Abstract
A fluid transfer device, or connector for a fluid transfer device, including a body member and a disconnecting member having a front portion and a rear portion. The disconnecting member is mounted to the body member so as to allow movement of its front portion relative to a fluid transfer tip, the fluid transfer tip may include a tapered friction fitting for a corresponding hub. There are provided engagement features operating between the disconnecting member and the body member which engage with one another to inhibit the front portion of the disconnecting member from moving relative to the fluid transfer tip. The device is arranged such that the disconnecting member deforms so that the engagement features are no longer in engagement with one another, thereby allowing the front portion of the disconnecting member to move relative to the fluid transfer tip and subsequently release the hub from the friction fitting.
Claims
1.-44. (canceled)
45. A connector for a fluid transfer device comprising a fluid transfer tip comprising a tapered friction fitting for a corresponding hub, the connector providing: a body member; a disconnecting member having a front portion and a rear portion; and engagement features operating between the disconnecting member and the body member which engage with one another to inhibit the front portion of the disconnecting member moving relative to the body member; the device being arranged such that upon application of a force to the rear portion of the disconnecting member, the disconnecting member deforms so that the engagement features are no longer in engagement with one another, thereby allowing the front portion of the disconnecting member to move relative to the fluid transfer tip and subsequently release the hub from the friction fitting.
46. (canceled)
47. A connector according to claim 45, wherein the body member comprises at least one of the engagement features and the disconnecting member comprises at least another one of the engagement features.
48. A connector according to claim 47, wherein the engagement features comprise at least one protrusion and at least one complementary recess.
49. A connector according to claim 48, wherein the protrusion is located on the body member and the recess is located on the disconnecting member.
50. A connector according to claim 45, wherein the engagement features are arranged such that there is a smooth transition from engagement to non-engagement.
51. A connector according to claim 45, wherein the body member comprises an integral mounting arrangement for the disconnecting member.
52. A connector according to claim 45, wherein the disconnecting member comprises a lever member and the mounting arrangement comprises one or more axles for pivotally mounting the lever member to the body member.
53. A connector according to claim 45, wherein the body member comprises means for gripping a barrel, hose or other suitable portion of a fluid transfer device.
54. A connector according to claim 45, wherein the disconnecting member comprises a screw thread arranged for holding the hub on the fluid transfer tip.
55. A connector according to claim 54, wherein the screw thread is an internal thread carried by a partial or hemi-cylindrical collar.
56. A connector according to claim 45, wherein the disconnecting member comprises a catch means arranged for catching the hub after it has been released from the friction fitting.
57. A connector according to claim 45, wherein the catch means is arranged opposite the screw thread.
58. A connector according to claim 56, wherein the disconnecting member is mounted to the body member so as to be resiliently biased such that the front portion moves back and the catch means is automatically released when the force is removed from the rear portion of the disconnecting member.
59. A connector according to claim 58, wherein the disconnecting member comprises a front surface that is substantially transverse to the axis of the body member and one or more side surfaces that extend in a direction substantially parallel to the axis of the body member.
Description
[0074] Some embodiments of the present invention will now be described, by way of example only, and with reference to the accompanying drawings, in which:
[0075] FIG. 1 is an exploded view of a fluid transfer device embodying the invention;
[0076] FIG. 2 is an enlarged view of the adapter of FIG. 1;
[0077] FIG. 3 shows the fluid transfer device in typical use;
[0078] FIGS. 4a and 4b are a pair of cross-sectional views on line A-A of FIG. 3 showing the lever member and corresponding adapter in both locked and unlocked positions;
[0079] FIG. 5 is a close-up view of a lever member in accordance with another embodiment of the invention;
[0080] FIG. 6 shows a lever member similar to that of FIG. 5 without the catch;
[0081] FIG. 7 shows another embodiment of a fluid transfer device wherein the axle and engagement features are integral;
[0082] FIG. 8 is a sectional view of the fluid transfer device of FIG. 7 with a lever member and hub attached;
[0083] FIG. 9 is a perspective view of the fluid transfer device of FIG. 8;
[0084] FIG. 10 shows another embodiment of the lever member with a threaded collar and catch integrally provided;
[0085] FIG. 11 shows the hub being screwed onto a fluid transfer device including the lever member of FIG. 10;
