Systems, methods, and apparatuses are disclosed for empty container removal. In one embodiment, an example method for removing empty containers may include opening a first gate, pushing a cart past the first gate, the cart comprising a handle and a trapdoor, where the cart comprises the empty containers, sliding the handle of the cart in a lateral direction from a default position to an extended position, opening a second gate, pushing the cart past the second gate using the handle, and actuating the trapdoor from a closed position to an open position, where actuating the trapdoor causes the empty containers to fall down a chute.

The present disclosure is directed to multi-use mobile robots that cater to both goods delivery and people mobility. These robots allow for seamless and dynamic transition between a rideable personal transport vehicle that may be driven by a user sitting in a removable robot seat, driven by the user standing onboard the vehicle, or driven by a second individual walking behind the multi-use robot. The multi-use robot may also function as an autonomous delivery vehicle, and can provide an option to allow both people and goods to be transported simultaneously. The multi-use robots can also integrate with mobile warehouses and neighborhood storage lockers and mobile warehouses, and provide last-mile handling of goods and supplies.

A liner (10) includes a liner base (11) and a cradle (12) which is used in conjunction with a conventional intermediate bulk container (13). The liner base has a bottom wall (15), a top wall (16) opposite the bottom wall, and four side walls (17) extending between the bottom wall and top wall. The four side walls include a front wall (18), a rear wall (19), and two oppositely disposed end walls (20). The top wall includes a top opening fitment (22). The front wall includes a dispensing opening fitment (23). The liner lifting cradle includes a bottom panel (26), two oppositely disposed end panels (27), and a rear panel (28). The end panels have an elongated terminal end (30) which includes a reinforced mounting hole (32). The rear panel has an elongated terminal end (34) which includes a grommet (35) defining a reinforced mounting hole (36).

A wheeled pouring apparatus for moving and pouring concrete and other materials includes a base having a base top side, a base bottom side, a base left side, a base right side, a base front side, and a base back side. A plurality of wheels is coupled to the base bottom side. A pair of supports is coupled to the base top. A bucket is coupled to the pair of supports. The bucket has a bucket left side and a bucket right side each having an axle pivotably coupled between the pair of supports. The bucket pivotably moves between a rest position with an open bucket top side horizontal and an angled pour position. A lip is coupled to the bucket. A lip front side contacts and extends past the base front side with the bucket in the pour position.

Apparatuses and methods described herein relate to arm carts for transporting and securing a robotic arm to a surgical table. In some embodiments, an arm cart may include an arm support having two joints that can be manipulated to move an arm into a position in which a coupler of the arm is engageable with a coupling site of a surgical table. In some embodiments, an arm cart may include an arm support that is rotatable and translatable to permit movement of an attachment area for receiving and attaching a coupling site of a surgical table to a coupler attached to an arm. In some embodiments, an arm cart may include an arm support that releasably couples to a middle segment of the arm positioned at least two segments away from an end of the arm having a coupler for coupling to a coupling site of a surgical table.

The construction industry ranks among the largest and most dangerous industries in the world. To promote worker safety, government regulations require use of fall protection equipment, such as railings, many of which are expensive, wasteful, and/or time consuming to use. Accordingly, the present inventor devised some alternatives. One exemplary system incorporates a dual post base plate configured for attachment to a concrete floor via a single concrete anchor bolt, instead of the multiple bolts used conventionally, thereby reducing assembly time and cost. Another embodiment includes a rolling cart assembly which stores the rails in a side-by-side vertical arrangement and the base plates in an interleaved sequence, promoting easy access during installation and inventory control during disassembly and storage. Additionally, some embodiments include four stacking posts that extend upward from the cart, enabling multiple carts to be stacked vertical on atop the other to save space on construction sites.

A pallet sled includes a sled base having wheels. A fork tine assembly extends from the sled base and includes a pair of fork tines. At least one of the pair of fork tines is configured to be secured to a base of a hand cart, such as with a slot or recess. The hand cart can be carried by the fork tine while the fork tines are supporting a pallet loaded with goods thereon.

The invention relates to a device for transporting large-format building boards, including a cart provided with wheels for the movement thereof and a transporter with suction cups for securing the large-format board to be transported. The cart comprises at the top removable coupling means of a modular transporter carrying suction cups on at least one of the ends thereof, front and rear, an extendable extension is provided with fastening means for fastening the cart in an essentially protruding position forming a support on the floor during the unloading of the device towards the end carrying said extension

A dish cart includes a top with a slot for receiving a lift arm that may be lifted up through the slot to raise or lower dishes. Lobe openings emanating from the slot receive lobes of a lift paddle secured to the lift arm. The cart may define a gap below the top for permitting insertion of the lift paddle and the lift arm. The cart may be adjusted to receive differently sized dishes by means of rails of different sizes or adjustable vanes. A dish drop station includes the lift arm and lift paddle and a lift mechanism for raising and lower the lift arm. The dish drop station may include a cart present sensor and include a lock for retaining the cart. The controller may be programmed to the lower the lift arm to an unlock position that disengages the cart lock.

The present disclosure is directed to multi-use mobile robots that cater to both goods delivery and people mobility. These robots allow for seamless and dynamic transition between a rideable personal transport vehicle that may be driven by a user sitting in a removable robot seat, driven by the user standing onboard the vehicle, or driven by a second individual walking behind the multi-use robot. The multi-use robot may also function as an autonomous delivery vehicle, and can provide an option to allow both people and goods to be transported simultaneously. The multi-use robots can also integrate with mobile warehouses and neighborhood storage lockers and mobile warehouses, and provide last-mile handling of goods and supplies.