EP0075287A2 - Apparatus and method for the series production of a valve mounting cup provided with a gasket for an aerosal container, and such a valve mounting cup - Google Patents

Abstract

1. Method for the mass production of an aerosol container mounting cup (10; 34; 98; 118; 234; 242) bearing a gasket (26; 30; 116; 230; 244; 292), the mounting cup having a cross panel (12; 113), an axial sidewall (14) surrounding the periphery at the cross panel and an annular channel (18; 294) extending outwardly from the sidewall, comprising a) forming a band (26; 30; 116; 230; 244; 292) of gasket material on the sidewall (14) of the mounting cup, which band extends above the cross panel (12; 113) of the cup, b) initially advancing the band of gasket material onto the widewall of the mounting cup to a first position, in which the gasket material distal from the annular channel of the mounting cup is positioned at or below the periphery of the cross panel (12; 113) of the mounting cup, c) heating the band of gasket material and d) then advancing the band of gasket material to its ultimate position on the mounting cup and simultaneously causing a deformation of the gasket material, characterized in that during the deformation accumulations of the gasket material are being produced at different positions.

Description

The invention relates to a device, a method and a mounting cap according to the preambles of claims 1, 3, 14 and 16.

Aerosol dispensers are widely used in the packaging of fluid materials, including a variety of both liquid and powder products. These containers are provided with a valve-controlled dispensing opening and are operated by a volatile propellant, which is contained in the container together with the product to be dispensed. Since the propellant has a considerable vapor pressure at room temperature, the generation in the closed container is under a pressure above atmospheric pressure.

A typical aerosol unit has a hollow cylindrical container that is sealed at one end and has an opening for receiving a dispensing valve at its opposite end arrangement is provided. A lid referred to as a mounting cap serves as a closure for the container and as a carrier for the valve arrangement. The mounting cap usually has a transverse wall with an opening for receiving the valve arrangement, a side wall depending on the peripheral edge of the transverse wall (or projecting upwards) and an annular channel projecting outwards from the edge of the side wall. When the mounting cap is placed tightly on the container, the channel overlies the flange edge surrounding the container opening and the lower portion of the side wall near the channel is flared outwardly against the container wall near the flange edge. In order to ensure a sufficient seal between the closure and the container, the cap is provided with a seal which can be arranged in the ring channel or predominantly in the ring channel of the cap.

So far, the seals of the mounting caps have first been cut and then arranged in the channel. This type of seal has the disadvantage that it does not remain stationary relative to the mounting cap during the filling of the propellant or the mounting of the valve unit, so that when the mounting cap and container are clamped or squeezed together to effect the seal, the seal (the sealing ring ) is often shifted to an inclined position, so that clamping or squeezing is less effective.

Another conventional method of forming the seal uses a liquid sealant which has an elastomer dispersed or dissolved in a volatile organic carrier liquid. In forming this seal, the liquid medium is placed in the desired shape in the channel of the cap while the cap is rotated under a metering nozzle through which the agent flows. The precipitate is then cured to a dry solid sealant by heating the carrier liquid. Although this method of injecting sealing rings at the desired installation location is used commercially to a large extent, it has the disadvantage that an expensive drying process is required, in which the mounting cap must be handled carefully in order to avoid undesirable build-up from the horizontal plane. Then an expensive recovery device for the expelled (vaporized) organic liquid is required. Overall, injecting the seal is an expensive process step in the manufacture of the mounting cap. As an example of the injection of a seal, reference is made to US Pat. No. 3,342,381.

Other methods of applying a seal to the mounting cap are described in U.S. Patent No. 3,417,177, in which the sealing ring is made from a heat shrinkable material. After a band of sealing material has been applied to the side wall, the diameter of the sealing ring being larger than the outer diameter of the side wall. Mounting cap, the mounting cap is heated so strongly and until the band is shrunk onto the side wall until a tight friction fit.

A similar process is disclosed in U.S. Patent 3,443,006, in which a band of sealing material is swollen using a swelling agent so that it increases in size until the band is firmly seated on the side wall of the mint cap. i.as the swelling agent is then from the seal material removed so that the tape comes into tight frictional contact with the side wall.

