EP0177426A1 - Method of curling can lids onto a can body - Google Patents

Abstract

The invention provides a method of crimping a bottom (21) to a container body (2) (barrel, etc.) with a bead of reduced radial projection. The container body (2) is centered on the bottom, which is engaged on a rotating mandrel (28), the edges of the body and of the bottom being superimposed. The skirt (26) of the bottom, for example frustoconical, widens from a transverse central portion (25), and moves away from the lateral wall of the mandrel, a contact of drive by the mandrel, continuous or discontinuous , being produced in the zone of connection of this skirt to the central portion, for example formed of circumferentially spaced and axially inclined ribs (22) which prove further beneficial for the stacking of such bottoms. The diameter of the axial end of the container body is reduced during the crimping process by application against the lateral wall of the mandrel.

Description

The present invention relates to the bottom assembly to a container body and more particularly to an improved crimping process.

The present invention relates to the manufacture of metal containers such as metal drums, barrels, cans and the like, typically of cylindrical or polygonal section.

It is well known to crimp ends with open ends of container body with a double or triple crimping bead. The container thus obtained by crimping has a bead which projects radially outwards relative to the side wall of the container body. In the case of containers having a crimp, the outside diameter of this bead

is noticeably larger than in the double-crimped container.

This difference even small on the overall diameter can be critical and lead to a considerable loss of space when loading drums in ISO type transport containers, namely by reducing the number of drums per row. In some cases, the resulting total loss of capacity of the transport container can be up to 15%.

It has been proposed to reduce the diameter of the container body before the crimping phase in order to reduce the radial projection of the bead of the container. Such a method has been successfully implemented in the case of small containers where there are similar problems of reducing the space lost.

Reducing the diameter of the ends of a container body involves a separate step prior to crimping, with the additional costs involved. In addition, the bottom must have been reduced accordingly in order to adapt to the reduced diameter of the ends of the container body.

An object of the present invention is a method of crimping bottoms to a container body by which the! final radial projection of the bead relative to the side wall of the container body is reduced during crimping.

The invention thus provides a method of crimping end wall _s bottom, or fundà a container body by crimping to each other of their edges, according to which a preformed bottom is produced having a hollow transverse central portion, a skirt extending axially from this central portion, and a rim extending radially outward from this skirt, as well as a preformed container body having a side wall and a rim extending radially towards the outside from this side wall, the bottom is fitted onto a mandrel in drive contact, the container body is engaged on the bottom in centering contact so that their edges are in mutual contact, and a tool is moved radially inward crimping so as to wind the edges into a crimping bead, characterized in that said bottom is worked so that its skirt extends both axially and radially from the cent portion rale, so that, when this bottom fits onto the mandrel, its skirt is radially spaced from the lateral wall of the mandrel, and that, when the crimping tool is moved, the skirt is deformed this bottom against the side wall of the mandrel, thereby reducing the radial projection of the resulting crimp bead relative to the side wall of the container body.

The initial space between the bottom skirt and the lateral wall of the mandrel makes it possible to reduce the diameter of the end of the container body and therefore the relative radial projection of the bead during crimping. Consequently, the cost of crimping is substantially that of a conventional operation of corresponding double or triple crimping. In fact, there may be reductions in ancillary costs, thanks to the reduced radial extension of the edges of the bottom and of the container body, since the length of sheets required is less than in the prior art because the bead of crimping is close to the axis of the container.

Preferably, when the crimping tool is moved, a tapered zone is formed in the side wall of the container body substantially at the level of the central portion of the bottom.

Preferably, the bottom skirt widens from the hollow transverse central portion towards the rim and the drive contact is defined by the complementary connection zones of the preformed bottom and of the mandrel. Although the flared skirt is preferably frustoconical (the half-angle at the top of it is largely responsible for the reduction of the radial projection of the final crimping bead) it may be only partially frustoconical or include an annular step at halfway in the axial direction.

According to another embodiment there is a plurality of circumferentially spaced ribs, radially offset inwards and axially inclined formed in the bottom between its skirt and the central portion in order to provide an engagement contact between the mandrel and the bottom preformed along the surface facing radially inward of the ribs.

