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Title:
METHOD AND APPARATUS FOR CONDITIONING OF CARDBOARD
Document Type and Number:
WIPO Patent Application WO/2022/029772
Kind Code:
A1
Abstract:
A method and apparatus are disclosed for conditioning a corrugated cardboard stack by causing air to flow through flutes of the stack from an air intake end to an air discharge end of the stack, air moved by an air moving device being confined to flow only, or at least predominantly, through the flutes.

Inventors:
AMIR NURIEL (IL)
KARP MICHAEL (IL)
BEN DAVID OR (IL)
Application Number:
PCT/IL2021/050941
Publication Date:
February 10, 2022
Filing Date:
August 03, 2021
Export Citation:
Click for automatic bibliography generation   Help
Assignee:
HIGHCON SYSTEMS LTD (IL)
International Classes:
F26B25/00; B23K26/16; B31B50/74; F26B21/00; F26B21/06; F26B21/14
Foreign References:
US3875680A1975-04-08
US5444922A1995-08-29
US10179378B22019-01-15
US5295309A1994-03-22
US3418725A1968-12-31
US3239944A1966-03-15
Attorney, Agent or Firm:
KVATINSKY, Hananel (IL)
Download PDF:
Claims:
- 8 -

CLAIMS

1. A method of conditioning a corrugated cardboard stack, which comprises causing air to flow through flutes of the stack from an air intake end to an air discharge end of the stack by confining air moved by an air moving device to flow only, or at least predominantly, through the flutes.

2. A method as claimed in claim 1, wherein the air moving device includes an air extractor connected to the air discharge end of the stack to place the air discharge end under sub-atmospheric pressure and thereby to draw ambient air into the flutes at the air intake end.

3. A method as claimed in claim 1 or 2, wherein the air moving device includes a fan or blower connected to the air intake end of the stack to raise the air pressure at the air intake end above ambient atmospheric pressure and thereby blow air into the flutes.

4. A method as claimed in claims 2 and 3, wherein the same air moving device serves both to reduce the air pressure at the discharge end of the stack and to increase the air pressure at the air intake end, thereby causing air to recirculate through the stack.

5. A method as claimed in claim 4, wherein the recirculated air is filtered.

6. A method as claimed in claim 4 or 5, wherein the temperature of the recirculating air is controlled by heating and/or cooling to remain within a predetermined range.

7. A method according to claim 6 wherein said predetermined range is between 30°C to 80°C, or 40°C to 70°C.

8. A method as claimed in claim 4, 5, 6 or 7, wherein the humidity of the recirculating air is controlled by a humidifier to remain within a predetermined range.

9. A method according to claim 8 wherein said predetermined range is from 40% to 80% or 50% to 70%.

10. A method as claimed in any one of claims 4 to 9, wherein ozone or other airborne material is introduced into the recirculating air. - 9 -

11. A method as claimed in any one of claims 1 to 10, wherein speed of the air in the flutes in the range from 0.3 m/s to 15 m/s.

12. An apparatus for conditioning a corrugated cardboard stack, which comprises an air moving device and a shroud to surround the stack so as to confine air moved by the device to flow only, or at least predominantly, through flutes of the cardboard in the stack, from an air intake end to an air discharge end of the stack.

13. An apparatus as claimed in claim 12, wherein the shroud includes an element made of a flexible material that is urged to seal against the sides of the stack by an air pressure differential generated by the air moving device.

14. An apparatus as claimed in claim 12 or 13, wherein the air moving device comprises an air extractor connected to the air discharge end of the stack to place the air discharge end under sub-atmospheric pressure and thereby to draw ambient air into the flutes at the air intake end.

15. An apparatus as claimed in any one of claims 12 to 14, wherein the air moving device comprises a fan or blower connected to the air intake end of the stack to raise the air pressure at the air intake end above ambient atmospheric pressure and thereby blow air into the flutes.

16. An apparatus as claimed in claims 14 and 15, wherein the same air moving device serves both to reduce the air pressure at the discharge end of the stack and to increase the air pressure at the air intake end, thereby creating an air recirculation circuit passing through the flutes of the stack.

17. An apparatus as claimed in claim 16, wherein the recirculation circuit includes a filter.

18. An apparatus as claimed in claim 16 or 17, wherein the recirculation circuit includes at least one of

(i) a heater or cooler for maintaining the temperature of the recirculating air within a predetermined range,

(ii) a humidifier for maintaining the humidity of the recirculating air within a predetermined range,

(iii) an ozoniser for introducing ozone into the recirculating air, and - 10 -

(iv) and atomiser for introducing airborne material into the recirculating air.