Both the shrinking and swelling processes for applying a sealing material to the mounting cap are expensive and relatively time consuming. So need to column 4, lines 27 to 31 of U.S. Patent No. 3,417,177 the bands two to three minutes are maintained at a temperature of 115.6 ⁰ C (240 ° F) long, in order to achieve a tight friction fit. According to Example 2 of US Pat. No. 3,443,006, the tapes must be placed in the swelling liquid for 0.5 to 1.5 minutes and then dried for a long time. Furthermore, a device for recovering the organic liquid must be used in every series production in which this method is used.

Furthermore, US Patent Application 112,791 (filed February 1, 1980) describes an apparatus and method for applying a sealing ring to a mounting cap, in which the sealing material is applied in the preferred position on the mounting cap to a Sealing between the mounting cap and the flanged edge of the container, and the disadvantages of the aforementioned methods are avoided. The sealing rings are applied extremely quickly and effectively to aerosol container mounting caps.

The method specified in this US patent application 112 791 essentially consists in that a tubular sleeve or a tube made of sealing material is applied to a compressible mandrel; that first the side wall of the mounting cap and the adjacent end of the mandrel are aligned with each other be that the sleeve of sealing material can be pushed over the side wall, the mandrel having fixed and movable parts relative to each other and to their movement towards the mounting cap and away from it; that the movable part of the mandrel carrying the sealing material is pressed towards the mounting cap in such a way that the sealing material is pushed over the side wall of the mounting cap; that the movable part of the mandrel is withdrawn in its initial position and the sleeve is cut between the mounting cap and the mandrel, so that a band of sealing material remains; and that the mounting cap is then conveyed to a station in which the band of sealing material is pushed further over the side wall of the mounting cap so that the band of sealing material does not protrude beyond the side wall of the mounting cap. In this state, the mounting cap provided with the seal can be processed further.

In certain applications of the sealing cap according to the US patent application 112 791, namely when using the mounting cap during the so-called 'under the cup "filling of the propellant into the container, it has been shown that the sealing tape is occasionally filled when filling the mounting cap It has also been found that with a significant number of mounting caps, the tape of sealing material moves out of its installed position in the channel or flanged part of the mounting cap before the mounting cap is crimped onto the container. Both night shrouds reduce productivity in series production,

to improve the generic type specified in US patent application 112 791, in particular in that it prevents the seal from slipping or shifting from or on the mounting cap.

The solutions to this problem are characterized in claims 1, 3, 14 and 16. Further developments are specified in the subclaims.

An essential feature of the invention is that one or more compression deformations are formed in the band of sealing material.

• Fig. 1 eine Schnittansicht einer nach dem Verfahren und mittels der Vorrichtung, die in der US-Patentanmeldung 112 791 angegeben sind, mit einer Dichtung versehene Montagekappe für einen Aerosolbehälter,
• Fig. 2A bis 2F eine schematische Darstellung eines Beispiels der nach der US-Patentanmeldung 112 791 angewandten Verfahrensschritte beim Aufbringen des Dichtungsmaterials auf einer Aerosolbehälter-Montagekappe,
• Fig. 3 eine perspektivische Ansicht der Vorrichtung nach Fig. 2 zusammen mit der Vorrichtung, die bei einer zweiten erfindungsgemäßen Maßnahme mit dem Erzeugnis nach Fig. 2 verwendet wird,
• Fig. 4 den Schnitt 4-4 der Vorrichtung nach Fig. 3,
• Fig. 5 den Schnitt 5-5 der Vorrichtung nach Fig. 3 bei Anwendung der zweiten Maßnahme mit dem Erzeugnis nach Fig. 2,
• Fig. 6 ein Zeitdiagramm des Ablaufs eines einzigen Zyklus der Herstellung der Montagekappe nach Fig. 2,
• Fig. 7 eine perspektivische Ansicht eines zweiten Ausführungsbeispiels der Erfindung, die
• Fig. 8 und 9 Ansichten der Vorrichtung nach Fig. 7 in verschiedenen Betriebsphasen, und zwar einerseits in einer Anfangslage und andererseits in einer vorgeschobenen Lage relativ zur Montagekappe,
• Fig. 10 eine Teilschnittansicht der Vorrichtung, die zum Vorschieben des Bandes aus Dichtungsmaterial in seine endgültige Lage auf der Montagekappe erfindungsgemäß verwendet wird, wobei die Vorrichtung im relativ zur Montagekappe nicht vorgeschobenen Betriebszustand dargestellt ist,
• Fig. 11 die Vorrichtung nach Fig. 10 im relativ zur Montagekappe vorgeschobenen Betriebszustand,
• Fig. 12 eine vergrößerte Darstellung des Kreisausschnitts der Fig. 11,
• Fig. 13 eine perspektivische Darstellung der erfindungsgemäBen mit einer Dichtung versehenen Montagekappe,
• Fig. 14 eine schematische Darstellung einzelner Verfahrensschritte oder Stationen des erfindungsgemäßen Verfahrens der Herstellung einer mit einer Dichtung versehenen Montagekappe,
• Fig. 15 einen Teilschnitt der bevorzugten Vorrichtung, die verwendet wird, um das Band aus Dichtungsmaterial so weit auf die Montagekappe aufzuschieben, daß das Ende des Dichtungsmaterials auf dem geraden Teil der Seitenwand der Montagekappe liegt,
• Fig. 16 eine perspektivische Ansicht eines der flexiblen Finger der Vorrichtung nach Fig. 15, die
• Fig. 17 und 18 die Querschnitte 17-17 und 18-18 der Fig. 15,
• Fig. 19 den Querschnitt 19-19 der Fig. 15,
• Fig. 20 einen Teilschnitt der bevorzugten Vorrichtung, die zum Vorschieben des Dichtungsmaterials in seine endgültige Lage auf der Montagekappe verwendet wird,
• Fig. 21 einen vergrößerten Teilschnitt der Stempelhülse nach Fig. 20, der Montagekappe und des Dichtungsmaterials in der vollständig vorgeschobenen Lage der Stempelhülse und
• Fig. 22 eine Draufsicht auf ein Teil einer Zentriereinrichtung.

