GR1009500B - Portable device for the measurement of the rigidity of an extendable film used for the wrapping of items - measurement method of the film's rigidity - Google Patents

Abstract

Novelty: a portable device 1 designed for the in-situ measurement of the rigidity force F of an extendable film or other packaging material used for the wrapping and consolidation of a load composed of one or more items habitually united on a pallet is disclosed. Constitution: a pallet comprising rectangular frames (2,3) with recesses (4,5) and magnets ( 6,7,8,9), rods-guides (10 11) and a threaded rod 12 whereon the moving rectangular frame 2 is moving, an ordinary dynamo cell 18 connectable to a control device and two independent metal little plates (19, 20) the size of which is inferior to the size of the rectangular frames (2,3); the invention refers also to the operation mode of the device 1 receiving the packaged unit at a selected position where the rigidity of the extendable film will be measured, following the respective steps.

Description

PORTABLE DEVICE FOR MEASURING IT

EXTENDED FILM-WRAPPED LOAD UNIT RIGIDITY AND

METHOD OF MEASURING IT

DESCRIPTION

TECHNICAL FIELD

[0001] The present invention relates to a portable device used for on-site testing and accurate measurement of the stiffness of stretch film or other packaging material used to wrap and stabilize a load consisting of one or more objects that have been consolidated, usually on a palette. The invention also relates to the method for field testing and accurate measurement of the stiffness of stretch film or other packaging material used to wrap and stabilize a load consisting of one or more articles that have been consolidated, usually on a pallet.

PRIOR ART

The wrapping and stabilization of a load consisting of one or more objects that have been consolidated, usually on a pallet, are known and are commonly used for the safe transport of the objects and to avoid damage to them. The object or set of objects form a load unit when wrapped. Wrapping with stretch film or other suitable material is already a known practice in transport. Stretch film is a stretch film, based on Linear Low Density Polyethylene (LLDPE), which is unrolled from a roll, which is usually stretched (either automatically or mechanically) and wrapped around a unit load. It acts as a compressive banding agent around the entire load unit, creating a holding force which keeps the individual packages together and stable. Containment of loads using stretch film has been used for decades and is well known in practice. Proper retention of a load allows the film to securely hold a load in place so that the load unit arrives intact at its destination location. Therefore, the quantification of the holding force is important for one to estimate, optimize and maintain the wrapping characteristics of a unit load. The retention force is affected by the type of film used, its thickness, the level of pre-stretch, the applied secondary force, etc.. Modifying any of these parameters can lead to a change in the retention force of the wrapped load. It is widely accepted that the holding force can be further broken down into a compression force or inwardly directed force, which is defined as the force exerted by the film on the unit load, specifically at the corners of the unit load, and stiffness (or force stiffness) or film strength, which is defined as the strength of the film to resist further stretching. Both properties are important as they affect the retention of a load in a different way. The compressive force holds the objects together and increases the friction between them, and the stiffness of the film allows the film to resist movement or deformation.

[0003] To date, a large number of devices for in-situ measurement of the retention of a load have been developed and are available in the art. All of these are based on methods that quantify only the compressive force or the combined effect of compressive force and film stiffness. Independent measurement of both of these properties, however, could significantly improve the process of optimizing the wrapping of a load unit.

The well-known standard ASTM D4649 - 03 provides two such methods, namely the Disc Pull Method and the Bale Wrap Method. According to the Disc Pull Method, which is the most widely used method in the art, a hook yoke is attached to a non-deformable circular disc, which is located between the wrap and the surface of the load, and the film is removed from the load by pulling the yoke. When the disk has reached a certain distance from the load, the force exerted by the film on the disk is recorded. The result of the measurement is a combination of the compressive force and the stiffness of the film, which is also a weakness of the method, as it cannot distinguish between the two forces. According to the Scale Wrap Method, a strain gage, such as a household scale, is attached to the load and the stretch film is wrapped around the load. The strain gauge is used to record the force exerted on the gauge by the film. The result of the measurement is only related to the compression force, which is also a weakness of the method, as it ignores the stiffness of the film.

