DE3237634A1 - Vacuum-tight container - Google Patents

Abstract

The vacuum-tight container has a container shell, made of paper strips which are wound spirally in several layers and bonded together as an outer surface, and an inner surface which is joined to the latter and is made of a multi-layer strip of composite material which is likewise wound spirally and consists of a plastic covering layer, a metal intermediate layer and a paper layer facing the outer surface, and metal lids beaded onto the container shell, wherein the abutting surface of the strip of composite material is folded over through 180 DEG in the edge region facing the outer surface and welded onto the adjacent straight edge region of the spirally wound strip of composite material and the flanges of the lid and the container body, obtained during the beading of the lids, are pressed onto the outer shell surface of the container body in the manner of a crease.

Description

description

The invention relates to a vacuum-tight can according to the preamble of claim 1 vacuum-tight cans with a cylinder jacket-shaped can body made of so-called cardboard have been known for a long time, but experience has showed that, despite many attempts, the required tightness of such cans is not could be achieved so that the shelf life of the packaged in such cans Food and luxury items, such as Bo powder coffee, is severely limited. Because of many Tests have now found that the main cause of the leaks that occur lies in the so-called spiral seam, i.e. at the joint of the end faces of the interconnected winding, despite this so far with a sealing strip or a so-called hot-melt sealing thread. The one for connecting The necessary melting process does not guarantee a seamless connection, as this melting must be done when winding the individual strips and thereby the lubricity the strip on the winding mandrel prevents it from partially sticking to the mandrel Apart from the fact that such a melting process does not guarantee a seamless connection, parts that have already been bonded are restored during production under unfavorable circumstances torn open. Another difficulty is to be seen in the fact that they are too connecting surfaces parts of a composite material made of paper, metal and plastic are, of which only the plastic components have to be welded or glued is.

Another critical point is the connection of the coiled can body with its lids, since when making the flanged connection between the lid and Can body there is a risk that the metallic component of the composite material tears and thus the formed can gastight skin becomes permeable. On the other hand, a sufficiently strong flanging is necessary to to get the junction of the lid / can body vacuum-tight.

The shortcomings described above so led to the fact that, in spite of the basic advantages of such winding cans for the vacuum-tight packaging of Food and luxury goods and, despite higher prices, still tin cans to be favoured. In addition to higher prices, bring tin cans compared to wrapped ones Cardboard cans continue to have problems with their disposal, as these form a very large part of household waste burden. Tin cans cannot be squeezed by hand like cardboard cans. So they take up a lot of space and are not only a risk of accident Housewives, as hand injuries on cut tin cans are extremely common. After all, tin cans cannot rot in a natural rotting process. So they represent an environmental burden and can only be done by selection from the remaining rubbish is disposed of.

The invention is therefore based on the object of providing a new inexpensive To create a vacuum-tight jar using wrapping cardboard, due to their Training is vacuum-tight for at least as long as a tin can.

According to the invention, this object is achieved by the characterizing features of claim 1 solved.

Further features of the invention emerge from the subclaims.

The invention has a number of advantages. So the spiral seam, that is, the abutment surface of the roll forming the inner jacket of the can body, for the first time be completely vacuum-tight, as by turning the Edge area of the composite material strip plastic comes to rest on plastic, which is easy and is safe to weld. In the previous butt welding, metal and paper components are always a cause of incomplete welding of the joint area. Since now it is certain that only plastic comes into contact with plastic, an absolutely secure welded connection is guaranteed. The extra reinforcement The aluminum and plastic layer also has the advantage of being stronger mechanical strength during deformation, i.e. the risk of tearing or the damage is significantly reduced.

This is particularly advantageous on the end faces of the can body, as this is now widened when the lid is flanged, similar to that of tin cans can be that the flanging cover and can body comprehensive flanges arise that folds on the outer surface of the can body, i.e. around 1800, can be turned over. This creates a perfect, long-lasting vacuum seal Connection between lid and can body The invention is based on the following an embodiment shown more or less schematically in the drawing described in the form of a section from a vacuum-tight paper wrapper.

Of the can designated as a whole by the reference number 1 is the For the sake of clarity, only part of the cylindrical can body is shown or -mantels 2 shown, each of a metallic can lid on its end faces 3 is closed vacuum-tight with the help of a flange 4 each.

The can body or jacket 2 consists of a multilayer in itself as is known, wound helically over a winding mandrel and at least with one another partially glued paper strips as the outer jacket 5 and one with this connected inner jacket 6, which in turn also consists of a in on in a known manner, helically wound multilayered over a winding mandrel Composite strip is made up. The composite strip has a dem Polyethylene film of 60 g / m2 facing the inside of the can, i.e. a thickness of approx. 50 y, a pore-free aluminum foil 8 of about 12 to 15 gl thickness and one the outer jacket 5 facing paper strips 9 of about 60 ß thickness. The paper thickness is irrelevant, it just has to be strong enough to ensure a secure adhesive connection can be made with the outer jacket. A slidable plastic film is used Polyethylene quality used in the known per se winding around a winding mandrel to prevent damage to the plastic coating when sliding on the winding mandrel.

To seal the spiral seam 10, a width of approx. 6 to 8 mm is made Edge area 12 of the composite material strip folded around 1800 on the adjacent one straight edge area 12 of the helical composite material strip 6 is placed and welded. This is done in such a way that the one not shown here Strips of composite material running through the mandrel beforehand in the area of the spiral seam Hot air is heated and melted to the extent that the subsequent Pressing on the winding mandrel, not shown, creates a gap-free gas-tight connection of the adjacent surfaces of the composite strip is made, as shown in FIG Drawing can be seen.

For attaching the cover 3, i.e. for producing the flanging 4, the respective end face of the can body 2 is to be expanded so that a flange 18 shown in phantom in the drawing is produced. On the lid 3 is in the entire area of contact with the flanged inner wall the can jacket is permanently elastic Sealant 19 applied. The closure takes place in a manner known per se by rolling the can lid on 3 on the can body 2 until the flange 4 shown in the drawing is produced und.der flange 18 with the associated cover part fold-shaped on the outer jacket surface of the can body 2 is pressed. This results in full-surface contact of the inner jacket 6 with the cover 3 and the sealing compound 19, so a vacuum-tight connection between Can body 2 and lid 3 reached.

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Claims (4)

Vacuum-tight box Patent claims t Vacuum-tight box with a can jacket made of several times helically wound strips of paper glued together as an outer sheath and an inner sheath connected to it from one as well Helically wound multilayer composite material strips, consisting of a plastic cover layer, a metallic intermediate layer and the outer jacket facing paper layer, and with lids flanged to the can jacket Metal, characterized in that the abutting surface (10) of the composite material strip (6) in the edge region (12) around 1800 facing the outer jacket (5) folded over onto the adjacent one straight edge area of the helically wound composite material strip (6) welded on and the flanges (18) produced when the cover (3) is flanged of lid (3) and can body by (2) fold on the outer surface of the can body are pressed on. 2. Can according to claim 1, characterized in that the composite material made of a 12 to 15 ß thick pore-free aluminum foil, an approx. 50 ß thick sealable polyethylene film and an approx. 60 ffi thick paper strip. 3. Can according to claim 1, characterized in that the edge region (12) is about 6 to 8 mm wide. 4. Can according to claims 1 to 3, characterized in that on the crimps between the can body (2) and lid (3) a sealing layer (19) is provided.