NO152077B - Disposable DENTAL Capsule - Google Patents

Abstract

DISPOSABLE DENTAL CAPSULES.

Description

The present invention relates to disposable dental capsules comprising a first, hollow, cylindrical part with an open end and a closed end, a second, hollow, cylindrical part with an open end and a closed end, means for connecting and fastening the open ends of first and second cylindrical parts to form a closed cylindrical container.

Suitable disposable capsules are known which contain interacting components, such as dental amalgam base substances, mercury and silver or silver alloy. However, with all known capsules, some manipulation of the capsule is required for mixing the interacting components.

It would be highly desirable to eliminate any such manipulation of the capsule. Particularly in the dental field, it would be desirable to provide a dental capsule containing the dental amalgam basic substances from which dental amalgam could be produced simply by placing such a capsule in an amalgamator.

Examples of known disposable capsules include capsules with tearable membranes and means for tearing the membranes before the interacting components are mixed. US-PS 3,451,540 describes e.g. a disposable capsule comprising a telescopically displaceable cylinder, where the individual parts are pushed together to tear apart the membrane that divides the capsule into two chambers, so that the interacting components, which have been stored in the chambers, can be mixed.

Similar capsules are described in US-PS 3,625,349 and 3,595,439, where the membrane is in the form of a bag containing one of the interacting components and where the bag is opened by pressing through a rotating or sliding mechanism, until it bursts. Reference is also made to US-PS 3,907,106, 3,860,114, 3,841,467, 3,831,742, 3,6555,035, 3,638,918, 3,756,571 and 1,774,258, which deal with similar capsules.

Disposable capsules are also known, where a removable stopper is used to isolate the cooperating components and where the stopper is removed, so that the components can be mixed. It is displayed, e.g. to US-PS 3,275,302> where a ball or disk is positioned so as to divide the capsule into two chambers, each containing one of the cooperating components. This capsule is activated by turning it upside down to displace the ball or disc. Reference is further made to US-PS 3,796,303, 3,809,225, 2,527,992, 2,527,991 and 3,785,481, which show other capsules with removable stoppers.

With other disposable capsules, a passage is used between the two chambers, which can be closed and opened either by turning, shifting or screwing one or more capsule parts. According to US-PS 3,357,545, e.g. upper capsule part unscrewed, so that a spindle on the upper capsule part is removed from a wire in the lower capsule part. When the spindle is removed, the cooperating component in the upper part can drop into the lower part. Reference is also made to US-PS 3,139,180, 3,139,181, 3,917,062, 3,963,129 and 3,924,741, which show similar capsules.

It is therefore an aim of the present invention to provide a capsule for pre-packing and storage of the basic substances in dental amalgam, especially mercury and silver or silver alloy. It is also a purpose of the invention to provide a dental capsule which allows the basic substances to be mixed and the amalgam to be prepared without special manipulation of the dental capsule on the part of the user. Another purpose of the invention is to provide a dental chapel which reduces the possibility of mercury escaping to the surroundings before or during the production of the dental amalgam. These and other purposes of the present invention will be apparent from the description below and from the subsequent claims.

In an embodiment of the invention, the disposable dental capsules comprise a closed, cylindrical container, which, by means of a displaceable, flexible disc which has an edge in sealing contact with the inner wall of the cylindrical container, divides the container into two inner chambers which are not connected to each other, and the disk has a surface that corresponds to the shape of the inner surface of the opposite container end, so that a surface of the disk, when the disk is displaced towards the container end, joins this, whereby one of the inner chambers is essentially eliminated.

The capsule is suitably composed of two lockable

cylindrical parts, each of which has a closed and an open end, and re-

includes means for joining the open ends to form a closed container. The capsule also preferably includes internal

provide means for positioning and securing the flexible disk against accidental movement for the capsule to be used, so that premature mixing of the amalgam components is prevented. The capsule may also have ribs or grooves in the mercury chamber wall to promote mercury

vet's strenght around the disk, when the capsule is placed in the amalgam

clean and the disc is driven towards the end of the capsule.