[0005] According to US2008295614 (A1 ), an apparatus and method for measuring the holding force of a load is provided. The apparatus may include first and second longitudinally extending arms, adjustable to engage first and second sides of a packaging material wrapped around the load appropriately, a pointer positioned substantially perpendicular to the first and second arms, a third longitudinally extending arm, and a force meter configured to measure a force applied to the third longitudinally extending arm. The method may include placing a portion of the package material wrapped around the load between the first and second arms of a force measuring device, rotating the first and second arms from an initial position to an end position, and measuring a force required to rotate the first and second arms to the final position. The result of the measurement is a combination of the compression force and the stiffness of the film, which is also a weakness of the method, as it is unable to distinguish between the two forces.

According to another known device, under the trade name FEF-200 of ESTL NV, it includes a central part in a 90° Angle Design; which holds a series of load cells, capable of measuring forces at 2 different heights and at two addresses each. Before wrapping a load unit, the device is placed on one of the four vertical edges of the load unit, along its entire height. The forces developed by the wrapping on the edge of the load unit are monitored during and after the completion of the wrapping process by means of load cells. The software generates a force profile as a function of the height of the load unit. The result of the measurement is only related to the compression force, which is also a weakness of the method, as it ignores the stiffness of the film.

[0007] According to another known device, with the trade name Portable Film Force System (Portable Film Force System) of Highlight Industries Inc, this includes an array of up to 3 force cells which can be placed on one of the sides of a load unit, with the second and third placed vertically below the first and held in place by supporting counterweights attached to the load cells. The forces exerted by the winding on the load cells are monitored during and after the completion of the winding process. The result of the measurement is mainly related to the compression force but also to the stiffness of the film, which is also a weakness of the method, as it is unable to distinguish between the two forces.

PURPOSE OF THE INVENTION

[0008] The purpose of the present invention is to eliminate at least part of the problems associated with the prior art and to provide a new simple to manufacture, short to assemble and install, and economical portable device used for field testing and accurate measurement of the stiffness of stretch film or other packaging material used to wrap and stabilize a load consisting of one or more items that have been consolidated, usually on a pallet. With the device according to the invention it is provided to clamp two parts of the wrap using suitable clamping means and then remove the two parts with simultaneous measurement of the stiffness force (F) exerted by the wrap during this movement.

[0009] The purpose of the present invention is also to provide a new method for field testing and accurate measurement of the stiffness of stretch film or other packaging material used to wrap and stabilize a load consisting of one or more articles that have been consolidated, usually on a palette.

DISCLOSURE OF THE INVENTION

The invention will now become apparent to those skilled in the art by reference to the drawings accompanying the present description, in which certain preferred industrial applications are illustratively illustrated. These depict:

- Figure 1 illustrates in a perspective view viewed from above the device (1 ) according to the invention,

- Figure 2 illustrates the rear side of the device (1) according to the invention,

- Figure 3 shows a top view of the device (1) according to the invention,

- Figure 4 shows in a perspective view viewed from the load side (not shown) the device (1) applied to the stretch film (21 ) and the metal plates (19, 20) in the position of measuring the stiffness force (F) of the stretch film (21 ).

