RU2196089C2 - Sealing device for creating zone of sealing (versions) and method of creating such zone - Google Patents

Abstract

FIELD: food industry; packing. SUBSTANCE: invention relates to device and method of connection of plastic layers forming sealed package. proposed device has sealing unit and induction heaters arranged in sealing unit. Each induction heater projects partially over surface of sealing unit and it comprises first compressing part to compress packing material. Sealing device includes also counter-elements, each arranged opposite to induction heaters to provide compressing of packing material between counter-elements and induction heaters. Voltage supply device for induction heaters is provided. Counter-element have second pressure section in position corresponding to section of packing material located closer to liquid food product than to sealing zone. Invention provides sufficiently strong tie in zone of sealing without formation of cracks near said zone and prevents flowing out of molten plastic beyond the limits of sealing zone even in case of rise of induction heating energy. EFFECT: provision of reliable package. 15 cl, 12 dwg

Description

 The invention relates to a sealing device and, in particular, relates to a device and method for the hermetic connection of the layers of plastic packaging material, for the formation of hermetic packaging.

 Standard packaging containers, such as rectangular bags for packaging liquid products such as milk and soft drinks, are manufactured using packaging machines. These machines turn a continuously moving ribbon-like packaging material, flexible, laminated, into a tubular shape, which is then filled with the desired liquid food product. Tape-like packaging material is produced on a machine that produces packaging material and is wound on a drum. This drum is then installed in the packaging machine, where it is unwound, passing inside the packaging machine, using the driving mechanisms located in several places of this machine.

 The packaging material is longitudinally sealed inside the packaging machine to form a tubular shape. For this reason, the packaging material has a layered structure consisting of a main paper layer covering the film layers on both sides of the main paper layer and, if necessary, an aluminum foil layer located between the main paper layer and the film.

 While the tube-like packaging material is moving down inside the packaging machine, a liquid product is fed from above to fill it. Then the packaging material is compressed on both sides and sealed on each side at certain intervals to form interconnected primary packets of the desired shape, for example, the shape of a pillow, bag, etc. Further, the horizontally drawn, sealed portions are cut, and each of the obtained primary packages is folded along preformed folding lines to form packets of a certain shape. Thus, many packaging bags are created, each of which contains a certain amount of liquid food product.

 To seal the packaging material in the longitudinal or lateral direction, plastic films on the surfaces of the packaging material are placed so that their edges coincide. In the aluminum foil of the packaging material with a sealing device such as an inductor, heat is generated and pressure is applied to fuse and bond the plastic films together.

 FIG. 2-4 illustrate the various stages of the sealing process using conventional sealing devices. As shown, tubular packaging material 11 is used, and tape-shaped packaging materials 51, 52 are placed face to face in the sealing zone S. Each of the packaging materials 51, 52 has a layered structure formed by a base paper layer 54, an aluminum foil layer 55 located on the inside the surface of the main paper layer 54, and a polyethylene film layer 56 located on the inner surface of the aluminum foil layer 55. Although not specifically shown, the outer surface of the main paper layer 54 is also coated This is a layer of plastic material such as polyethylene. The polyethylene parts 56 of both packaging materials 51, 52 are bonded together by heat fusion.

 U.S. Patent 528,402, Cl. 65 V 61/18, publ. 1994, and 4630429, cl. 65 V 9/00, publ. 1986, devices are known, respectively, for forming packages of liquid contents having means for re-closing each package and a sealing device for at least two plastic layers from a continuous cylinder of a sealed elastic polymer film.

 Conventional machines use a sealing device to seal and cut the packaging material 11. The sealing device is equipped with cutting jaws and thermal sealing jaws (the specific details of which are not shown), located opposite each other. Each of the cutting jaws is provided with a pair of cutting guides 61, while each of the sealing jaws is provided with a pair of sealing blocks 62. A cutter (not shown) is located between two cutting guides 61.

 The cutting guide 61 includes a rubber counter 63 along the cutting guide 61, while the sealing block 62 is provided with an inductor 65 opposite the counter element 63. The inductor 65 is located along the sealing block 62 and provided with a protrusion 66 directed towards the cutting jaws. The inductor 65 has a cooling channel 67 for controlling the temperature of the inductor 65 as a result of the cooling emulsion flowing through the cooling channel 67.