Preferably, the mandrel has a transverse end wall and a lateral mandrel wall which tapers axially outwards from this end wall, the taper angle of this lateral mandrel wall relative to the axis of the mandrel. mandrel up to 5 ° and preferably about 3 °.

According to another aspect of the invention there is provided a preformed stackable bottom adapted to be crimped to a container body, comprising a hollow transverse central portion, a skirt extending axially from this central portion, a concave annular zone. connection connecting this central portion to this skirt, a flange extending radially outward from this skirt axially at a distance from this central portion, characterized in that said skirt extends both axially and radially from of this central portion, and that a plurality of hollow stamps projecting inwards are formed in the concave connection zone and are adapted coming into contact with a corresponding connection zone of a crimping mandrel to drive the bottom in rotation with the mandrel, these stampings being further adapted to come into contact with the convex face of a connection zone of a bottom identical underlying in interlocking relationship therewith so that the edges of this bottom and of the underlying bottom are axially spaced from one another in order to facilitate their separation and handling. Preferably these stampings have axially inclined ribs extending from the central portion into the skirt about halfway between the central portion and the flange.

In all cases, the container body is in centering contact on the bottom skirt. The location of this contact zone varies according to the desired embodiment. In general, this does not require any modification of the configuration of the container body except as regards the radius of the connection zone between the side wall and the rim thereof. Alternatively, however, an annular or equivalent indentation may be formed in the side wall of the container body to form the centering contact area with the bottom.

It will be appreciated that the diameter of the conventional bearing rods axially spaced along the container body is adapted to that of the bead. Consequently, in the case of barrels obtained by triple crimping in accordance with the invention, the diameters of the rolling rods is to be reduced correspondingly to that of the rods of conventional barrels obtained by triple crimping.

The present invention is particularly suitable for triple crimping, in which case it is possible to reduce the radial projection of the bead below the diameter obtained by a conventional process. The invention also applies to double crimping, in which case the diameter of the bead can be reduced to the nominal diameter of the side wall of the container body.

• La figure 1 est une vue partielle en coupe d'un corps de récipient muni d'un rebord et d'un fond à rebord reçu sur un mandrin préalablement au sertissage, conformément à l'art antérieur ;
• La figure 2 est une vue partielle en coupe d'un bourrelet de triple sertissage terminé lorsque l'outil de sertissage est écarté vis-à-vis du mandrin, conformément à l'art antérieur ;
• La figure 3 est une vue partielle en coupe correspondant à la figure 1, représentant le corps de récipient à rebord et le fond sur le mandrin préalablement au sertissage, conformément à un premier mode de réalisation de l'invention ;
• La figure 4 est une vue partielle en coupe montrant un triple sertissage terminé de projection radiale réduite selon le mode de réalisation de la figure 3, lorsque l'outil de sertissage est écarté par rapport au mandrin ;
• La figure 5 est une vue partielle en coupe, semblable à la figure 3 pour un second mode de réalisation de l'invention ;
• La figure 5A montre la position relative des rebords du corps de récipient et du fond après une première étape de sertissage selon le mode de réalisation de la figure 5 ;
• La figure 5B montre la position relative des rebords du corps de récipient et du fond dans une deuxième étape de l'opération de sertissage, lorsque la zone de raccordement entre le rebord et la jupe du fond vient en contact avec la paroi latérale du mandrin ;
• La figure 5C montre le bourrelet de triple sertissage terminé pour le mode de réalisation de lafigure 5 à la fin du déplacement de l'outil de sertissage ;
• La figure 5D montre en coupe partielle deux fonds préformés conformément au mode de réalisation de la figure 5 en relation d'empilage ;
• La figure 6 montre le triple sertissage de la figure 5C lorsque l'outil de sertissage est partiellement écarté par rapport à sa position de la figure 5C ;
• La figure 7 est une vue de dessous du fond de la figure 5 ;
• La figure 8 est une vue partielle en coupe semblable à celle de la figure 3 pour un autre mode de réalisation de l'invention ;
• La figure 9 est une vue partielle en coupe d'un bourrelet de triple sertissage terminé selon le mode de réalisation de la figure 8 ;
• La figure 10 est une vue partielle en coupe semblable à celle de la figure 3, pour encore un autre mode réalisation de l'invention ;
• La figure 11 est une vue partielle en coupe avec l'outil de sertissage partiellement écarté après finition du triple sertissage dans le mode de réalisation de la figure 10 ;
• La figure 12 est une vue partielle en coupe similaire à celle de la figure 3 pour encore un autre mode de réalisation ;
• La figure 13 montre un bourrelet de triple sertissage terminé dans le mode de réalisation de la figure 12, l'outil de sertissage étant partiellement retiré ; et
• La figure 14 montre un bourrelet de double sertissage terminé de projection radiale réduite, l'outil de sertissage étant partiellement retiré, obtenu conformément au procédé de l'invention.
• Les figures 1 et 2 montrent le triple sertissage d'un fond 1 en tôle à un corps de récipient en tôle 2 d'un fût conformémemt au procédé décrit dans le brevet d'addition FR 89 175 du 9 Décembre 1965.

