CAP FOR A SYRINGE WITH LUER-LOCK CONNECTOR

Abstract

A cap for a syringe with Luer-lock connector comprising: a main body provided with a first handle portion and a second portion having an external threading for coupling with a corresponding internal threading of the Luer-lock connector of the syringe, an axial cavity having an aperture at the second coupling portion being formed in the main body; and a rubber housed in the axial cavity of the main body. The rubber has a surface facing the aperture of the axial cavity and designed to abut against an open free end of a tip of the syringe for air-tightly closing the open free end and raised elements are formed at the external threading of the second coupling portion.

Claims

1-11. (canceled)

12. A cap for a syringe with Luer-lock connector, comprising: a main body provided with a first handle portion and a second coupling portion having an external threading for coupling with a corresponding internal threading of the Luer-lock connector of the syringe, an axial cavity having an aperture (at the second coupling portion being formed in the main body; and a rubber housed in the axial cavity of the main body, wherein the rubber has a surface facing the aperture of the axial cavity and designed to abut against an open free end of a tip of the syringe for air-tightly closing the open free end; wherein raised elements are formed at respective crests of threads of the external threading of the second coupling portion and in that the raised elements are dimensioned so as to frictionally couple with a bottom of corresponding threads of the internal threading of the Luer-lock connector.

13. A cap according to claim 12, wherein the raised elements comprise at least two sets of raised elements provided in a diametrically opposite position on the external threading.

14. A cap according to claim 13, wherein each set of raised elements comprises at least one raised element (30).

15. A cap according to claim 13, wherein the raised elements of each set of raised elements are aligned therebetween along the external threading of the second coupling portion.

16. A cap according to any one of the preceding claims, wherein the raised elements have a substantially trapezoidal or rectangular section.

17. A cap according to claim 12, wherein the raised elements are recessed or aligned with respect to an edge of the external threading of the second coupling portion.

18. A cap according to claim 12, wherein the surface of the rubber facing the aperture of the axial cavity (is plane or convex with convexity facing the aperture of the axial cavity).

19. A cap according to claim 12, wherein the axial cavity comprises a side surface and a rigid bottom surface, against which a surface of the rubber (opposite to the surface facing the aperture of the axial cavity (abuts.

20. A cap according to claim 12, wherein the rubber further comprises at least one longitudinal groove formed in a side surface (thereof.

21. A cap according to claim 12, wherein the second coupling portion (has a conical mouth at a free end thereof.

22. A syringe with Luer-lock connector, and a pre-filled syringe comprising a cap according to claim 12.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0028] Further characteristics and advantages of the present invention will become clearer from the following detailed description of a preferred embodiment thereof, given below, by way of non-limiting example, with reference to the attached drawings. In the drawings:

[0029] FIG. 1 is a perspective view of a cap for a syringe with Luer-lock connector according to a preferred embodiment of the present invention;

[0030] FIG. 2 is an exploded perspective view of the cap of FIG. 1 and part of a Luer-lock connector of a syringe;

[0031] FIG. 3 is a perspective and longitudinal section view of the cap of FIG. 2 and part of a Luer-lock connector of a syringe;

[0032] FIG. 4 is an enlarged perspective view of a detail of a coupling portion of the cap of FIG. 1;

[0033] FIG. 5 is a partial perspective view and in longitudinal section of the cap of FIG. 1, mounted on a syringe with Luer-lock connector;

[0034] FIG. 6 is an enlarged view of a detail of FIG. 5; and

[0035] FIG. 7 is a perspective view of the cap of FIG. 1 mounted on a syringe with Luer-lock connector.

DETAILED DESCRIPTION OF EMBODIMENTS

[0036] With reference to FIGS. 1 to 6, a cap for a syringe with Luer-lock connector according to a preferred embodiment of the present invention is illustrated.

[0037] The cap, generally indicated with the reference number 100, comprises a main body 10, substantially cylindrical, including a first portion 14 for handling the cap 100 and a second portion 15 for coupling the cap 100 with a syringe with Luer-lock connector.

