This invention relates to a packaging machine, and more particularly to a sanitary construction for various components of a packaging machine.
Equipment used in sanitary environments, such as in the handling of food products or pharmaceuticals, must frequently be washed down or sanitized for product safety. In such equipment, it is desirable that the construction and assembly details are such as to avoid areas in which particulate material can build up. Accordingly, components or connectors that include recesses, pockets, crevices or the like, such as set screws, socket head cap screws, etc. should be avoided. However, connectors of this type are commonly employed in the construction of such machinery components. In addition, welding of such components is also not desirable because welded joints include pockets or cracks in which particulate matter can become trapped.
It is an object of the present invention to provide a construction for certain components of equipment for use in a sanitary environment which does not include the use of undesirable welds, connectors or the like. It is a further object of the invention to provide such a construction in which the various parts of the components are securely and permanently interconnected together. Yet another object of the invention is to provide such a construction which allows components to be assembled together in layers so as to provide internal chambers, recesses or passages which are unobstructed.
The present invention contemplates a forming tool usable with a packaging machine in which adhesive rather than weld joints or fasteners are used to assemble the components of the forming tool. Using adhesive rather than weld joints and mechanical fasteners provides smooth, crevice-free and pocket-free interfaces between the various components of the forming tool. Such smooth interfaces are less prone to germ and other bacteria collection that can affect the sterility of the packaging machine, which is particularly advantageous for packaging machines used in sanitary environments, such as for food or pharmaceutical packaging. The forming tool is adapted to removably engage a receiver of the packaging machine. This removability allows different forming tools to be mounted to the receiver as packaging needs or conditions change.
Therefore, in accordance with one aspect of the invention, an apparatus for use with a packaging system includes a base plate adapted to be received by a receiver of the packaging system. A box is coupled to the base plate and has a set of frame members coupled to the base plate. The set of frame members and the base plate define an interior volume accessible from an opening normal to the base plate. The box is coupled to the base plate by a bonding agent. In a further aspect, the bonding agent is a water resistant epoxy. In yet a further aspect, tongue and groove joints together with adhesive are used to connect the frame members to one another. In addition, the base plate may be secured over a vacuum plate. The vacuum plate includes a passage through which vacuum may be supplied from the receiver to the interior of the box, for deforming a web of packaging material into the interior of the box in order to form a product-receiving cavity in the web. The vacuum plate includes an inlet that cooperates with a vacuum supply associated with the receiver. The vacuum plate has a layered construction, in which the layers are bonded together using an adhesive.
Various other features, objects and advantages of the invention will be made apparent from the following description taken together with the drawings.
The drawings illustrate the best mode presently contemplated of carrying out the invention.
In the drawings:
The present invention will be described with respect to a food packaging machine and, more particularly, to a formation tool usable with a food packaging machine. However, it is understood that the invention may also be applicable with other food handling machines as well as non-food handling systems, such as packaging systems for packaging pharmaceutical products or any other product that is suitable for packaging between a pair of sealed webs.
With reference to
The formation station 16 includes a lift mechanism 40 that reciprocally moves a formation box 42 between a lowered position and a raised position. As is known in the art, the formation box 42 may have a set of dividers that define a set of cavities that may be evacuated using vacuum supplied from a vacuum pump (not shown) so as to draw the lower web material into the cavities. More particularly, when the formation box 42 is in its fully raised position, the formation box 42 contacts an underside of the lower web material. The cavities may then be evacuated to draw the lower web of flexible material downward into the cavities to form a deformed lower web of flexible material. It is recognized that stamps (not shown) may also be used to help force the lower web of flexible material into cavities so as to deform the lower web of flexible material. This process forms a number of cavities in the lower web that may be used for receiving product as described with respect to
As known in the art, the formation box 42 is lowered and the deformed web material is advanced to the filling station 18 and thereafter to the finishing stations of the machine 10, such as the upper web station 20, the sealing station 24, and the cutting, labeling and bulk packaging stations. The upper web station 20 may include an evacuation box (not shown) that receives the filled lower web material. The upper web material is then placed atop the filled cavities whereupon the evacuation box is evacuated to draw the upper web material into contact with the lower web and evacuate the cavities. The pair of webs are then sealed, cut, labeled, etc.
