An automated lumber handling method laser-scans the top profile of multiple stacks of lumber, each of which contain boards of a unique size. Based on the scanned profiles, the method determines the order in which individual boards from a chosen stack should be transferred to a numerically controlled saw. The saw cuts the boards to size and in proper sequence to facilitate orderly assembly of a roof truss or prefabricated wall. In some examples, the method lifts individual boards by driving two retractable screws, or some other piercing tool, down into the upward facing surface of the board. A track mounted cantilever, holding the screws and a laser unit, translates over the lumber stacks to retrieve and deliver individual boards and, while doing so, the laser repeatedly scans the stacked lumber profiles on-the-fly to continuously update the profiles. The open cantilever design facilitates replenishing the stacks of lumber.

The disclosure relates to multi-station conveying equipment which comprises a driving device, a conveyance coupling device and a station combination device, wherein the station combining device includes a plurality of conveying station mechanisms arranged side by side in proper order corresponding to a plurality of stations, wherein each conveying station mechanism is suitable for placing and supporting a material frame; the driving device can drive the plurality of material frames on the plurality of conveying station mechanisms to synchronously move through the conveyance coupling device; and the conveyance coupling device comprises at least one set of drawstring shifting fork mechanism. The driving device drives the drawstring shifting fork mechanism to reciprocate, and drives the material frame to move forward simultaneously. The electric system and the mechanical system in the existing conveying mechanism are simplified, the manufacturing cost and the energy consumption of the equipment are reduced, fault points are reduced.

The disclosure relates to multi-station conveying equipment which comprises a driving device, a conveyance coupling device and a station combination device, wherein the station combining device includes a plurality of conveying station mechanisms arranged side by side in proper order corresponding to a plurality of stations, wherein each conveying station mechanism is suitable for placing and supporting a material frame; the driving device can drive the plurality of material frames on the plurality of conveying station mechanisms to synchronously move through the conveyance coupling device; and the conveyance coupling device comprises at least one set of drawstring shifting fork mechanism. The driving device drives the drawstring shifting fork mechanism to reciprocate, and drives the material frame to move forward simultaneously. The electric system and the mechanical system in the existing conveying mechanism are simplified, the manufacturing cost and the energy consumption of the equipment are reduced, fault points are reduced.

This sample rack conveying apparatus is provided with a pusher unit, a linear motion guide, and a conveyance drive mechanism. The pusher unit has a base portion, a moving member, and a base-side guide. The base portion is supported by the linear motion guide so as to be movable in a first guide direction. The moving member is provided with a pusher that pushes a sample rack. The base-side guide supports the moving member such that the moving member is movable in a second guide direction that crosses the first guide direction.

An ambulance cot loading and unloading system for an emergency vehicle includes a base for mounting in the emergency vehicle and an arm mounted for linear movement along the base, wherein the arm configured to support a cot while the cot is being loaded into or unloaded from the emergency vehicle. The ambulance cot loading and unloading system further includes an indicator mounted relative to the arm and a control system, which is in communication with the indicator and configured to generate a status indication of the cot loading and unloading system at the indicator.

An ambulance cot and cot loading and unloading system for an emergency vehicle comprises a cot having a head end, a base for mounting to a deck of an emergency vehicle, a track mounted for linear movement along said base, and an arm mounted for linear movement along said track from a retracted position to an extended position. The arm is and configured to engage the cot, and wherein when the track is extended along the base and the arm is extended along the track the arm is extended from the base in an extended position and is configured for lifting the cot and providing cantilevered support to the cot while in the extended position.

Apparatuses, systems, and methods of manufacturing are described that provide a conveying module and conveying table for item transport. An example conveying module include a frame and an item transport plate that supports one or more items received thereon. The conveying module further includes a conveying drive motor supported by the frame and operably coupled to the item transport plate. The conveying drive motor causes rotation of the item transport plate about the conveying drive motor. The conveying module further includes a tilt adjustment mechanism that adjusts a tilt direction of the item transport plate relative to the frame. The conveying module also includes, in some instance, a tilt drive mechanism that controls operation of the tilt adjustment mechanism.

A linear conveyor includes a plurality of modules constituting a conveyance path and a slider that travels along the conveyance path. The linear conveyor includes at least one relay unit disposed across adjacent modules. The modules are configured such that each of the modules has first and second module-side connection sections provided at both ends in a direction along the conveyance path, the modules being connected in a row along the conveyance path. The relay unit includes a first unit-side connection section that is connected to the second module-side connection section of one of a set of the adjacent modules, a second unit-side connection section that is connected to the first module-side connection section of the other of the set of the adjacent modules, and a first circuit that electrically connects the first and second unit-side connection sections to each other.

In a walking floor conveyor, an arrangement of panels lined longitudinally in a side-by-side fashion are organized into at least two correlating groups of panels. At least two panels within each group. Each panel grouping is propelled and retracted in a reciprocating manner, each by a hydraulic cylinder. The panels comprising wheel receptacles underneath the panels and at least one wheel fitted within a wheel receptacle to allow for forward and backward movement along a wheel support beam. These reciprocating panels supported by a series of wheel support beams, interior support beams and side support beams. These side support beams are at their tallest in the back and shortest in the front to provide a slant allowing for a flow of cargo and liquid runoff captured within a plurality of panel drains located between the panels towards a frontally placed auger designed for the assistance of cargo discharge.

The apparatus comprises a rotary put wall having a plurality of totes. The apparatus further comprises a vertical reciprocating conveyor (VRC) placed within the rotary put wall. The internal vertical reciprocating conveyor (VRC) comprises a plurality of chutes to receive one or more items from a robotic device. The internal vertical reciprocating conveyor (VRC) is further configured to be rotatable with respect to the rotary put wall and to convey the one or more items into one tote of the plurality of totes of the rotary put wall.