The invention and its developments are described in more detail below with reference to the drawings, which represent preferred exemplary embodiments. Show it:

• 1 shows a sectional view of a mounting cap for an aerosol container provided with a seal by the method and by means of the device which is specified in US patent application 112 791,
• 2A to 2F show a schematic illustration of an example of the method steps used according to US patent application 112 791 when applying the sealing material to an aerosol container mounting cap,
• 3 shows a perspective view of the device according to FIG. 2 together with the device used in a second measure according to the invention with the product according to FIG. 2,
• 4 shows the section 4-4 of the device according to FIG. 3,
• 5 shows the section 5-5 of the device according to FIG. 3 when using the second measure with the product according to FIG. 2,
• 6 is a timing diagram of the sequence of a single cycle of manufacturing the mounting cap of FIG. 2,
• Fig. 7 is a perspective view of a second embodiment of the invention, the
• 8 and 9 views of the device of FIG. 7 in different operating phases, on the one hand in an initial position and on the other hand in an advanced position relative to the mounting cap,
• 10 is a partial sectional view of the device which is used according to the invention for advancing the band of sealing material into its final position on the mounting cap, the device being shown in the operating state not advanced relative to the mounting cap,
• 11 shows the device according to FIG. 10 in the operating state advanced relative to the mounting cap,
• 12 is an enlarged view of the circular section of FIG. 11,
• 13 is a perspective view of the mounting cap provided with a seal according to the invention,
• 14 shows a schematic illustration of individual method steps or stations of the method according to the invention for producing a mounting cap provided with a seal,
• 15 is a partial section of the preferred device used to push the tape of sealing material onto the mounting cap until the end of the sealing material lies on the straight portion of the side wall of the mounting cap.
• 16 is a perspective view of one of the flexible fingers of the device of FIG
• 17 and 18 the cross sections 17-17 and 18-18 of Fig. 15,
• 19 shows the cross section 19-19 of FIG. 15,
• 20 is a partial section of the preferred device used to advance the sealing material into its final position on the mounting cap.
• Fig. 21 is an enlarged partial section of the stamp sleeve according to Fig. 20, the mounting cap and the sealing material in the fully advanced position of the stamp sleeve and
• 22 is a plan view of part of a centering device.

FIG. 1 shows the mounting cap 10 provided with a seal in the opposite position to its arrangement on the assembled aerosol container The mounting cap has a circular transverse wall 12 with a circumferential side wall 14 integrally formed on its peripheral edge. The free edge 16 of the side wall 14 is bent radially outward so that it forms an annular channel 18 which, after attachment to a not shown Aerosol container which surrounds the opening edge. The inner part of the transverse wall 12 is sunk so that it forms a tubular rim or pot 20 which has a cylindrical wall 22 which is integrally connected to a perforated horizontal wall 24. If the mounting cap 10 is connected to the aerosol container, the pot 20 acts as a base for a valve unit, the valve stem of which projects through the perforated wall 24 into the container. An annular seal 26 is arranged on the outside of the side wall 14, which runs over the junction of the side wall 14 and the channel 18 and extends into the channel.

