This invention relates to an apparatus for erecting open-topped containers or trays.
At the present time, tray erectors having a well of fixed dimensions and a mandrel of fixed dimensions adapted to fit within the well, are used to erect corrugated cardboard or other packaging material trays or open topped cartons from a flat blank. The blank is positioned over the well and mandrel pushes on the blank in the base region to force the sides of the blank up as the blank is pushed into the well. Whilst this arrangement works well for trays of one fixed footprint size, if a tray of a different size is required, the components from which the well and mandrel are constructed must be repositioned or replaced to suit the dimensions of the new tray. Alternatively, more than one machine will be required. This adds to the cost of equipment or to the cost of operating the machine to allow for the erection of trays of various footprint dimensions.
Other forms of tray erector machines are known in the patent literature. Examples of such machines will be found in U.S. Pat. No. 3,882,655 (Monaghan) and U.S. Pat. No. 6,186,931 (Calvert, et al). It will be noted that the machines described in these United States patents are complex and do not allow for the erection of trays using a well/mandrel combination.
It is an object of the present invention to provide an apparatus or machine for erecting open topped cartons or trays of varying dimensions.
The invention provides a machine for erecting open topped cartons or trays from substantially flat blanks, comprising a magazine for storing a supply of flat blanks of predetermined dimensions, means for delivering a blank from the magazine to a tray forming section, said tray forming section including a well defined by wall elements which are movable in two directions to adjust the size of the well, a mandrel having portions which are movable in two directions to adjust the size of the mandrel, and drive means for pushing the mandrel into the well to fold the blank into a tray.
In one form, the wall portions defining the well and the portions defining the mandrel include connected wall elements which define the corners of the well and the corners of the mandrel, said elements being moveable towards and away from each other to vary the dimensions of the well and the mandrel to suit blanks of various dimensions.
The wall elements defining the well include plate members assembled to define a corner of the well, the plate members having upper edges which are rolled outwardly to allow the blank to be pushed into the well by the mandrel, the wall elements defining the mandrel comprising plates formed from or coated with low friction material such as nylon.
The well corner elements may be adjusted by screw driven means while the mandrel wall elements can be adjusted by pneumatic cylinder means.
The means for delivering blanks to the tray forming section may include a pair of blanks support rails which are adjustable towards and away from each other to suit blanks of various dimensions.
The means for delivering blanks may include blank kickers for moving the blanks from the magazine, pinch rolls for moving the blanks towards the tray forming section and blank kickers for moving the blanks to the tray forming section.
The magazine may include a support for a stack of blanks which is vertically moveable towards a vacuum transfer means which transfers blanks one at a time from the stack to the means for delivering blanks.
The machine may further including blank end stops which are adjustable in position to ensure that blanks of various sizes are correctly positioned over the well.
Other features of an embodiment of the invention will be found in the description below.
In order that the invention may be more readily understood, one embodiment of the invention will now be described with reference to the accompanying drawings in which:
Referring to
Referring to
Referring to
To ensure that the blanks are correctly positioned over the well 6, blank end stops E are mounted on a cross shaft S carried by mounting blocks B on an adjustable screw drive D driven by motor M to position the end stops E appropriately for the blank size input into the machine controller. In addition, one-way dogs 66 (
The size adjustment of the well 6 by movement of the corner defining assemblies 11 to 18 is achieved by a screw driven ball nut drives 28, 29, and a drive not visible, driven by well size change motor pair 31 and motor 32. The motor pair 31 controls the well length on each side and the motor 32 changes the width of the well via driving chains (not shown) engaging sprockets 33.
To prevent mechanical damage to the various drives, end of limit travel switches (not shown) are mounted at both ends on each screw drive. The feedback for correct positioning is achieved by a proximity switch sensing an encoding disc mounted on the gearbox output shaft (not shown).
The well size and the blank end stop position may be adjusted automatically to suit a multiplicity of tray footprint sizes, and in this regard, the size adjusting motors are controlled by a programmable software associated with the control system (not shown) for the machine.
Referring to
When a size change is required, the well 6 is automatically extended to its outermost limits. When at this position, the mandrel 7 is retracted to its smallest size and extended down into the well 6. The well 6 is then driven inwards to the inner dimensions of the tray size which has been put into the control system. The mandrel 7 is then expanded outwardly, at which point proximity switches (not shown) detect contact of the end and sides of the mandrel 7 against the well 6, at which time the mandrel drives are locked and the mandrel 7 is set at the correct footprint dimensions. At this time, the well 6 is driven outwardly to enable the tray blank to fold up in the well 6 as the mandrel 7 pushes the blank into the well 6.
Referring now to
Referring to
The second major function of the rails is size change, and since the machine is capable of forming a range of different tray sizes, the rails 62,63 must be able to adjust in order to accommodate each specific blank size. To this end, the rail 62,63 move in and out on a series of threaded shafts as illustrated in the drawing, which are driven by a rail size change motor 67. The size change is effected according to pre-programmed settings at the same time as the well and mandrel settings are changed to suit the blank to be erected. When the blank is delivered to the forming well region 5, two secondary pneumatic cylinders (not shown) ensure that the blank is in the correct position against the blank end stops E. Reed switches on the extend sides of the pneumatic cylinders and a “box in position” photoelectric cell (not shown) will confirm the blank position. At this point the mandrel will actuate and the tray will be formed. The tray will be held in the forming well until such time as the next tray is formed and this tray will eject the presetting tray onto the conveyor 8 which carries the completed tray away.
It will be appreciated from the above that by providing a variable well 6 and a variable mandrel 7, numerous blank footprint sizes are able to be erected by a single machine thereby reducing the cost and speeding the erection of different sized blanks.
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Number | Date | Country | |
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20070037682 A1 | Feb 2007 | US |