This application claims the benefit of EP Appl. No. 14193316.8, filed 14 Nov. 2014, which is hereby incorporated by reference.
Traditionally, printing and packaging materials such as paper, cardboards and cartons are processed to cut the substrate and/or to score the substrate with folding lines, depending on the printing and packaging material being produced. Thus, a cutting machine, such as for example a die cutter including cutting and scoring blades, is applied to cut and shape the printing and packaging material, whereas the substrate may also be scored with folding lines if the printing and packaging material is to be folded by a user.
Examples of this disclosure are described with reference to the drawings which are provided for illustrative purposes, in which:
Analog die cutters can process large batches of printing and packaging materials, but have long setup times and are thus only designated for long run jobs. Traditional cutters using cutting tables and mechanical cutting blades can be adapted to cut thick boards and to structure almost any shape of cutting and folding lines, but generally require a large set of “puzzle” of blades. Hence, depending on the job, such sets of cutting blades must be provided and adapted to each different task, must be stored if the job is to be repeated, must be maintained, have a mechanically limited lifetime and require significant setup efforts. Hence, although such cutting machines allow fast processing, these machines can be very costly and complicated to handle. Alternatively, simpler cutting machines can be used for cutting packaging materials, for example by allowing only limited thickness of the material being cut. The use of cutting blades such as for example knifes generally requires significant cutting forces when cutting thicker materials. This results in short lifetime and high maintenance cost of the system. Non-contact systems, such as for example laser systems can cut cardboards or cartons but it is difficult to keep laser light focused in the cutting process when cutting thick printing and packing materials. For example, although it is possible to cut thin cartons using powerful CO2 lasers, laser focus difficulties prevent using such lasers to cut thick corrugated boards. Even at low numerical apertures, such as for example at 10u wavelength, the depth of focus will be in tens of microns range, which is insufficient to cut thick substrates. Moreover, laser systems are not suited for scoring folding lines into paper, cardboards and cartons. Fluid jet cutters can be used to cut different types of materials, such as for example metal sheets and the fluid can include abrasive particles and cooling fluids, such as for example metal particles and liquid nitrogen for treating hard and heat sensitive materials.
According to one example, this disclosure provides a jet system for processing at least one sheet of paper, cardboard or carton.
In this example, the corrugated cardboard 10 has sufficient thickness to provide rigid boxes with strong walls. The cutting of thick corrugated cardboards 10 using mechanical cutting blades, such as for example knifes requires significant cutting forces which affect the lifetime and maintenance cost of the processing system. This is particularly the case when many corrugated cardboards 10 are tiled in the cutting device in a stacked arrangement for cutting a plurality of sheets in a single processing step.
Mechanical cutting blades have a body including and supporting a cutting edge, wherein the body must be strong enough to withstand the respective cutting force. Hence, the physical dimensions of mechanical cutting blades generally depend on the processing speed and the thickness and material properties of the substrate being cut. Thick or tiled corrugated cardboards 10 generally require stronger and thus larger mechanical cutting blades than thinner and single layered corrugated cardboards 10. However, although increased dimensions of mechanical cutting blades can improve the robustness of the system, it also affects the maneuverability required to arrange the cutting edge, for example in the process of following the cutting lines 20.
“Pizza” type roller cutters represent robust mechanical cutting blades comprising a circular body having a cutting edge provided along the circumference of the circular body. The circular body is rotatable about an axis such as to be rolled through the substrate being cut. Although this type of mechanical cutting blades can withstand and convey significant forces to the cutting edge, the mechanical cutting blades are adapted to roll along the cutting edge in a straight direction and are thus only suitable for cutting straight or only slightly curved lines. It follows that “Pizza” type roller cutters are not well suited for cutting curved and edged outlines of corrugated cardboard boxes such as for example illustrated in
Another type of cutting systems controls the position of a mechanical cutting blade in the XY plane of the corrugated cardboard 10. In this respect, the XY plane of the corrugated cardboard 10 represent one of the flat surfaces of the corrugated cardboards 10 carrying the cutting and/or folding lines 20, 30. The mechanical cutting blade represents a knife or a mechanical saw which is mechanically arranged in the XY plane such as to apply a cutting force on the substrate 10. Thus, a mechanical actuator system is adapted to arrange the cutting blade such as to position the cutting blade in the XY plane of the corrugated cardboard 10, to turn by rotation the cutting blade into the desired cutting direction and to move the cutting blade in the Z direction towards and away from the corrugated cardboard 10 such as to initiate and interrupt cutting processes. Also in this example, the physical dimensions of the mechanical cutting blade are selected to cope with the processing speed and to withstand the cutting force applied to the substrate. Thus, the physical dimensions and strength of the mechanical cutting blade depends on the processing speed and the thickness and material properties of the substrate being cut. For example, in order to cut thicker or tiled corrugated cardboards 10, the dimensions of the mechanical blade must be adapted accordingly, which affects the maneuverability of the cutting edge, reduces processing speed, and increases wear and maintenance costs of the system.