 At the initial stage of the sealing process shown in FIG. 2, the packaging material 11 is placed between the sealing unit 62 and the cutting guide 61, after which the cutting sponge and the thermal sealing sponge are moved so that they approach each other. In the next step shown in FIG. 3, the cutting sponge and the heat sealing sponge are then moved towards each other, and the sealing part of the packaging material 11 is strongly compressed and deformed by the inductor 65 and the counter element 63. As shown in FIG. 3, the energy source ( not shown) supplies a high frequency voltage to cause aluminum foil 55 to generate heat using an induction current. As a result, the paired polyethylene portions 56 of the packaging material adjacent to each other and compressed between the paired layers of aluminum foil 55 are heated, and the polyethylene layers 56 in the sealed area S melt. As a result of this process, the packaging material 11 is joined together by heat melting.

 Using conventional sealing devices, such as those described above, it was found that the fused polyethylene 56 flows strongly outside the sealing zones of the packaging material 11 and stops flowing from the sealing zone S to the AR1 region on the torch side and to the AR2 region on the liquid product side. As a result, the amount of polyethylene 56 involved in heat melting in the sealing zone S is reduced, so that the necessary bond strength may not be obtained. Accordingly, a liquid food product may leak. In addition, it is possible that the polyethylene 56 flowing from the sealing zone S to the AR2 region on the side of the liquid product will be rapidly cooled by the liquid product, harden and adhere to the inner surface of the primary package, thereby creating cracks near the sealing zone S during the formation process, performed after filling and sealing.

 If we reduce the energy of induction heating, trying to prevent the intensive leakage of polyethylene 56 from the sealing zone S, then polyethylene 56 cannot be reliably melted to the required degree, and again, sufficient bond strength cannot be achieved.

 An object of the present invention is to provide a sealing device that would prevent molten plastic from flowing out of the sealing zone even when the induction heating energy increases to increase the sealing strength.

 In addition, the technical objective of the present invention is to provide a sealing device, which creates the possibility of obtaining sufficient bond strength in the sealing zone and prevents the formation of cracks near the sealing zone.

 An object of the present invention is also to provide a method for creating a sealing zone using such a sealing device.

 These technical problems are solved due to the fact that in the sealing device to create a sealing zone in the packaging material having a plastic layer and containing a liquid food product, including a sealing unit with a front surface, inductors inserted into the sealing unit, each inductor partially protruding on the front the surface of the sealing unit and has a first compressing part for compressing the packaging material during the sealing operation, a counter element located opposite each respective o inductor having a front surface that allows you to hold the packaging material between the front surface of the counter elements and the front surface of the sealing unit, and means for supplying high-frequency voltage to the inductor. According to the invention, the front surfaces of the counter elements or the front surface of the sealing unit have second compression parts located on the parts corresponding to the portion of the packaging material, which is closer to the liquid food product than to the sealing area, to compress the packaging material during sealing to prevent molten plastic from escaping out outside the sealing zone in the direction of the liquid food product.

 Preferably, the sealing device includes a pair of cutting guides, each of the counter elements being located on a corresponding cutting guide.

 Preferably, the cutting guides include a first holding portion and a second holding portion that hold the corresponding counter element in place on the cutting guide.

 In addition, each second holding part is a protrusion formed by a pair of obliquely oriented surfaces.

 Also preferably, each of the counter elements includes a stop-engagement portion that engages a protrusion on a corresponding cutting guide.

 Preferably, the cutting guides are spaced apart and made on the cutting insert, and the device includes a groove located between the cutting guides, in which the cutter moves to cut the sealing zone.

 Preferably, each counter element has a remote edge, and the distance between the compression part of each inductor and the remote edge of the corresponding counter element, measured along the front surface of the sealing unit, is greater than the distance between the first compressing part of each inductor and the groove measured along the front surface of the sealing unit.

 Also preferably, each of the second compressing parts is made in the form of a protruding part on the sealing unit or in the form of an extension on one of the counter elements.