The objects, characteristics and advantages of the invention appear from the following description, given by way of non-limiting illustration, with reference to the accompanying drawings on which :

• Figure 1 is a partial sectional view of a container body provided with a rim and a bottom rim received on a mandrel prior to crimping, according to the prior art;
• Figure 2 is a partial sectional view of a triple crimping bead completed when the crimping tool is moved away from the mandrel, according to the prior art;
• Figure 3 is a partial sectional view corresponding to Figure 1, showing the rim container body and the bottom on the mandrel prior to crimping, in accordance with a first embodiment of the invention;
• Figure 4 is a partial sectional view showing a triple crimping completed with reduced radial projection according to the embodiment of Figure 3, when the crimping tool is spaced from the mandrel;
• Figure 5 is a partial sectional view, similar to Figure 3 for a second embodiment of the invention;
• FIG. 5A shows the relative position of the edges of the container body and of the bottom after a first crimping step according to the embodiment of FIG. 5;
• FIG. 5B shows the relative position of the rims of the container body and of the bottom in a second step of the crimping operation, when the connection zone between the rim and the skirt of the bottom comes into contact with the side wall of the mandrel;
• FIG. 5C shows the triple crimping bead completed for the embodiment of FIG. 5 at the end of the displacement of the crimping tool;
• Figure 5D shows in partial section two preformed bottoms according to the embodiment of Figure 5 in stacking relationship;
• Figure 6 shows the triple crimping of Figure 5C when the crimping tool is partially spaced from its position of Figure 5C;
• Figure 7 is a bottom view of the bottom of Figure 5;
• Figure 8 is a partial sectional view similar to that of Figure 3 for another embodiment of the invention;
• Figure 9 is a partial sectional view of a triple crimping bead completed according to the embodiment of Figure 8;
• Figure 10 is a partial sectional view similar to that of Figure 3, for yet another embodiment of the invention;
• Figure 11 is a partial sectional view with the crimping tool partially spaced after finishing the triple crimping in the embodiment of Figure 10;
• Figure 12 is a partial sectional view similar to that of Figure 3 for yet another embodiment;
• Figure 13 shows a triple crimping bead completed in the embodiment of Figure 12, the crimping tool being partially removed; and
• FIG. 14 shows a bead of double crimping finished with reduced radial projection, the crimping tool being partially removed, obtained in accordance with the method of the invention.
• Figures 1 and 2 show the triple crimping of a sheet metal bottom 1 to a sheet metal container body 2 of a barrel in accordance with the method described in patent FR 89 175 of December 9, 1965.

The bottom 1 and the container body 2 are suitably preformed. The side wall of a container body 2 has a rim 3 extending radially outwards which is connected to it by an annular zone of connection with a large radius. The preformed bottom 1 has a hollow transverse central portion 5 connected by a concave annular connection zone 6A to a generally cylindrical skirt 6 which is extended radially outwards by a flange 7 of a predetermined length for a triple crimping. The thickness of the container body 2 is denoted e and that of the bottom 1 is denoted e ', which in the following description will be considered as equal.