Non-contact systems, such as for example laser systems can cut cardboards or cartons without mechanically rotating a cutting edge of a cutting blade for applying lateral cutting forces on a substrate. In contrast, laser systems direct a focused laser beam substantially perpendicular to the cutting surface of the substrate and thus burn cutting lines 20 into the paper, cardboard or carton 10. Thus, the laser beam can be directed in a flexible manner to follow complicated patterns of cutting lines 20, including edges and sharp curves. However, laser systems are costly, in particular for cutting large formats of paper, cardboards or cartons. Laser systems are also not suitable for cutting thick materials, such as for example stacked sheets of corrugated cardboards 10, in particular because it is difficult to keep laser light focused throughout thick substrates 10 to achieve a clean cutting effect and profile. Moreover, as laser systems are based on controlling the XY position of laser beams and burning cutting lines 20 into the cardboard or carton 10, such systems are not suited for scoring folding lines into a substrate 10.
Fluid jet cutters can cut different types of materials, such as for example metal sheets, and are based on directing a narrow jet stream containing a fluid towards the substrate 10 to be cut. The fluid can include abrasive particles, such as for example metal particles for improving the speed of processing and the outlines of the cutting profile. The fluid can also include cooling fluids, such as for example liquid nitrogen, such as to cool the processing area of the substrate 10, in particular for treating hard and heat sensitive materials. Traditionally, fluid jet cutters are applied to fluid resistant materials such as metals and plastic, because a jet stream of fluid is being directed to the material.
An example of a jet system 50 for processing at least one sheet of paper, cardboard or carton 10 is schematically illustrated in
The jet system 50 illustrated in
The jet system 50 illustrated in
In another example, the holding unit 100 can also move the jet nozzle 70 to increase or decrease the distance between the jet nozzle 70 and a surface of the at least one sheet of paper, cardboard or carton 10. In this way, the impact of the jet stream on the surface of the substrate 10 can be reduced or increased by adjusting the distance between the jet nozzle 70 and substrate 10. For example, the distance between the jet nozzle 70 and substrate 10 can be adjusted to either cut or score the at least one sheet of paper, cardboard or carton 10.
In the example of a jet system 50 illustrated in
The nozzle 70 provides a jet stream of liquid nitrogen which is directed to for example cut or score lines 20, 30 into the paper, cardboard or carton 10. When the jet stream of liquid nitrogen impacts the paper, cardboard or carton 10 it is quickly vaporized due to heat development. Thus, the liquid nitrogen quickly changes from the state of liquid to vapor without depositing residual liquids on the paper, cardboard or carton 10. Thus, although a liquid jet stream is used to process fluid sensitive paper, cardboard or carton 10 the liquid nitrogen quickly vaporizes before any liquid damage is caused to the material being processed.
Moreover, the jet nozzle 70 directs the liquid nitrogen into a narrow jet stream which can cut paper, cardboard or carton 10 without significantly deflecting the jet stream travelling through the material. It follows that the narrow jet stream remains substantially undistorted throughout the cutting process and can thus be used to cut thick substrates 10, such as for example thick or stacked paper, cardboards or carton 10.
Hence, the liquid nitrogen jet stream allows fast processing, such as for example cutting and/or scoring of paper, cardboards or carton 10 without causing any liquid damage to the fluid sensitive material being cut. Moreover, paper, cardboards and cartons 10 can be stacked and processed in single cutting processes such as to improve efficiency and achieve fast processing. It is further possible to increase the number of jet nozzles 70 and holding units 100 to enable fast parallel processing. For example,
Thus, the cutting of at least one sheet of paper, cardboard or carton 10 using a jet stream of liquid nitrogen can provide a fast cutting process capable of processing stacks of substrates 10 in single processing steps. As mentioned above, substrates 10 can be supported and moved during the cutting process by a conveyor belt, wherein the processing surface 60 represent a surface of the conveyor belt. In an example, fast processing of a series of at least one sheet of paper, cardboard or carton 10 is achieved by moving the conveyor belt 60 at speeds of at least 0.10 m/s, 0.5 m/s or 5 m/s during processing of each of the substrates 10.
