Heating means for a flow wrapper

Abstract

The invention relates to improvements of a heating means particularly in a vertical flow-wrapper.

Claims

1. Heating means comprising: a heating element; and a tube through which a medium to be heated is configured to flow; wherein the tube is incorporated into a block of a solid-state thermos-conductive material.

2. Heating means according to claim 1, wherein the block forms sidewalls of the tube.

3. Heating means according to claim 1, wherein the heating means comprises a multitude of outlets, which are incorporated into the block.

4. Heating means according to claim 3, wherein the outlets comprise a nozzle incorporated in the block.

5. Heating means according to claim 1, wherein the block is a 3D-print.

6. Heating means according to claim 1, wherein the tube comprises a spiral-shaped part.

7. Heating means according to claim 6, wherein a counter flow of the medium is provided by the spiral-shaped part.

8. Heating means according to claim 6, wherein a closed loop pressure chamber is provided downstream of the spiral-shaped part.

9. Heating means according to claim 8, wherein each outlet is connected to a pressure chamber.

10. Heating means according to claim 1, planes.

11. Heating means according to claim 10, wherein a minimum inner angle of the two planes is 90 degrees.

12. Heating means according to claim 1, wherein a number of nozzles, a shape of the nozzles and/or a distribution along a height of the block adapted to a specific application.

13. Heating means according to claim 1, wherein a temperature and/or a humidity of an ejected gas is altered by mixing a cold gas into a hot gas.

14. Packaging machine comprising the heating means according to claim 1.

15. Packaging machine according to claim 14, wherein the heating means is provided upstream from a sealing means.

16. Packaging machine according to claim 14, wherein the packaging machine a vertical flow wrapper.

Description

[0028] The invention is disclosed referring to the figures of the attached drawings, by way of non-limiting examples.

[0029] FIG. 1 shows schematically the vertical flow-wrapper according to the invention.

[0030] FIGS. 2 shows the inventive heating means.

[0031] FIGS. 3-7 show details of the tube of the heating means.

[0032] FIGS. 8 depicts the planes around the nozzles.

[0033] In FIG. 1, the vertical flow-wrapper 1 according to the invention is schematically shown. A vertical flow wrapper is a packaging machine, which forms a plane foil web into a foil tube, which is transported along a form-fill tube. Two opposing ends of this foil tube are sealed together by a longitudinal sealing means 5. Subsequently, the packaging item is filled into the foil tube and a cross-seal is applied to the foil tube to close the package. Simultaneously or after applying the cross-seal, the finalized packages are cut off the foil tube. The vertical flow wrapper comprises a frame/housing 8, at which a form shoulder 3, a form-fill tube 4 and longitudinal sealing means 5 and cross-sealing means 6 are provided. The vertical flow-wrapper may comprise gusset-forming means to form the bottom and/or the top of each bag. The longitudinal sealing means comprises means to heat the film and to press the two opposing ends together. Due to the heat and the pressure the films seal together. Preferred pressure means are rolls which can apply a pressure to the film-ends, while the film is moving. The heating means are provided upstream from the pressure means and preferably also heat the film while it is moving past the heating means. This is preferably done with a gas, preferably air, which is blown towards the film and hence heats the film. A possible heating means to heat the film prior to applying pressure is depicted in FIGS. 4-7.

[0034] A web of a foil 4, especially a weldable plastic foil 4, is supplied from a reel, which supplies the plane foil continuously or intermittently to a form shoulder 3, which shapes the foil web into a rather tubular form around a form-fill tube 2. In the context of the present invention, a tubular form of the bags or of the foil means any cross-sectional form including a circular form or another form, and especially a rectangular or generally a polygonal form. Longitudinal sealing means 5, which are provided downstream from the form shoulder, seal the edges to the foil tube together. After sealing, the bottom of the bag 7 can be formed by a special bottom forming means, for example gusset-forming means. Finally, cross seals, extending preferably perpendicularly to the direction of flow of the foil, are applied, especially by means of cross-sealing means 6. These cross sealing means 6 apply to the bag 7 not only a cross-seal closing the top of the bag 2, but these cross-sealing means 6 advantageously also provide, preferably simultaneously a cross-seal defining the bottom of the subsequent, upstream bag 2. The bags 2 produced are separated from one another by a cutting means, which are preferably incorporated into the cross-sealing means 6. Between the application of the bottom- and top-cross-seal of each bag, the bag is filled with the product, preferably an edible product.