The preformed bottom 1 is forcibly engaged on a rotary mandrel 8 which comprises an end wall 8A connected by a curved connection portion 8B to a side wall cylindrical 8C. The transverse central wall 5 of the bottom 1 bears against the end wall of the mandrel 8A and the skirt 6 of the bottom 1 is tightly engaged on the cylindrical side wall 8C of the mandrel 8. For this purpose the side wall 8C of the mandrel 8 can be knurled in view of increasing the driving contact between it and the adjacent skirt 6. The annular connection zone 6A is' normally out of contact with the annular connection portion 88. The base 1 thus rests on the mandrel in the manner of a hat on board resting on a head.

Then the container body 2 is received on the bottom 1, the edges 3 and 7 overlapping, the connection zone connecting the rim 3 to the container body 2 coming into centering contact with the skirt 6 of the bottom 9A, close of the junction of the side wall 8C with the curved connection portion 8B. The free edge 9B of the rim 3 of the container body bears against the bottom rim 7 in a circle offset inwards relative to the free edge of the rim 7 of the bottom.

The crimping operation is carried out by displacement of the crimping tool or wheel 8 'radially inwards against the edges ⁷ and ³ of the bottom 1 and of the container body 2 while rotating the mandrel 8. Due to the configuration of the 'or crimping tools 8' a triple crimping bead of suitable conformation is obtained as shown in Figure 2, the flanges 7 and 3 being wound against the outer face 2A of the end of the container body 2 and the bottom skirt 1 so as to define seven sheet thicknesses. When removing the crimping tool, the bead 4 elastically projects outwards relative to the lateral wall of the mandrel leaving an annular space in the form of a wedge between them (see FIG. 2), thus increasing the actual diameter of the resulting bead 4. The radial projection of this resulting bead 4 on the side wall of the container body is approximately 5 times the thickness e of sheet metal, that is to say 5th as shown.

In the various embodiments of FIGS. 3 to 14, the outside diameter of the resulting crimping bead is reduced during crimping.

In the first embodiment of the invention shown in Figure 3, we take a preformed container body 2 identical to that shown in Figure 1 and described above. The preformed bottom 11, for example in a press, is of a configuration different from that of the prior art. The bottom 11 has a hollow central transverse wall 15 connected by a concave curved annular zone of connection 16A to a frustoconical skirt 16 widening axially outwards, or downwards as shown, which is connected by an annular zone concave 16B to a flange 17 extending radially.

The bottom 11 is received on the mandrel 18 substantially as in the prior art. The lateral wall of the mandrel 18C widens axially outwards, or downwards as shown, with an angle α relative to the vertical axis of the mandrel (not shown). The side wall 16, as opposed to the illustrated prior art which provided a drive contact between the bottom and the mandrel, is radially separated from the side wall of the mandrel 18C. In the embodiment, the rotary drive contact of the base 11 by the mandrel 18 is obtained by close interlocking contact between the complementary connection zone 16A of the base and the connection zone 18B of the mandrel. Since the friction contact is ensured via the connection portion 18B of the bottom 11, it is possible to reduce the radius of the side wall of the mandrel 18C without reducing the radial dimension of the end of the side wall of the body container.

Figure 4 illust-- a bead or bead 14 of triple crimping finished with seven layers or thicknesses of bottom sheet or container body after the crimping tool 8 'has been partially withdrawn in its recoil movement towards the position starting point (not shown). It will be understood, as is described in more detail with reference to FIGS. 5A, 5B, and 5C, that during crimping, the frustoconical skirt 16 is deformed into a substantially cylindrical configuration, as shown, due to the action of 'drive radially inward of the crimping tool 8'. At the end of the radial inward movement of the crimping tool 8 ', the internal surface of the skirt 16 bears completely against the tapered side wall 18C of the mandrel. When removing 1 seassage tool 8 ′ the elasticity of the sheet causes a slight withdrawal radially outward from the triple crimping bead 14 completed, out of contact with the tapered side wall 18C, as shown in Figure 4.