2A to 2F, corresponding parts are given the same reference numerals as in Fig. 2A. These figures represent schematically the relative position of the moving parts of a device for pushing a sealing material made of plastic onto the mounting cap and cutting off the tubular sealing material, so that a band of sealing material results on the side wall of the mounting cap, in different operating states or operating phases.

Base of the mounting cap 34 projects a positioning pin 38, which ensures a fixed distance between the underside 40 of the mandrel 32 and the mounting cap 34. The mandrel 32 has an upper part 42 and a lower part 44 which are axially displaceable relative to one another and can be separated. Its structure is described in more detail with reference to FIG. 4. The upper part 42 of the mandrel is surrounded by an upper gripping or clamping part 46 and the lower part 44 by a lower gripping or clamping part 48.

In the initial phase of an assembly cycle shown in FIG. 2A, the mandrel 32 is arranged on the positioning pin 38 and covered with the sealing material up to its underside 40. Both clamping parts 46 and 48 are open.

In the operating phase of FIG. 2B, the upper clamping part 46 is closed around the mandrel 32, and then it pushes the upper part 42 of the mandrel 32 towards the mounting cap 34. This seals the sealing material 30 over the fixed bottom 40 of the mandrel 32 pushed out. The lower clamping part 48 is open.

According to FIG. 2C, the sealing material is first pushed onto the side wall of the honing cap 34 in the desired length and then the lower clamping part 48 is closed around the lower part 44 of the mandrel 32.

2D, the upper clamping part 46 is opened so that the upper part 42 of the mandrel 32 can return to its initial position. At the same time, the positioning pin 38 is lowered under the mounting cap 34, and then

a cutting edge 50 (only shown in FIG. 2D) is passed through the sealing material 30.

2E illustrates a mounting cap with a band of sealing material 30 on the side wall of the mounting cap.

In the next phase of FIG. 2F, the lower gripping part 48 is closed around the lower part 44 of the mandrel 32 and the positioning pin 38 is pushed into the position shown in FIG. 2A, and then the gripping part 48 is opened so that the system 2A is in the initial phase.

3 shows a mounting device with six stations for applying the seals to a mounting cap. The sealing material 30 is unwound from individual supply rolls (not shown). The upper clamping part 46 has a series of openings 52 which receive the mandrel 32. With 48 the lower gripping part is designated. The mounting cap 34 is conveyed along a track 54 under the individual mandrels. The known conveyor device provided for this purpose is not shown. It conveys a predetermined number of mounting caps, here six, along the track 54 vertically under one of the mandrels. In the time diagram according to FIG. 6, parts of this conveying device are designated as conveying fingers, conveying arms and locators. The cutting edge 50 is mounted on a rotating wheel 56 so that it moves on an elliptical path during its back and forth movement during a cutting cycle. After the sealing material 30 has been pushed over the mounting cap, it is conveyed to a station in which a stamp 58 with a hollow bottom, which is shown in more detail in FIG the side wall of the mounting cap is pushed and the sealing material 30 moves along the side wall.

Fig. 4 illustrates the construction of a single mandrel mounting cap station of the embodiment of Fig. 3 in more detail. The upper part 42 of the mandrel 32 has a tip 60 which is screwed onto the upper part 42 and the pushing of the sealing material onto the mandrel 32 relieved. Furthermore, the upper part 42 of the mandrel 32 has a cavity 62 in which a spring 64 is arranged. 2A to 2F can be seen most clearly, the upper part 42 of the mandrel 32 is provided at the lower end with a plurality of fingers 68 and the lower part 44 of the mandrel 32 at the upper end is provided with a plurality of recesses 70 which are oriented in such a way that that they pick up the fingers 68 when the upper part of the mandrel 32 is moved towards the lower part of the mandrel.

The upper clamp member 46 is a conventional chuck which is attached to a reciprocating plunger or ram so that it can be quickly moved towards and away from the mounting cap and when the upper part of the Dorns has pinched, can move this part towards the mounting cap.

The lower gripping part 48 is also a conventional clamping device.

