NO124202B - - Google Patents

Description

Clamp.

This invention relates to a clamp for tight closure

a<y> an object, e.g. a flexible container, made of wire with essentially the same cross-section over the entire length, in the shape of a U

which has a base and two arms arranged to be deformed into engagement with each other to surround a portion of the object, the clamp having a substantially planar inner surface to engage with the object. The clamp is particularly suitable for placing around the neck

a flexible container, such as a plastic bag, to provide an airtight seal when the container is evacuated to keep the product in the container under vacuum.

When wrapping vacuum-packed products, such as meat, cheese, chickens etc., it is essential that a perfect seal is achieved to prevent damage to the product due to leakage of air in the container. Until now, many attempts have been made to improve clamping devices and sealing clamps to achieve the best possible sealing effect.

If you want to achieve an airtight connection, it is necessary to subject the material at the mouth of the container to extremely large, radially inward pressure forces to prevent leakage. This is particularly the case with bags and other containers made from modern, strong, elastic plastic materials. When a clamp is placed to seal the neck of a container made of a relatively brittle material such as cellulose, the application of large, radially inward pressures has in many cases resulted in this material being crushed and separated, thereby been destroyed for its intended purpose.

The above-mentioned crushing effect is partly due to the fact that wire of circular cross-section has been used almost exclusively in the art for providing clamps of the first-mentioned type. In this context, it is clear that the inner element of a U-shaped clamp, which is made of wire with a circular cross-section, is a U-shaped line that engages the material only when the clamp has been deformed into a closed loop which surrounds the mouth of the container. The fact that the material of the container is extremely flexible can give the impression that the special cross-section of the wire from which the clamp is made has no particular significance, but it has been found in practice that a significant reduction of the pressure per unit length of the material can be achieved by making the inside of the U-shaped clamp flat instead of semi-circular, as is the case with a clamp made of wire with a circular cross-section. This also applies to clamps with a symmetrical, polygonal cross-section.

It has also been found that the sealing effect of a clamp

is proportional to the width of the clamp as well as the radially inward pressure that the clamp exerts.' Flat clamps of the non-sealing type are usually quite wide, but as indicated above, no successful attempts have been made in the past to make such clamps sufficiently tight to maintain the seal of a vacuum seal, in particular a clamp size must be used to seal different amounts of material. The resistance moment of these planar clamps is, moreover, usually insufficient to be able to withstand the outward pressure of the material which seeks to open the closure.

The purpose of this invention is to provide a new clamp which can create an effective closure around the neck of a flexible container, but which requires less material than previously known clamps to achieve the same effect. The clamp according to the invention is distinguished by the cross-section of the a-clamp which has a straight base, has two converging sides emanating from the ends of the base so that the cross-section width decreases from the inside outwards. By using this clamp, the advantage is also achieved that permanent deformation is achieved in the outer part of the clamp, so that the clamp does not seek to regain its original shape. You then do not need to dimension the clamp stronger than exactly necessary for the specific purpose.

The invention will be described in more detail below with reference to the drawing, where: Fig. 1 is partly a schematic side view showing a clamp according to the invention with the associated tool at the time when the legs of the clamp are to be deformed inwards towards each other, fig. 2 shows on a substantially larger scale a typical cross-section of an embodiment of the clamp, fig. 3 a corresponding cross-section of a preferred embodiment of the clamp according to the invention, fig. 4 a cross-section of a mouth part of a closed container with the clamp deformed around the mouth, and fig. 5 is a schematic side view of a sausage package with the clip according to fig. 3 placed on the package.

A clamp designated 10 is arranged to be pressed against a press A by means of a piston B to be deformed around the neck C of the container to be closed. As can be seen from fig. 1, the undeformed clamp 10 consists of two opposite legs 11, 12 which are connected at their corresponding ends by means of a main part 13 with bent connection parts 14, 15 between the main part and the legs. The legs 11,12 are straight and can be considered parallel, but it is preferred that they diverge somewhat outwards at their free ends to facilitate regulated feeding of the clamp along a feeding track not shown. The main part 13 is straight and can be considered perpendicular to the axes of the legs 11,12. The connecting parts 14,15 are designed with a relatively small radius, but which is sufficiently large not to distort the thread too much during the bending operation during the forming of the clamp. The clamp can be made of different materials including steel and aluminium, and it is preferably cold-worked to the one in fig. 1 shown form. The cross-section of the clamp 10 shown in fig. 2, is mainly triangular with rounded corners and has the same shape along the entire length of the clamp. The cross-sectional shape of the clamp is such that a relatively wide side 20 is directed towards the material to be compressed and closed. The other sides 21,22 converge from the inner side 20. It is therefore clear that the extremely high, local pressures that occur when using a clamp with a circular cross-section will not be able to occur here and that the clamping forces are distributed over the entire width W of the clamp. As mentioned above, the flat side 20 is not only desirable to reduce local stresses to a minimum, but the increase of . the width of the inside of the clamp in a direction along the mouth of the bag also increases the sealing effect and reduces the likelihood of leakage.