19. An apparatus as claimed in claim 18, further comprising a temperature sensor and a controller for controlling the heater or cooler to maintain the circulating air within the range from 30°C to 80°C, or 40°C to 70°C.

20. An apparatus as claimed in claim 18, further comprising a humidity sensor and the control is operative to maintain the relative humidity of circulating air in the range from 40%-to 80% or 50% to 70%.

21. An apparatus as claimed in claim 19 or 20, wherein the controller is operative to control the air moving device to maintain the speed of the air in the flutes in the range from 0.3 m/s to 15 m/s.

Description:
METHOD AND APPARATUS FOR CONDITIONING OF CARDBOARD

Field of the invention

The invention relates to treatment of cardboard, in particular corrugated cardboard, for instance following processing in a conversion apparatus, in order to remove burn fumes and odour caused by laser cutting of the cardboard.

Background of the invention

The use of laser beams to cut and perforate cardboard (as used in conversion machines such as Highcon Euclid or Highcon Beam available from Highcon Systems Ltd. in Yavne, Israel) creates undesired fumes and odour due to the burning of the cardboard during the process. To reduce the odour, it is common practice to leave the cardboard to ventilate in free air. Even when fans or blowers are used to cause air circulation, it can take a day or more for the smell to be reduced to an acceptable level. Such a method is therefore not efficient, in particular for corrugated cardboard.

An alternative method is described in US Patent US 10,179,378, which describes removing the smell by heating the cardboard to a temperature as high as 150-260°C using laser light or in an oven. Such a method is wasteful of energy and dries out the cardboard.

Object of the invention

The invention seeks to provide a method and apparatus for conditioning cardboard, by removing fumes and odour more effectively.

Summary of the invention

According to a first aspect of the invention, there is provided a method of conditioning a corrugated cardboard stack, which comprises causing air to flow through flutes of the stack from an air intake end to an air discharge end of the stack by confining air moved by an air moving device to flow only, or at least predominantly, through the flutes. The term “flutes” is used herein to describe the flow channels defined by the corrugations.

After treatment in a conversion machine, cardboard is commonly in the form of individual sheets and the cardboard stack may typically comprise several separate sheets placed one

SUBSTITUTE SHEET (RULE 26) over the other. However, the term “cardboard stack” as used herein is also intended to include cardboard that is coiled into a roll having overlying, or stacked, layers rather than individual sheets and in the ensuing description all references to a stack should be regarded as including a roll.

The invention is predicated on the realisation that, when cardboard is exposed to fumes, such as the fumes that are created during laser cutting, they tend to permeate into the flutes defined by the corrugations. If, as has been the common practice in the past, a corrugated cardboard stack is merely placed in a room in which air circulates, the air flows predominantly around the outer surface of the stack, because it encounters far less resistance that when flowing through the flutes. By guiding the air to ensure that it flows through the flutes, in preference to flowing around the stack, the invention ensures more effective and rapid removal of the fumes and odour.

In some embodiments of the invention, the air moving device may comprise an air extractor connected to the air discharge end of the stack to place the air discharge end under sub-atmospheric pressure and thereby to draw ambient air into the flutes at the air intake end.

Alternatively, or additionally, the air moving device may comprise a fan or blower connected to the air intake end of the stack to raise the air pressure at the air intake end above ambient atmospheric pressure and thereby blow air into the flutes.

In some embodiments, the same air moving device may serve both to reduce the air pressure at the discharge end of the stack and to increase the air pressure at the air intake end, thereby causing air to recirculate through the stack. In this case, to prevent the extracted fumes from recirculating, the recirculated air may be filtered.

As well as removing the smell, in order to preserve certain characteristics of the cardboard, especially its crease readiness quality (i.e. its ability to crease without cracking), it is necessary to control its moisture content. For this reason, after removal of the smell, it is common practice to condition the cardboard by storing it in a moisture- controlled and temperature-controlled room, typically at a temperature in the range of 18- 25°C and a relative humidity of 50-60%RH, for a few days.

In some embodiments, the temperature of the recirculating air is controlled by heating and/or cooling the air to remain within a predetermined range. If desired, the humidity of the recirculating air may additionally, or alternatively, be controlled by a humidifier to remain within a predetermined range.

According to as second aspect of the invention, there is provided an apparatus for conditioning a corrugated cardboard stack, which comprises an air moving device and a shroud to surround the stack so as to confine air moved by the device to flow only, or at least predominantly, through flutes of the cardboard in the stack, from an air intake end to an air discharge end of the stack.

