This invention relates to a cutting device for cutting pre-fabricated transverse seams of a plastic-film sleeve that is filled with food, in particular with processed cheese, whereby each transverse seam of the film sleeve to be processed and continuously fed separates one portion of the food from the next portion. The device according to the invention has a rotating knife holder equipped with at least one cutting blade, in particular in the form of a blade cylinder, whereby the cutting blade strikes against an opposing bearing, in particular a counter-rotating opposing roller, when cutting a transverse seam.
Cutting devices are known from, for example, the production of individually packaged processed cheese slices. Such a process for production and the corresponding device are indicated in, for example, DE 42 04 357 A1. In this case, processed cheese is filled into a film sleeve that is sealed at a longitudinal seam, and this sleeve is then rolled flat and subsequently cooled. In this case, the cheese belt surrounded by film is cut into portions only after cooling (“cold squeezing”) by the cheese being squeezed at cross strips and the film sleeve from which cheese is removed being sealed at these cross strips by exposure to the action of heat. With modern machines, this squeezing takes place as long as the cheese mass is still hot (“hot squeezing”). To make individual slices from this “chain” or this belt of slices attached to one another, the seams formed by the cross-seals that are several millimeters wide are cut through with the knife or knives of the cutting device. In this case, such cutting devices can be designed in the manner of guillotines. The use of blade cylinders, whose flexible cutting blades cut on the hardened surface of an opposing roller, has proven especially advantageous, however, whereby the chain of the individual slices is fed through the two rollers.
A drawback of the known cutting devices is that the cutting blades become blunt after a certain number of cuts and have to be replaced. This is due to the fact that the double-layer film, which in most cases consists of polypropylene and is about 50 micrometers thick, is relatively tough in the state to be cut. The blunting of the cutting blades affects the service life negatively and reduces the productivity of the machine. Moreover, the cutting blades that are to be replaced are a cost factor in and of themselves, to which the assembly process with the expensive adjustment is added.
The object of the invention is now to propose a cutting device that in a simple design, which makes possible a modular type of construction and a simple assembly, ensures an extended service life because of less use of the cutting blades.
This object of the invention is achieved by the present invention described below.
One aspect of the present invention is a cutting device for cutting pre-fabricated transverse seams of a plastic-film sleeve that is filled with food, whereby each transverse seam of the film sleeve to be processed and continuously fed separates one portion of food from the next portion, wherein the device comprises:
Another aspect of the invention is a method for cutting pre-fabricated transverse seams of a plastic-film sleeve that is filled with food, whereby each transverse seam of the film sleeve to be processed and continuously fed separates one portion of the food from the next portion, the method comprising:
A further aspect of this invention is a method for cutting pre-fabricated transverse seams of a plastic-film sleeve that is filled with food, whereby each transverse seam of the film sleeve to be processed and continuously fed separates one portion of the food from the next portion, the method comprising:
Further aspects of the invention are illustrated in the drawings and described in the following detailed description of the invention.
An essential idea of the invention is to provide the knife holder with a heating element, which causes a targeted heating of the cutting blades. In this case, as a “targeted heating of the cutting blades,” such a heating is meant that goes beyond the normal operating temperature of the cutting blades and that primarily does not lead to a noteworthy heating of the knife holder, which because of heat expansion would irreversibly alter its geometry with respect to its smooth operation. In particular, the heating according to the invention is also not so great that the film at the transverse seam is opened by melting. The temperature of the cutting blade thus advantageously remains below the melting temperature of the plastic used for the film.
On this point, it can be emphasized that the procedure according to the invention is distinguished from the prior art, as it is disclosed in, for example, DE 39 20 867 A1. There, in a single operating step, the product is squeezed in the area of the sleeve that is to be cut, is transverse to this area and is cut here. The knife thus performs sealing and separating at the same time. At no point does the pre-fabricated transverse seam exist. Thus, this procedure, in the sleeve that is present here and filled with food, in particular with processed cheese, is not possible, since in the manufacturing procedure, first a chain of connected portions is formed and has to be fed to a cooling process. Only the thus pre-manufactured portions are then separated.
In the additional heating according to the invention, it is necessary to hold the latter as far as possible from the bearings. This object can be achieved in that the knife holder is designed so that the flow of heat is essentially sent to the cutting blades. This can be affected by the selection of material or the provision of insulation and/or the installation of a heat trap, for example in the form of cooling by a corresponding cooling device. It is especially advantageous, since it is especially simple to achieve, however, if the heating element is arranged near the cutting blade and with corresponding heat contact to the cutting blade in such a way that a large portion of the heat output is fed as directly as possible to the cutting blade and heats the latter more greatly than the remaining knife holder.
In general, the advantage of heating the cutting blade lies in the fact that the film sleeve that is locally heated for a short time resists the cutting blade when cutting a reduced resistance, so that the degree of wear and tear of the cutting blade is reduced and thus the service life of the cutting device is increased. Ultimately, the film sleeve that is formed from plastic film, for example polypropylene, is softer by the heating at the interface than it is at room temperature, so that it can be cut more easily. It has been shown that the service life of the cutting blades can be increased by a multiple in the method according to the invention. In this case, it has also been shown that it is advantageous when the heat output and the arrangement of the heating element are selected so that a temperature of over 80° C., in particular of about 100° C., is produced on the cutting edge of the cutting blade. Temperatures of up to 130° C. are not ruled out.