Depending on the thickness of the at least one sheet of paper, cardboard or carton 10 the holding unit may according to an example be moved at speeds of at least 20 mm/s, 35 mm/s or 50 mm/s relative to the surface of the substrate 10 being cut. However, the cutting lines 20 to be cut into the substrate 10 may represent non-connected lines which thus require that the process of cutting the paper, cardboard or carton 10 must be interrupted at high speed to move the jet nozzle 70 between two non-connected cutting lines 20. In other words, after processing one of the cutting lines 20 it may be required to temporarily interrupt the cutting process such as to move the jet nozzle 70 without cutting action to a different cutting line 20 and continue with the cutting process. The interruption of the cutting action may for example be performed by closing a valve or by turning off a pump in the fluid conductor 90 such as to interrupt the flow of liquid nitrogen to the jet nozzle 70. However, interrupting the liquid stream to the nozzle 70 by operating a pump or a valve in the fluid conductor 90 does not instantly cut the jet stream exiting the jet nozzle 70. As a matter of fact, the jet stream exiting the jet nozzle 70 decays depending on the buffer effect and pressure fall of the liquid nitrogen present in the fluid conductor 90 between the valve and jet nozzle 70. Consequently, when the jet nozzle 70 is moved at high speed during processing, the achievable speed of processing can depend on the time required to interrupt the liquid flow to the jet nozzle 70.
In a different example of this disclosure, a modulator unit 150 is provided to modulate the jet stream provided by the jet nozzle 70. In other words, the modulator unit 150 influences the jet stream exiting the jet nozzle 70 and is thus not subject to time constants induced by the fluid conductor 90. It follows that the modulation can be applied to quickly turn off and on the jet stream and thus to interrupt the cutting process of the at least one sheet of paper, cardboard or carton 10. During interruption of the jet stream, the jet nozzle 70 can be moved between two non-connected cutting lines 20 for further processing.
Moreover, in this example, the modulator unit 150 is provided to modulate the jet stream directed by the jet nozzle 70. In other words, and as illustrated in
In an example, the distortion blade 170 is made of a hard material such as for example metal, steel or diamond. This is for example useful if the pressure of the jet stream exiting the jet nozzle 70 requires a hard and resistant material for distorting the jet stream.
In an example, the distortion blade 170 is shaped and movable to only partially distort the jet stream exiting the jet nozzle 70. Consequently, only a part of the jet stream is prevented from impacting the substrate 10, wherein the remaining part of the jet stream has less impact and is applied to score folding lines 30 into the at least one sheet of paper, cardboard or carton 10.
In an example, a single distortion blade 170 is used to perform both the off/on modulation of the jet stream, and also to only partially distort the jet stream exiting the jet nozzle 70. For example, the actuator 160 may extend the distortion blade 170 into the jet stream such as to only partially distort the jet stream and thus enable scoring of the substrate 10. However, if the actuator 160 further extends the distortion blade 170 into the jet stream, such that the jet stream is prevented from impacting the substrate 10, an on/off modulation is provided. Thus, the modulator unit 150 comprising the single distortion blade 170 can switch between cutting and scoring the substrate 10, without requiring any additional tools or devices.
In an example, the distortion blade 170 has a flat surface such as to effectively block the jet stream by the flat surface with low deflection. In another example, as shown in
An example of the present disclosure is illustrated in
Thus, a jet stream of liquid nitrogen is directed via a nozzle 70 to process the at least one sheet of paper, cardboard or carton 10, wherein the at least one sheet of paper, cardboard or carton 10 is supported by a processing surface 220. When the jet stream of liquid nitrogen impacts the paper, cardboard or carton 10 the liquid nitrogen is quickly vaporized due to heat development. Thus, the liquid nitrogen quickly changes from the state of liquid to vapor without depositing residual liquids on the paper, cardboard or carton 10. It follows that although a liquid jet stream is used to process fluid sensitive paper, cardboard or carton 10 the liquid nitrogen quickly vaporizes before any liquid damage is caused to the material being processed.
In an example, moving the holding unit 100 comprises moving the holding unit 100 with a speed of at least 20 mm/s, 35 mm/s or 50 mm/s relative to the surface of the at least one sheet of paper, cardboard or carton 10.
In a further example illustrated in
Moreover, a holding unit 100 is moved 240, wherein the holding unit 100 holds the jet nozzle 70 at a distance from a surface of the at least one sheet of paper, cardboard or carton 10.
In an example, the respective modulation of the jet stream 250 is performed by moving a distortion blade 170 relative to the jet stream. In this respect, the jet stream is distorted by the distortion blade 170 for interrupting cut processing 20 of the at least one sheet of paper, cardboard or carton or for scoring folding lines 30 into the at least one sheet of paper, cardboard or carton 10.
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Number | Date | Country | |
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20160136834 A1 | May 2016 | US |