[0086] FIG. 12 is a sectional view of the embodiment of FIG. 11 with the hub in the locked position on the fluid transfer device;
[0087] FIG. 13 shows the lever member being depressed in order to release the engagement features and release the hub;
[0088] FIG. 14 shows the lever member being returned to its original position and the hub being released from the device;
[0089] FIG. 15 is an enlarged sectional view of the hub being held in the locked position by the threaded collar;
[0090] FIG. 16 shows the hub attached to the fluid transfer device in the locked position;
[0091] FIG. 17 is a cross sectional view of a fluid transfer device in accordance with the invention with the lever member in the locked position;
[0092] FIG. 18 is an enlarged view of the side walls of the lever member and body member of FIG. 17 when the lever member is in the locked position;
[0093] FIG. 19 is a view of the fluid transfer device when the lever member has been depressed;
[0094] FIG. 20 is a cross sectional view of the fluid transfer device when the lever member has been depressed and he side walls of the lever member have expanded;
[0095] FIG. 21 is an enlarged view of the side walls of the lever member and fluid transfer device when the lever member is in the un-locked position;
[0096] FIG. 22 is view similar to FIG. 2 of a further embodiment of an adapter in accordance with the invention;
[0097] FIG. 23 is an enlarged view of the gripping features of FIG. 22;
[0098] FIG. 24 is an exploded view of a fluid transfer device embodying the invention incorporating a lever member without a threaded collar;
[0099] FIG. 25 shows an assembled view of the fluid transfer device seen in FIG. 24;
[0100] FIG. 26 shows an exploded view of a fluid transfer device embodying the invention incorporating a different lever member without a collar; and
[0101] FIG. 27 shows a perspective view of the lever member seen in FIG. 26.
[0102] There may be seen in FIG. 1 an embodiment of a disconnecting mechanism for a fluid transfer device taking the form of a syringe 2. The syringe 2 generally comprises a fluid barrel 4 in communication with a male tip 6. The tip 6 is tapered from its aft end, proximal to the barrel 4, to its forward end according to the standard Luer slip design i.e. a 6% taper (equivalent to around 3.43). Fluid in the barrel 4 can be transferred through the tip 4 by pushing or pulling a plunger 8 inserted in the barrel 4. However, although a syringe 2 is shown in each of the embodiments for simplicity, such a Luer slip tip could equally be part of another fluid transfer device such as a drip, a hose connector or an extension bridge connector, as mentioned earlier.
[0103] FIG. 1 demonstrates how the syringe 2 can be connected with a body member in the form of an adapter (or connector) 10, a lever member 12 and a female hub 14. In this embodiment the lever member 12 is attached to the adapter 10. This adapter 10 can then be positioned on the syringe 2. The male connector tip 6 may be connected to a corresponding female hub 14 in order to transfer fluid to a needle 16 or other cannula mounted on the hub 14. Although not shown, the needle 16 might already be inserted into a living subject, for example for IV therapy with the hub 14 providing an IV port for the injection and/or removal of various fluids.
[0104] The tapered tip 6 is inserted into the hub 14 and forms a friction fit that is fluid-tight. In each of the embodiments, a lever member 12 is provided that can be manually operated to move relative to the male tip 6 between a first position, proximal to the syringe barrel 4 and a second position spaced from the first position towards the distal end of the male tip 6 so as to push against the hub 14. Operation of the lever member 12 therefore acts to disconnect the syringe hub 14 from the tip 6 without a user needing to pull or tug the syringe hub 14 to release the friction fit of the Luer slip connection.
[0105] In the embodiment of FIG. 1 the lever member 12 is pivotally mounted to the adapter 10 which is attached to the syringe barrel 4. The adapter 10 can be held on the syringe 2 by any suitable means. This may be a friction fit or there may be locking features that hold the adapter 10 on the syringe barrel 4. Alternatively the adapter 10 may comprise an internal thread and the syringe 2 may comprise an external thread to allow the adapter 10 to be screwed onto the syringe 2.
[0106] The lever member 12 comprises a front surface 18 and rearwardly extending surface. The rearwardly extending surface comprises a top surface 20 and side surfaces 22. In the embodiment shown in FIG. 1 the lever member further comprises a screw threaded collar 24 and a catch 26. The purpose of the threaded collar 24 is to engage with the hub 14 to lock it in position and the catch 26 is present to catch the hub 14 once it has been released from the male tip 6 by the lever member 12. The collar 24 carries slanted threads on its internal surface.
[0107] There is shown in FIG. 2 an enlarged view of the adapter 10. The adapter 10 has the general form of an annular band 28 enabling it to be fitted onto the syringe 2. The band 28 has a smooth inner surface 30. This inner surface 30 could be tapered or stepped to allow the adapter 10 to be fitted on to syringe barrels or other devices which have different diameters. In this embodiment the adapter is held on due to the frictional force between the adapter 10 and the outer surface of the syringe barrel 4.