[0038] As shown in detail in FIGS. 2, 3 and 7, the syringe, generally indicated by reference number 1, is preferably a pre-filled syringe and comprises a typically transparent cylindrical body 2, for containing a product to be injected, and a plunger 3 sliding inside the transparent cylindrical body 2. A hollow and substantially frusto-conical tip 4, onto which a needle (not shown) is subsequently fitted for the injection of the product present in the transparent cylindrical body 2, extends from the transparent cylindrical body 2. At the tip 4 there is a Luer-lock connector 5 provided with an internal threading 6. A space S is delimited between the Luer-lock connector 5 and the tip 4.

[0039] The first handle portion 14 preferably has a faceted external surface 16 to facilitate the gripping of the cap 100 by a user in the step of screwing/unscrewing the cap 100 onto/from the syringe 1.

[0040] Preferably, the second coupling portion 15 has an external diameter smaller than the external diameter of the first handle portion 14, so that an annular surface 19 is delimited between the first handle portion 14 and the second coupling portion 15, which is designed to abut against a corresponding annular surface 7 of the Luer-lock connector 5, when the cap 100 is mounted on the syringe 1.

[0041] The second coupling portion 15 also has a conical mouth 18 at a free end thereof, which advantageously facilitates the insertion of the cap 100 into the space S comprised between the tip 4 and the Luer-lock connector 5 of the syringe 1.

[0042] The second coupling portion 15 has, in addition, an external threading 17 for coupling with the internal threading 6 of the Luer-lock connector 5 of the syringe 1.

[0043] In the external threading 17 of the second coupling portion 15, preferably at a crest portion of the threads, raised elements 30 are formed, preferably having a substantially rectangular or trapezoidal section, the function of which is to generate friction with corresponding threads of the internal threading 6 of the Luer-lock connector 5 in order to ensure a tight and unintentional anti-unscrewing closure of the cap 100 on the syringe 1.

[0044] In the illustrated embodiment, two sets of raised elements 30 are provided, each comprising at least one raised element, preferably three raised elements 30, provided on the external threading 17 in a diametrically opposite position. Alternatively, only one set of raised elements may be provided, or a number of sets of raised elements 30 greater than two, suitably distributed on the external threading 17 along the circumference of the second coupling portion 15, each set being composed of a number of raised elements less than or greater than three. For example, if three sets of raised elements are provided, these sets are preferably arranged at 120 degrees around the circumference of the second coupling portion 15 of the cap 100.

[0045] Preferably, the raised elements 30 of each set of raised elements are aligned with each other along the external threading 17 of the second coupling portion 15 of the cap 100 according to a longitudinal axis of the cap 100.

[0046] Preferably, the raised elements 30 are recessed or aligned, but never protruding, with respect to an edge of the external threading 17 of the second coupling portion 15 of the cap 100.

[0047] In particular, and as shown in detail in FIG. 6, the raised elements 30 constitute active components, which cause, when screwing the cap 100 onto the Luer-lock connector 5 of the syringe 1, a localised static friction to be generated between an upper surface 32 of the raised elements 30 and a bottom 8 of respective threads of the internal threading 6 of the Luer-lock connector 5.

[0048] This localised static friction is added to the one generated between the flanks 6a and 17a, respectively, of the internal threading 6 of the Luer-lock connector and the external threading 17 of the cap 100, advantageously avoiding that, in particularly extreme conditions, for example during the step of sterilisation of the syringe 1 in an autoclave, where high values of pressure, humidity and temperature are reached, a loosening of the cap 100 occurs, with consequent reduced tightness of the same and penetration of air into the cylindrical body of the syringe 1.

[0049] In fact, this configuration of the external threading 17 of the second coupling portion 15, in particular the presence of the raised elements 30, ensures that the interference between the cap 100 and the Luer-lock connector 5 is contained in a well-defined region, thus obtaining an effective unintentional anti-unscrewing effect and, at the same time, allowing the Luer-lock connector to deform elastically just enough to avoid cracks and breakage.

