FI58895C - MEDICINAL PRODUCT FOR THE PURPOSE OF THE PURPOSE OF THE PURPOSE - Google Patents

Description

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Sweden-Sweden (SE) 7602685-5 (Tl) Rhenag AG, Im Riet 26¾, CH-8260 Stein am Rhein, Switzerland-Switzerland (CH) (72) Richard Friedrich, Engen, Federal Republic of Germany Förbundsrepubliken Tyskland (DE) (7¾ ) Forssen & Salomaa Oy (5¾) Device for the reception and disposal of liquid and pasty substances - Medel för mottagning och avgivning av ämnen i vätske- och pastform

The invention relates to a means for receiving and discharging liquid and pasty substances under pressure, which means comprises a pressure outer container and a flexible inner container, the upper edge of which is placed on the inwardly bent edge of the outer container, and an inner discharge - and over the upper edges of the outer containers and thus connect them together, in which means there is a closable opening in the bottom of the outer container for filling the pressure medium, and in which means the inner container is against the sealing edge of the outer container.

The inner container of this device is filled with the substance to be dispensed. The annular space between the inner and outer tanks is filled with working gas. The tasks to be solved in the structure of such a device are to avoid the leakage of both the compressed gas filled into the outer tank and the substance filled into the inner tank. Mixing of the working gas and the substance must also be prevented.

2 58895 Numerous forms of this device are known, including two-chamber boxes or two-chamber pressure vessels. They differ mainly in the fastening and connection between the inner and outer tank and the bottom of the discharge valve placed in the upper opening of the tank lid or outer tank.

In one embodiment, the inner container is rolled at its upper edge between the outer container and the container lid. This ensures good attachment and sealing. However, folding of the inner container during emptying and thus emptying depending on the folding is not desirable. In many cases, the inner tank consists of plastic. The metal-corrosive substance filled inside it therefore has no harmful effect. However, the substance comes into contact with the tank lid. Many substances cannot therefore be filled into it.

What is special about another embodiment is that the inner container is rolled to the bottom of the outer container. The working gas for squeezing out the substance is then placed in an inner tank. The substance itself is placed in the ring space between the inner and outer tanks. Thus, it is in contact with the entire jacket of the outer container. Thus, this embodiment is excluded from all substances that corrode metal.

In a third known embodiment, the inner container is located on the upper winding edge of the outer container. The discharge valve is set to the bottom. Its edge is flanged and thus connects the inner and outer tank. It gives a tight and strong connection. The substance filled in the inner tank does not come into contact with the metal in the outer tank. In this known embodiment, the upper edge of the pressure vessel is rolled or bent outwards. In the insertion and pressing of the valve base, the inner container is thus pressed against the conically outwardly extending edge strip of the outer container. This compression takes place immediately below the winding edge. The inner and outer containers touch along the strip. Thus, surface sealing takes place. This always leads to uncertainties in the seal. When using plastic in the inner tank, there is a risk of cold running at the nip. Thus, the valve may loosen and gas leaks out of the outer tank. With the cold flow of plastic, the flanged edge of the valve base can also expand under the high pressure prevailing in the outer tank and the valve loses its grip.

Consequently, it is an object of the invention to provide a device in such a way that the space of the inner container is properly sealed with respect to the space between the inner and outer containers and that loosening and slipping of the valve is reliably prevented. According to the invention, the solution for this task is created in that the upper edge of the outer container is bent inwards and that the upper edge of the inner container extends to the center of the bent upper edge of the outer container and is on its edge. The edge of the inner tank in the middle of the bent upper edge of the outer tank is under the sealing compound. This in turn is compressed downwards by means of the superimposed bottom of the discharge valve. As a result of this compression pressure, the sealing compound is compressed and pressed into the open gap between the edge of the inner container and the upper side of the bent upper edge of the outer container. The compression pressure compresses the sealing mass to about 20-30% of its original volume. This results in high sealing forces. An absolutely tight seal is created.

In another embodiment, it has been proposed that the upper edge of the outer container extends completely over the bent upper edge of the outer container and that the lower edge of the bottom of the discharge valve rolled over the upper edges of the inner and outer container is pressed radially inwardly against the inner container edge. In this embodiment, the sealing edge is moved radially further outwards. It runs along the outer edge of the bottom of the discharge valve, which presses along the line of the overstretched edge of the inner container radially against the outer side of the outer container.

What is special about another embodiment is that the upper edge of the outer container is bent inwards to form an edge strip with a sealing edge and is against this inner edge with this sealing edge.

Another embodiment is characterized in that the upper edge of the outer container is bent outwards. This embodiment is suitable for cases where the sealing edge is formed by parts of the bottom of the discharge valve.

Particularly for those embodiments in which the outer container has an inwardly bent upper edge, it has proved expedient for the sealing compound to be placed under the inwardly bent edge strip of the outer container between the walls of this outer container and the inner container. This sealing mass is pressed against the sealing edge between the inner container and the edge strip by the pressure prevailing in the gas space between the two tanks.

