Described herein are systems and methods for using different truck types for deliveries. A package is initially loaded into a specially configured cargo container that can be transported either on a primary truck or a secondary truck. A secondary truck is smaller than a primary truck and is configured to transport fewer cargo containers than the primary truck. An initial leg of the overall delivery (e.g., from a warehouse to a transfer point) is performed using a primary truck. The cargo container is then transferred to a secondary truck, which completes the delivery. Empty cargo containers can be transferred back to a primary truck, e.g., in a stacked or folded manner, for transporting back to the warehouse. The configurations of primary and secondary trucks are such that these transfers can occur at any location (e.g., a parking lot) with minimal human involvement.

Described herein are systems and methods for using different truck types for deliveries. A package is initially loaded into a specially configured cargo container that can be transported either on a primary truck or a secondary truck. A secondary truck is smaller than a primary truck and is configured to transport fewer cargo containers than the primary truck. An initial leg of the overall delivery (e.g., from a warehouse to a transfer point) is performed using a primary truck. The cargo container is then transferred to a secondary truck, which completes the delivery. Empty cargo containers can be transferred back to a primary truck, e.g., in a stacked or folded manner, for transporting back to the warehouse. The configurations of primary and secondary trucks are such that these transfers can occur at any location (e.g., a parking lot) with minimal human involvement.

A vehicle flooring system configured to enable movement of cargo within a vehicle. The flooring system is made up of individual flooring panels connected via a snap fit type connection. In one embodiment, the flooring panels define one or more openings/slots configured to receive and secure one or more rollers. The rollers are configured to enable slidable movement of cargo within the vehicle. In another embodiment, the flooring panels include one or more lightweight panels and one or more reinforced panels. In one example, the reinforced panels are metal, such as extruded aluminum. In another example, the lightweight panels are a polymeric material, such as extruded plastic. The flooring system is further configured to satisfy government regulations concerning pull testing.

A vehicle according to a vehicle system and method includes a chassis, a coupler, and a platform on the chassis. The coupler is mounted to the chassis at a first end of the chassis and is configured to releasably connect the vehicle to a second vehicle. The platform is for supporting a cargo container and includes a base portion and a bridge member. The bridge member is located at an end of the platform and is extendable relative to the base portion from a retracted position to an extended position to lengthen the platform. The bridge member in the extended position projects beyond the first end of the chassis, above the coupler, towards the second vehicle for establishing a bridge to transload the cargo container from the platform to the second vehicle.

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 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 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.

The present invention relates to security systems and methods for vehicles and/or vehicle users that prevent the theft of vehicles, and/or that guarantee the security of the vehicle user. In order to achieve the above, the system of the present invention has an enabling system that controls the ignition of the vehicle, and/or a device for helmets intended for the monitoring of the security of the user, and makes it possible to determine, for example, whether the user is wearing the helmet and is using the same correctly, or whether the vehicle user has suffered an impact. Specifically, the system of the present invention has an interactive system (mobile device) associated with the user which, depending on the need, signals the enabling system to enable the vehicle ignition, provided that at least one condition is fulfilled, where a condition may be that the interactive system is close to the enabling system and/or emits an alert message to the external device of a third party if any novelty is detected in the helmet device.

A bucket system (10) comprising a frame (12) including first and second rails (26, 27). A bucket (14) is provided having a bucket support (16) including front wheels (32, 33) and rear wheels (34, 35) being slidable within channels (30) in the first and second rails (26, 27). Rear portions (39) of the rails (26, 27) are pivotable between extended and stored positions. When the rear portions (39) are moved to the extended positions, gaps (42) are defined in upper sides of each of the rails (26, 27) such when the rear wheels (34, 35) are moved into the rear portions (39) of the first and second rails (26, 27), the front wheels (32, 33) may move upwardly through the gaps (42) to allow the bucket (14) to pivot about the rear wheels (34, 35).

A bucket system (10) comprising a frame (12) including first and second rails (26, 27). A bucket (14) is provided having a bucket support (16) including front wheels (32, 33) and rear wheels (34, 35) being slidable within channels (30) in the first and second rails (26, 27). Rear portions (39) of the rails (26, 27) are pivotable between extended and stored positions. When the rear portions (39) are moved to the extended positions, gaps (42) are defined in upper sides of each of the rails (26, 27) such when the rear wheels (34, 35) are moved into the rear portions (39) of the first and second rails (26, 27), the front wheels (32, 33) may move upwardly through the gaps (42) to allow the bucket (14) to pivot about the rear wheels (34, 35).

Described herein are systems and methods for using different truck types for deliveries. A package is initially loaded into a specially configured cargo container that can be transported either on a primary truck or a secondary truck. A secondary truck is smaller than a primary truck and is configured to transport fewer cargo containers than the primary truck. An initial leg of the overall delivery (e.g., from a warehouse to a transfer point) is performed using a primary truck. The cargo container is then transferred to a secondary truck, which completes the delivery. Empty cargo containers can be transferred back to a primary truck, e.g., in a stacked or folded manner, for transporting back to the warehouse. The configurations of primary and secondary trucks are such that these transfers can occur at any location (e.g., a parking lot) with minimal human involvement.