[0050] Preferably, the threads of the cap 100 and the threads of the Luer-lock connector 5 are slightly tapered, thereby further facilitating the operations of screwing and unscrewing the cap 100 on the syringe 1. In fact, the contact forces between the cap 100 and the Luer-lock connector 5 do not persist for the entire duration of the screwing and unscrewing steps of the capthat is, they are present in the final part of the screwing and in the initial part of the unscrewing. Furthermore, the contact forces between cap 100 and Luer-lock connector 5 are also generated at the raised elements 30.

[0051] As clearly visible in FIG. 3, an axial cavity 11, it being also substantially cylindrical, having an aperture 11a at the second coupling portion 15 is formed in the main body 10. The axial cylindrical cavity 11 also has a side surface 12 and a plane bottom surface 13, perpendicular to the longitudinal axis of the cap 100.

[0052] The main body 10 is made of a rigid and non-deformable material, for example compact polycarbonate (Makrolon?), cyclic-olefin polymer (COP), or cyclic-olefin copolymer (COC), and the plane bottom surface 13 of the axial cylindrical cavity 11 is also rigid and non-deformable.

[0053] The cap 100 also comprises a rubber 20, which is housed in the axial cylindrical cavity 11 of the main body 10.

[0054] The rubber 20 is substantially cylindrical in shape and has a surface 21, a surface 22, opposite to the surface 21 and facing the aperture 11a of the axial cavity 11 so as to abut, in use, against a free end 4a of the tip 4 of the syringe 1, and a side surface 23.

[0055] The surfaces 21 and 22 are preferably plane, while, at the side surface 23, at least one longitudinal groove 24, preferably a pair of opposed longitudinal grooves 24, more preferably a series of longitudinal grooves 24 are formed, which allow the user to deform the rubber 20 to advantageously facilitate the insertion thereof into the axial cylindrical cavity 11 of the main body 10, during the assembly of the cap 100. The longitudinal grooves 24 also advantageously allow air to escape when inserting the rubber 20 into the axial cavity 11 during the assembly phase of the cap 100, so that no air is trapped between the bottom surface 13 and the surface 21 of the rubber 20.

[0056] Alternatively, instead of being plane, the surface 22 of the rubber 20 designed to abut, in use, against the free end 4a of the tip 4 of the syringe 1 can be convex, with convexity facing the tip 4. In this case, as the cap is screwed onto the syringe, the convex surface 22 of the rubber 20 flattens, thus abutting against the free end 4a of the syringe 1, air-tightly closing the opening thereof.

[0057] In the assembled condition of the cap 100, shown in detail in FIG. 5, the surface 21 of the rubber 20 abuts against the bottom surface 13 of the axial cylindrical cavity 11 of the main body 10 and the side surface 23visible in FIG. 2is in contact with the side surface 12 of the internal axial cylindrical cavity 11 of the main body 10. On the other hand, the surface 22 of the rubber 20 abuts against the free end 4a of the tip 4 of the syringe 1.

[0058] In the illustrated embodiment, the bottom surface 13 of the axial cylindrical cavity 11 is a plane, rigid surface. Alternatively, recesses may be formed at the bottom surface 13, between which an abutment surface 21 of the rubber 20 is delimited.

[0059] In yet another alternative embodiment, a seat for housing a pin extending from the bottom surface 13 of the axial cylindrical cavity 11 of the main body 10 may be formed in the surface 21 of the rubber 20.

[0060] With reference to FIGS. 5 and 6, the sealing and unintentional anti-unscrewing action of the cap according to the invention is described below when the cap is mounted on the syringe 1.

[0061] In the mounting condition of the cap 100 on the syringe 1, the second coupling portion 15 of the main body 10 is screwed onto the Luer-lock connector 5 by coupling the corresponding threadings 17 and 6.

[0062] In particular, each raised element 30 formed on the external threading 17 of the second coupling portion 15 is frictionally coupled with the bottom 8 of a corresponding thread of the internal threading 6 of the Luer-lock connector 5 and this localised static friction is added to that produced by the coupling between flanks 6a and 17a, respectively, of the internal threading 6 of the Luer-lock connector and of the external threading 17 of the cap 100.