 Technical problems are also solved due to the fact that in the sealing device to create a sealing zone in the packaging material having a plastic layer and containing a liquid food product, including a sealing unit with a front surface, an inductor inserted into the sealing unit, the inductor partially protruding on the front surface the sealing unit and has a first compressing part for compressing the packaging material during the sealing operation, a counter element located opposite the inductor having a front turn the ability to hold the packaging material between the front surface of the counter element and the front surface of the sealing unit, and means for supplying high frequency voltage to the inductor according to the invention, the front surface of the counter element or the front surface of the sealing unit has a second compressive part located on the part corresponding to the portion of the packaging material located closer to the liquid food product than to the sealing zone, for compressing the packaging material during sealing and to prevent the molten plastic from leaking out of the sealing zone toward the liquid food product.

 Preferably, the counter element is located on the cutting guide, the cutting guide including a first holding part and a second holding part that hold the counter element in place on the cutting guide, the second holding part being a protrusion formed by a pair of obliquely oriented surfaces.

 The technical problems are also solved due to the fact that in the method of creating a sealing zone in a tubular packaging material, in which a tubular packaging material consisting of an outer layer of plastic and an adjacent layer of aluminum foil and containing liquid between the cutting plate and the sealing block is placed, the sealing block includes at least one inductor protruding on the front surface of the sealing unit and including a first compressing part protruding towards the cutting insert, and the cutting insert includes at least one counter element having a front surface and mounted opposite the inductor, compressing the tubular packaging material between the front surface of the sealing unit and the front surface of the counter element to bring together the opposite sections of the plastic layer and deform the portion of the tubular packaging material along the sealing zone located in the place corresponding to the first compressing part, apply a high frequency voltage to the inductor to generate heat in the aluminum layer foil and melting of the adjacent plastic layer, so that the opposite sections of the plastic layer of the tubular packaging material are joined together by thermofusion in the sealing zone, according to the invention, the sections of the packaging material located closer to the liquid than to the sealing zone are compressed together using the second compressing part, available on the front surface of the sealing unit or on the front surface of the counter element, to prevent the molten plastic from flowing out of the sealing zone tion towards the fluid.

 It is preferable to compress together portions of packaging material closer to the liquid than to the sealing zone when the high frequency voltage is applied to the inductor.

 Also preferably, the sealing unit includes a pair of separately separated inductors placed in the sealing plate, and the cutting insert includes a pair of counter elements, each of which is opposite one of the inductors, while the tubular packaging material is compressed between the cutting plate and the sealing plate to bring together opposite sections of the plastic layer and deformation of the packaging material in two separately spaced places corresponding to the first compressive part of each inductor.

 Preferably, the compression together of the sections of packaging material located closer to the liquid than to the sealing zone is carried out using the protruding second compressive parts available on the sealing block.

Additional details and features of the present invention will be apparent from the following detailed disclosure of the invention and the accompanying drawings, in which
FIG. 1 is a cross-sectional view of a portion of a sealing device according to a first embodiment of the present invention;
FIG. 2 is a sectional view of part of a conventional sealing device during the first stage of the sealing process;
FIG. 3 is a cross-sectional view of a portion of a conventional sealing device during the second stage of the sealing process;
FIG. 4 is a cross-sectional view of part of a conventional sealing device during the third stage of the sealing process;
5 is a general schematic diagram of a part of a packaging machine to which the sealing device of the present invention is applied;
FIG. 6 is a side view, partially in section, of a sealing device of the present invention during use;
FIG. 7 is a general block diagram illustrating power supplies used in the present invention;
Fig. 8 is a cross-sectional view of a part of the sealing device of the present invention during the first stage of the sealing process;
FIG. 9 is a cross-sectional view of a portion of a sealing device of the present invention during a stage of a sealing process; FIG.
FIG. 10 is a cross-sectional view of a portion of a sealing device of the present invention during a third stage of a sealing process;
FIG. 11 is a cross-sectional view of a portion of a sealing device according to another embodiment of the present invention; and
FIG. 12 is a cross-sectional view of a portion of a sealing device according to another embodiment of the present invention.

 We turn first to figure 5. The tape-shaped packaging material 10, consisting of a flexible laminate set produced by the packaging material production machine, is mounted as a reel 21 in the packaging machine. The packaging material 10 is unwound and advanced using various motors (not specifically shown) installed in several places in the packaging machine. The packaging material 10 is obtained by layering, for example, a layer of polyethylene, a layer of aluminum foil, a sheet of paper base and a layer of polyethylene in this order from the inside out.