As noted above in connection with the prior art, the elastic withdrawal of the bead inevitably increases the resulting radial projection of this bead. Thanks to the tapered side wall 18C of the mandrel according to the invention, it is possible to further reduce the radial projection of this bead, the resulting skirt 16 of the bottom returning to a generally cylindrical configuration after elastic withdrawal. The angle α of taper of the lateral wall of the mandrel 18C is chosen so as to allow relatively easy disengagement of the mandrel after crimping. For this purpose, the taper angle α can preferably go up to 5 °, and is advantageously of the order of 3 °. The mandrel 18 can also. be equipped with an extraction device generally used in the prior art so as to facilitate the withdrawal of the mandrel _ from the bottom of the container.

Due to the combination of the tapered side wall of the mandrel 18C and the increased radial space between the inner surface of the container body 2 and the side wall 18C of the mandrel, the resulting radial projection of the finished triple crimp bead 14 relative to at the outer surface 2A of the container body is approximately four times the thickness e or e 'of the bottom sheet 11 and of the container body, that is to say approximately once the sheet thickness in less compared to the conventional triple crimp bead of FIG. 2.

Figures 5, 5A, 5B, 5C, 5D, 6 and 7 show a second embodiment of the intention. Again the starting preformed container body 2 is the same as in the prior art of FIGS. 1 and 2. The bottom 21 is of a different configuration and comprises in the connection zone between the frustoconical skirt 26 flaring towards the bottom as shown and the hollow transverse central portion 25 a plurality of ribs 22 regularly or irregularly spaced in circumferential direction offset radially inward and axially inclined (see Figures 5 and 7). The face turned radially towards the interior of these ribs 22 is curved in the plane of FIG. 5 so as to match the curvature of the curved convex connection portion 28B of the mandrel 28.

Due to the radial depth of the ribs 22 in the arrangement of the embodiment of FIG. 5, the rest of the frustoconical skirt 26 of the bottom 21 is more apart from the side wall 28C of the mandrel, which, as in the mode embodiment of Figure 4, is tapered down as shown. The annular contact zone 29A between the frustoconical skirt 26 and the adjacent portion of the container body 2 is likewise more radially spaced with respect to the lateral wall of the mandrel 28C.

The contact zone between the mandrel 28 and the bottom 21 is circumferentially interrupted and alternates with the non-ribbed curved zones of connection between the container body 2 and the bottom 21. This arrangement is satisfactory with regard to the engagement contact necessary for a rotation without sliding of the bottom 21 on the mandrel and a centering of the container body 2 on the bottom 21.

As shown in FIG. 5D and in accordance with another aspect of the invention, such preformed bottoms 21 are easily stackable. Due to the arrangement of the embodiment of FIG. 5, the circumferentially alternating ribs 22 are adapted to come into contact with the convex face of the curved connection zone 26A 'of the underlying bottom 21'. In this way the central portions 25 and 25 'are axially spaced from one another as are the flanges 27 and 27'. It will immediately be appreciated that this arrangement facilitates the manipulation of the preformed bottom and avoids the problems which traditionally arose in the prior art. Obviously, for the aforementioned reason, it is preferable to choose the circumferential dimension of the ribs to a value greater than that of the non-ribbed curved connecting zones with which they alternate. Therefore, regardless of the angular orientation, there is a high probability of contact between the inclined ribs 22 and the underlying non-ribbed curved areas of connection 26A '.

The crimping procedure will now be described in more detail with reference to FIGS. 5A, 5B and 5C.

FIG. 5A shows a first step in the formation of a triple crimping cord, in which a first crimping tool 8 "is moved radially inwards so as to form an annular hook 17A, and the entire portion radially outer side 27 is brought above the free edge of the rim 3 of the container body.

After this first step, another crimping tool 8 'winds both the flanges 3 and 27 one on the other and at the same time brings the skirt of the bottom 26 and the long radius connection zone of the container body. radially inwards against the side wall of the mandrel 28C as shown in FIG. 58.

When the radial displacement of the crimping tool 8 continues, the winding of the edges 3 and 27 is continued until it forms a tight winding in which the free edge portions are nested one inside the other as well as 'it is shown in Figure 5C. At the same time, the skirt 26 of the bottom 21 is "flattened" against the side wall of the mandrel 28C.

