Stack Lifting Assembly

Abstract

A stack lifting assembly for incrementally lifting stacks of flats loaded typically with produce to an unloading device and system. The assembly is configured to receive stacks of flats full of produce such as berries, and to lift the stacks to an unloader. The stack of flats is lifted allowing for the top flat to be removed and dumped, with the remaining stack of flats lifted and the process repeated. The stack lifting assembly has a frame, with two counter rotating belts that have flat support tabs that engage the bottom flat in a stack of flats, and lift the entire stack of flats. The dumping operation is allowed to proceed continuously, with no pauses to load stacks of flats. Throughput and safety are greatly improved.

Claims

1. A stack lifting assembly for use in lifting a stack of flats for removing produce from the flats, said stack lifting assembly comprising: a stack lifting frame, said stack lifting frame defining a loading chamber having an opening configured for insertion therethrough of a stack of flats to a loading position in said loading chamber; a pair of opposing lifting belts positioned on opposing sides of said loading chamber, said opposing lifting comprising a pair of opposing flat support tabs, wherein said pair of flat support tabs are configured to support the bottom flat of a stack of flats from opposing sides of said bottom flat, wherein said opposing lifting belts are configured for opposing rotation such that said pair of flat support tabs are configured for parallel upward movement to lift said stack of flats from said bottom flat; wherein stack lifting assembly is configured to incrementally lift the stack of flats from the bottom flat of said stack positioned in said loading position to a launch position so that the top flat may be removed from the stack by a flat flipper assembly.

2. The stack lifting assembly of claim 1 further comprising an infeed conveyor positioned adjacent to said stack lifting frame and configured to deliver a stack of flats to said loading chamber.

3. The stack lifting assembly of claim 1 wherein said flat support tabs are configured to support a base of the bottom flat in a stack of flats.

4. The stack lifting assembly of claim 1, wherein said opposing lifting belts each comprise two opposing chains, wherein said each of said flat support tabs extend between said opposing chains.

5. The stack lifting assembly of claim 1, wherein said opposing lifting belts comprises a plurality of paired flat support tabs.

6. The stack lifting assembly of claim 1, wherein said stack lifting assembly is configured to receive a second stack of flats in said loading position under a previous stack of flats before the last flat of said previous stack of flats has been engaged by the flat flipper assembly and removed, so that flats can continually be lifted and unloaded without stopping said stack lifting assembly to insert another stack of flats.

7. The stack lifting assembly of claim 5, wherein said opposing lifting belts comprise two pairs of flat support tabs, wherein said pairs of flat support tabs are positioned in a spaced apart relationship to allow for said stack lifting assembly is configured to receive a second stack of flats in said loading position under a previous stack of flats before the last flat of said previous stack of flats has been engaged by the flat flipper assembly and removed, so that flats can continually be lifted and unloaded without stopping said stack lifting assembly to insert another stack of flats.

8. The processing machine of claim 4 in which said infeed conveyor further comprises a powered belt to feed stacks of flats laden with produce into the loading position in said stack lifting assembly.

9. The processing machine of claim 1 wherein said stack lifting assembly is configured to incrementally lift said stack of flats in increments of a height of a flat.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0013] FIG. 1 is a perspective view of the disclosed flat unloading system.

[0014] FIG. 2 is a perspective view of the stack lifting crane portion of the flat unloading system.

[0015] FIG. 3 is a perspective view of the stack lifter portion of the disclosed flat unloading system.

[0016] FIG. 4 is a perspective view of the cradle and a stack of flats of the disclosed flat unloading system.

[0017] FIG. 5 is a perspective view of the flat flipping portion of the disclosed flat unloading system

[0018] FIG. 6 is a perspective view of the dumper arms and a flat to be dumped.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0019] While the presently disclosed inventive concept(s) is susceptible of various modifications and alternative constructions, certain illustrated embodiments thereof have been shown in the drawings and will be described below in detail. It should be understood, however, that there is no intention to limit the inventive concept(s) to the specific form disclosed, but, on the contrary, the presently disclosed and claimed inventive concept(s) is to cover all modifications, alternative constructions, and equivalents falling within the spirit and scope of the inventive concept(s) as defined in the claims.

[0020] Shown in FIG. 1 is a view of the disclosed flat unloading system 10. The processing machine of the disclosed technology is designated 10, also called a flat unloading system, is made up of several subunits, which each performing an essential task. The subunits include the stack moving assembly 11, made up cradle 12, the stack lifting assembly 14, the crane track 16 and the load frame 18. The function of these last four elements is to engage a stack of flats, lift the stack of flats without the operator having to lift any weight, and moving the stack of flats onto the end of infeed conveyor 20. More about this system and its parts is more clearly shown in FIG. 2. Another subcomponent of the flat unloading system 10 which is shown in FIG. 1 is the stack lifter 22. The stack lifter 22 is shown more clearly in FIG. 3. The stack lifter 22 includes a stack lifting frame 24 with a lifting belt 26, 27 on each side of the lifting frame. The lifting belt has tabs 29, 31, 33, 35 on the belts on either side of the lifting frame, with the tabs structured to engage the bottom flat of a stack of flats.