 The packaging material 10 is guided by a guide 24, sealed longitudinally by a sealing device (not specifically shown), and formed into the tubular packaging material 11. While the tubular packaging material 11 is fed down, the liquid product flows from above through the filler pipe 16 for filling the inner container of the packaging material 11. Then the packaging material 11 is compressed on the sides of both sides with a cutting sponge and a heat sealing sponge (both of which are not specifically shown in FIG. 5 ), so that the tubular packaging material is laterally sealed at predetermined intervals to form primary pillow-shaped bags.

 Further, the laterally stretched sealed parts are cut to separate the individual pillow-shaped primary bags 23. The resulting primary bags 23 are folded on pre-configured folding lines to give them a specific or desired shape, after which they are ready as one of many packages, each of which contains a certain amount of liquid product.

 Turning to FIGS. 1 and 6. The packaging material 11 is continuously fed down and compressed by two sealing cutting units 14, 15 at regular intervals, so that the opposite parts of the plastic layer are brought together and sealed laterally to form a tape-like sealing zone S. The sealing zone S is then cut off to obtain a primary bag 23 containing a certain amount of liquid product 12. For this purpose, the sealing cutting units 14, 15 are provided with cutting jaws 14a, 15a and thermal sealing lips kami 14b, 15b, respectively.

 To increase the processing speed of the sealing device, it is equipped with two sets of sealing-cutting units 14, 15 having the same structure, which operate alternately, and their operation time is shifted by half a cycle relative to each other.

 Each of the cutting inserts 18 is provided at the front end with cutting jaws 14a, 15a. Each of the sealing blocks or insulators of the inductors is provided at the front end with thermal sealing jaws 14b, 15b. The cutting jaws 14a, 15a and the heat sealing jaws 14b, 15b are moved towards the packaging material by means of cutting inserts 18 and sealing blocks 19 to compress the packaging material 11 on both sides and thereby bring the opposing surfaces of the plastic of the packaging material into contact with each other aim to seal them laterally.

 In the center of each of the cutting jaws 14a, 15a there is a horizontally located flat cutter 21, which is adapted to extend or retract depending on what is required. The cutter 21 is positioned so that in an extended position cut in the center or middle part of the sealing zone S. To carry out the necessary movement of the cutter 21 between the extended and retracted positions, a cylinder 22 is installed at its rear end. The cutter 21 can be extended or retracted by feeding into the cylinder 22 working environment or release it from the cylinder.

 Paired flaps 21a, 21b are also installed on each side of the tubular packaging material. They are designed to make free oscillatory movements relative to the cutting jaws 14a, 15a and thermal sealing jaws 14b, 15b. The flaps 21a, 21b are adapted to surround the packaging material 11, guide it and form it into a rectangular shape.

 In FIG. 6, the sealing-cutting assembly 14 is in the starting position of the sealing-cutting cycle, where the cutting jaw 14a and the heat-sealing jaw 14b move in the direction of the packaging material 11 to compress it on both sides and bring both opposing surfaces of the packaging material 11 into contact with each other . When the sealing-cutting unit 14 moves downward by compressing and holding the packaging material 11, the sealing zone S is bonded and formed.

 The sealing cutting assembly 15 shown in FIG. 6 is in the end position of the sealing-cutting cycle when the cutter 21 of the sealing-cutting assembly moves toward the sealing zone S to cut off the central or middle part of the sealing zone S and to separate the primary bag 23 from the packaging material 11. Once the center of the sealing zone S cut off, the cutting jaw 15a and the heat sealing jaw 15b of the sealing-cutting assembly 15 are retracted, rotated and set to the start position of the sealing-cutting cycle. When the sealing-cutting unit 15 moves to the start position of the sealing-cutting cycle, and the cutting sponge 15a and the heat-sealing lip 15b move to the sealing area S, the cutter 21 of the sealing-cutting unit 14 moves in the direction of the sealing zone S to cut in the central or the middle part of the sealing zone S, thus separating the primary package 23 from the packaging material 11.

 Although not specifically shown, the sealing cutting assemblies 14, 15 are provided with cylindrical mechanisms designed to pull together the cutting jaw 14a (or 15a) and the heat-sealing jaw 14b (or 15b) to provide the necessary pressure force during sealing. The pressure force between the cutting jaw 14a (or 15a) and the heat-sealing jaw 14b (or 15b) is quickly removed, and the sealing-cutting units 14, 15 reach the end position of the sealing-cutting cycle.