[0063] The advantage given by the frictional coupling between each raised element 30 and the bottom 8 of a corresponding thread of the threading of the Luer-lock connector is that it does not have such a tangential component as to unscrew the cap. The tangential component is instead always present in the friction between the flanks of the threads, since the threads are helical, and therefore the friction tangent to the flanks of the threads has a component that tends to unscrew the cap from the syringe. This aspect is of fundamental importance when the syringe, e.g. pre-filled with acid and placed in an autoclave, is subject to internal pressure. Indeed, the internal pressure pushes the cap axially and the tangential component of the friction between the flanks of the threads would tend to unscrew the cap. However, thanks to the friction between each raised element 30 and the bottom 8 of a corresponding thread of the threading of the Luer-lock connector 5, which has no such a tangential component as to unscrew the cap, the cap is prevented from unscrewing from the syringe 1.

[0064] Furthermore, the annular surface 19 of the cap 100 abuts against the corresponding annular surface 7 of the Luer-lock connector 5, thus providing a mechanical stop and at the same time ensuring a suitable elastic deformation of the rubber 20. In fact, when the annular surface 19 is in abutment against the Luer-lock connector 5, the rubber 20 has the plane surface 22 in abutment against the free end 4a of the tip 4 of the syringe 1 and the surface 21 against the plane, rigid bottom surface 13 of the axial cylindrical cavity 11 of the main body 10. The rubber 20 is therefore suitably elastically compressed between the free end 4a of the syringe 1 and the bottom surface 13 of the main body 10 of the cap 100.

[0065] Under its compressed condition, the rubber 20 generates an appropriate elastic reaction force, which acts on the threaded coupling between the second coupling portion 15 and the Luer-lock connector 5, so that the threadings 6 and 17 of the Luer-lock connector 5 and of the cap 100 press between them, completely eliminating any clearance between the threads, generating friction between them and therefore eliminating any possibility of unintentional unscrewing of the cap 100 from the syringe 1.

[0066] Furthermore, since the contact between rubber 20 and tip 4 of the syringe 1 is essentially frontal, that is, between the plane surface 22 of the rubber 20 and the free end 4a of the tip 4 of the syringe 1, there is no friction between the rubber 20 and the external surface of the tip 4. It follows that the operations of screwing and unscrewing the cap 100 by the operator are facilitated.

[0067] Under this mounted condition, the cap according to the invention achieves the desired air-tight and anti-unscrewing effect.

[0068] In fact, the rubber 20, in addition to air-tightly closing the free end 4a of the tip 4 of the syringe 1, due to the effect of the elastic deformation, increases the degree of coupling between the threadings 6 and 17, of the Luer-lock connector 5 and of the second coupling portion 15, respectively, with an anti-unscrewing effect which is very similar to that obtained by inserting an elastic washer between screw and nut, tightening the latter.

[0069] The localised static friction force generated between the surface 32 of each raised element 30 of the external threading 17 of the second coupling portion and the bottom 8 of the corresponding thread of the internal threading 6 also contributes to increase the anti-unscrewing effect of the Luer-lock connector 5 of the syringe 1.

[0070] Furthermore, the presence of the rubber 20 eliminates the anti-unscrewing effects due to thermal cycles and/or vibrations since the elastic material is able to absorb these effects, always guaranteeing an adequate elastic reaction force.

[0071] From the above description, the characteristics of the cap for a syringe with Luer-lock connector, and of the syringe comprising it, of the present invention are clear, as well as are the relative advantages.

[0072] Finally, it is clear that the cap as conceived herein is susceptible to many modifications and variations; furthermore, all the details are replaceable by technically equivalent elements. In practice, the materials used, as well as their dimensions, can be of any type according to the technical requirements. For example, the cap and the cylindrical body of the syringe can be made of the same material, so as to advantageously have the same thermal expansion coefficient.