[0035] The film web 4 can be heated by utilizing the heating means as depicted in FIG. 2. FIG. 2 shows an overall image of the heating means 9, which essentially comprises a solid-state block 10. This solid state block is preferably produced by 3D-printing; i.e. the body is build up layer by layer. Each layer is connected to the previous layer by adhesive connection, for example by means of an adhesive and/or by the application of heat. The material utilized to produce the block is preferably a thermally conducting material, such as aluminum, an aluminum alloy, copper, iron and/or steal. For 3D-printing, the material is provided as a powder. Preferably, no machining is utilized after the block has been printed. As depicted by the dotted lines, in its inner, the block comprises a tube 11, through which the medium to be heat, preferably a gas, particularly air flows. This medium leaves the block via an outlet, here a multitude of outlets, here a multitude of nozzles, preferably provided along a line. Furthermore, in or around, here in the block, a heating means 15, here a cartridge is provided, which heats the entire block to a desired temperature. The heating is monitored and preferably controlled by a temperature sensor 16, for example a thermos-couple. The medium enters the block, here via a separator 14, which avoids, that the tubes upstream from the separator are heated too much. Preferably this separator 14, the tube connection between the separator and the block 10 are provided as one piece and are more preferably all produced by means of 3D-printing during one and the same printing process. The medium enters the separator or the block 10 directly via an inlet 13, flows through the tubes, in which a heat transfer from the sidewalls of the tube 11 to the medium. After the medium has been heated, it exits the block via the outlet(s) 12. In the present case, the outlet is an array of nozzles which extend preferably equidistantly along a line, which is preferably parallel to the direction of motion 22 of a film past the heating means 9. It can be seen that the outlets, here, do not extend over the entire height of the block. However, there may be applications in which more nozzles are preferable. It has turned out that for the heating of a film, particularly in a vertical flow wrapper, it is advantageous that the outlets are framed by two planes 21 which extend parallel to the direction of motion 21 of the film 4. The planes are provided to the left and to the right of the array of outlets 12. The planes are preferably provided at an angel , so that the cross-section of the block 10 is triangular shaped in the vicinity of the outlets with the outlets at the tip of the triangular. The outlets are preferably provided as nozzles which eject the medium towards the body to be heated, preferably a moving film.

[0036] FIGS. 3-7 shows details of the tube 10 and the outlets/nozzles 12. For the sake of clarity, the block 10 has been omitted. However, the person skilled in the art understands that the lines that delimit the tube and the outlets is the block 10 itself. Particularly from FIG. 5 it can be seen that the tube 10 comprises here a spiral part 17 and a pressure chamber 18. The gas enters the tube via inlet 13 and then flows through the spiral part. The flow-direction of the medium is depicted by a multitude of small arrows. In the present case, the spiral part 17 is designed such that there is a counter-flow of the medium in the spiral part. This assures more uniform heating of the gas and a shorter height H. Downstream of the spiral part a pressure chamber is provided, which is designed as a closed loop. Depending on the pressure distribution in the pressure chamber, the medium can flow in the pressure chamber in both directions. The outlets 12 are flow-wise connected to the pressure chamber. Due to closed loop design, there is no or no significant pressure drop along the array of outlets with the result, that the gas flow out of the various outlets is at least essentially equal. The fluid flow in the pressure chamber is also depicted by small arrows in FIG. 5.

[0037] FIG. 3 shows the location of the heating means 15 and the temperature sensor 16. The temperature sensor 16 in the block measures the temperature of the gas in the tube and/or the temperature of the block.

[0038] FIG. 7 a sectional view along the cut A-A depicted in FIG. 4. It can be clearly seen, that the pressure chamber 18 is designed as a closed loop.

[0039] FIG. 8 depicts details of the planes 21 around the outlet 12, here a nozzle 12, particularly the angle between the two planes. Each outlet is framed by two planes. The planes are preferably provided to the left and to the right of each outlet and at an angel relative to each other. Preferably, the angel is 90-130, more preferably 92-120 and even more preferable 93-110.

[0040] Preferably referring to all drawings, and particularly to FIG. 5, the form and/or number of nozzles 12 and/or the shape of the block, particularly its cross-section is preferably adapted to and/or designed for the individual application, e.g. in order to optimize the pressure, the flow and the flow distribution.

[0041] The following parameters can be changed [0042] the shape of the nozzle, particularly its cross-section and/or shape, preferably at its outlet. [0043] the diameter of the nozzle [0044] the length of the nozzle [0045] the outside surface of the block 10 adjacent to the nozzles 12 [0046] the angel of the surface adjacent to the nozzles 12 [0047] number of holes [0048] the distance between nozzles [0049] distribution of the nozzles along the height H of.

[0050] Only one or a multitude of those adaptations can be carried out, wherein any combination of adaptations or modifications can be carried out for a certain application. Preferably, the changes are made at the computer and the changed block is then 3D-printed. Some adaptations, like the size, the number and/or the distribution of the nozzles can also be incorporated by machining, e.g. drilling.

LIST OF REFERENCE SIGNS

[0051] 1 Packaging machine, flow wrapper, vertical flow-wrapper

[0052] 2 form-fill tube

[0053] 3 form shoulder

[0054] 4 foil, film

[0055] 5 longitudinal-sealing means

[0056] 6 cross-sealing- and/or cutting means

[0057] 7 package

[0058] 8 frame/housing

[0059] 9 heating means

[0060] 10 block of solid state thermoconductive material

[0061] 11 tube

[0062] 12 outlet

[0063] 13 inlet

[0064] 14 separator

[0065] 15 heating element

[0066] 16 temperature sensor

[0067] 17 spiral part

[0068] 18 pressure chamber

[0069] 19 end section

[0070] 20 tip of the block (10)

[0071] 21 plane

[0072] 22 direction of movement of a film past the heating means (9)

[0073] angel

[0074] H Height of the block