SE535700C2 - Piston for containers and containers with such piston - Google Patents

Description

In a particularly advantageous embodiment, the upper surface of the piston extends up to the piston rod 5 and is attached to it. This gives the piston an even more pronounced non-return valve function.

In a further advantageous embodiment, at least one recessed channel 9 can extend on the upper surface of the piston from the periphery of the piston towards its center. This channel provides an even clearer non-return valve function with the piston.

The invention also relates to a container 1 with a cylindrical inner surface, typically a syringe, with such a piston.

Brief description of the figures Fig. 1 shows a syringe with piston according to the invention in a first use step.

Fig. 2 shows the syringe with piston according to the invention in a second use step.

Fig. 3 shows the syringe with piston according to the invention in a third use step.

Fig. 4 shows a syringe with a first embodiment of a piston in a first stage of use.

Fig. 5 shows in greater detail the syringe with the first embodiment of the piston.

Fig. 6 shows the syringe with the first embodiment of the piston in a second use step.

Fig. 7 shows in greater detail the syringe with the first embodiment of the piston.

Fig. 8 shows the first embodiment of the piston seen from the side.

Fig. 9 shows the first embodiment of the piston seen obliquely from above.

Fig. 10 shows the first embodiment of the piston seen from below.

F ig. 1 1 shows a syringe with a second embodiment of a piston in the first use step.

F ig. 12 shows in greater detail the syringe with the second embodiment of the piston. Fig. 13 shows the syringe with the second embodiment of the piston in the second use step.

Fig. 14 shows in greater detail the syringe with the second embodiment of the piston.

Fig. 15 shows the second embodiment of the piston seen from the side.

Fig. 16 shows the second embodiment of the piston seen obliquely from above.

Fig. 17 shows the second embodiment of the piston seen from below.

Description of Preferred Embodiments Figs. 1-3 show a simplified illustration of a syringe with a plunger according to the invention in a first, second and third use step. Fig. 1 shows the syringe with the piston in a storage position, Fig. 2 shows the syringe with the piston when mixing and Fig. 3 shows the syringe with the piston in its lower end position when the contents of the syringe have been emptied.

The syringe usually comprises a substantially cylindrical container 1 with a spout 2 at its lower end and a top 3 at its upper end. Inside the cylindrical container runs a piston 4 which is connected to a piston rod 5. The piston rod extends from the piston towards the top and runs through an upper seal 6. On the pipe a pipe cap 7 is arranged so that between the pipe cap and the upper seal extends in the the inner chamber of the cylindrical container. The chamber is divided into two, an upper and a lower one, by the piston and the two sub-chamber chambers are approximately iron-sized.

The piston keeps substances in the two sub-cores water-tight separated, so that with the piston in the position illustrated in fi g. 1, the two different substances can be kept completely separate for an indefinite period of time.

The syringe thus forms a two-core marble syringe where, for example, a dry substance can be stored in the lower sub-chamber and a solvent can be stored in the upper sub-chamber.

The piston is designed so that it functions as a pit valve as described more clearly in connection with fi gures 4-17. Pulling the plunger towards the top of the syringe releases liquid, while pushing it against the syringe barrel does not release liquid but forces it to follow the plunger. I fi g. 2, the piston has been pushed towards the top of the syringe and liquid from the upper sub-chamber has been forced past the piston and sprayed out into the lower sub-chamber. The two substances are illustrated in the form as separate only to explain the function, but in practice the liquid sprays out under pressure and mixes, which is the purpose of the construction.

When the substances are fully mixed, the piston is pushed down towards the spout illustrated with the arrow in fi g. 3.

In order to be able to empty the contents through the spout, the spout cap must be removed and in the figure this is removed.

Fig. 4 shows a syringe with a first embodiment of a piston in a first use step where the substances in the two sub-combs are kept separate by the piston for storage. F ig. 5 shows in greater detail the syringe with the first embodiment of the piston in the first use step. The figure illustrates the lower end of the piston rod where a widened end portion 8 is arranged. The end portion locks the piston to the piston rod and is arranged near the center of the piston.

The piston extends a short portion up the sides of the piston rod and forms a cylindrical symmetrical portion with the slightly larger diarnetes than the piston rod. The plunger then widens downwards and finally reaches the cylindrical inner wall of the syringe. The piston has at its widest a diameter which slightly exceeds the diameter of the inner wall, so that it abuts against the inner wall with a certain pressure. The lower end of the piston is sharply cut off and forms a substantially flat, circular surface. Around the upper and below the circular edges of the widest portions of the piston, the piston is rounded to facilitate movement in either direction.