In some embodiments, the shroud may include an element made of a flexible material that is urged to seal against the sides of the stack by an air pressure differential generated by the air moving device.

The air moving device may, in some embodiments, comprise an air extractor connected to the air discharge end of the stack to place the air discharge end under sub-atmospheric pressure and thereby to draw ambient air into the flutes at the air intake end.

Alternatively, or additionally, the air moving device may comprise a fan or blower connected to the air intake end of the stack to raise the air pressure at the air intake end above ambient atmospheric pressure and thereby blow air into the flutes.

The same air moving device may, in some embodiments, serve both to reduce the air pressure at the discharge end of the stack and to increase the air pressure at the air intake end, thereby creating an air recirculation circuit passing through the flutes of the cardboard in the stack. In such an embodiments, the recirculation circuit may include a filter, for example containing activated carbon.

For improved conditioning of the cardboard, the recirculation circuit may additionally include at least one of

(i) a heater or cooler for maintaining the temperature of the recirculating air within a predetermined range,

(ii) a humidifier for maintaining the humidity of the recirculating air within a predetermined range,

(iii) an ozoniser for introducing ozone into the recirculating air, and

(iv) and atomiser for introducing airborne material into the recirculating air. Brief description of the drawings

The invention will now be described further, by way of example, with reference to the accompanying drawings, in which:

Figure 1 shows a stack of cardboard sheets and arrows to demonstrate the desired air flow through the stack,

Figure 2 shows a perspective view of a first embodiment of an apparatus of the invention,

Figure 3 is a plan view of a second embodiment of an apparatus of the invention, and

Figure 4 is a plan view of a further embodiment of the invention.

Detailed description of the drawings

Figure 1 shows a stack 10 made up of cardboard sheets that have all been stacked with the same orientation, that is the say with all the corrugations lie parallel to one another. Each sheet may have been pre-treated in a conversion machine, such as a Highcon Euclid or a Highcon Beam machine. The cutting of cardboard using a laser by such machines generates fumes that create an unpleasant odour. While Figure 1 shows a cubic stack of individual sheets, as previously mentioned, the invention is equally applicable to removing odour from a roll of cardboard, which may have acquired an odour through improper storage or exposure to fumes.

In order to reduce the smell, the present invention proposes flowing air in the direction indicated by the arrows 12 in Figure 1, that it to say with the air flowing through flutes defined by the corrugations of the cardboard, rather than around the stack 10. In this way, most of the cardboard is placed in the immediate vicinity of the air flow, being spaced from the air flow preferably by less than a few millimetres, or even less than one millimetre.

If a cardboard stack is merely left to ventilate, any air flow that takes place through the flutes of the stack is almost insignificant. This is because, even if the stack is placed in air stream, the flow resistance around the stack is much less that the flow resistance through the stack. To achieve the desired air flow through the stack, embodiments of the invention therefore confine the air flow, so as to prevent it as much as practicable from flowing around the outside of the stack. In Figure 2, ambient air is sucked through the stack 10 in the direction of arrows 12 by means of an air extractor 24. The intake end of the extractor 24 is connected to a plenum 20. The plenum 20 has on its front side 28 facing the stack 10, a mouth, which may be covered by a grille, against which the stack 10 is placed. A shroud 22 in the form of a skirt of a flexible material is attached to front side 28 of the plenum 20 and surrounds the mouth and the stack 10.

In use, the stack 10 is transported, for example by means of a forklift truck, and placed in front of the mouth in the front side 28 of the plenum 20 and the shroud 22 is loosely placed over the sides of the stack 10. When the extractor 24 is then operated, the low pressure created in the plenum 20 sucks the shroud into intimate contact with the stack 10 and the against the grille, so that no air can flow around the stack 10. Instead, the moved air follows the path indicated by the arrows 12 and flows through the flutes defined by the corrugations int the stack into the plenum 20, being then discharged to atmosphere through an exhaust duct 26 of the extractor 24.

The use of a flexible, air-impermeable material, as a shroud 22 has been found effective as it can form a good seal against the stack 10, even if the cardboard sheets in the stack 10 are not perfectly aligned. It should be clear to the person skilled in the art that other means may be employed to shroud the stack in order to prevent or minimise the flow of air around the stack 10. For example, slidable shutter plates may be mounted on the front side 28 of the plenum, or the mouth may be surround by an inflatable bladder or a ring of compressible, closed cell, foam.