As a heating element, for example, a commercially available heating cartridge of sufficient size can be used that is held in a hole made in the knife holder and is supplied with voltage. The dimensioning of the heating cartridge and its voltage supply can be adapted according to the geometry of the knife holder. The heat output of the heating cartridges can be adapted to the application speed to obtain the desired temperature. Although the measurement of the current temperature by a corresponding sensor and also its controllability has a certain advantage, it is not absolutely necessary. Ultimately, the cutting device cuts “in emergency operation” even without a heated cutting blade.
Since it is structurally expensive to minimize undesirable heat expansions that change the position of the cutting blade and such changes occasionally cannot be completely avoided, it is especially advantageous when the cutting blade is held in a flexible manner on the knife holder, so that the cutting blade can be flexible in the cutting direction. In this case, the elasticity is adjusted so that a pressure that is adequate for the cutting action is maintained. The flexibility according to the invention can in this case be produced from the cutting blade itself or via an elastically suspended receiving part in which the cutting blade is held. Actually, the idea of the cross-cutting device with an elastically suspended cutting blade is, to a certain extent, independent of the knife holder with heating element according to the invention. However, special advantages arise specifically from the combination of the two ideas.
One advantage of such flexibility lies primarily in the associated increase in the tolerance of the cutting blade compared to a possible maladjustment, which can take place during operation. This advantage especially has an effect if the knife holder and the opposing bearing are designed as rollers, and the cutting blade during cutting has to be lined up exactly against the smooth and hardened surface of the opposing roller. In such an arrangement, any maladjustment produces a gap between the cutting blade and the surface of the opposing roller, so that the cut cannot be made completely. With the elastic suspension according to the invention, which advantageously also still allows a little play in other degrees of freedom, such a formation of gaps is avoided. As a result, the flexibility produces a certain tolerance against maladjustment, and even reduces the expense in the assembly of cutting blades.
With respect to an especially high production speed, it is advantageous if the knife holder is designed as a rotating means, in particular in the form of the already mentioned blade cylinder, whereby the latter is equipped in particular with several, advantageously with four, cutting blades. In the case of such a blade cylinder, it is then advantageous if the opposing bearing is formed from a counter-rotating opposing roller, which has, in particular, a surface made of hard metal. The opposing roller can have a somewhat different diameter from the blade cylinder. To eliminate another drive, it is especially advantageous if the blade cylinder drives the opposing roller over boundary areas that roll off on one another. With such a drive that has little slack or with a somewhat different roller diameter, the result is that the cutting blade does not always press down on the same spot on the opposing bearing, so that it results in a uniform use of the opposing bearing. Advantageously, the bearing of the opposing roller is also somewhat prestressed to produce the corresponding contact pressure and to offset tolerances.
In the case of such a blade cylinder, there are two advantageous possibilities of holding the cutting blades: in one case, the fastening for a cutting blade is implemented as a separate receiving part that is held in a radially-oriented guideway in the blade cylinder and is pressed down by springs. Such a design offers several possibilities relative to the adjustment parameters; the adjustment is still expensive because of the high number of parts. In an especially simple alternative, the material of the blade cylinder forms the actual support surfaces. The support surfaces are recessed to a certain extent in the material of the blade cylinder, whereby correspondingly adjusted support edges can be provided. The cutting blades then need to be put only on these support surfaces and be fastened. To obtain elasticity, the support surfaces are somewhat shorter than the cutting blades, so that the latter flex with their extension when held accordingly.
Advantageously, the cross-sealing during cutting is not completely separated, but rather perforated to a certain extent, so that after cutting, film arms remain, at which the chain adheres, and have to be conveyed a bit further on until the final separation of the individual links occurs. The final separation then takes place by, for example, tearing off, by the leading portion, in particular the cheese slice, being somewhat accelerated in comparison to the trailing portion. Such a “perforation” can be produced so that the cutting edge of the cutting blade is shorter than the transverse seam, so that during cutting, two arms remain on the edge. To achieve this perforation, grooves can also be ground into the cutting blades.
It is also especially advantageous if the blade cylinder and the opposing roller are combined in a common module that can be held on the machine and easily replaced. Such a module has the advantage that the cutting blades are preassembled and can be adjusted. To make possible the replaceability, the blade cylinder is equipped with an electrical connection arranged in the drive shaft, via which connection the supply lines of the heating element(s) can be put into contact with corresponding cables that run in the shaft.
The invention is explained in more detail below based on
The cut that is depicted in
The end of the drive shaft 6 has a hole with a splined hub profile, into which a corresponding splined shaft profile 11 of the blade cylinder 2 (see
In
Easier to see are the cutting blades 22 from
In
In
The elasticity of the cutting blades 22 is ensured by the fact that they are held on one side and that the support on the support surface 27 is incomplete. Because of this special holder, an elasticity in the direction of arrow A and thus also in radial cutting direction is provided. The direction of travel is identified with arrow B.
The following is a summary of certain preferred aspects of the invention:
Number | Date | Country | Kind |
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102007015624 | Mar 2007 | DE | national |
This application is a divisional of U.S. non-provisional patent application Ser. No. 14/284827 filed on May 22, 2014, which is a divisional of U.S. non-provisional patent application Ser. No. 12/532,713 which entered the U.S. national phase on Sep. 23, 2009, based on international patent application no. PCT/EP2008/052934 filed on Mar. 12, 2008, which claims priority based on German patent application no. 102007015624 filed on Mar. 29, 2007.
Number | Date | Country | |
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Parent | 14284827 | May 2014 | US |
Child | 15495123 | US | |
Parent | 12532713 | Sep 2009 | US |
Child | 14284827 | US |