Pre-assembled, self-contained, portable tank and method of using the tank for storing backflow fluids during hydrocarbon production operations. Tank is rapidly deployable and has a collapsible and refillable bladder for storing approximately 50,000 gallons or 1200 BBLS of fluids and a secondary containment with a holding capacity 120% of that of the bladder. When closed for transport, the tank is sufficiently compact and light to be movable with a light body pickup truck with an accompanying trailer over public roadways. After delivery to a site, a crew of two to five persons can set-up the tank for use within about 20 to 120 minutes.

The present invention relates to a method of assembling a folding container. A base comprising a floor is provided, and at least two side panels are attached to the base. A rear panel is pivotally attached to the base, wherein the rear panel is operable to pivot between a folded position that contacts the floor and a vertically deployed position. A hinge block is attached to the base. A front panel comprising a front door is pivotally attached to the hinge block, wherein the front panel is operable to pivot between a folded position that contacts the front panel and a vertically deployed position.

An unmanned aerial vehicle (UAV), and specifically discloses a UAV transport box. The UAV transport box has a mounting frame, a box body, a driving device, and a control system. The box body has a bottom plate and a side plate, the bottom plate is fixedly installed on the mounting frame, the UAV is arranged on the bottom plate, and the side plate can be unfolded through the driving device, so that the side plate and the bottom plate are in the same plane to form an area which is large enough to provide a suitable take-off and landing platform for the UAV, and can realize the automatic opening and closing for the UAV transport box.

A container that is formed from a plurality of panels that are joined to each other by a plurality of edge brackets. Each of the edge brackets includes a first channel member and a second channel member that are joined to each other. The first channel member includes a first receiving channel and the second channel member includes a second receiving channel. The first and second receiving channels are arranged to be perpendicular to each other and are each sided to receive a side edge of one of the panels that form the container. The series of edge brackets can be used to securely assembly the container from the plurality of panels after the disassembled container has been shipped.

A device may include a frame having a first beam, a second beam, and a plurality of supports extending therebetween. The device may include a twist lock operably coupled to a first actuator and situated within a hollow corner of the frame. The device may include an arm having a roller, a second actuator being operably coupled to the arm, and a third actuator operably coupled to the roller. The device may include a first powered winch mounted to the first beam, the first powered winch having a first line with a first attachment feature at an end of the first line. The device may include a first pulley mounted to the second beam, the first pulley being operably coupled to the first line.

A modular multiple mobility base assembly apparatus is described for transporting an item being shipped having a base adapter plate and two cooperating and coordinating modular mobility bases that are each coupled to the bottom of the base adapter plate and collectively support the base adapter plate. One of the modular mobility bases operations a master autonomous mobile vehicle, while the other operates as a slave autonomous mobile vehicle that receives propulsion and steering control signals from the master while providing feedback sensor data to the master for use in coordinated and cooperative movement of the assembly apparatus. Each of the modular mobility bases also including respective wireless transceivers through which at least the control signals and sensor data are provided between mobility base units.

Methods are described that perform a dispatched inventory operation related to an inventory item within a modular autonomous bot apparatus assembly and a dispatch server. modular mobile autonomy control module (MAM) receives an inventory dispatch command from the dispatch server and a modular cargo storage system (CSS) receives the inventory item at an inventory hub location. The MAM autonomously causes the assembly to then move to a remote business facility as a destination location, receive authentication input from an authorized delivery recipient, coordinates with the CSS to provide selective access to the inventory item, detects when the inventory item has been removed from within the CSS, and autonomously causes the assembly to move on a return route back to the inventory hub location after removal of the inventory item.

Methods are described that perform dispatched store-to-consumer logistics operations for an ordered item using a modular autonomous bot apparatus assembly and a dispatch server. A dispatch command is received from the dispatch server. The different modular components of the bot assembly are verified to be compatible with the dispatched operation and the ordered item is received in a payload area of a modular cargo storage system. The bot assembly autonomously moves from an origin location to a destination location and notifies the delivery recipient of the approach delivery. When delivery recipient authentication input is received that correlates to the authentication information, selective access is provided to the ordered item within the cargo storage system at the destination location. The bot apparatus monitors unloading, and autonomously moves back to the origin location after the ordered item is detected as removed from the cargo storage system.

A modular auxiliary power module is described for a modular autonomous bot apparatus that transports an item being shipped. The modular auxiliary power module includes a base adapter platform, a cargo door, an auxiliary power source, and an output power outlet disposed on the base adapter platform as part of a modular component electronics interface. A top side of the base adapter platform has a cargo support area configured to support the item being shipped. Interlocking alignment interfaces (such as channels or latches) are on the top and bottom of the platform. The cargo door is movably attached to and extending from an edge of the base adapter platform, and the output power outlet is coupled to the auxiliary power source and provides access to power for other components of the modular autonomous bot apparatus from the auxiliary power source.

Methods perform one or more dispatched medical logistics operations using a modular autonomous bot apparatus assembly and a dispatch server where the operations are related to a diagnosis kit for treating a patient. The MAM of the bot receives a dispatch command, verifies compatibility of the bot assembly with the dispatched operation(s), receives a diagnosis kit in the CSS, has the MAM autonomously causing the MB to move to a destination location while notifying the authorized delivery recipient for the diagnosis kit of the approaching delivery. With appropriate authentication input received, the MAM coordinates with the CSS to provide access to the kit, monitor unloading of the kit, provide instructional information on use of the kit, and autonomously cause the MB to return to the original location with a return item related to the diagnosis kit with notification to personnel at the medical entity about the return item.