[0011] Drawing 1 shows a front perspective view of the device (1), which consists in a front view of the overall device (1), of a left rectangular movable frame (2) and a right rectangular stationary frame (3), where each frame includes a rectangular recess, where frame (2) contains recess (4) and frame (3) contains recess (5). Two identical conventional intermittent magnets (6, 7, 8, 9) are attached to each recess (4, 5), of which the intermittent magnets (6, 7) penetrate the recess (4) and the intermittent magnets (8, 9) penetrate the recess (5). The rectangular frames (2, 3) are pierced by an upper guide bar (10) and a lower guide bar (11), which support the rectangular frames (2, 3). Between and parallel to these rods (10, 11 ) below the recess (4) extends a smaller screw rod (12) along which the rectangular movable frame (2) moves. The screw rod (12) is manually set in rotary motion by means of the rotating wheel (13), which is fixed to the outer end of the screw rod (12) and is in contact with a conventional connecting base (14) of the rotating wheel (13) and the screw rod (12). Alternatively, the rotating wheel (13) can be replaced by a conventional motor to set the screw rod (12) in motion. Through the rotary movement of the screw rod (12) the moving rectangular frame (2) moves along the guide rods (10, 11). Alternatively, the screw rod (12) and swivel wheel (13) can be omitted and the movement of the rectangular frame (2) along the guide rods (10, 11) done manually with a simple handle (not shown).

The two rectangular frames (2, 3) with recesses (4, 5), the intermittent magnets (6, 7, 8, 9) that penetrate the recesses (4, 5), the rods (10, 11, 12), the rotating wheel (13) and the connecting base (14) are fixed to three metal rectangular plates (15, 16, 17), which are bolted together forming an inverted U-shaped base. Between the plate / right leg (16 ) of Π and the stationary rectangular frame (3) a conventional load cell (18) is fixed, which immobilizes the frame (3) and with a cable (not shown) is connected to a load cell control device. The device (1) is completed by two independent metal plates (19, 20), which are smaller in size than the rectangular frames (2, 3). In the prior art, no similar device has been constructed to measure the stiffness of the film.

[0013] The steps of the method of operation of the device (1) for measuring the stiffness of the stretch film (21) with which a load unit A is packaged by wrapping it with the stretch film (21) one or more times, creating one or more layers of film (21) around charge A (not shown) are as follows:

(a) selecting the location on the packaged load unit A at which it is desired to measure the stiffness of the stretch film (21), (b) making a small cut (not shown), for example with a cutter, which cut should to penetrate all layers of the stretch film (21) at a point above the preselected position, followed by manual insertion through the intersection of the two metal plates (19, 20), so that they are placed tangentially to the load unit, one next to the other in the other a short distance apart (see Figure 6). It is noted that it must be ensured that each metal plate (19, 20) is in contact with the film (21) on one side and with the load unit A (not shown) on the other side and that it has not been inserted in between by the film layers (21 ). The user must also be careful not to tear the film (21) as he moves the metal plates (19, 20) into place.

(c) The user brings the two rectangular frames (2, 3) to an initial position by appropriately rotating the rotating wheel (13). Next, the user places the body of the device (1) on the metal tiles (19, 20), so that each rectangular frame (2, 3) is aligned with a corresponding metal tile (19, 20), and the intermittent magnets ( 6, 7, 8, 9) are activated by rotating their switches, with the consequence that the wrapping of the film (21) between the device (1) and the metal tiles (19, 20) is tightened.

(d) The reading on the load cell device (18) is set to zero and the distance of the rectangular frames (2, 3) is increased by rotating the screw rod (12) using the rotating wheel (13), i.e. two forces are applied to remove the rectangular frames (2 , 3) between them and as a consequence of this the part of the film (21) located between the tiles (19, 20) resists exerting the equal reaction forces (F, F') respectively which are shown in Figure 4. The value of the force stiffness (F) is measured by the load cell (18) and can be recorded by a load cell monitor (not shown). The final position of the movable rectangular frame (2), at which the final measurement of the stiffness force (F) is taken, as well as the intermediate positions at which more measurements of the stiffness force (F) may be taken can be varied and are selected by the user. It is preferable to take at least three measurements of the stiffness force (F) in three different positions by moving the rectangular frames (2, 3) away respectively. The time during which the movable rectangular frame (2) remains in the same position so that the film (21) relaxes before a measurement of the stiffness force (F) is taken can be varied and depends on the user. It is preferable to measure the stiffness force (F) after 15 seconds have passed in order for the stiffness force (F) reading to stabilize. This kind of upper film stiffness measurement has not been applied in the prior art.