The cutting edge 50 is mounted in a conventional manner and describes an elliptical path when it moves back and forth relative to the mounting cap 34.

5 shows a reciprocating stamp 104, the lower outer shoulder of which rests against the upper edge of the sealing material and pushes it further over the side wall of the mounting cap. The punch 104 has a hollow lower portion 106 that ends in a shoulder 108. A spring-loaded centering pin 110 with a projection 112 is arranged within the lower part 106. The projection 112 has a bevelled end portion 114 which fits into the mounting cap 34 and centers it by abutting the conical transverse wall 113.

5 is to push the band of sealing material so far onto the mounting cap that it lies at or below the conical surface 113 of the mounting cap 34. The purpose of this arrangement of the sealing tape is that a tape edge is supported by the straight part 115 of the side wall of the mounting cap 34 and thereby occupies such a position that it moves with the stamp at the second and last stamp displacement to advance the tape of sealing material into it final position on the mounting cap comes to rest.

FIG. 6 describes the timing of an operating cycle of the device shown in FIG. 3. In Fig. 6, the "clamp" is the clamping part, the "pins" are the positioning pins, the "conveying finger" and "conveying arm" are parts of a conventional conveying device for conveying six assembly caps per cycle into the respective position for assembling the sealing material.

A second embodiment of the mandrel clamping part arrangement is shown in FIGS. 7 to 9. This exemplary embodiment has the advantage of a simple construction, in which a positioning pin which passes through the central opening of the mounting cap is omitted. 7, the sealing material 30 is pushed over a mandrel 80. The mandrel has an upper portion 82 and a lower portion 84, the lower portion having a recessed portion 86 and an upper extension 88 which extends through the upper portion 82 and the upper extension 88 resiliently at the top of the portion 80 supports. The upper clamping part 90 has upper and lower groups of rollers 92 and 94 which bear against the upper mandrel part 82 in such a way that they prevent displacement of the mandrel part 82. The lower clamping part 96 is designed in a conventional manner as a clamping device and has means, not shown, for moving the lower clamping part back and forth relative to the mounting cap. The mounting cap 98 is fastened in a holding device on a base or base plate 100.

Fig. 9 shows the mandrel-clamping part arrangement of the embodiment of FIG. 7 in the initial position, from which the sealing material is pushed onto the mounting cap. The sealing material 30 protrudes a short distance, preferably about 1/4 "in length, beyond the lower portion of the mandrel portion 84. In the phase of Fig. 9, the lower clamp portion 96 is around the mandrel portion 84. While the lower clamping part 96 is being pushed downwards towards the mounting cap 98, the sealing material 30 is pushed over the side wall of the mounting cap, the sealing material being such that it moves between the rollers 92 during the advance movement of the mandrel part 84 and 94 of the upper clamping part 90. After the you tion material has been pushed over the side wall of the mounting cap, the lower clamping part 96 is opened and the mandrel part 84 is returned to the starting position shown in FIG. 8. Then a new cycle can begin. After the resetting of the mandrel part 84, the cutting edge 102 is advanced and the sealing material is cut through. The mounting cap is then conveyed to a station (see FIG. 5), in which the sealing material 30 is pushed further over the side wall of the mounting cap. Instead of the single mandrel according to FIGS. 7 to 9, a plurality of mandrels and clamping parts can also be used, as in the exemplary embodiment according to FIGS. 2 to 5.

After the initial feed of the tape of sealing material onto the side wall of the mounting cap, the mounting caps are conveyed under conventional guidance through a zone in which the tape of sealing material is heated by conventional heating devices. In this zone, the mounting cap can be passed indirectly through an insulated hot water system, the temperature of which can be controlled precisely to the desired value by a control device. Here, heating the mounting cap to a temperature of about 71 to 83 ° C (160 to 180 ° F) has proven beneficial.

The assembly caps provided with a seal are transported from the heating zone to a secondary or second stamping station. The stamp and its mode of operation in the secondary stamp station are described with reference to FIGS. 10 to 12.

10, the band 116 is in a Position in which it is initially pushed onto the side wall of the mounting cap 118. The stamp 120 according to FIG. 10 has an outer sleeve part 122, a head part 124, and a clamping part 126, which is fastened to a stamp feed device (not shown). The head part 124 and the sleeve part 122 delimit a cavity 128. Inside the cavity 128 there is a mounting cap stripping member 130 with slidably interlocking parts 132 and 134 and a mounting cap centering member 136 which is pressed away from the head part 124 by a spring 138. The part 132 of the mounting cap stripping member 130 is pressed away from the head part 124 by a spring 140. The part 134 of the mounting cap stripper 130 is pressed away from the part 132 by a spring 142.