The advantage of the dental capsule according to the present op-

invention lies in the fact that no manipulation is required

ing of the capsule by the dentist or dental technician for mixing the components. As the capsule forms a closed be-

holder and there are no external, moving parts, it is possible-

the heat for mercury to escape to the environment, essentially

just eliminated.

After the amalgam has been prepared in the capsule, the cylindrical parts are separated for extraction of the amalgamated composition.

The two cylindrical parts, one of which contains the flexible

the disc and the stotter, are then discarded.

In another embodiment of the present invention,

see, the capsule comprises a hollow, cylindrical part with an axial

arranged shoulder at a distance from the cylinder ends, so that the internal diameter of the cylinder is reduced at the shoulder, a removable cap which closes one end of the hollow, cylindrical part and a flexible plug with a spindle which extends through and is in flexible in-

handle with the narrowing in the cylindrical part. A flange projecting from the end of the spindle is spaced from the shoulder of the cylinder and is in frictional contact with the inner wall of the cylindrical portion along its entire circumference, so that the cylindrical portion is divided into two non-communicating chambers.

The quicksilver is located in the chamber that surrounds the stopper's spindle, while the sol powder is located in the cylinder's other chamber.

more. A tappet in the chamber containing the sol powder has sufficient weight and dimensions to impinge on the flexible plug to drive the plug against the shoulder of the cylindrical portion,

when the capsule is placed in an amalgamator. With such a movement, the plug's spindle is driven further through the constriction in the cylinder,

until the plug's flange rests against the shoulder and thereby presses

the mercury past the edge of the flange and into the chamber containing the mercury powder to form the dental amalgam.

The drawings show

fig. 1 a capsule according to the present invention,

fig. 2 a played out . partial section of the capsule according to fig. 1,

fig. 3 a section of the capsule according to fig. 1 for activation,

fig. 4 the relationship between the flexible disc and the assembly of the cylindrical capsules according to fig. 3 in a more detailed rendering,

fig. 5 the capsule according to fig. 1 after activation and mixing of the interacting components,

fig. 6 a partial section of the flexible disk and the cylindrical parts in another embodiment of the capsule,

fig. 7 a partial section of the flexible disk and the cylindrical parts of a third embodiment of the capsule,

fig. 8 a partial section of the flexible disc and the cylindrical parts in a fourth embodiment of the capsule,

fig. 9 shows the outside of another embodiment of the capsule according to the invention,

fig. 10 a section of the capsule according to fig. 9 for activation,

fig. 11 is an expanded view of the capsule according to fig. 10,

fig. 12 a section of the capsule according to fig. 10 after activation and mixing,

fig. 13 the circumference of the flange of the movable stopper in cross section.

fig. 14 the relationship between the circumference of the flange according to fig. 12 and the inner walls of the capsule,

fig. 15 is an end view of the capsule according to fig. 9 after the line 15-15.

In fig. 1-5, a preferred embodiment of the present invention is illustrated. A disposable capsule comprises a first cylindrical part 10 with an open end 9 and a conical closed end 12, a second cylindrical part 18 with an open end 19 and a closed hemispherical end 20 and a flexible disk 14, which divides the assembled capsule in two inner chambers 23 and 24, which are not connected to each other, as most clearly shown in fig. 3.

The flexible disc 14 is arranged in the cylindrical part 10

with the edges of the disc in contact with the wall of the part to form a continuous seal around the circumference of the disc. The surface of the flexible disk 14 has a positive conical shape that matches the negative conical shape of the end 12 of the cylindrical part 10, so that the disk follows the cylinder end when it is pressed against the capsule end.

The cylindrical part 10 also has an axially extending groove 11 around its open end, so that the cylindrical part 10 can telescopically engage with the open end 19 of the cylindrical part 18

for forming a sealed capsule, when the first and second cylindrical parts are so connected.

