Methods and apparatus for advertising, promoting, marketing and/or selling products and services. The inventions include a mobile vehicle and moving showroom for advertising, promotion, marketing, and sales of products and services. The products and services may be promoted for direct sale from the moving showroom, or for sale from other outlets, such as retail stores and internet sales.

The present disclosure provides a method and system for scheduling pieces of materials based on a real-time status of a device. Scheduling rules for scheduling the pieces of materials are obtained according to determined parameters. It is determined whether all designated transmission and process tasks of the pieces of materials are completed. If the designated transmission and processing tasks of the pieces of materials are completed, terminating the scheduling of the pieces of materials. If the designated transmission and processing tasks of the pieces of materials are not completed, each of the scheduling rules for scheduling the pieces of materials according to real-time status information of the device are traversed, and according to a traversing result, operation instructions corresponding to the scheduling rules for scheduling the pieces of materials are executed. The real-time status information of the device is updated according to a device status after executions of the operation instructions are completed.

The present disclosure provides a method and system for scheduling pieces of materials based on a real-time status of a device. Scheduling rules for scheduling the pieces of materials are obtained according to determined parameters. It is determined whether all designated transmission and process tasks of the pieces of materials are completed. If the designated transmission and processing tasks of the pieces of materials are completed, terminating the scheduling of the pieces of materials. If the designated transmission and processing tasks of the pieces of materials are not completed, each of the scheduling rules for scheduling the pieces of materials according to real-time status information of the device are traversed, and according to a traversing result, operation instructions corresponding to the scheduling rules for scheduling the pieces of materials are executed. The real-time status information of the device is updated according to a device status after executions of the operation instructions are completed.

The improved mobile robot utilizes a cooperative wheeled support arrangement having a unique axle design that preferably cooperates with a base support module. A tri-axle is preferably used to support at least one omni-wheel on each axle section. Multiple omni-wheels on each section can be used for higher load applications. The tri-axle is of a fixed design and each wheel pivots on the individual axle section. Preferably, the axle sections are welded to each other.

The improved mobile robot utilizes a cooperative wheeled support arrangement having a unique axle design that preferably cooperates with a base support module. A tri-axle is preferably used to support at least one omni-wheel on each axle section. Multiple omni-wheels on each section can be used for higher load applications. The tri-axle is of a fixed design and each wheel pivots on the individual axle section. Preferably, the axle sections are welded to each other.

A drive system for an all-terrain vehicle (ATV) comprises an electric motor, at least three wheel and tire assemblies, a primary battery, a control module and a throttle device. The primary battery may be located within at least two opposing frame rails of a chassis of the all-terrain vehicle.

A spherical body drive type movement device 10 includes rotary bodies 14, 15, and 16 rotating n number of driving spherical bodies 11, 12, and 13 by being rotationally driven in a state of being in contact from two different directions with each of the driving spherical bodies 11, 12, and 13, and moves on a traveling surface G. The rotary bodies 14, 15, and 16 come into contact with the driving spherical bodies 11, 12, and 13 at positions higher than centers P1, P2, and P3 of the driving spherical bodies 11, 12, and 13 in contact and inside a virtual inverted n-gonal pyramid H or, at positions higher than the centers P1, P2, and P3 of the driving spherical bodies 11, 12, and 13 in contact and on lateral faces α, β, and γ of the virtual inverted n-gonal pyramid H.

A spherical body drive type movement device 10 includes rotary bodies 14, 15, and 16 rotating n number of driving spherical bodies 11, 12, and 13 by being rotationally driven in a state of being in contact from two different directions with each of the driving spherical bodies 11, 12, and 13, and moves on a traveling surface G. The rotary bodies 14, 15, and 16 come into contact with the driving spherical bodies 11, 12, and 13 at positions higher than centers P1, P2, and P3 of the driving spherical bodies 11, 12, and 13 in contact and inside a virtual inverted n-gonal pyramid H or, at positions higher than the centers P1, P2, and P3 of the driving spherical bodies 11, 12, and 13 in contact and on lateral faces α, β, and γ of the virtual inverted n-gonal pyramid H.

A dolly for indoor and outdoor use including a supporting frame extending along a main axis of extension and a loading platform mounted above said frame. The dolly also includes at least one steering and drive wheel coupled to the bottom of the frame and at least one pair of idle wheels coupled to the bottom of the frame and positioned symmetrically relative to the main axis of extension. The dolly also comprises includes a control structure including a plurality of sensors configured for measuring a plurality of operating parameters of the dolly and for generating respective signals representing operating parameters and a processing unit configured to receive the representative signals and to impart a steering command to the at least one steering and drive wheel at least as a function of the representative signals.

A dolly for indoor and outdoor use including a supporting frame extending along a main axis of extension and a loading platform mounted above said frame. The dolly also includes at least one steering and drive wheel coupled to the bottom of the frame and at least one pair of idle wheels coupled to the bottom of the frame and positioned symmetrically relative to the main axis of extension. The dolly also comprises includes a control structure including a plurality of sensors configured for measuring a plurality of operating parameters of the dolly and for generating respective signals representing operating parameters and a processing unit configured to receive the representative signals and to impart a steering command to the at least one steering and drive wheel at least as a function of the representative signals.