The fact that the elastic piston extends up along the lower end of the piston rod and thus reaches the piston distinguishes it from typical seals for pistons. Pistons usually consist of a rigid cylinder element around the periphery of which an elastic seal is arranged and the seal then does not reach the piston rod. In that the piston, which in the illustrated embodiment approximately corresponds to both the rigid cylinder element and the sealing ring in a conventional piston, extends on its upper side all the way to the piston rod, the piston provides an opportunity to extend downwards from the piston rod and along its periphery so that it yields for fluid pressure from above. The piston according to the invention consists, subject to the widened end portion 8 of the piston rod and a short piece of the piston rod next to the end portion, in its entirety of an elastic material such as rubber, silicone or the like.

F ig. 6 shows the syringe with the first embodiment of the piston in a second stage of use, where liquid from the upper sub-chamber fl flows past the periphery of the piston and into the lower sub-chamber.

Fig. 7 shows in greater detail the syringe with the first embodiment of the piston in the second use step. The piston is moving upwards in the figure and liquid passes the piston in the downward direction 535 700 as the arrows in the figure illustrate. Because the piston is asymmetrical in it energetic in different ways when moving upwards and downwards, respectively. When the piston is moved upwards as in the fi gure, the material around the periphery of the piston is stretched downwards, which gives a very small movement in the material in the direction of the center axis of the piston. This small movement or the reduced pressure that the piston exerts on the inside of the syringe is sufficient to allow liquid to pass by.

If the piston is then pushed down, the periphery of the piston is stretched upwards and the conical upper part of the piston then causes the piston to strive to widen in the radial direction so that the pressure the piston places on the inner surface of the syringe increases and blocks the passage of liquid in the opposite direction.

Figs. 8-10 show the first embodiment of the piston seen from the side, seen obliquely from above and seen from below, respectively. The figures illustrate five channels 9 on the top of the piston which extend radially from the center of the piston. The channels consist of recessed grooves extending from the narrower upper part of the piston towards the periphery of the piston, but do not reach the periphery in the unloaded position. If the piston is pushed upwards, the periphery of the piston will be stretched slightly downwards and those end portions of the channels which are closest to the periphery of the piston will then be stretched with the piston so that they reach closer to the periphery or all the way to the periphery. In this way, the channels facilitate further passage of liquid past the periphery of the piston when the piston is pulled upwards. If, on the other hand, the piston is pulled downwards, the periphery of the piston will on the contrary be stretched upwards, so that the channels are removed from the periphery and the piston continues to block the flow of liquid past the piston despite the channels.

Fig. 11 shows a syringe with a second embodiment of a piston in the first stage of use, where the piston thus seals between the upper and lower sub-chambers. Fig. 12 shows in greater detail the syringe with the second embodiment of the piston in the first use step. The piston is largely identical to that of the first embodiment, but comprises a cylindrical symmetrical recess 10 around the center axis of the piston in its lower surface. The lower surface, which is flat in the first form of drying, has a drying depression which extends upwards towards the piston rod but does not reach all the way to the end portion 8 of the piston rod.

The recess 10 is intended to further weaken the piston so that it becomes more resilient as the piston moves upwards in the syringe, but with almost unchanged behavior when the piston is pushed downwards. Alternatively, the recess, which has its greatest depth in the middle of the underside of the piston, can be replaced by a shallow, annular recess which extends circularly symmetrically about the central axis of the piston around the underside of the piston near its periphery. 535 700 Pig. 13 shows the syringe with the second embodiment of the piston in the second use step and fi g. 14 shows in greater detail the syringe with the second embodiment of the piston in the second use step. In Figures 13-14, the piston is moving upwards and the periphery of the piston is then stretched downwards. The downward stretching of the periphery provides a reduced radially outward pressure from the piston towards the inner surface of the syringe and this is sufficient to allow liquid to pass past the piston in the downward direction. In the second embodiment of the piston, its asymmetry between the bottom and top is even more pronounced than in the first embodiment. Here the upper part of the piston is conically extended upwards, while downwards it is provided with an approximately conical recess with the tip of the cone directed upwards.

Fig. 15 shows the second embodiment of the piston seen from the side, seen obliquely from above and seen from below. The second embodiment of the piston is also provided with five channels which further facilitate the passage of liquid when the piston is pushed upwards. The recess in the underside of the piston increases the tendency of the piston to allow its periphery to stretch as it is pushed upwards, compared to the first embodiment.