The wall thickness of the cylindrical part 17 around the circumference of the open end 19 is somewhat greater than the depth of the axially extending groove 11 in the cylindrical part 10. When the cylindrical parts are telescoped, an axially extending step 22 is formed in the interior of the capsule at the point where the two parties are connected.

The cylindrical part 10 comprises a number of ribs 15, which extend along the wall of the part from the closed end towards the open end of the cylinder. In the illustrated example, eight ribs are arranged which are placed at equal intervals along the inner wall of the cylindrical part. It is desirable that at least three ribs are provided to prevent the disc from coming into tension while the cylinder is being filled or during activation, as discussed below0

The dimensions of the ribs are chosen so that the flexible disc is held

at a suitable distance from the closed cylinder dividing end without the disc being prevented from bending towards this end when the capsule is activated. In a typical dental capsule with overall dimensions of 25.4 or 31.7 mm by approx. 12.7 mm, the ribs can protrude approx. 0.07-0.38 mm from the inner wall of the cylindrical part and be 0.17-0.38 mm wide0 The ribs can taper towards the open end of the cylindrical part to promote the displacement of the disk on the ribs during mixing. It is, however, a prerequisite that the angle is sufficient to prevent displacement of the disc during storage and transport of the filled dental capsules0 It has been shown that when the number and stbrrel of the ribs are increased, more of

the reactive component remained in the capsule after mixing. Professionals will therefore choose the dimensions of the ribs with a view to securing the disc's position during storage and transport, while at the same time ensuring the least possible residue in the capsule after mixing.

As most clearly illustrated in fig. 4, the flexible disc 14 will be in contact with the inner wall of the capsule around the entire inner circumference of the cylindrical part 10. The disc 14 is held in place between the ribs and the step 22, so that the capsule is divided into a first inner chamber 23 and a second inner chamber 24. The disc's edge preferably has a somewhat greater thickness than the distance between the step and the ribs, so that the disc is pressed somewhat together in the fitted capsule. In a typical dental capsule, the said distance can vary from approx. 0.12 to 1.52 mm and is usually approx. 0.76 mm.

In the embodiment shown, disc 14 has a conical surface which extends into chamber 23 and corresponds to the conical shape of the opposite end of the chamber. The chamber end and corresponding surface of the disk can also be elliptical or hemispherical, but is preferably not flat, as there would be a greater tendency for mercury to be retained between such flat surfaces during activation of the capsule.

As shown, the chamber 23 contains quicksilver 25 and is considerably smaller than the chamber 24, which contains sblv powder 27 and a stbter 26. The pre-filled capsule can be activated by shaking in a dental amalgamator, where the capsule is moved back and forth along the main axis of the capsule. The pusher is thrown between the capsule end 20 and the opposite surface of the disk and drives the disk rapidly towards the closed end 12 of the cylindrical part 12. When the disk is moved to the end surface 12, the mercury is hydrostatically pressed to flow around the edges of the disk and into the chamber 240. This mercury flow is promoted by the ribs 15 on the wall of the part 10, which create openings in the seal around the edges of the disc. After a short time in the amalgamator, the capsule has in reality only one, large, inner chamber with a volume which essentially corresponds to the sum of the volumes of the original chambers 23 and 24. This chamber now contains both the quicksilver and the solvate.

The edge of the flexible disc must, as mentioned, seal against liquid leakage from the chamber 23 during storage and transport" In an embodiment illustrated in fig. 4, the disc's edge is provided with grooves for the creation of a double sealing line at the disc's upper and lower surface, so that the sealing capacity is increased. The disk 14 is also provided with a concave surface on the side facing the pusher, so that the force from the moving pusher is assumed to be directed evenly across the disk, This reduces the risk of the disk getting stuck when it slides onto the ribs and is moved towards the closed end of the cylindrical part 10.