In the embodiment of Figure 2 there is no air recirculation, and the apparatus relies only on drawing ambient air into the stack 10 and discharging the air, together with any scavenged fumes, into the ambient atmosphere through the exhaust 26. If desired, a filter may be placed in the plenum 20 or in the exhaust duct 26 to reduce pollution of the ambient air.

The embodiment of Figure 3 is a modification of the embodiment of Figure 2 and, in order to avoid repetition, like parts have been reallocated the same reference numerals. The essential difference between the embodiment of Figure 3 and that of Figure 2 is that the air discharged through the exhaust duct 26 of the extractor 24 is recirculated, via an air duct 30 and a horn 32, back to the air intake side of the stack 10 so that much of the air is recirculated and only a small proportion escapes to the ambient atmosphere through the gap between the horn 32 and the stack 10. By increasing the pressure differential across the stack, the embodiment of Figure 3 allows the air flow rate to be nearly doubled and this has been found to improve odour removal even in the absence of a VOC filter.

Figure 3 also shows that a volatile organic compound (VOC) filter 34 may be mounted in the plenum, to neutralise the fumes scavenged from the stack 10. The filter may for example be an activated carbon filter. As previously mentioned, such a filter may also be included in the embodiment of Figure 2.

Figure 3 also shows an ozoniser 36 is provided to introduce ozone into the air entering the stack 10. The ozone, which may be generated for example by an ultraviolet lamp, has a sterilising effect and also assists in regeneration of the activated carbon filter 34. Ozone may alternatively be generated by commercially available ozonisers, as available for example by Ecozone Technologies in Hasharon Industrial Park, Kadima, Israel (https://ecozone-technologies.com/). Various walls have been shown in Figures 3 and 4 in dotted lines, this being to indicate that air is allowed to pass through them.

In the embodiment of Figure 4, like parts have again been allocated the same reference numerals. As in the embodiment of Figure 3, the air in this embodiment is recirculated but instead of flowing through an air duct, it flows through a housing comprises of a stationary part 40 and a pivotable cover 42, show in solid lines in its closed position and in dotted lines in an open position. In addition to an ozoniser 36, as previously described, various devices are arranged within the housing 40, 42.

Reference numeral 44 represents temperature control equipment, that may comprise a heater and/or a cooler, for maintaining the temperature of the recirculated air within a predetermined desired range. A humidifier 46 is provided to regulate the relative humidity of the air.

In Figure 4, an atomiser 48 is also provided to spray airborne material into the air. The sprayed material may be any desired treatment solution, for example it may be a perfume or an anti-bacterial compound.

Figure 4 also shows that sensors 50 and 52 may be mounted in the housing to monitor desired parameters of the recirculating air, such as its temperature and relative humidity, the output of the sensor being provided to a control circuit that controls the operation of the heater/cooler and humidifier. It is additionally possible to use as a sensor an ‘artificial nose’, such as Cyranose 320 commercially available from Sensigent in Baldwin Park, CA, USA or any other suitable smoke detector) in order to “smell” the level of fumes or odour removal which may also allow for automatic stopping of the conditioning operation when the level of odour reduction (or level of moisture) is achieved.

The embodiment of Figure 4 offers the advantage that when the cover 42 is open, there is unhindered access to the mouth of the plenum 20. A stack 10 can therefore readily be placed in front of the plenum 20 and the shroud 22 deployed to seal around the stack 10. When next the cover 42 is pivoted into its closed position, a closed recirculation path, represented by the arrows 12 in the drawing, is created and clean air at a desired temperature and relative humidity can be circulated through the flutes of the stack 10 to remove any odour and also condition the cardboard.

If the pre-processed cardboard sheets have cuts in them, when they are stacked they may create paths for air to enter or exit from the stack, other than through its intake and discharge ends. If a shroud of flexible material is used, it may block air flow through these additional paths to ensure that air flow through the entire length of the flutes.

Figure 4 also shows that an exhaust port 54 may be provided in the stationary part 40 of the housing. The port may be kept closed during air recirculation and only opened to vent the housing and discharge accumulated VOC’s to atmosphere between operating cycles. Alternatively, a proportion of the recirculating air may be discharged during operation and replenished with clear air, whereupon an intake port 56 containing a oneway valve may be provided in the cover 42.

The inventors have found that a suitable temperature range for heating the recirculating air is 30°- 80°C, preferably 40° - 60°C. An air flow through flutes at a speed of 0.3 - 15 m/s, for a period of only 3 - 15 min was found to suffice for effective removal of odours.

To compensate for paper moisture loss due to the heating, the humidifier may be controlled to maintain the relative humidity of the circulating air at 40-80%, and more preferably 50-70%.