[0108] The adapter 10 comprises two axle portions 32 integrally moulded at its forward end. These mount the lever member 12 to the adapter 10 so that it can pivot about an axis defined by the axle portions 32. The adapter 10 further comprises protrusions 34 extending from a rear part thereof. The protrusions 34 have chamfered edges 36 which ensure that they pass smoothly into and out of corresponding recesses on the lever member 12 as will be explained hereinbelow.
[0109] FIG. 3 shows the fluid transfer device 2, adapter 10, lever member 12 and female hub 14 in normal use. The adapter 10 is positioned on the device 2 and the lever member 12 is pivotally mounted to the adapter 10 in such a way that pivotal movement is inhibited as is shown more clearly on the left hand side of FIG. 4. The female hub 14 can be screwed onto the male connector 6 tip by screwing it through the thread on the threaded collar 24. This is made possible as the hub 14 comprises an annular flange 40. As the collar 24 is hemi-cylindrical in the embodiment shown, it is not necessary for the hub 14 to have a threaded section, an annular flange is sufficient to allow it to engage with the half screw thread 24. In different embodiments if the collar extends substantially around the male connector tip 6 then it may be necessary for the hub 14 to be threaded. The catch 26 on the lever member 12 prevents the hub 14 from being dangerously ejected from the device as will be explained later.
[0110] As seen in FIGS. 1 and 3, the lever member 12 is formed in a shroud shape which extends rearwardly and partially surrounds the adapter 10 and syringe barrel 4 through an angle of approximately 270. Internal sockets (not shown) receive the axle portions 32 when the lever member 12 is clipped onto the adapter 10 to allow for pivotal movement between them. As shown in FIG. 4a, however, such pivotal movement is inhibited by the protrusions 34 on the adapter 10 being received in complementary recesses 38 on the inner surface of the side portions 22 of the lever 12. This can therefore be considered to be a locked position.
[0111] FIG. 4b shows what happens when a user applies a force to the rear part 20 of the lever member 12. Pivotal movement is inhibited by the engagement between the protrusions 34 and recesses 38, but because the lever member 12 is moulded from a flexible plastic material the force applied to the rear part 20 of the lever causes the side surfaces 22 of the lever member to deform and bow out. As a result the recesses 38 are disengaged from the protrusions 34 and so the lever member 12 can then be pivoted about the axle portions 32 (seen in FIGS. 1-3).
[0112] In the embodiments shown the protrusions 34 and recesses 38 are positioned centrally about the axis of the fluid transfer device 2, however it will be appreciated that depending on the application they could be positioned away from the centre axis and further towards the top or the bottom of the adapter 10.
[0113] FIG. 4 illustrates that the shape of the lever member 12 can provide a resilient bias. Here the top portion 20 of the lever member is narrower in horizontal extent than the lower section. When the lower sections 22 are made to bow out by an applied force as seen in FIG. 4b, when the force is subsequently removed, the deformed sides 22 tend to return to their original shape. As the top portion 20 is narrower than the lower portion 22, this pulls the lever member 12 upwards and thus causes the protrusions 34 and recesses 38 to become re-engaged, thus locking the lever member 12 in place once more.
[0114] Because the lever member 12 is locked into position unless pressure is applied to the rear portion 20, when the hub 14 is screwed into the threaded collar 24, the collar 24 (which is an integral part of the lever member 12) resists the tendency to be drawn up by the hub 14 which would otherwise give rise to a tendency to slip off the flange 40 (see FIG. 3) and so reduce the connection strength.
[0115] FIG. 5 shows a different embodiment of the lever member 12. The lever member 12 still has a shroud shape with a hemi-cylindrical collar 24 and a catch 26. However in this embodiment the collar 24 also comprises split sections 41 which extend away from the collar 24 in a conical shape. This effectively increases the size of the opening of the collar 24 and makes it easier for the user to locate the female hub onto the device. FIG. 6 shows a similar embodiment except there is no catch provided.
[0116] FIG. 7 shows a further embodiment. In this embodiment instead of the annular adapter there is provided an adapter 42 that can be fitted directly to a hose or other fluid transfer device rather than a syringe. In this embodiment it can be seen that the aft end of the adapter 42 comprises a nozzle 44 which can be connected to another device. This has a cylindrical section 46 with an enlarged frusto-conical end portion 48. This allows a hose or other device to be slid easily onto the end of the device and be held in place. In other embodiments (not shown) a similar adapter could be provided which forms a luer lock/luer slip male/female bridge extension which is able to connect to other devices which luer lock/luer slip compatiblee.g. by including in the adapter a hub-like structure able to receive a standard male tip and a tip-like structure able to receive the hub bearing the needle.