The present invention will be described with respect to the formation box 42 for use with a packaging machine, such as that described with respect to
Turning now to
As shown in
The support plate 58 is adhesively affixed to the vacuum plate 60. Preferably, a thin sheet of adhesive is applied to either the top surface of the evacuation plate, the underside of the support plate 58, or both. The support plate 58 and the vacuum plate 60 are of equal length and width and, as such, the alignment of the support plate 58 and the vacuum plate 60 is straightforward. Nevertheless, it is preferred that the adhesive have a bonding time of sufficient length to allow fine adjustments, as needed, to the placement of the support plate 58 atop the vacuum plate 60.
Before the adhesive is applied, the vacuum recesses 70 of the vacuum plate 60 are filled with a blocking material, such as wax, to the top surface of the vacuum plate 60. If desired, the elongated slots 68 of support plate 58 may also be filled with a blocking material, such as wax. In this manner, when the adhesive is applied to the upper surface of vacuum plate 60 and/or the underside of support plate 58 and the vacuum plate 60 and support plate 58 are secured together, any excess adhesive that would otherwise drip or run into vacuum recesses 70 or elongated slots 68 comes into contact with the wax material in the recesses 70 and slots 68. After the adhesive has set and cured, the assembled vacuum plate 60 and support plate 58 are subjected to a sufficiently high temperature to melt in the wax material contained within the vacuum recesses 70 and slots 68. In this manner, the vacuum recesses 70 and slots 68 are free of adhesive that otherwise may make its way into the recesses 70 and slots 68 when the vacuum plate 60 and support plate 58 are adhesively secured together.
The support plate 58 includes a first pair and a second pair of upwardly extending dowels 82 and 84, respectively. Dowels 82 are slidable along a groove 86 whereas dowels 84 are slidable along a groove 88 spaced from and parallel to groove 86. The base panel 56 of the formation box 42 includes pairs of spaced openings 90 and 92 such that when the formation box 42 is fitted onto the support plate 58, the dowels 82 and 84 extend therethrough, respectively. The base panel 56 is preferably adhesively affixed to the support plate 58, which also may be accomplished using the lost wax process described above in connection with the adhesive securement of vacuum plate 60 and support plate 58. The combination of the dowels and the corresponding openings assist with aligning the base panel 56 to the support plate 58. Alternatively, the engagement of base panel 56 and support plate 58 may be accomplished using studs extending upwardly from support plate 58, in combination with threaded nuts that are engageable with the studs. In this regard, wall panels 50 and 54 include pockets, such as shown at 93, 95, which are configured to receive the dowels or fasteners that are used to align or connect base panel 56 to support plate 58. The pockets are sufficiently deep so that the dowels or fasteners do not extend past the inside surface of the panels 50 and 54, so as not to interfere with deformation of the web material into the interior of the formation box 42.
With additional reference to
It is contemplated that a number of different adhesives may be used to for the aforementioned adhesive bonds, but it is preferred that an adhesive, such an epoxy, be used that is water resistant. It also desirable that the adhesive bonds maintain their integrity when exposed to cleaning and sterilizing agents.
It is understood that the principles of the formation box 42 heretofore described can be applied to the construction of an evacuation formation box. More particularly, using adhesive rather than conventional mechanical fasteners is particularly advantageous in reducing the collection of bacteria and other germs, as well as cleaning residue on the surfaces of the evacuation box.
Various alternatives and embodiments are contemplated as being within the scope of the following claims particularly pointing out and distinctly claiming the subject matter regarded as the invention.
Number | Date | Country | |
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Parent | 12271535 | Nov 2008 | US |
Child | 13402265 | US |