The two cylindrical parts which form the capsule according to the present invention are provided with means for interlocking the capsule, so that the parts are not separated with certainty during transport and handling. In fig. 1 shows the cylindrical part 18 provided with an axially extending holding flange 40 around the outer surface. Around the flange 40, one or more tabs 41 are snapped, which are formed in one with an axially extending flange 42 on the outer surface of the cylindrical part 10. The flanges 40 and 42 are also suitable for separating the hollow, cylindrical parts. As shown in fig. 5, the tabs 41 can be provided with extensions 43, which extend past the flange 42 and form means for opening the tabs by the extensions being pressed against the capsule body.

In the embodiment shown in fig. 1-5, the cylindrical portion 10 has external ribs 16, which extend radially from the center of the closed end to adapt the shape of the capsule to that of conventional amalgamator clamps. The shape according to fig. 1 is preferred, because it maintains a uniform wall thickness and thus uniform relaxation during stopping of the capsule. The cylindrical part 18 is also provided with suitable, friction-inducing gripping means around the outer circumference, such as knurling 21 (fig. 1), which facilitates holding and opening of the capsule after activation"

In fig. 6-8 further examples of the present invention can be seen, where other bodies have been used for placement

and fixing the disk 14 in the capsule. In fig. 6, the disk 14 is provided with an annular flange 31, which projects into a space and is compressed between the base of the groove 11 in the cylindrical part 10 and the end 19 of the cylindrical part 18. During activation of the capsule, the flange 31 is torn loose as follows of the ram's action on the disk 14 and the disk is released and driven towards the end of the cylindrical part 10. The side wall ribs which are illustrated in the previous figures are not necessary in the embodiment shown in fig. 6, as the disk's construction does not offer significant resistance to the quick-flow stream around the edge of the disk when it is freed from the annular flange.

In fig. 7 another embodiment example is illustrated, where the disc 14 is placed and secured in a circumferential groove 32, which is taken out in the capsule wall at the connection between the two cylindrical parts. In yet another embodiment shown in fig. 8, the disc 14 is placed and secured between an annular rib 33 in the cylindrical part 10 and a lip 22 formed at the end 19 of the cylindrical part 18.

Those skilled in the art will realize that many other solutions can be used to place and secure the disk 14 in the capsule before it is activated. The disc can e.g. be firmly cemented to the capsule wall or fixed by induction welding or it can be held in place by other mechanical means. The invention is obviously not limited to the mentioned structural solutions.

The cylindrical capsule parts can be made of any material that is indifferent to the interacting components the capsule must contain. Normally, the cylindrical parts will be made of rigid material, such as metal, plastic etc. In a preferred embodiment, they are produced from a rigid thermoplastic material/ such as polycarbonate, polyacrylic plastic, polyvinyl chloride etc. A material that makes production easy is a polycarbonate.

The disk 14 is preferably made of an elastic, flexible material, e.g. acetal or polyester or a similar thermoplastic material.

The disk and the cylindrical parts are preferably formed by sprby stoping, but any suitable technique for forming the materials can be used.

Using a rigid material for the hollow, cylindrical parts reduces the risk of mercury being retained in the capsule. The combination of a rigid capsule and a flexible disk makes it less necessary to maintain strict production tolerances, because the disk's flexible material will compensate for minor deviations in the structure of the hollow, cylindrical parts. Thereby, a more economical and efficient production of the capsule according to the invention is achieved.

To fill the dental capsule according to the invention, a measured amount of alloying powder 27 or a tablet of such powder is placed in the cylindrical part 18 together with the mixer 26, which has sufficient weight to drive the disk 14 backwards in the cylindrical part 10 during mixing. The correct amount of mercury for the production of dental amalgam with the sol powder is placed in the cylindrical part 10, preferably when this is standing with the closed end facing down. The flexible disc 14 is then placed in the cylindrical part 10 and is held in place by frictional contact with the inner wall of the sewing part or other appropriate organs. The cylindrical part 10 containing the quick blow and the flexible disk 14 is then turned over and attached to the cylindrical part 18 by means of the tabs 41.