 FIG. 1 illustrates various features associated with a cutting insert 18 and a sealing unit 19. A pair of inductors or inductor bodies 31, 32 are mounted in the sealing unit so that part of each of the inductors 31, 32 protrudes on the extreme surface of the sealing unit 19. Each of the inductors 31 , 32 is connected to the power source using a connecting element.

 A groove 38 is made in the sealing block 19, located between the two inductors 31, 32. The groove 38 extends along the sealing block 19 and is designed to accommodate the front end of the cutter 21 when it is extended.

 Each of the inductors 31, 32 is made respectively with protruding parts 71, 72 forming the first pressure stage. The protruding parts 71, 72 are directed towards the cutting insert 18 and are located in the longitudinal direction of the inductors 31, 32.

 The cutting insert 18 is provided with paired cutting guides 73, 74. The cutter 21 is adapted to move within the gap 75 limited by the cutting guides 73, 74.

 Each of the cutting guides 73, 74 is provided with a counter element 76, 77 extending along the cutting guides 73, 74. Each counter element 76, 77 is mounted in the groove of the corresponding cutting guide 73, 74. The sealing zone S of the tubular packaging material 11 is strongly compressed by the counter elements 76, 77. For this reason, the counter elements 76, 77 are made of rubber material having a sclerometric hardness of about 95. In addition, each of the counter elements 76, 77 has a front surface facing the sealing unit 19. As shown in FIG. 1, the front surface of each of the counter elements is flat.

 Each of the cutting guides 73, 74 is also provided with first holding parts 73a, 74a and second holding parts 73b, 74b for holding the counter elements 76, 77 in place. Each of the first holding parts 73a, 74a has a surface 31 protruding toward the sealing unit 19. The surface S1 is strictly perpendicular to the front surface of the sealing unit 19. Each of the second holding parts 73b, 74d has oblique surfaces S2, S3 forming protrusions 73c, 74c. Each of the protrusions 73c, 74c is oriented towards the cutter 21.

 Each of the counter elements 76, 77, respectively, has an engaging-stopping portion 76a, 77a strictly in the form of a protrusion. The counter elements 76, 77 are fixed inside the respective cutting guides 73, 74 by mutual engagement of the engaging-stopping sections 76a, 77a and the corresponding protrusions 73c, 74c.

 The counter elements 76, 77 are also provided with corresponding extensions 76b, 77b forming the second pressure portions. These extensions 76b, 77b extend along the front surface of the respective cutting guide 73, 74. The extensions 76b, 77b also protrude from the sealing zone S of the packaging material 11 towards the liquid product 12 to compress portions of the packaging material 11 that are closer to the liquid product 12, than to the sealing zone S.

 In order to prevent the extensions 76b, 77b from deflecting when the counter elements 76, 77 put pressure on the packaging material 11, and thereby prevent a decrease in the pressure force as a result of such a deflection, each of the cutting guides 73, 74 is provided with a corresponding holding portion 73d, 74d extending along the extensions 76b, 77b.

 Due to this design, when the opposite portions of the plastic or polyethylene of the packaging material melt and compress together with the protrusions 71, 72, the molten plastic or polyethylene does not extend towards the product 12 outside the sealing zone S, because the extensions 76b, 77b compress the portions of the packaging material 11, located closer to the liquid product 12 than to the sealing zone S. As a result, the amount of plastic or polyethylene involved in the heat melting in the sealing zone S is guaranteed. Thus, the corresponding and favoring the necessary bond strength. At the same time, leakage of the liquid product 12 is prevented. In addition, the formation of cracks near the sealing zone S during formation after filling and sealing is prevented.

 Another positive result of the design of the sealing device of the present invention is that since the extensions 76b, 77b compress together portions of the packaging material 11 closer to the product than to the sealing zone S, the residual liquid product 12 is prevented from inside the seal S. Therefore, mixing is prevented liquid product with molten plastic or polyethylene. Accordingly, there is no harmful reduction in the bond strength of the hermetic package. Moreover, although a small amount of plastic or polyethylene may leak from the sealing zone S of the packaging material 11 to the cutter 21, this molten plastic or polyethylene is not cooled by the liquid product, thus making cracking impossible.