When removing the crimping tool 8 '(see FIG. 6), the entire bead 24 tends to spring back slightly radially outward due to the inherent resilience of the skirt 26 and the adjacent end portion of the container body 2 so as to provide a small annular space in the form of a wedge between the radially internal wall of the bead and the facing portion of the lateral wall of the mandrel 28C.

Due to the presence of the radial ribs 22 it is possible to further reduce the radial projection of the final bead to approximately three times the thickness e of the sheet, as shown in FIG. 6. The initial ribs 22 are flattened in the skirt area against the side wall of mandrel 28C and remain only, after crimping, in the curved connection area.

Another embodiment will now be described with reference to Figures 8 and 9. Figure 8 shows a preformed bottom 31 engaged on a mandrel 38 and a preformed container body 32. In this embodiment, the radius of curvature Rl of the connection zone between the side wall of the container body 32 and the rim 33 of the container body is smaller than in the abovementioned embodiments. The bottom 31 comprises a hollow transverse central portion connected by a curved annular connection zone 36A to a frustoconical skirt 36 which widens radially outwards, or downwards, with a half angle at the top which is greater than that of the skirts 16 and ^26, this skirt being followed halfway between the central zone 35 and the rim 37 by a curved connection zone having a radius R2. The connection zone of the container body 32 of radius R1 is fitted into the radius connection zone R2 of the bottom 31 due to an appropriate choice of these radii. In practice, the radius R2 is slightly larger than the radius Rl. The container body 32 is in contact with the bottom 31 by the free edge of the container end rim 33 and in centering contact at 39A near the zone of infection between the frustoconical skirt 36 and the convex radius connection zone R2.

The crimping is carried out as described above and the triple crimping bead thus obtained is shown in FIG. 9. The radial projection of the resulting triple crimping bead 34 beyond the nominal radius of the side wall 32A in this mode of realization is approximately two to three times the thickness e of the sheet. Incidentally, it should be noted that the particular configuration of the skirt _{of 'background} préfnrmé March ¹ (Figure 8) allows the side wall of the container body to be spaced from the side wall of mandrel 38C over a distance substantially equal to that of the previous embodiment and leads to a crimping bead whose radial projection is equivalent to that of FIG. 6.

In Figures 10 and 11, the base 41 and the container body 42 are both of different configurations relative auxmodesprécédent _s embodiment.

First of all, the general shape of the bottom 41 is substantially the same as in FIG. 3 and includes a hollow transverse central portion 45 connected to a tapered flared skirt 46 by a concave curved zone 46A, this tapered skirt 46 being in turn connected to a flange 47 extending radially outwards by a convex connection zone. The bottom 41 of FIG. 10 differs from that of FIG. 3 by a larger angle of flaring of the skirt 46 relative to the skirt 16.

The container body 42 includes a cylindrical side wall and a radial rim 43 at the end of an annular connection zone, as in the previous embodiments.

A groove 428 turned radially outwards, of cross section at C, comes into contact with the bottom 41 in the infection zone 49A between the concave connection zone 46A and the frustoconical skirt 46. It will be noted that, although the wall side of the container body 42 is substantially spaced radially from the mandrel side wall 48C, the drive contact area 49A is virtually at a minimum spacing from the mandrel side wall and carries directly through the bottom against the mandrel 48.

The resulting triple crimp bead 44 is shown in Figure 11. The radial projection of this bead 44 relative to the nominal wall of the container body 42A is about 2 to 3 times the thickness of the sheet.

At the location of the axially internal, or upper flank of the groove 42B, there remains an oblique annular portion which is shaped by the oblique upper face of the crimping tool 8 "'at the end of the movement towards the axis of the crimping tool.