As an example, it has been found that with a clamp with a cross-section according to fig. 2 with the width W equal to 2.5 mm and the cross-section height D equal to 2.5 mm, a significantly improved sealing effect is achieved just opposite a clamp with a circular cross-section with a diameter of 1.8 mm and with an equivalent resistance moment.

Another important advantage of the cross section according to fig. 2 is that the tensile strength per unit area is not as large as with a clamp with a circular cross-section as the deformed clamp is by its nature a bent beam (fig. 5) and as such should have more material near its bending center than at a point further from this centre. For this reason, excessive stresses and deflections at the material's fibers are avoided.

Another advantage of the cross section according to fig. 2 is that the clamp can be more easily controlled during feeding along a feed channel than a clamp with a circular cross-section.

The strength of the clamp can be increased and certain additional advantages obtained by using the preferred cross-sectional shape of fig. 3.1 in this case, the cross-section 10' is designed as a trapezoid with the shortest base 23 having a length that is at least half of the maximum length W for the largest base 24 that abuts the material to be closed. The height of the cross-section may be roughly equal to the length of the base W. It is clear that the moment of resistance of the trapezoidal cross-section is substantially greater than that of the triangular-shaped cross-section and in reality this moment is more than twice as great. For this reason, the closed clamp's resistance to opening as a result of the radially outwardly directed pressure from the container's deformed material is substantially greater than the corresponding resistance in a circular cross-section clamp with the same area.

If e.g. the clamp's width (the length of the cross-section base) W and the cross-section height or the clamp's thickness D is equal to 2.5 mm, the moment of resistance about the neutral axis of the cross-section according to fig. 3 greater than the corresponding moment of resistance for a circular cross-section with a diameter of 2.5 mm. It is also clear that the general comparison of the bending resistance of trapezoidal and circular clamp cross-sections remains approximately the same even if the neutral axis is moved towards the inner side 24, which is the case-if the loop according to fig. 4 is considered to be a bent beam.

As is the case with the clamp according to fig. 2 with a triangular cross-section, one also has the clamp according to fig. 3 with a trapezoidal cross-section has the advantage that the feeding of the clamp along a channel can be easily controlled or controlled. In this context, it should be noted that the clamp's converging sides 25,26 are flat surfaces which can interact with complementary shaped inner sides of the feed slot. It is therefore not necessary to hold the clamp during feeding along the outer side 23, and this outer side is therefore available for e.g. embossing a code number on the clamp to be able to identify the place or time of manufacture for the product. As the outer side 23 does not need to cooperate with the channel, there is no risk of the imprinted characters being deformed during the deformation of the clamp.

The clamp according to the invention is also advantageous in that it has a flat surface on the outer sides of the clamp, so that an adhesive strip for connecting several clamps can be stuck on a larger surface than with clamps with a circular cross-section.

It has been mentioned that the clamp described above is used in particular for sealing a vacuum container because this application is associated with the greatest problems. However, it is clear that the clamp can just as well be used for other purposes. In many cases, e.g. the container exposed to an internal positive pressure instead of negative pressure. In such cases, the clamp's increased resistance to opening under the internal excess pressure at the mouth is equally advantageous. In cases where the weight of the contents affects the clamp, such as when the product is suspended, the clamp's resistance to sliding along the mouth of the container is particularly important. This will depend on the size of the building surface.

Claims (2)

1. Clamp for tightly closing an object, e.g. a flexible container, made of wire of substantially the same cross-section over its entire length, in the shape of a U having a base and two arms arranged to deform in contact with each other to surround a part of the object, the clamp having an essentially flat inner side which must come into contact with the object, characterized in that the cross-section of the clamp, which has a straight base (20,24), has two converging sides (21,22;25,26) emanating from the ends of the base so that the cross-sectional width decreases from the inside outwards. 2. Clamp according to claim 1; characterized by the cross-section having the shape of a symmetrical triangle or trapezoid with rounded corners.