 Inductors 31, 32 are connected to a power supply or to a voltage supply device so that the high frequency voltage generated by the power supply is supplied to the inductors 31, 32. FIG. 7 is a block diagram of a power supply. The AC source 81 generates a three-phase AC voltage, and the high voltage rectifier 82 converts the AC voltage generated by the AC source 81 to a constant voltage.

 The DC voltage obtained using the high-voltage rectifier 82 is supplied to a pair of generators 83, 84, which generate high-frequency pulses. The generators 83, 84 are connected to a pulse generating circuit 97, which receives pulses of a certain frequency. Each of the generators 83, 84 is also connected to a corresponding high-frequency voltage conversion circuit 85, 86 to generate high-frequency voltages, which are then supplied to the respective inductors 98, 99. In this case, the inductors 98, 99 shown in FIG. 7 are located so as to correspond to the sealing-cutting units 14, 15 shown in FIG. 6, and comprise inductors 31, 32, respectively shown in FIG. 1.

 When the high-frequency voltage generated by the high-frequency voltage conversion circuits 85, 86 is supplied to the inductors 31, 32, an electric field is created in the packaging material between the inductors 31, 32 and the aluminum foil, which varies according to the high-frequency voltage. As a result, eddy current is induced in the aluminum foil, which generates heat due to eddy current losses.

 The operation of the sealing device of the present invention is described below with reference to FIGS. 8-10, where FIG. 8 illustrates the sealing device during the first stage of the sealing operation, FIG. 9 shows a sealing device during a second stage of a sealing operation, and FIG. 10 shows a sealing device during a third stage of a sealing process.

 FIG. 8-10 show the tubular packaging material 11 in general, and also illustrate the tape-shaped packaging materials 51, 52, which are located in the sealing zone S face to face with one another. Each of the packaging materials 51, 52 has a layered structure comprising a main paper layer 54, an aluminum foil layer 55 located on the inner surface of the main paper layer 54, and a plastic film or layer 56, for example, polyethylene, located on the inner surface of the aluminum foil layer 55 The outer surface of the main paper layer 54 is also covered with a plastic layer or film, for example, polyethylene (this layer is not shown separately, so as not to clutter the drawings) with unnecessary details. The plastic or polyethylene parts 56 of the packaging materials 51, 52 are meant to be bonded together by heat melting.

 The sealing device is designed to seal and cut the packaging material 11. The sealing device is provided with cutting jaws 14a, 15a and thermo-sealing jaws 14b, 15b, which are located opposite each other, as shown in FIG. 6. The cutting guide 74 is also located on the cutting jaws 14a, 15a, and the sealing unit 19 is located on the thermo-sealing cutting jaws 14b, 15b.

 The cutting guide 74 is provided with a counter element 77 extending along the cutting guide 74, and the sealing block 19 includes an inductor 32 located opposite the counter element 77. A feed channel for the cooler 67 is provided in the inductor 32 to allow the coolant to flow through the inductor. 10 also shows the holding portion 74d on the cutting guide 74.

 In the first stage of the sealing operation shown in FIG. 8, the packaging material 11 is located between the sealing unit 19 and the cutting guide 74. The cutting jaws 14a, 15a and the thermo-sealing jaws 14b, 15b then move towards each other.

 In the second stage of the sealing process shown in FIG. 9, the cutting jaws 14a, 15a and the heat-sealing jaws 14b, 15b move further towards each other. This leads to a strong compression of the sealing zone S of the packaging material 11 and its deformation by the inductor 32 and the counter element 77.

 In the third stage of the sealing operation shown in FIG. 10, a high frequency voltage is supplied from the high frequency voltage conversion circuit 86 shown in FIG. 7 to an inductor 32 to cause the aluminum foil 55 to generate heat using an induction current. As a result, a pair of plastic or polyethylene sections 56 enclosed between a pair of layers of aluminum foil 55 is heated. As shown in FIG. 10, the packaging material 11 is thus bonded by heat melting in the sealing zone S.

 During the sealing operation, the plastic or polyethylene sections adjacent to each other melt and are compressed by the protruding portion 71. Under normal conditions, this would cause the molten plastic or polyethylene 56 to leak outside the sealing zone S. However, since the extensions 76b, 77b compress the sections together AR2 of the packaging material 11, which is closer to the liquid product 12 than to the sealing zone S, the flow of molten plastic or polyethylene 56 is prevented from escaping from the sealing zone S in the direction of the liquid product 12. AR1 and the area on FIG. 10 denotes an area that is closer to cutter 21 than to sealing zone S.

