Load Handling Module for a Material Handling Vehicle

We claim: 1 . A load handling module for a material handling vehicle, the material handling vehicle including a vehicle body, a mast, a tower, and at least one fork extending from a load backrest to a tip end, the tower extending upwardly from the load backrest, and the at least one fork being selectively movable relative to the vehicle body and configured to support a load, the load handling module comprising: a first camera secured to the load backrest and positioned proximate a top surface of the at least one fork, the first camera being configured to determine a position of an object in a first camera field of view; a second camera secured to the tower so that it is positioned above the first camera, the second camera being configured to determine the position of an object in a second camera field of view; a fork tip sensor secured to the at least one fork proximate a tip end, the fork tip sensor being configured to detect a presence of an object within a fork sensor field of view extending in front of the tip end; and a controller in communication with the first camera, the second camera, and the fork tip sensor, the controller being configured to autonomously control movement of the at least one fork. 2 . The load handling module of claim 1 , wherein the first camera field of view is configured to cover at least a portion of a bottom of the load when the load is supported on the at least one fork. 3 . The load handling module of claim 1 , wherein the second camera field of view is configured to cover at least a portion of a top of the load is in the second camera field of view when the load is supported on the at least one fork. 4 . The load handling module of claim 1 , wherein the tower includes a tower actuator configured to selectively move the second camera with respect to the first camera. 5 . The load handling module of claim 1 , wherein the at least one fork includes two forks that extend from the load backrest to the respective fork tip, and wherein the first camera and the second camera are positioned between the two forks. 6 . The load handling module of claim 5 , wherein the fork tips sensors on the fork tips are configured to detect the presence of an object between the two forks. 7 . The load handling module of claim 1 , further comprising a load seated sensor configured to detect if the load is fully seated on the at least one fork. 8 . The load handling module of claim 1 , further comprising a weight sensor configured to determine the weight of the load supported by the at least one fork. 9 . A method for picking up a load with a material handling vehicle that includes at least one fork extending from a load backrest, a mast, a tower extending upwardly from the load backrest, a first camera mounted to the load backrest, a second camera mounted to the tower, and a fork tip sensor disposed proximate a tip of the at least one fork, the method comprising: moving the material handling vehicle to a pick up location; identifying a pallet the load is resting on; aligning the at least one fork with the pallet by moving the at least one fork into alignment with a pallet pocket of the pallet; determining if the at least one fork is aligned with the pallet pocket; extending the forks to engage the pallet; and lifting and retracting forks to pick up the load with the fork, wherein identifying the pallet includes using at least one of the first camera and second camera to identify a center stringer of the pallet, and wherein determining if the at least one fork is aligned with the pallet pocket includes using at least one of the first camera and the second camera to determine of the pallet is positioned within a predefined tolerance from the at least one fork by identify the center stringer of the pallet. 10 . The method of claim 9 , further comprising correcting a position of the fork relative to the pallet pocket by detecting a pallet position and executing an adjustment vector that adjusts a position of the fork relative to the detected pallet position. 11 . The method of claim 9 , further comprising verifying that the at least one fork is aligned with the pallet pocket using the fork tip sensor. 12 . The method of claim 9 , wherein extending the forks to engage the pallet further comprises determining, with a load seated sensor, that the at least one fork fully engages the load. 13 . A method for dropping off a load supported by a material handling vehicle, the material handling vehicle including at least one fork extending from a load backrest, a mast, a tower extending upwardly from the load backrest, a first camera mounted to the load backrest, a second camera mounted to the tower, and a fork tip sensor disposed proximate a tip of the at least one fork, the method comprising: moving the material handling vehicle to a drop-off location provided wirelessly to a controller; determining if the drop-off location is vacant using at least one of the second camera and the fork tip sensor to search for a presence of an object in the drop-off location; extending the forks to move the load into the drop-off location; lowering the forks to place the load in the drop-off location; retracting the forks to disengage the load; and verifying that a position of the load is within predefined tolerance of the drop-off location using at least one of the first camera and second camera to measure a distance between the load and the at least one of the first camera and the second camera. 14 . The method of claim 13 , wherein determining if the drop-off location is vacant further comprises analyzing pixels in an image for indications of an object. 15 . The method of claim 13 , wherein determining if the drop-off location is vacant further comprises identifying at least one of a horizontal load bar, an upright beam, and an adjacent load of a racking structure. 16 . The method of claim 15 , wherein determining of the drop-off location is vacant further comprises quantifying at least one of a minimum volume of interest or a maximum volume of interest. 17 . The method of claim 13 , further comprising raising the forks to a drop-off height, wherein the fork tip sensor quantifies a predefined offset height associated with a horizontal load bar of a drop-off racking structure, and wherein the forks are raised the distance of the predefined offset height. 18 . The method of claim 17 , wherein lowering the forks to place the load in the drop-off location comprises lowering the forks at least the distance of the predefined offset height. 19 . The method of claim 13 , wherein verifying the position of the load includes capturing an image of the placed load with the first camera, and measuring a distance between the load and the first camera. 20 . The method of claim 13 , wherein the material handling vehicle further comprising a weight sensor configured to determine a weight of the load supported by the at least one fork, and wherein lowering the forks to place the load in the drop-off location further comprises determining, with the weight sensor, if the weight of the load supported by the at least one fork decreases.