The sleeve 122 has a lower part 144 with an annular shoulder 146 and an edge part 148. The annular shoulder 146 lies against the band of sealing material 116 and moves the band into its final position on the mounting cap 118.

The edge portion 148, the shape of which can best be seen from FIG. 12, has a projection 150 and a contour provided with a weak radius of curvature.

During operation, mounting caps 118 are placed in the secondary stamp station. The stamp 120 is then advanced in the direction of the mounting cap 118, the mounting cap being centered relative to the stamp 120 by the centering member 136. As FIG. 10 shows, the stripping member 130 is also brought into contact with the mounting cap. With a further feed movement of the stamp 120, the end of which is shown in FIG. 11, it lies down the sleeve 122 with its shoulder 146 on the band of sealing material 116, so that the band 116 is pushed further over the side wall of the mounting cap 118 to the end position shown in FIG. 11. As shown in Fig. 12, the feed movement of the sleeve 122 is terminated by the edge 148 of the sleeve 122 abutting against the wall 152 of the channel of the mounting cap 118, while at the same time an annular rib 154 in the band of sealing material 116 during the compression deformation the protrusion 150 pressing on the sealing material is formed. During the return of the plunger 120, the part 134 of the mounting cap stripping member is pressed against the mounting cap 118 by the spring 142 until the sleeve 122 lifts off the advanced seal, so that the mounting cap 118 is prevented from being raised by the returning sleeve 122. The springs 140 and 142 are dimensioned such that they allow the movement of the part 132 in the direction of the part 134 during the advance of the stamp 120.

The preferred stamps used in the secondary stamp station are described with reference to FIGS. 15 to 21.

15, the stamp 200 has a carrier 202 which is connected by conventional means to a reciprocating plunger (not shown). A link 206 can be telescoped in the bore 204 under spring loading. The telescopic member 206 ends in a slotted collar 220. Inside the member 206, a mounting cap centering device 208 is slidably mounted under spring load. The telescopic member 206 is surrounded by a slotted ring 210, in the slots of which fingers 212 are supported. Those in more detail in Fig. 16 The illustrated fingers 212 are attached to the carrier 202 by dowel pins 214. The fingers have grooves 216 (FIGS. 15 and 16) in which O-rings 218 are arranged which exert constant, inward pressure on the fingers 212. The fingers 212 are further arranged in slots 222 (FIG. 18) of the slotted waistband 220. A plate 224 is attached to the underside of the telescopic member 206, which forms a shoulder 226, on which the lower shoulder 228 of the fingers 212 rests when the stamp 200 moves forward. The length of the path that fingers 212 travel before striking shoulder 226 determines the distance that seal 230 is advanced onto side wall 232 of mounting cap 234. An outer, adjustable sleeve member 236 is screwed onto the slotted ring 210, which prevents the fingers 212 from spreading outward and thereby directs the underside 238 of the fingers 212 against the upper edge of the sealing material 230.

After the gasket is initially slid onto the mounting cap, the mounting cap and gasket are heated to a temperature of about 71 to 83 ° C (160 to 180 ° F) and then transferred to the last stamp station.

20 shows a stamp device 240 which initially centers the mounting cap 242 and pushes the seal 244 into its end position on the mounting cap 242. The stamp device 240 is attached to a support (not shown) which in turn is connected by conventional means to a reciprocating press (not shown). The stamp device has an insert member 250 with a central bore which delimits a chamber 252. At the insert member 250 is an inner Fixed sleeve 254, which has a flange 256 for connection to the insert member 250.

An outer sleeve 258 is connected to the inner sleeve 254 by a flange 260.

A centering device 262 with a spring receiver and stop 264, a rod 266, a piston 268, 0-rings 270 and a centering insert 272 is arranged in the inner sleeve 254 and the chamber 252.