For all embodiments, it is preferred that a sealing compound be interposed between the bent upper edge of the outer container and the upper edge of the inner container thereon.

According to another suitable embodiment, the bottom of the discharge valve in the region of the edge of the outer container is rounded radially outwards to form a curvature. Thus, the inner container is pressed radially from the inside outwards against the edge of the outer container. Thus, high sealing pressures are generated here.

In another embodiment, it has been proposed that the vertical edge of the bottom of the discharge valve be made cylindrical, thereby forming a sealing edge with the horizontal portion of the bottom. Thus, the transition between the vertical edge of the base and its horizontal part takes place at a right angle. At this crossing point, the sealing edge is pressed against the inner tank by the pressure in the gas space between the inner and outer tanks. Thus, high sealing pressures are also generated here.

Finally, in another embodiment, it has been proposed that the upper edge of the outer container be made cylindrical, thereby forming a sealing edge with the associated extended portion of the outer container and the inner container being against this sealing edge.

The invention will be explained in more detail with reference to the accompanying drawings. Fig. 1 shows a side view of an embodiment with a sectional view of the outer tank and the valve base.

Figure 2 shows a section along the line II-II in Figure 1.

Figure 3 shows an enlarged view of the circle III marked in Figure 1 in one embodiment.

Fig. 4 shows the view according to Fig. 3 in another embodiment.

Figure 5 likewise shows the image according to Figure 3 in yet another embodiment.

Fig. 6 likewise shows the image according to Fig. 3 in yet another embodiment.

The metal outer tank 12 has a plastic inner tank 14. A filling valve 16 for the working gas is located at the bottom of the outer tank 12. This is bent inwards at its upper edge 18 in the embodiment shown in Fig. 3. It forms a bent edge strip 20 with a sealing edge 22. The discharge valve 32 is pressed into its base 26. This is pulled upwards along its edge 24 and bent downwards outwards at point 28. The expansion tool expands the base outwardly from the lower area of the rim 24 to form a curvature 34. The sealing ring 30 is still on the end edge of the inner container 14 and the inwardly bent outer edge 12 of the outer container 12.

The curvature 34 presses the inner container 14 firmly against the edge strip 20 of the outer container 12. The sealing edge 22 of this is pressed into the plastic of the inner container 12. For example, a latex sealant 38 is located between the inner and outer containers 12 and 14 below the sealing edge 22. The pressure prevailing in the gas space between the inner and outer container presses it against both edges of the edge strip 20. Thus, the gas space is further condensed. The sealing of the inner container 14 containing the beneficial agent takes place by tightening its upper edge between the edge strip 20 of the outer container 12 and the pulled-up edge 24 of the valve base. Additional sealing takes place along the end edge 36 of the inner tank 5 58895. Against this, the sealing ring 30 is pressed under high pressure. As discussed above, the sealing ring 30 compresses up to 30% of its volume. This results in high sealing forces along the end edge 36.

The embodiment shown in Figure 4 differs from that of Figure 3 in that the inner container 14 is pulled completely over the inwardly bent upper edge 18 of the outer container 12. In this embodiment, a sealing edge 40 is formed along the lower edge 42 of the bent edge of the valve base. Along this sealing edge 40, the edge 42 presses the inner container 14 radially inwards against the outer side of the outer container 12.

In the embodiment shown in Figure 5, the edge 18 of the outer container 12 is bent outwards. Another feature of this embodiment is that the pulled-up edge 24 of the bottom of the discharge valve is cylindrical. Thus, a sealing edge 44 is created for the transition between this pulled-up edge 24 and the horizontal passage portion of the base 26. The pressure in the gas space between the two tanks presses the inner tank against this sealing edge 44. Thus, high sealing pressures are generated here. Also in this embodiment, there may be a sealing mass 38 for further sealing.

In the embodiment shown in Fig. 6, the upper edge of the outer container 12 is cylindrical and first has a convex area with a larger diameter below this cylindrical part. A sealing edge 44 runs along this transition point. The raised edge 24 of the discharge valve base 26 is made radially outwardly curved, as in the embodiments of Figures 3 and 4. Thus, the inner container 14 now presses against the sealing edge 44 in the outer container 12.

Common to all embodiments is that the inner container 14 is pressed against the linear sealing edge. In Figures 3 and 4, this sealing edge runs at the edge of the inwardly bent edge strip of the outer container and joins this edge. In Fig. 5, a sealing edge runs at the overflow point between the pulled-up cylindrical edge of the discharge valve bottom and the horizontal portion. In Figure 6, the sealing edge is moved radially outwards and is located on the inside of the outer container. Figure 3 shows an additional sealing edge along the end edge 36 of the inner container 14. Figure 4 shows an additional sealing edge along the lower edge of the bent edge of the valve base. These different sealing edges can also cooperate in the context of the invention, contrary to what is described in detail.