Figures 5-15 show that the capsule according to the shown embodiment comprises a hollow, cylindrical part 110 with an axially positioned shoulder 111 at a distance from the upper end 112 and lower end 113 of the part 110, so that the inner diameter of the part 110 is narrowed in a point at a distance from the ends 111 and 112.

In the embodiment shown in fig. 9 it can be seen that the upper part of the part 110 is provided with ribs 114, which facilitate gripping of the capsule in the amalgamator and make it easy to stop the capsule. The ribs are oriented radially around the upper part of the part 110 with

equally spaced apart. In the embodiment shown, 16 ribs are arranged. However, a larger or smaller number may also be appropriate, depending on the appearance, design considerations and the distortion and shrinkage that can be tolerated during the manufacture of the capsule.

The ribs are curved at the upper end 112 of the part 110 and extend towards the lower end 113 and merge with the walls of the part 110 at a point near the shoulder 111. The shoulder 111 divides the inner volume of the part 110 into a spindle receiving chamber 115 towards the upper end of the part 110 and a chamber 116 to hold the cooperating components towards the lower end of 110.

A flexible plug 117 with a spindle 118 and a flange 119 is arranged in the chamber 116 to divide the chamber into two compartments for separate storage of the cooperating components. The circumference of the flange 119 matches in shape the inner diameter of the chamber 116, although it is somewhat larger and is generally circular and disc-shaped. As shown, the flange 119 is positioned around the lower end of the spindle 118 and contacts the inner wall of the chamber 116 in a sealing manner. The spindle 118 is in frictional contact with the shoulder 111 towards its upper end by sliding fit. The plug's material is elastically flexible,

so that the flange forms a suitable seal between the interacting components in the chambers 120 or 121, while the plug can be moved backwards towards the upper end of the portion 110. The plug 117 preferably consists of a uniform rigid thermoplastic, such as low density polyethylene, polyester or polyacetal.

The shoulder ill can have any shape that allows it to have axial contact

with the spindle 118 in a sealing manner, which does not, however, prevent displacement of the spindle when the plug is pressed against the upper end 112. I

the embodiment shown has the shoulder truncated cone shape in cross section with the flat surface in contact with the spindle, The shoulder can of course be rounded or pointed in cross section, but it has been shown that the truncated cone shape provides the best balance between sealing and displacement possibility.

It should be noted that the sealing function of the shoulder 111 is not

as critical as the flange's 119 sealing function, since leakage at the shoulder would only allow the reactive component to pass out into the environment, while leakage at the flange could lead to premature reaction of the interacting components. But when quicksilver is present in the chamber 120, it is critical for safety reasons that the shoulder forms at least as effective a seal as the flange.

As will be seen, the plug 117 is arranged in the part 110 in such a way that the chambers 120 and 121 are given sufficient volume to contain the necessary quantities of interacting components. The relative volumes of the chambers 120 and 121 can be regulated by setting the plug 117. The chamber 120 is particularly suitable for recording liquid interacting components, such as quicksilver. The chamber 121 will usually contain a liquid or a powder as an interacting component, e.g. sblv or sblv alloy. As indicated above, the shown capsule works by moving the plug back towards the upper end of part 110 to reduce the volume in the chamber 120 with a corresponding reduction in the volume of the chamber 121. Thereby, the cooperating liquid component is pressed into the chamber 121.

In order to create a suitable force that moves the plug in the above-mentioned manner, and to contribute to the mixing of the cooperating components, a stbter is placed in the chamber 121. The dimensions of the chamber 121 along the longitudinal axis are significantly larger than those of the chamber 120, so that the stotter can create a larger force during the shaking in the amalgamator.

The chamber 121 is sealed with an end cap 122, which is removably attached to the lower end of part 110.

As shown, the cap 122 has a hemispherical lower end 123 which is integral with a hollow, cylindrical, upper end 124, which engages telescopically in an axial groove 125, which is arranged around the lower end of part 110. In the example shown the cap 122 is connected to part 110 in line with this, so that a smooth inner surface is formed in the chamber 121. It has been shown that inner surface irregularities lead to larger residues of both interacting components that remain in the capsule after use. Apart from the obvious economic disadvantage of used residues, the environmental pollution problems of disposing of used capsules containing mercury or another toxic substance will be obvious.