A mounting cap wiper 274 is independently spring loaded and is disposed in the inner sleeve 254 and abuts a shoulder 276 of the inner sleeve 254. An opening 278 of the scraper 274 has a slot shape, as shown in Fig. 22 on a larger scale. The slot shape prevents the centering device from being removed from the stamp assembly, with the edge 280 of the spring retainer and stop 264 striking the surface 282 of the scraper 274. The end face 284 formed by the inner sleeve 254 and the outer sleeve 258 is most clearly shown in FIG. 21. The end face 284 of the outer sleeve 258 has a recess 286. The inner sleeve 254 is also provided with a shoulder 290 (FIG. 21).

During operation, the centering device 262 is pushed toward the mounting cap by passing compressed air into the chamber 252, this advance being in the initial phase of the downward stroke of the press. The compressed air flows through the slot of the scraper 274 and exerts a pressure on the piston 268, which is the restoring force of the Spring exceeds 288 and causes a displacement of the centering device in the direction of the mounting cap. Before the feed sleeves touch the seal, the centering device is reset by interrupting the compressed air supply and allowing the spring to return the centering device to its initial position. As the punch sleeves continue to advance, the shoulder 290 finally abuts the seal 292 so that the seal continues to slide onto the mounting cap, as shown in FIG. Finally, the inner and outer sleeves rest on the bottom of channel 294 of the mounting cap. By placing the sleeves, a compressive force is exerted on the plastic sealing material and the sealing material is pressed into the recess or recess 286, so that the surface of the seal is deformed, as shown in FIG. 21. After the plunger has been advanced and attached, the sleeves are withdrawn while the wiper remains in contact with the mounting cap due to its independent spring preload during part of the return stroke, namely until the inner sleeve lifts off the mounting cap. Following this stamp actuation, the mounting caps are immediately cooled to about 4.4 ° C (40 ° F).

It has been found that with a mounting cap approximately 0.279 mm (0.011 ") thick and a gasket material approximately 0.356 mm (0.014") thick and such adjustment of the sleeve advance that it is approximately 0.406 mm (0.016 ") ) ends in front of the surface on which the mounting cap rests, which results in sufficient compression and deformation of the sealing material.

The mounting cap is preferably cooled down to room temperature together with the seal pushed into its final position.

In order to achieve a frictional fit between the sealing material and the side wall of the mounting cap, the inner diameter of the sleeve made of sealing material is selected to be somewhat smaller than the outer diameter of the side wall of the mounting cap. Usually, the so-called 1-inch aerosol mounting caps have a side wall diameter of 24.892 to 25.146 mm (0.980 to 0.990 "). It has been shown that sealing material with a thickness of 0.432 mm (0.017") is sufficient. Mounting caps with a side wall diameter of 24.13 mm (0.950 ") were used to adapt to this sealing material thickness. Sealing tapes with a width of 7.14 mm (9/32") were satisfactory.

Although any plastic sealing material made of plastic with sufficient elasticity can be used, provided there is compatibility between the container contents and the plastic, it has been found that a plastic which is a low density polyethylene (a density in the range 0.916 to 0.922), the 5 to 15% polyisobutylene in the molecular weight range of 40,000 to 200,000 and stabilizers, which are usually used for polyethylene in an environment in which the sealing material is, results in a satisfactory sealing material in a wide range of products.

Instead of only one annular rib in the sealing ring, it is also possible to use a plurality of ribs in the radial direction across the width of the sealing ring. Furthermore, several annular ribs can also be provided be, since it has been shown in principle that a discontinuity in the flatness or smoothness of the sealing ring, as caused by a ribbed design, gives the sealing ring resistance to loosening during filling or displacement on the mounting cap, namely in that the Seal returns to its initial feed position. 13 shows a mounting cap provided with a seal according to the invention in perspective.

In contrast to mounting caps, which are provided with sealing material only along the side wall part of the cap, the sealing cap has a better sealing effect due to the fact that the sealing material extends from the pinching point between the cap and the flange edge of the container and into the channel. Furthermore, the seal of the mounting cap according to the invention has a substantially uniform thickness even before it is flanged to the container, while the known seal formed by injection is non-uniform because it tapers towards the outer edge of the channel and to the transition point between the side wall and the channel. A uniform thickness results in a better sealing effect.

