AN INDUCTION HEAT SEALING DEVICE AND A METHOD FOR TRANSVERSALLY SEAL A TUBE OF PACKAGING MATERIAL

Abstract

An induction heat sealing device (300) for providing a transversal sealing of a tube (104) of packaging material, said induction heat sealing device (300) comprising a main body (302) comprising a first and a second sealing surface (314a, 314b) arranged to face the packaging material during a sealing state (S), a recess (308) provided in the main body (308) for receiving a knife during a cutting state (C), wherein the first and second sealing surface (314a, 314b) are placed on opposite sides of the recess (308), and an electric conductor arrangement (306a, 306b, 306c, 306d), provided in the main body (302), for inducing eddy currents in the packaging material during the sealing state (S), wherein at least part of the first and second sealing surface (314a, 314b) are inclined and provided with a first and a second top section (316a, 316b), respectively, such that particles in a product held inside the tube (104) are pushed away from a sealing band of the tube as the sealing band is pressed towards the first and second top section (316a, 316b).

Claims

1. An induction heat sealing device for providing a transversal sealing of a tube of packaging material, the induction heat sealing device comprising: a main body comprising a first sealing surface, a second sealing surface, and a recess, the recess configured to receive a knife; and at least one electric conductor arrangement in the main body, the at least one electric conductor arrangement configured to induce eddy currents in the packaging material, wherein the first and second sealing surface are on opposite sides of the recess, wherein the first sealing surface has a first top portion adjacent to the recess, and wherein the second sealing surface has a second top section adjacent to the recess.

2. The induction heat sealing device according to claim 1, wherein the first sealing surface and the second sealing surface slope downward away from the recess

3. The induction heat sealing device according to claim 1, wherein the first sealing surface and the second sealing surface are symmetrical with respect to the recess.

4. An induction heat sealing device for providing a transversal sealing of a tube packaging material, the induction heat sealing device comprising: a main body comprising a first sealing surface, a second sealing surface, and a recess, the recess configured to receive a knife; and at least one electric conductor arrangement in the main body, the at least one electric conductor arrangement configured to induce eddy currents in the packaging material, wherein the first sealing surface and the second sealing surface are on opposite sides of the recess, and wherein the first sealing surface comprises a first slope, a second slope comprising a different slope angle from the first slope, and a first top portion between the first slope and the second slope.

5. The induction heat sealing device according to claim 4, wherein the second sealing surface comprises a third slope, a fourth slope comprising a different slope angle from the third slope, and a second top portion between the third slope and the fourth slope.

6. The induction heat sealing device according to claim 4, wherein the first sealing surface and the second sealing surface are symmetrical with respect to the recess.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0022] Embodiments of the invention will now be described, by way of example, with reference to the accompanying schematic drawings, in which

[0023] FIG. 1 is a general illustration of a roll-fed packaging machine.

[0024] FIG. 2 is a more detailed view of a sealing apparatus used for providing transversal sealings.

[0025] FIG. 3 illustrates a cross-sectional view of a heat induction sealing device.

[0026] FIG. 4 illustrates a transversal sealing system.

[0027] FIG. 5 illustrates a flow chart of a method for transversally seal a tube of packaging material.

DETAILED DESCRIPTION

[0028] FIG. 1 generally illustrates a packaging machine 100. In the illustrated example, the packaging machine 100 is a roll-fed carton packaging machine. The general principle of such a machine is that from a roll of packaging material a web 102 is formed. Although not illustrated, if needed in order to fulfill food safety regulations, the web 102 may be sterilized using a hydrogen peroxide bath, a Low Voltage Electron Beam (LVEB) device or any other apparatus capable of reducing a number of unwanted microorganisms. After sterilization, by using a longitudinal sealing device, the web 102 can be formed into a tube 104. When having formed the tube a product, for instance milk, can be fed into the tube 104 via a product pipe 106 placed at least partly inside the tube 104.

[0029] In order to form a package 108 from the tube 104 filled with product, a transversal sealing can be made in a lower end of the tube by using a sealing apparatus 110. Generally, the sealing apparatus 110 has two main functions—providing the transversal sealing, i.e. welding two opposite sides of the tube together such that the product in a lower part of the tube, placed downward the sealing apparatus, is separated from the product in the tube placed upward the sealing apparatus, and cutting off the lower part of the tube such that the package 108 is formed. Alternatively, instead of providing the transversal sealing and cutting off the lower part in one and the same apparatus as illustrated, the step of cutting off the lower part may be made in a subsequent step by a different piece of equipment, or by the consumer if the packages are intended to be sold in a multi-pack.