(e) The process can be repeated so as to obtain multiple measurements of the film stiffness force (21 ) and at other locations on the wrapped load, for example vertically below the first location so as to obtain a profile of film stiffness forces (21 ).

The initial position of the rectangular frames (2, 3), the final position of the rectangular frames (2, 3), the intermediate positions of the rectangular frames (2, 3) at which a stiffness force measurement is taken, the movement speed of the of rectangular frames (2, 3) and the time during which the moving rectangular frame (2) remains in the same position so that the film (21) relaxes before a measurement of the value of the stiffness force (F) can be varied and depend on the testing protocol followed by the user without departing from the scope of the invention.

In the described embodiment, the clamping of the film (21) at two points around the load unit (not shown in the drawings) is achieved using the four intermittent magnets (6, 7, 8, 9) and the two metal plates (19) , 20), however the clamping of the film (21) at two points around the load unit could also be achieved using a different number of magnets or other clamping means, for example screws or the like, without departing from the scope of the invention.

In the described embodiment, the variation of the distance of the two rectangular frames (2, 3) is achieved manually by rotating the screw rod (12) using the rotating wheel (13), however this could be achieved using mechanical means, for example conventional motor and others, without deviating from the scope of the invention.

In the described embodiment, a screw rod (12) is used so as to move the movable rectangular frame (2), however in another embodiment of the invention, this movement could be carried out without the screw rod (12), pulling manually the movable rectangular frame (2) along the guide rods (10, 11 ), for example using a handle and fixing the movable rectangular frame (2) in certain predetermined marked positions of the guide rods (10, 11), without deviating from the field of invention.

In a preferred embodiment of the invention, the distance of the two rectangular frames (2, 3) and the corresponding measured stiffness force (F) are recorded using suitable electronic means.

In a preferred embodiment of the invention, the edges of the metal plates (19, 20) are covered with rubber or other soft material so as to prevent tearing of the film (21).

The description of the device focuses on stretch film, but other packaging materials, such as stretch hoods or shrink film, can be used to measure their stiffness using the device (1) of the invention, without deviating from the scope of the invention .

It should be appreciated that the object of the invention is not limited to the above exemplary applications. The achievement of the invention is also possible with other manufacturing methods, methods, components and mechanisms included in the scope of the present invention.

[0022]

List of reference numbers

1 Device

2 Left rectangular scroll box

3 Right rectangular immovable frame

4 Rectangular frame recess 2

5 Rectangular frame recess 3

6 Conventional intermittent magnet

7 Conventional intermittent magnet

8 Conventional intermittent magnet 9 Conventional intermittent magnet 10 Upper guide bar

11 Lower guide rod

12 Screw Rod

13 Rotary wheel

14 Conventional dock

15 Metal rectangular plate

16 Metal rectangular plate

17 Metal rectangular plate

18 Conventional dyno cell

19 Metal tile

20 Metal tile

21 Movies

F Stiffening force

Claims (8)