Claims (18)

1. Device for series production of a mounting cap for aerosol containers which carries a seal, the mounting cap having a transverse wall, a circumferential side wall depending on the peripheral edge of the transverse wall and an annular channel projecting radially outward from the side wall, characterized by: a) a device for arranging a band of sealing material on the side wall of the mounting cap such that the end remote from the channel of the mounting plate projects beyond the transverse wall of the mounting cap, b) a primary stamping device for advancing the band of sealing material onto the side wall of the mounting cap in such a way that the mentioned distal end of the band lies at or below the peripheral edge of the transverse wall of the mounting cap, c) means for heating the band of sealing material following use of the primary stamp means and d) a secondary stamping device with a retractable sleeve part for advancing the heated band of sealing material into its final position on the side wall and in the channel of the mounting cap and for causing a compression deformation of the band of sealing material. 2. Apparatus according to claim 1, characterized by a device for cooling the band of sealing material after using the secondary stamp device. 3. For use in the series production of a mounting cap carrying a seal with a transverse wall, a peripheral side wall depending on the peripheral edge of the transverse wall and a channel, a device for advancing the sealing material into its final position on the mounting cap, characterized by a stamping device with a retractable sleeve, which has a seal contact part for forming a compression deformation in the sealing material. 4. Device according to one of claims 1 to 3, characterized in that the secondary stamp device has a device for preventing displacement of the mounting cap provided with the seal during the retraction of the sleeve part. 5. Device according to one of claims 1 to 4, characterized in that the secondary stamp device has a device for mutual alignment of the mounting cap and the secondary stamp device. 6. Device according to one of claims 1 to 5, at least claim 4, characterized in that the secondary stamp device has a recess delimited by the stamp head and the retractable stamp sleeve and the device for preventing displacement of the mounting cap provided with the seal during the advance or the retraction of the stamp sleeve is arranged within this recess. 7. Device according to claims 5 and 6, characterized in that the device for mutually aligning the mounting cap and the secondary stamp device is arranged within the recess of the secondary stamp device. 8. The device according to claim 6, characterized in that the means for preventing displacement of the mounting cap provided with the seal has a member which is pressed against the mounting cap under spring tension during the advancement and retraction of the secondary stamp sleeve. 9. The device according to claim 7, characterized in that the device for aligning the mounting cap and the secondary stamp is pressed under spring tension against the mounting cap during the advance and retraction of the secondary stamp sleeve. 10.The device according to claim 7, characterized in that both the device for aligning the mounting cap and stamp and the device for preventing displacement of the mounting cap during the advance and retraction the secondary stamp sleeve are pressed against the mounting cap under spring tension. 11. The device according to claim 1, characterized in that the secondary stamp device has a stamp sleeve with a seal contact part which carries a projecting part for forming a compression deformation of the band of sealing material. 12. The apparatus according to claim 11, characterized in that the sleeve of the secondary stamp has such a dimensioned sealing contact part that the periphery of the sealing contact part touches the leading edge of the band of sealing material simultaneously or immediately before the final advance of the stamp sleeve, so that in the seal compression deformation is caused. 13. Device according to one of claims 8 to 11, characterized in that the secondary stamp device has a stamp sleeve with a sealing contact part which carries a projecting part for forming an annular rib in the band of sealing material. 14. A method for mass production of a seal-bearing mounting cap for aerosol containers, the mounting cap having a transverse wall, a peripheral side wall hanging from the peripheral edge of the transverse wall and a channel, characterized in that a) a band of sealing material is formed on the side wall of the mounting cap, which extends beyond the transverse wall of the mounting cap extends. b) that the band of sealing material is first pushed as far onto the side wall of the mounting cap as far as a first point in which the end remote from the channel of the mounting plate lies at the level or below the peripheral edge of the transverse wall of the mounting plate c) that the band of sealing material is heated and d) that the band of sealing material is then pushed into its final position on the mounting cap and at the same time a compression deformation is formed in the sealing material. 15. The method according to claim 14, characterized in that the seal is cooled by the compression deformation after the formation of a rib. 16. Provided with a seal mounting cap which has a transverse wall and a peripheral side wall formed in one piece with the transverse wall and depending from its peripheral edge, the side wall expanding outward to form an annular channel for receiving the flanged edge of a container opening, characterized in that the sealing material is arranged on the side wall from below the clamping point so far into the channel that the sealing material extends outside the inner diameter of the head of the container, which is the one provided with the seal Receiving mounting cap, and that a compression deformation of the seal is formed on the outside of the seal after being placed in the final position on the mounting cap. 17. Mounting cap according to claim 16, characterized in that the deformation comprises an annular rib. 18. Mounting cap according to claim 16, characterized in that the deformation is a series of radial ribs along the width of the seal.

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