[0021] FIG. 2 shows the stack engaging frame called a cradle 12, which has cradle handles 42, and at least one pair of attached cradle forks 44. The configuration of the cradle, cradle handles, and cradle forks depends on the size of the flats or totes used, but for typical flats which are 24″×16″ with 1.5″ or 3″ high sidewalls, the cradle would be approximately 66″ tall, it would have 3 pairs of forks, each fork being 15″ long. The forks 44 are shaped to engage a lip on the side of flats 30 in the stack of flats 32. The stacks of flats are typically moved on a pallet 46 with 4 stacks of flats per pallet and with 20 flats per stack. The cradle 12 can be easily moved left or right, in or out, by a roller 48 which slides on rollers 48 on an overhead crane track 16, providing movement from a first end 68 of the crane track to a second end 70 of the crane track 16. The crane track 16 moves side to side on a curved lateral track 50, by use of a second roller 52. The crane track 16 pivots at a pivot point 54 attached to the load frame 18. The load frame 18 includes the support legs 56, the crane track 16, the lateral track 50, the hoist 14, and the roller 48. The support legs in a typical installation are made of square steel tubing 4″×4″, and would be about 120″ tall. The crane track 16 in a typical configuration would be 96″ long.

[0022] After a stack of flats is engaged by the attached cradle forks 44, a hoist 14 lifts the entire stack of flats, and the stack of flats is moved over the infeed conveyor 20, and the stack of flats is lowered by the hoist 14 onto the infeed conveyor 20.

[0023] Shown in FIG. 3 is the stack lifter 22 portion of the device, the flat flipper assembly 58 portion of the device, and the infeed conveyor 20. Shown in various stages of processing are four flats 30, but it is understood that the entire area inside the stack lifter would typically contain a stack of flats or a partial stack. Shown in FIG. 3 is the infeed conveyor 20. The normal state of the device would have one or more stacks of flats 32 on the infeed conveyor 20, and a full stack or a partial stack off flats in the flat lifter 22.

[0024] The stack lifter 22 has a stack lifting frame 24, and is positioned adjacent to the infeed conveyor 20. The infeed conveyor can be powered, such by a motor, or passive, such as with rollers. A stack of flats is moved into the loading chamber 25 in the loading position 34 of the stack lifter 22, and the stack is lifted by flat support tabs 29, 31, 33, 35 on lifting belts 26, 27 on either side of the stack lifter lifting frame 24. In one configuration, the lifting belts are formed of two chains 41, 43, 45, 47 on each side of the stack lifter frame, and each lifting belt has two flat support tabs 29, 31, 33, 35 which support the base of the bottom flat. Each of the lifting belts rotate opposite of each other, so the right belt rotates clockwise, and the left lifting belt rotates counterclockwise. The flat support tabs 29, 31, 33, 35 of each support the base of the bottom flat, and lift that flat and those above it toward the launch position 36. More than two pairs of tabs are possible on the lifting belts 26. The stack of flats is thus lifted in increments of one flat height at a time, and is coordinated so that as a flat 30 is lifted off the launch position, the entire stack of flats in the stack lifter is moved up the height of one flat. In this way there is always one flat in the launch position when the dumper arms 38 swing back to engage a new flat.

[0025] Dimensions of each part of the machine would vary depending on the size of the flats used. As noted above, a flat which has higher sidewalls is called a tote, and the flats would typically be 16 inches wide and 24 inches long, with sidewalls 1.5 or 3 inches high. A tote would typically be 16 inches wide and 24 inches long, with sidewalls 7 inches high. The position at the bottom of the stack lifter is called the chamber 34 and the position of the flat at the top of the stack lifter is said to be in the launch position 36.

[0026] A stack of flats is inserted into the stack lifter 22 as soon as there is room available from the previous stack being sufficiently lifted and dumped. The stack 32 slides into the chamber 34 and entire stack is lifted in the stack lifter 22.

[0027] FIG. 4 shows a stack of flats 32, the cradle 12, cradle handle 42, and attached cradle forks 44. The cradle forks 44 are structured to be inserted in a generally horizontal angle of attack in to the flats, to engage one flat, and to lift the flats in a generally horizontal direction.

[0028] FIG. 5 shows the flat flipper assembly 58 portion of the device. Flats 30 are lifted off of the launch position 36 one flat at a time by a pair of dumper arms 38. The dumper arms rotate toward the flat to grasp the lip 60 on the side of the flat 30 which is in the launch position 36, and then the dumper arms rotate approximately 120 to 180 degrees in the opposite direction and lift the flat 30 to an inverted position, and drop the inverted flat a preselected distance onto a pair of ejector arms 40. The point at which the inverted flat drops away from the dumper arms is called the release point. The ejector arms 40 then flip the flat 30 again in a direction away from the flat flipper assembly 58 and deposit it in another location, such as a removal belt (not shown). While the dumper arms 38 engage a flat in the launch position 36, the ejector arms move into a position to be under the flat 30 as it is flipped and dropped by the dumper arms. As the ejector arms flip the flat away from the flat flipper assembly unit 58, the dumper arms rotate back toward the stack lifter 22, and engage the flat 30 which has been raised into the launch position 36. After engagement by the dumper arms 38, the flat 30 is rotated and dropped onto a pair of ejector arms 40, which are positioned where the flat will fall from the dumper arms. The lip 60 of the flat 30 can be engaged by a spring loaded catch on the dumper arms, which pass over the flat lip 60 in the downward movement of the dumper arm, and which engage the flat lip 60 when the dumper arm moved upward. Other structures for engaging the flat lip are possible, which as by pneumatic, hydraulic, or electric activation.

[0029] FIG. 6 shows two flats 30, with one of them in the launch position 36. Each flat has a lip 60 on each side. The lip 60 is shown engaged by the dumper arms 38. When activated, the dumper arms 38 and flat 30 full of produce rotate around the dumper axle 66, and drop the flat onto the waiting ejector arms shown in FIG. 5.

[0030] While certain preferred embodiments are shown in the figures and described in this disclosure, it is to be distinctly understood that the presently disclosed inventive concept(s) is not limited thereto but may be variously embodied to practice within the scope of the following claims. From the foregoing description, it will be apparent that various changes may be made without departing from the spirit and scope of the disclosure as defined by the following claims.