1. A portable device (1) for on-site testing and accurate measurement of the stiffness of stretch film or other packaging material used to wrap and stabilize a load consisting of one or more items that have been consolidated, usually on a pallet, characterized by that the device (1) comprises a left rectangular moving frame (2), a right rectangular stationary frame (3), with rectangular recesses (4, 5) in which intermittent magnets (6, 7, 8, 9) are fixed, an upper guide rod (10) a lower guide rod (11) and a screw rod (12) along which the rectangular moving frame (2) moves, wherein the screw rod (12) is manually or motor driven in rotary motion by means of a rotating wheel (13), where through this rotary movement of the screw rod (12) the moving rectangular frame (2) moves along the guide rods (10, 11) and where the device includes three metal rectangular plates ( 15, 16, 17), which are bolted together forming an inverted P-shaped base and where between the plate / right leg (16) of the P and the stationary rectangular frame (3) is fixed a conventional load cell (18), which immobilizes the frame (3) and can be connected to a load cell control device, and wherein the device (1) also comprises two independent metal plates (19, 20), with a smaller size than that of the rectangular frames (2, 3). 2. A method of operating the device (1) according to claim 1, for measuring the stiffness of the stretch film (21) with which a load unit A is packaged by wrapping it with the stretch film (21) one or more times, creating one or more layers of film (21) around the charge A (not shown), which method is characterized in that it includes the following steps: (a) selecting the location on the packaged load unit A at which it is desired to measure the stiffness of the stretch film (21 ), (b) making a small cut (not shown), for example with a chisel, which cut should to penetrate all layers of the stretch film (21) at a point above the preselected position, followed by manual insertion through the intersection of the two metal plates (19, 20), so that they are placed tangentially to the load unit, one next to the other to the other at a short distance between them (see Figure 6), while ensuring that each metal plate (19, 20) is in contact with the film (21) on one side and with the load unit A (not shown) from the other side of it and that it has not been inserted between the layers of the film (21 ), (c) the user brings the two rectangular frames (2, 3) to an initial position by appropriately rotating the rotating wheel (13) and then places the body of the device (1) on the metal tiles (19, 20), so that each rectangular frame (2, 3) to be aligned with a corresponding metal plate (19, 20), and the switched magnets (6, 7, 8, 9) are activated by rotating their switches, thus tightening the film wrap (21 ) between the device (1) and the metal tiles (19, 20), (d) the reading on the load cell device (18) is set to zero and the distance of the rectangular frames (2, 3) is increased by rotating the screw rod (12) using the rotating wheel (13), i.e. two forces are applied to remove the rectangular frames (2 , 3) between them and as a consequence of this the part of the film (21 ) located between the tiles (19, 20) resists exerting the equal reaction forces (F, -F), where the value of the stiffness force (F) is measured by the load cell (18) and can be recorded by a load cell monitor (not shown), while the final position of the moving rectangular frame (2), at which the final measurement of the stiffness force (F) is taken, as well as the intermediate positions in which more measurements of the stiffness force (F) may be taken may vary n and are selected by the user, (e) the process can be repeated so as to obtain multiple measurements of the film stiffness force (21) and at other locations on the wrapped load, for example vertically below the first location so as to obtain a profile of film stiffness forces (21 ). 3. Method according to claim 2, characterized in that the initial position of the rectangular frames (2, 3), the final position of the rectangular frames (2, 3), the intermediate positions of the rectangular frames (2, 3) in which a stiffness force measurement is taken, the speed of movement of the rectangular frames (2, 3) and the time during which the moving rectangular frame (2) remains in the same position so that the film (21) relaxes before a measurement of of stiffness force (F) values vary and depend on the testing protocol followed by the user. Device according to the preceding claims, characterized in that the clamping of the film (21) at two points around the load unit is carried out using a different number of magnets or other clamping means, for example screws or the like. 5. Device according to the preceding claims, characterized in that the change of the distance of the two rectangular frames (2, 3) is achieved using mechanical means, for example a conventional motor and others. 6. Device according to the preceding claims, characterized in that the movement of the movable rectangular frame (2) is carried out by manually pulling the movable rectangular frame (2) along the guide rods (10, 11), for example using a handle and fixing the movable rectangular frame (2) in specific predetermined marked positions of the guide rods (10, 11). 7. Device according to the preceding claims, characterized in that the distance of the two rectangular frames (2, 3) and the corresponding measured stiffness force (F) are recorded using suitable electronic means. 8. Device according to the preceding claims, characterized in that the edges of the metal plates (19, 20) are covered with rubber or other soft material so as to prevent tearing of the film (21).