Figures 12 and 13 show a final embodiment for the formation of a triple crimping bead of reduced radial projection according to the invention. The side wall and the rim 33 of the container body are substantially as in FIGS. 8 and 9, with a connection zone with a relatively small radius. The preformed bottom 51 comprises a hollow transverse central portion 5.5 which is surrounded by a concave annular zone. 56A connection in intimate contact with the curved connection area 58B of the end wall of the mandrel and with the side wall of the mandrel 58C. Halfway axially between the radial rim 57 of the bottom 51 and the central portion 55 is formed an annular step 52 which increases in diameter from the concave connection area 56Towards the convex connection area of the bottom 51. The contact area 59A between the bottom 51 and the container body 32 is the radially outermost part of the step 52. The annular step 52 is slightly frustoconical and widens radially and axially outwards, or downwards as shown.

The bead resulting from the triple crimping 54 is similar to that shown in FIG. 9. Here again the radial projection of the bead beyond the nominal wall of the container body is between two to three times the thickness e of the sheet .

FIG. 14 shows the principle of the present invention applied to the assembly of a bottom 61 at the end of a container body 62 with a conventional double crimping bead 64. The double crimping tool 8 "" is classic. The mandrel 68 has a wall 68C tapered axially outwards, or downwards, which, before crimping, is radially spaced relative to the side wall of the container body over a distance greater than the thickness of the bottom 61 thus that he is represented in one any of the previous embodiments. Obviously, the lengths of the edges of the preformed container body and of the preformed bottom are to be dimensioned in accordance with a double crimping. The radial projection of a double crimping bead 64 relative to the nominal side wall of a container body 62A is practically zero and for this reason allows optimum storage capacity for drums in a given space. The double crimping 64 can be adapted in certain uses although the person skilled in the art may prefer a triple crimping barrel because of the reinforced resistance of the bead which is associated with it.

Although several preferred embodiments have been described and illustrated above, it will be understood that the variants and other embodiments can be used to form crimp beads having projections or reduced radial projections relative to the side wall. nominal of the container body. In all cases, the effective diameter of the bead is reduced during crimping, a sufficient radial space is provided between the side wall of the mandrel and the side wall of the container body so as to allow such a reduction in the final diameter of the barrel or similar.

It will be appreciated by those skilled in the art that the manipulation of the barrel or of other containers assembled in accordance with the invention by means of appropriate gripping devices cooperating with the crimping bead may be. Unchanged compared to the practice of the art prior.

In this regard, the frustoconical zone formed in the side wall of the container body spaced axially inwards relative to the crimping cord may prove to be beneficial.

Although the side wall of the container body described above is generally cylindrical, the present invention is easily applicable to container bodies of different sections, for example polygonal, in particular.

The preformed bottoms and the container bodies described above are preferably obtained as illustrated by stamping operations well known in the art prior.

In fact, very generally, the present invention relates to a sealing method by crimping and constricted from one end of a ferrule by a crimped bottom as well as a crimped bottom suitable for the implementation of this method.

Claims (20)