In the illustrated embodiments, the container with a tubular inner surface is exemplified by a syringe, but obviously the syringe can be any type of such container, where the piston according to the invention keeps its inner volume divided into two portions and where liquid can pass the piston only when the piston is stirred. one direction. The two embodiments of the piston are well-functioning examples of this. a more generalized shape having a convex upper surface and a lower surface less convex than the upper one, planar as in the first embodiment or concave as in the second embodiment. Both embodiments are illustrated with channels, but this is only an example and its not necessary for the function.

The terms concave and convex are typically used for spherical or near-spherical objects, but the terms here refer to the more generalized terms growing towards the center and shrinking towards the center, respectively. The container with a tubular inner surface in the two illustrated embodiments has a circular cross-section through the inner surface, but this can of course be elliptical, rectangular or have an optional shape. The terms growing towards the center then refer to a more arbitrarily chosen center point such as the center of gravity of the cross section. The illustrated two-chamber syringe can obviously be provided with several pistons which separate the storage volume into three or more sub-chambers. In both illustrated embodiments, the piston extends at the top all the way to the piston rod and is attached to it by casting the entire piston around the piston rod. The purpose of this is that the upper part that the piston should be forced to stretch when the piston is pushed upwards, while the more resilient lower part, which is not attached to any central element, tends to move outwards in radial direction when the piston is pushed downwards. A corresponding effect is achieved even if the piston is more voluminous on the upper side than on the underside, but obviously the attachment to the piston gives a greater such effect.

Claims (10)

1 535 700 Claim 1 A piston (4) for a container (1) with a cylindrical inner surface, wherein the piston and the container form parts of a syringe for medical purposes, wherein the container is provided with a sealing upper closure (3, 6) through which at least one piston rod (5) is slidably formed and where the piston is attached to the lower end of the piston rod, where furthermore the container has a lower closable opening (2), characterized! in that the main part of the upper surface of the piston is convex while the main part of the lower surface of the piston is less convex than the upper surface. A piston according to claim 1, characterized in that the upper surface of the piston extends to the carbon rod and is attached to it. A piston according to claim 1 or 2, characterized in that the main part of the lower surface of the piston is flat. A piston according to claim 1 or 2, characterized in! that the main part of the lower surface of the piston is concave. A piston according to any one of the preceding claims, characterized in that the upper surface of the piston around its periphery has an upper bevel. A piston according to any one of the preceding claims, characterized in that at least one recessed channel (9) extends on the upper surface of the piston from the periphery of the piston towards its center. A piston according to claim 6, characterized in! in that the at least one recessed channel extends from the upper bevel of the piston towards its center. A piston according to claim 5, characterized in! that the lower surface of the piston around its periphery has a lower bevel. A piston according to claim 8, characterized in! in that the upper surface of the piston before the upper bevel is convex while the lower surface of the piston inside the lower bevel is less convex than the upper surface. A piston according to claim 9, characterized in that the lower surface of the piston inside the lower bevel is flat. A piston according to claim 9, characterized in that the lower surface of the piston inside the lower bevel is concave. A container (1) with a cylindrical inner surface, wherein the container forms part of a syringe for medical purposes, wherein the container is provided with a sealing upper closure (3, 6) through which at least one piston rod (5) is slidably made and where a piston is attached to the lower end of the piston rod, where furthermore the container has a lower dry-closable opening (2), characteristics! in that the main part of the upper surface of the piston is convex while the main part of the lower surface of the piston is less convex than the upper surface. A container according to claim 12, characterized in that the upper surface of the piston extends to the piston rod and is attached thereto. A container according to claim 12 or 13, characterized in that the main part of the lower surface of the piston is flat. A container according to claim 12 or 13, characterized in that the main part of the lower surface of the piston is concave. A container according to any one of claims 12-15, characterized in that the upper surface of the piston around its periphery has an upper bevel. A container according to any one of claims 12-16, characterized in that on the upper surface of the piston at least one sunken channel (9) extends from the periphery of the piston towards its center. A container according to claim 17, characterized in that the at least one sunken channel extends from the upper bevel of the piston towards its center. A container according to claim 16, characterized in that the lower surface of the piston around its periphery has a lower bevel. A container according to claim 19, characterized in that the upper surface of the piston inside the upper bevel is convex while the lower surface of the piston inside the lower bevel is less convex than the upper surface. 535 700 21 A container according to claim 20, characterized in! that the lower surface of the piston inside the lower bevel is flat. A container according to claim 20, characterized in that the lower surface of the piston inside the lower bevel is concave. 10