A preferred embodiment of the present invention will now be described with reference to the accompanying drawings in which:
A generic silicone pad, when used with the Glopak jaw mentioned above, provides adequate performance. However, it can be improved substantially, and the improvement can be financially justified, if it is applied in existing industry applications where such a process is useful.
In the case of VFFS (Vertical Form, Fill and Seal) filling machinery, for example, and in the case of the manufacture of pouches destined to a retail market, the silicone pad can be fine-tuned to provide accurate sealing results since the pad is designed specifically for this particular use. It may be said also that this same pad would be inappropriate in other applications.
The pad of such sealing jaws must be designed to provide ideal sealing results by understanding a) the geometry and dimensions that is ideal for the film being used, b) the mechanical operation and detail which provides the sealing system and c) the conditions that will exist during the sealing process for the active jaw inherent to the process. A number of assumptions must be made. The mechanical and electrical systems involved in the process must be in good working order and provide the level of accuracy and speed required by the process.
With reference to
The passive jaw 13 is a pad of soft rubber, 60 to 70 duro compound, and modified to provide an ideal sealing geometry. From the drawings, it can be established that the width L is equivalent to the width of the passive jaw 13. During sealing, this width L provides ample heat energy and the films 14 and 14′ are compressed between the active and passive jaws and are heated in a molten state in the area (L) defined by the width of the shaped passive jaw 13. Only one side of the seal 15 is herein illustrated having been cut by the projecting point 16 of the shaped passive jaw 13.
The cutting edge or point 16 is disposed at the center of the area (L). The passive jaw 13 has a triangular-like profile with opposed inclined side walls 17 and 17′. The point 16 of the triangular shape provides the cutting edge to sever the seal in two parts, only one part 15 being shown herein, and each inclined side wall provides pressure in the sealing zone (L), thereby sealing the films using pressure and temperature.
Following this, the ideal geometry of the passive jaw 13 can be achieved. The ideal seal geometry must be calculated using scientific means. However, regardless of what this geometry is, an appropriate profile can be developed and the silicone pad can be designed to meet precisely the application.
Preferably, the sealing jaw is used for sealing superimposed polyolefin films, such as films 14 and 14′ herein illustrated, having gauges in the range of 1.5 mil to 4 mil thickness. The passive jaw which is profiled for the specific polyolefin film so that the shape of the seal 15 has a crucial impact on the quality of the seal whereby to improve seal quality for specific film material used for specific pouches formed.
The ideal sealing geometry can be investigated and determined using a scientific approach, trial and error and data gathering. This exercise is necessary to determine the precise angles, % compression and L values. Existing seal quality theory has evolved around film chemical composition which is a crucial sealing factor.
However, for all films to be sealed, it must be concluded that some physical mechanical seal geometry is better, ideal in fact, and anything less is a compromise. The seal geometry is a factor relative to the film's gauge, and the dimensional factors of the width of the wall. Seal quality is a factor of seal geometry, film composition, homogeneity of the film composition in the seal zone, and other factors utilized during a sealing process.
Testing of this novel concept, without generating scientific data but instead making repeated observations on a prototype assembly, has shown that seal geometry definitely has a significant importance on seal quality.
It is therefore within the ambit of the present invention to cover any obvious modifications of the preferred embodiments described and illustrated herein provided such embodiments fall within the scope of the appended claims.
Number | Date | Country | Kind |
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2551221 | Jun 2006 | CA | national |