 A second embodiment of the sealing device of the present invention is shown in FIG. 11. In this embodiment, the inductors 131, 132 are elliptical or, in general, elliptical in cross section and are located closer to the cutter 21 than to the outer edge of the counter elements 76, 77. As a result, the corresponding distances L1 between each of the protruding parts 71, 72 and a groove 38, measured along the front surface of the sealing block, is shorter than the corresponding distances L2 between each of the protruding parts 71, 72 and the outermost edge of the corresponding counter element 76, 77, measured along the front surface of the sealing block.

 As a result, portions of the counter elements 76, 77 between the protruding parts 71, 72 (i.e., the place where the protruding parts 71, 72 are in contact with the corresponding counter elements 76, 77) and the outermost edges of the counter elements 76, 77 act as second pressure portions, which compress areas of the packaging material 11 that are closer to the liquid product 12 than to the sealing zone S. As a result, the molten plastic or polyethylene 56 does not extend beyond the sealing zone S to the liquid product 12.

 According to a third embodiment of this invention, shown in FIG. 12, the sealing device is designed so that each of the surfaces of the sealing unit 19 directed towards the counter elements 76, 11 is formed with protrusions 19a, 19b parallel to the inductors 31, 32. These protrusions 19a, 19b serve as a second pressure portion. When the plate 18 and the sealing unit 19 are moved so as to reach each other, the protrusions 19a, 19b compress sections of the packaging material 11 located closer to the liquid product 12 than to the sealing zone S. As a result, the molten plastic or polyethylene 56 does not extend beyond sealing zone S in the direction of the liquid product 12.

 The sealing device according to the present invention, as described above, includes a combination of a sealing block, inductors inserted into the sealing block so that a part of each inductor protrudes above the surface of the sealing block and is provided with a first pressure portion for compressing the packaging material during sealing, anti-elements compress the packaging material, and voltage supply devices supplying high frequency voltage to the inductors. When a high-frequency voltage is supplied from the voltage supply device to the inductors, the induction current causes the aluminum foil of the packaging material to generate heat. As a result, the plastic material covering the packaging material is heated.

 At least one of the inductors and counter elements is advantageously provided with a second pressure portion for compressing the packaging material closer to the liquid product than to the sealing zone S. Thus, even if the plastic sections of the packaging material adjacent to each other melt and contract pressure, plastic leakage outside the sealing zone is prevented towards the liquid product, because the second pressure section compresses the packaging material located closer to the liquid product the one than to the sealing zone. Accordingly, molten plastic does not leak out of the sealing zone. This happens even if the energy of induction heating is increased in order to increase the sealing strength. Since molten plastic is prevented from flowing out in this regard, an appropriate bond strength can be obtained in the sealing zone and the occurrence of cracks near the sealing zone is prevented.

 In addition, the amount of plastic involved in thermal swimming in the sealing zone remains unchanged, and thus, an undesirable decrease in the bond strength in the sealing zone does not occur. The bond strength is maintained even if an elevated coupling temperature is used by increasing the high frequency voltage supplied from the voltage supply device, or if a large force is used to compress the packaging material. As a result, a high processing speed becomes possible by shortening the duty cycle of the sealing device.

 The principles, preferred embodiments and modes of operation of the present invention are described in the above description. However, the invention, which is intended to be protected, should not be construed as limited by the described particular embodiments. Moreover, the embodiments described herein should be considered as illustrative rather than limiting.

 Other specialists may make variations and changes, use equivalents without deviating from the essence of the present invention. Accordingly, it is specifically intended that all such variations, changes and equivalents falling within the spirit and scope of the present invention, as defined in the claims, should be included in connection with it.