[0030] In FIG. 2 a general principle of the sealing apparatus 110 is illustrated in further detail. The tube 104 can be fed from above since this provides for that product can be held inside the tube. In a first stage, a sealing stage S, a first jaw provided with a sealing device 200 and a second jaw provided with a counter pressure device 202 are moved towards each other such that two opposite sides of the tube 104 are pressed towards one another. In order to provide for the transversal sealing, heat can be provided by inducing eddy currents in the packaging material while pressing the two opposite sides together. The heat provides for that a polymer layer of the packaging material is melted, which in turn provides for the polymer layer can be used for making sure that the two opposite sides can attach to each other and stay together after the jaws are removed. In a subsequent step, herein referred to as a cutting stage C, the lower part of the tube 104 can be cut off such that the package 108 is formed. In order to increase a speed in which packages are formed, the jaws can be moved together with the tube 104 in a tube feeding direction A during the sealing stage S and the cutting stage C.

[0031] In order to provide for a more controlled forming process of the package 108 so-called volume forming flaps 204a, 204b can be used. More specifically, by using these the tube 104 having a round cross-section may be steered into a package 108 having a rectangular cross-section in a controlled manner.

[0032] The sealing device can be provided with two inductors, a first inductor 206a and a second inductor 206b. In the illustrated example, the first inductor 206a is arranged above the second inductor 206b. After having provided the transversal sealing a knife 208 can be used for cutting off the lower part of the tube and thus form the package 108. In this example, the knife 208 and the first and second inductors 206a, 206b are provided in the sealing device, but other arrangements are also possible. For instance, the knife may be provided on the other side of the tube, in the counter pressure device, or the cutting step may be performed by a separate device downstream the sealing device.

[0033] In FIG. 3, by way of example, an induction heat sealing device 300 that may form part of the sealing apparatus 110 is illustrated in detail. More particularly, the induction heat sealing device 300 may be used as the sealing device 200 illustrated in FIG. 2.

[0034] The induction heat sealing device 300 can comprise a main body 302. In the main body 302 a magnetic flux concentrator arrangement 304a-d may be provided. A purpose of the magnetic flux concentrator arrangement 304a-d can be to direct the electromagnetic radiation formed by an electronic conductor arrangement 306a-d, that also can be comprised in the main body 302, towards the tube 102 of packaging material during the sealing stage S. The magnetic flux concentrator arrangement 304a-d can be made of different materials, such as plasto-ferrite or soft magnetic composite.

[0035] The induction heat sealing device 300 may be designed in different ways. In FIG. 3, a so-called twin coil inductor is illustrated by way of example. In the twin coil inductor, the electronic conductor arrangement 306a-d may comprise a first coil 306a-b and a second coil 306c-d, that is, one coil is provided on either side of a recess 308 configured to receive the knife during the cutting stage C. Another option, is a so-called single-coil inductor where one coil is provided and arranged such that part of the coil is provided on one side of the recess 308 and another part of the coil is provided on the other side of the recess 308. Put differently, a first inductor 310 and a second inductor 312, representing a first part of the main body 302 on one side of the recess 308 and a second part of the main body 302 on the other side of recess 308, respectively, may share a single coil or may be provided with one coil each, as illustrated in FIG. 3.

[0036] Further, as illustrated, the electronic conductor arrangement 306a-d may be held by the magnetic flux concentrator arrangement 304a-d such that the electronic conductor arrangement 306a-d forms part of an outer surface of the main body 302. Another option, even though not illustrated, is that the electronic conductor arrangement 306a-d is held completely within the magnetic flux concentrator arrangement 304a-d such that the electronic conductor arrangement 306a-d does not form part of the outer surface of the main body 302. Still an option is to have a surface cover, not illustrated, such that neither the magnetic flux concentrator arrangement 304a-d nor the electronic conductor arrangement 306a-d form part of the outer surface.

[0037] A first and second sealing surface 314a, 314b of the first and second inductor 310, 312, respectively, may be inclined as illustrated in FIG. 3. There are several advantages with having the first and second sealing surfaces 314a, 314b inclined. First, during the sealing stage S, particles in the food product in the tube 104 may be pushed out from a sealing band of the tube 104, that is, a section of the tube 104 that is to be formed into a transversal sealing, in a more controlled manner compared to when having flat-surfaced inductors. More particularly, an effect of having the first and second sealing surfaces 314a, 314b inclined is that a pressure gradient can successively be built up inside the tube 104. Since different products may differ in terms of e.g. viscosity and in that they comprise particles or not, and if comprising particles that these may have different properties, different products may require different measures for avoiding product residues in the sealing band. By customizing an inclination profile, that is how the sealing surfaces 314a, 314b are inclined, based on the product held inside the tube 104, the pressure gradient build-up can be optimized for the product, implying an even further improved transversal sealing.