Other means for removably securing the cap 122 to the part 110 will be obvious to those skilled in the art. It can e.g. screw threads, snap fit, slide fit, etc. are used. In order to achieve a smooth inner surface in the chamber 121, however, the method described above is preferred.

As shown, the cap may have an external, axially extending ridge 126 which facilitates removal from part 110. It is also noted that the hollow, cylindrical, upper end 124 of the cap in the example shown has a greater height than the length of the axially extending groove 125. This structural conditions provide an external, axially extending groove 127 near the ridge 126, so that removal of the cap with a thin tool or a fingernail is further facilitated.

To return to the relationship between the plug 117 and part 110, it will appear from the figures that the length of the spindle is preferably less than the distance between the shoulder 111 and the upper end 112, i.e. the length of the chamber 115 which occupies the spindle.

In order to ensure maximum passage of the reactive component in the chamber 120 to the chamber 121, it is desirable that the flange is pressed against the upper end of part 110, until the upper surface 119a of the flange makes contact with the shoulder 111. The spindle must therefore not have such a length that the is blocked against lateral movement by the gripping means in an amalgamator, so that the flange is prevented from contacting the shoulder. The easiest way to ensure that the lateral movement of the plug is not inhibited by any amalgamator means is to let the length of the spindle be less than the chamber that accommodates the spindle.

In a typical dental capsule, i.e. with dimensions 25.4-31.7 mm by approx. 12.7 mm, chamber 115 which accommodates the spindle may have a length of 4.06 mm, chamber 120 may have a length of 3.35 mm and chamber 121 may have a length of 20.57 mm (for actuation).

As a further safety measure against mercury passing through the seal in the form of the shoulder 111 and escaping into the environment, a removable tape or end cap (not shown) can be used to seal the upper end of part 110. If such a tape or removable end cap is used, an air hole is arranged, so that an air lock does not form during movement of the spindle into the chamber 115. An air hole can also be placed in the walls of the chamber 120 near the shoulder 111, so that an air lock does not prevent the movement of the flange 119 towards the shoulder.

Another structural feature of the capsule according to the invention is that the upper surface of the flange is shaped to adapt to the lower surface Illa of the shoulder 111. This feature ensures that these surfaces fit together and thus ensures a more complete transfer of the reactive component from chamber 120 to 121 as, at the end of activation, chamber 120 will, so to speak, not exist. This is most clearly shown in fig. 12.

The capsule can be activated by shaking in a dental amalgamator, where the capsule is shaken in a direction perpendicular to the plane of the flange. The impactor will hit the lower surface of the flange and push the flange backwards against the shoulder of the hollow, cylindrical part. As shown in fig. 12, the mercury is pushed past the circumference of the flange. In order for the mercury to pass more easily, the circumference of the flange preferably has a reduced thickness, compared to the thickness of the flange in general, i.e. the circumference is tapered (see fig. 13). After mixing, the capsule can be pulled apart to remove the amalgam.

For filling the capsule according to the present invention, the stopper 117 is placed in the hollow, cylindrical part 110 towards the lower end of the part 110. The spindle part 118 is then not in contact with the shoulder 111, although the flange 119 is in sealing contact with the inner wall of the part 110. Quicksilver is fed into part 110 through the valve receiving chamber 115 and the stopper 117 is moved towards the upper end of part 110, until the spindle 118 makes sealing contact with the shoulder

111. The end cap 122 can be filled with mercury or mercury alloy, either in powder or tablet form, a pusher is placed in the cap and this is attached to the lower part of 110. Alternatively, mercury or mercury alloy and/or the pusher can be placed in the chamber 116 after the quicksilver has been sealed in chamber 120 and the end cap is attached to part 110.

