrella skeleton to expand or retract.

Embodiments of the present invention provide an umbrella, comprising: an umbrella frame, an umbrella cloth, solar chips, a storage battery, and an electrical driving mechanism. The umbrella cloth covers the umbrella frame, the solar chips are disposed on an upper surface of the umbrella cloth, the solar chips are electrically connected with the storage battery, and the storage battery provides electrical energy to the electrical driving mechanism disposed on the umbrella frame so that the umbrella frame, driven by the electrical driving mechanism, achieves opening and closing motion. The present invention solves problems with the umbrellas in the prior art such as single functionality and difficult opening and closing.

Systems, methods, and computer-readable storage devices for providing directions haptically such that sight and hearing can continue unimpeded. In one exemplary embodiment, a wearable device (such as earphones, ear rings, gloves, glasses, or other wearable objects) configured as disclosed herein receives directions to an intended destination for a user, the directions comprising a movement action and a distance to the movement action. The wearable device has multiple haptic output units and generates, through one of those units, a haptic output based on the directions. This allows the user to receive the directions through touch rather than looking at their mobile device or from audio.

The present utility model provides a lifting device and shading device for a sunshade, which comprises a mounting bracket, a sunshade cloth, a support mechanism and a lifting device set on the mounting bracket, wherein the support mechanism comprises a fixed support member arranged at the top of the mounting bracket, a movable support member sliding on the mounting bracket, and a support component connected to the fixed support member and the movable support member respectively and used for unfolding or closing the sunshade cloth, and the lifting device comprises a driving motor, a transmission mechanism connected to the driving motor and used to drive the lifting motion of the movable support member relative to the mounting bracket, and a control component used to control the start and stop of the driving motor.

An electric has comprises a column, a first driving assembly, a slider, an umbrella frame, a second driving assembly, a power source and a control module. The first driving assembly is arranged on the column. The umbrella frame connects to the column and the slider, and the second driving assembly is arranged on the umbrella frame. A power source is charged by solar energy, a control module connects to the first driving assembly, the second driving assembly and the power source, respectively. When the electric umbrella needs to be folded or unfolded and the angle of the electric umbrella needs to be adjusted, a motor operates to drive a rope winding wheel to rotate, and the rope winding wheel rotates to adjust a traction rope, thereby enabling the folding or unfolding of the umbrella and adjustment of the angle of the umbrella frame.