1. Method for assembling a bottom to a container body by crimping to each other bottom flanges and container body, according to which a preformed bottom is produced (11, 21, 31, 41, 51) having a hollow transverse central portion, a skirt (16, 26, 36, 46, 56) extending axially from this central portion, and a flange (17, 27, 37, 47, 57) s' extending radially outward from this skirt, as well as a preformed container body (2, 32, 42, 62) having a side wall and a rim extending radially outward from the side wall of the container body, the bottom is fitted onto a mandrel (18, 28, 38, 48, 58) in drive contact with the latter, the container body is engaged on the bottom in centering contact, their edges being in reciprocal contact, and a crimping tool (8 ', 8 ", 8"', 8 "") is moved radially inward so as to wind the edges into a crimping bead, characterized in that it ela boron the preformed bottom (ll, 21, 31, 41, 51) so that its skirt extends both axially and radially from the central portion, so that this bottom skirt is radially spaced from to the side wall of the mandrel, and when the crimping tool is moved radially inward, this bottom skirt is deformed against the side wall of the mandrel thereby reducing the radial projection of the resulting crimp bead relative to the wall side of the container body. 2. Method according to claim 1, according to which the central portion of the bottom is connected to its skirt by a concave annular connection zone (16 A, 26 A, ...) and the mandrel has a connection portion (18 A, 28 A, ...) between its side wall and its end wall which is complementary to that of the concave annular area of connection of the bottom, said drive contact being obtained by contact between the connection area of the bottom with the area of chuck connection. 3. Method according to claim 1 or claim 2, characterized in that the radius of the side wall of the container body at the crimping bead is less than the nominal radius of the side wall of the container body axially inside the bottom. 4. Method according to any one of claims 1 to 3, characterized in that, during the movement of the crimping tool, the radius of the side wall of the container body at the crimping bead is reduced relative to the rest of the side wall of the container body. 5. Method according to any one of claims 1 to 4, characterized in that there is further formed, during the approximation of the crimping tool, a tapered area in the side wall of the container body substantially at the central portion of the bottom. 6. Method according to any one of claims l _. to 5, characterized in that the skirt of the preformed bottom widens axially outward between the central hollow portion and the rim. 7. Method according to any one of the preceding claims, characterized in that the skirt of the preformed bottom (51) has an annular step substantially halfway axially between its central portion and its rim. 8. Method according to any one of claims 1 to 6, characterized in that the skirt of the preformed bottom is frustoconical is connected to the central portion by a concave connection zone and to the flange by a convex connection zone. 9. Method according to any one of claims 1 to 5, characterized in that a portion of the skirt of the preformed bottom is frustoconical and connected to the central portion of the bottom by a concave connection zone and to the edge by a convex zone connection, the infection (39A) between the frustoconical portion and the convex connection zone defining a contact zone for centering the container body relative to the bottom. 10. Method according to any one of claims 1 to 6 or claim 8, characterized in that a plurality of ribs (22) are spaced apart circumferentially, offset radially inwards and axially inclined in the bottom, between the skirt and the central portion, so as to provide a drive contact between the mandrel and the preformed bottom along the surface facing radially inward of its ribs. 11. Method according to any one of claims 1 to 6, characterized in that the preformed bottom comprises a plurality of circumferentially spaced zones formed between the central portion and the skirt for the purpose of driving contact with the mandrel . 12. Method according to any one of claims 1 to 6 or 8, characterized in that the centering of the container body relative to the bottom is obtained by an annular groove (42B) formed in the side wall of the container body nearby from the axially internal end of the skirt. 13. The method of claim 12, characterized in that a portion of the groove (428) defines after crimping an annular step in the side wall of the container body, between the end of the side wall of the container body where the crimping bead is obtained and the rest of this side wall. 14. Method according to claim 8 or any one of claims 10, 11 or 12 made dependent on this claim 8, characterized in that the convex connection zone comes into contact with the side wall of the mandrel before the skirt is deformed against the side wall of the mandrel at the end of the radial movement towards the inside of the crimping tool. 15. Method according to any one of the preceding claims, characterized in that the mandrel has an end wall, and a lateral wall of mandrel which tapers axially outwards from this end wall. 16. Method according to claim 15, characterized in that the taper angle. of the lateral wall of the mandrel relative to the axis of this mandrel is of the order of at most 5 °. 17. The method of claim 15 characterized in that the taper angle of the side wall of the mandrel relative to its vertical are is about 3 °. 18. Preformed bottom adapted to be crimped to a container body according to the method according to any one of Claims 1 to 17, of the type comprising a hollow transverse central portion, a skirt extending axially from this central portion, a concave annular connection zone connecting this central portion to said skirt, then a rim extending radially towards the exterior from this skirt away axially from this central portion ^, characterized in that the skirt (26) extends both axially and radially from the central portion and that a plurality of stampings inwardly projecting recesses (22) are formed in the concave connection zone so as to come into contact with a corresponding connection zone of a crimping mandrel for the purpose of rotating this bottom (2 ¹ ) by the mandrel, these stampings can also come into contact with the convex face of the connection zone of an underlying bottom (21 ′) identical in interlocking relationship so that the edges of this bottom and of the bottom under -jacent be axi Also spaced from each other so as to facilitate their separation and handling. 19. Preformed bottom according to claim 18, characterized in that these stampings are circumferentially spaced from one another in this connection zone. 20. preformed base according to claim 18, characterized in that these stampings are axially inclined ribs (22) which extend from the central zone in the skirt until approximately halfway between the central portion and said ledge.

Images