According to the invention, the pre-measured components can be mixed without being touched or measured by the consumer in a more convenient and simple way than previously known. It should be noted that although the container according to the invention is described by the example of mixing dental amalgam, other dental compositions, such as acrylate-polymer dental filling, can be packed and mixed in it. The container can also be used in areas other than dental, where a liquid component must be kept separate until ready for use, e.g. in pre-packing of epoxy resin and accelerators for the production of cement„

Claims (14)

1. Dental capsule for single use including a first, hollow cylindrical part (10) with an open end (9) and a closed end (12), a second hollow cylindrical part (18) with an open end (19) and a closed end (20), means for connection and joining the open ends of the first and second cylindrical parts to form a closed, cylindrical container, characterized by a displaceable, flexible disk (14) having an edge in sealing contact with the inner wall of the cylindrical container, whereby the container is divided into two inner chambers (23, 24) which are not connected to each other, and where the disc (14) has a surface (13) which corresponds to the shape of the inner surface of the opposite container end (12), so that said surface of the disc (14), when the disc is displaced towards said container end, it follows this and one (23) of the inner chambers is essentially eliminated. 2. Capsule according to claim 1, characterized in that the inner surface of one end (12) of said container is concave and that the opposite surface (13) of the disc (14) is convex. 3. Capsule according to claim 2, characterized in that the disk (14) has a positive conical shape and that said container end (12) has a corresponding negative conical shape. 4. Capsule according to claim 1, characterized in that the first, hollow, cylindrical part (10) has an axially extending internal groove (11) around its open end (9) which is in telescopic connection with the open end (19) of the second cylindrical part (18). 5. Capsule according to claim 4, characterized in that the first and second cylindrical parts (10, 18) are secured in said telescopic connection by means of tabs (41) on the first part which engage with a circumferential flange (42) which projects from the second cylinder -risky part. 6. Capsule according to claim 1, characterized in that the inner wall of the container comprises organs for placement and securing the edge of the flexible disc (14). 7. Capsule according to claim 6, characterized in that the means for placing and securing the disk (14) comprise a circumferential groove (32) in the wall which occupies said disk edge. 8. Capsule according to claim 6, characterized in that the means for placing and securing the disk (14) comprise circumferential ribs (15) on the wall on one of the sides of said disk edge. 9. Capsule according to claim 6, characterized in that the means for placing and securing the disc (14) comprise a circumferential ridge (33) on one side of the disc edge and a number of ribs arranged at a distance from each other around the wall and extending to the other side of the disc edge . 10. Capsule according to claim 6, characterized in that the means for placing and securing the disc (14) comprise a circumferential groove (31) in the wall between the connection point between first and second cylindrical parts, which receive an annular flange projecting from the disc edge. 11. Capsule for single use according to claim 1, characterized in that the first part (10) has an axially extending internal groove (11) around its open end and a number of ribs (15) at a distance from the groove (11) and extending perpendicularly to said closed end, that the open end (17, 19) of the second part (18) is in telescopic engagement with said inner groove (11) in the first part and has sufficient thickness to form an axially extending shoulder (22) with the first part, that the flexible disc (14) is with a surface in contact with the axially extending shoulder (22) and with the edge of the disc in contact with the wall of the first part (10) in the space between the perpendicularly extending ribs (15) and the shoulder (22) , where the disk (14) thus divides the capsule into two chambers (23, 24) which are not connected to each other. 12. Capsule according to claim 1, characterized in that the surface of the flexible disc (14) facing the closed end (12) of the first part (10) has a positive conical shape and that the inner surface of the closed end (12) of the first cylindrical part (10) has a corresponding negative conical shape. 13. Capsule according to claim 11, characterized in that the edge of the flexible disc (14) has a thickness from 0.127 to 1.524 mm. 14. Capsule according to claim 11, characterized in that the edge of the flexible disc (14) has a greater thickness than the space between the axially extending shoulder (22) and the perpendicularly extending ribs (15).