[0038] In addition to improving that product residues are adequately removed from the sealing band in the sealing stage S, having the sealing surfaces 314a, 314b inclined also has a positive effect on sealing quality. A pressure gradient is namely also formed in the polymer layer that is melted during the sealing stage S. This provides for that how melted polymer in the packaging material is moved can be controlled in a more precise manner compared to if using the flat-surfaced inductors. In turn, this may result in that a risk of having aggregations of melted polymer in the packaging material can be reduced. Put differently, the melted polymer can be distributed more efficiently. Another positive effect is that less polymer may be required for making reliable transversal sealing. Since how the melted polymer is distributed during the sealing stage S can be controlled in a more precise manner, this may imply that less polymer is required, which is advantageous from an environmental point of view as well as from a cost perspective.

[0039] In the example illustrated in FIG. 3, the first and second sealing surface 314a, 314b are provided with a first and second top section 316a, 316b, respectively. As illustrated, in this example the first and second top section 316a, 316b are placed next to the recess 308, but other placements of the first and second top section 316a, 316b are also possible. Further, as illustrated in FIG. 3, magnetic flux concentrator top surfaces 318a-d can be inclined and form part of the first and second sealing surface 314a, 314b. As illustrated, also electronic conductor arrangement top surfaces 320a-d may be inclined and form part of the sealing surface 314a, 314b. Further, the first and second sealing surfaces 314a, 314b may be symmetrical with respect to a recess axis RA running through the recess 308.

[0040] FIG. 4 generally illustrates a transversal sealing system 400 comprising the induction heat sealing device 300 and a counter-pressure arrangement 402a, 402b in turn comprising a first and a second counter-pressure element 402a, 402b.

[0041] The induction heat sealing device 300 illustrated in FIG. 4 is different from the one illustrated in FIG. 3 in that the first and second top section 316a, 316b are placed in a mid-portion of the first and second sealing surfaces 314a, 314b, respectively, instead of next to the recess 308 as is the case in the example illustrated in FIG. 3. Further, the sealing surfaces 314a, 314b in the example illustrated in FIG. 4 is only inclined in part, that is, the sealing surfaces 314a, 314b comprise inclined sections and flat sections.

[0042] The first and second counter-pressure element 402a, 402b may comprise a first and second counter pressure pad 404a, 404b, respectively, which may for instance be made of rubber or other elastic material. The first and second counter pressure pad 404a, 404b can be provided with a first and a second counter-pressure pad surface 406a, 406b arranged to face the tube 104 during the sealing stage S. The first and second counter-pressure pad surface 406a, 406b can be convex-shaped and provided with a first and a second counter-pressure pad top section 408a, 408b, respectively.

[0043] As illustrated in FIG. 4, the first and second counter-pressure pad top section 408a, 408b may be offset with respect to the first and second top section 316a, 316b, herein illustrated by a first pressure pad top section FPPTS axis running through the first counter-pressure pad top section 408a, a second pressure pad top section SPPTS axis running through the second counter-pressure pad top section 408b, a first top section FTS axis running through the first top section 316a, and a second top section STS axis running through the second top section 316b. Even though not illustrated, it is also possible to have the first and second counter-pressure pad top section 408a, 408b aligned with respect to the first and second top section 316a, 316b.

[0044] Further, as presented above, the inclination profile of the first and second sealing surface 314a, 314b may adjusted to meet needs of a specific product, a specific packaging material, a specific type of sealing apparatus 110, a specific packaging machine 100 or a combination thereof. In addition, to even further improve sealing properties, also an inclination profile of the first and second counter-pressure pad surface 406a, 406b may be adjusted to meet the needs stated above.

[0045] In addition, the first and second counter-pressure element 402a, 402b may be shaped differently such that the first and second counter-pressure pad surface 406a, 406b have different inclination profiles. One reason for having these shaped differently is that the tube 104, placed upstream the transversal sealing system 400, provides a pressure caused by the food product held in the tube 104 down onto the transversal sealing system 400. By having the first and second counter-pressure element 402a, 402b, and optionally also, or instead, the first and second inductor 310, 312 shaped differently, the pressure caused by the food product can be compensated for.

[0046] FIG. 5 is a flow chart 500 illustrating a method for transversally seal the tube 104 of packaging material by using the induction heat sealing device 300. The method can comprise placing 502 the tube 104 such that the sealing band of the tube is facing the induction heat sealing device 300 and the counter-pressure arrangement 402a, 402b, moving 504 the induction heat sealing device 300 and the counter-pressure arrangement 402a, 402b towards one another such that particles of the product held inside the tube is pushed away, inducing 506 eddy currents in the packaging material of the tube by using the induction heat sealing device 300, pressing 508 the first side and the second side of the tube 104 towards one another such that the melted polymer in the polymer layer of the first and the second side of the tube attach to each other, and distributing 510 the melted polymer using the inclined sealing surfaces of the induction heat sealing device 300 such that a risk for insufficient sealing is reduced.

[0047] From the description above follows that, although various embodiments of the invention have been described and shown, the invention is not restricted thereto, but may also be embodied in other ways within the scope of the subject-matter defined in the following claims.