Claims (15)

 1. A sealing device for creating a sealing zone in a packaging material having a plastic layer and containing a liquid food product, including a sealing unit with a front surface, inductors inserted into the sealing unit, each inductor partially protruding on the front surface of the sealing unit and has a first compressing part for compressing the packaging material during the sealing operation, a counter element located opposite each respective inductor having a front surface, allowing I want to hold the packaging material between the front surface of the counter elements and the front surface of the sealing unit, and means for supplying a high frequency voltage to the inductor, characterized in that the front surfaces of the counter elements or the front surface of the sealing unit have second compressive parts located on the parts corresponding to the portion of the packaging material, which located closer to the liquid food product than to the sealing zone to compress the packaging material during sealing to prevent Keeping molten plastic out of the outside of the sealing zone toward the liquid food product.  2. The sealing device according to p. 1, characterized in that it includes a pair of cutting guides, each of the counter elements is located on the corresponding cutting guide.  3. The sealing device according to claim 2, characterized in that the cutting guides include a first holding portion and a second holding portion that hold the corresponding counter element in place on the cutting guide.  4. The sealing device according to p. 3, characterized in that every second holding part is a protrusion formed by a pair of obliquely oriented surfaces.  5. The sealing device according to claim 4, characterized in that each of the counter elements includes a stop-engagement portion that engages a protrusion on a corresponding cutting guide.  6. The sealing device according to p. 2, characterized in that the cutting guides are spaced apart and made on the cutting plate, and the device includes a groove located between the cutting guides, in which the cutter moves to cut the sealing zone.  7. The sealing device according to claim 6, characterized in that each counter element has a remote edge, and the distance between the compressing part of each inductor and the remote edge of the corresponding counter element, measured along the front surface of the sealing unit, is greater than the distance between the first compressing part of each inductor and the groove, measured along the front surface of the sealing unit.  8. The sealing device according to p. 1, characterized in that each of the second compressing parts is made in the form of a protruding part on the sealing block.  9. The sealing device according to p. 1, characterized in that the second compressing part is made in the form of an extension on one of the counter elements.  10. A sealing device for creating a sealing zone in a packaging material having a plastic layer and containing a liquid food product comprising a sealing unit with a front surface, an inductor inserted in the sealing unit, the inductor partially protruding on the front surface of the sealing unit and has a first compressing part for compression of the packaging material during the sealing operation, a counter element located opposite the inductor having a front surface that allows holding the packaging material l between the front surface of the counter element and the front surface of the sealing unit, and means for supplying a high frequency voltage to the inductor, characterized in that the front surface of the counter element or the front surface of the sealing unit has a second compression part located on the part corresponding to the portion of the packaging material that is closer to liquid food product than to the sealing zone, to compress the packaging material during sealing to prevent the molten plate from flowing out tic outwardly beyond the sealing zone towards the liquid food product.  11. The sealing device according to p. 10, characterized in that the counter element is located on the cutting guide, and the cutting guide includes a first holding part and a second holding part that hold the counter element in place on the cutting guide, while the second holding part is a protrusion formed by a pair inclined surfaces.  12. A method of creating a sealing zone in a tubular packaging material, in which a tubular packaging material consisting of an outer layer of plastic and an adjacent layer of aluminum foil and containing liquid is placed between the cutting plate and the sealing block, the sealing block comprising at least one inductor protruding the front surface of the sealing unit and comprising a first compression part protruding toward the cutting insert, and the cutting insert includes at least one counter element, having the front surface and installed opposite the inductor, compress the tubular packaging material between the front surface of the sealing block and the front surface of the counter element to bring together opposite sections of the plastic layer and deform the portion of the tubular packaging material along the sealing zone located in the place corresponding to the first compressing part, apply a high voltage frequency to the inductor for generating heat in the layer of aluminum foil and melting the adjacent layer of plastic with so that the opposite sections of the plastic layer of the tubular packaging material are joined together by thermofusion in the sealing zone, characterized in that the sections of the packaging material located closer to the liquid than to the sealing zone are compressed together using a second compression part located on the front surface of the sealing block or on the front surface of the counter element, to prevent the molten plastic from leaking out of the sealing zone towards the liquid.  13. The method according to p. 12, characterized in that the compression together of the sections of packaging material located closer to the liquid than to the sealing zone, is carried out during the application of high-frequency voltage to the inductor.  14. The method according to p. 13, characterized in that the sealing unit includes a pair of separately separated inductors placed in the sealing plate, and the cutting plate includes a pair of counter elements, each of which is opposite one of the inductors, while the tubular packaging material is compressed between the cutting plate and a sealing plate for bringing together opposite sections of the plastic layer and deformation of the packaging material in two separately spaced places corresponding to the first compressive part of each inductor.  15. The method according to p. 12, characterized in that the compression together of the sections of packaging material located closer to the liquid than to the sealing zone is carried out using the protruding second compressive parts available on the sealing block.

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