[0117] The adapter 42 also comprises an integral male connector tip 6 and the adapter 42 shown in FIG. 7 also comprises axle portions 32 for enabling a lever member 12, 12 to be mounted to the adapter 42. Also seen on the side of the adapter 42 is one of two protrusions 34 which engage in complementary recesses in the lever member 12, 12 to lock it into position as previously described. A reinforcing ring 50 of material ensures that when pressure is applied to the lever member 12, 12 it does not deform into the void space around the adapter 42 and instead expands to disengage the protrusions 34.
[0118] Also shown is a base plate 52 on the opposite side of the adapter 42 to the axle portions 32. This has a curved rear portion 54. The base plate 52 is provided to allow the user to grip the adapter 42 securely. This assists both when positioning the female hub 14 on the male tip 6 and when releasing the hub 14.
[0119] FIG. 8 shows an assembled implementation of the adapter 42 of FIG. 7, in which the female hub 14 mas been placed on the male tip 6. It can be seen that the flanged portion 40 of the hub 14 is held in place by the internally threaded collar 24 on the lever member 12.
[0120] FIG. 9 is another view of the same embodiment whereby the lever member 12 and hub 14 are shown. This Figure shows where the user can grip both the lever member rear portion 20 and the base plate 52. In this Figure the benefit provided by the split diverging portion 41 of the collar 24 can be seen since it effectively increases the aperture size of the collar, making guiding the hub 14 into the internally threaded collar 24 easier.
[0121] FIG. 10 shows he lever member 12 of FIG. 1. The threaded collar 24 comprises half a turn of internal thread 56 (slanted thread) which enables the user easily to screw the hub onto the device as it requires turning the hub (not shown) through a small angle to attach it.
[0122] FIGS. 11-14 show the sequence of events when a hub 14 is attached to the device and later removed. As seen in FIG. 11 the device comprises an adapter 10 carrying a lever member 12 attached to a syringe 2 as previously described, e.g. with reference to FIG. 1. The hub 14 bearing a needle 16 is attached to the syringe 2 by first by placing the hub 14 onto the male connector tip 6 and screwing it into position. During this the flange 40 on the hub 14 engages with the internal thread on the collar 24. Throughout the attachment of the hub 14, the lever member 12 remains in the locked position whereby the protrusions 34 and recesses 38 are in engagement. This ensures that when the hub 14 is screwed on, the lever member 12 is not pulled towards the distal end of the male connector tip 6, thus ensuring a good connection between the hub 14 and male tip 6. Thus as the hub 14 is screwed on, the connection with the male tip 6 is improved and a better fluid-tight fit is achieved.
[0123] Once the hub 14 is fully screwed into position it is in a locked position. It is held in place by the friction fit provided by the male tip 6, and by the screw fit of the threaded collar 24 (i.e. a so-called Luer Lock connection). This locked position can be seen in FIG. 12. In this state the user can apply pressure to the plunger 8 which will result in fluid being transferred through the male tip 6 and out of the needle 16.
[0124] When the user has finished using the device and wishes to remove the female hub 14, they simply apply pressure to the top surface 20 of the lever member 12. This process can be seen in FIG. 13. The applied pressure causes the side surfaces 22 of the lever member 12 to deform and thus the recesses 38 disengage from the protrusions 34. As soon as the recesses 38 are free from the protrusions 34, the force applied to the lever 12 causes it to rotate about the axle portions 32. This causes the threaded collar 24 to move away from the flange 40 on the hub 14 and the front surface of the lever member 12 to move towards a distal end of the male connector tip 6 pushing away the female hub 14. This acts to release the hub 14 from the friction fit. The catch 26 also moves towards the hub 14 to arrest its free movement and prevent it from being ejected dangerously from the device. At this stage, as shown in FIG. 13, the hub 14 is still loosely over the male tip 6, however it is held only by the catch 14.
[0125] When the user wishes to remove the female hub 14 completely for safe disposal, they can release the applied pressure to the lever member 12. This process is illustrated in FIG. 14. After the force being applied to the lever member 12 is released, the lever member 12 returns to its un-deformed state and so to its locked position as previously described with reference to FIG. 4. The hub 14 is thereby freed from the catch 26 and can be discarded appropriately in a sharps bin or other suitable place.
[0126] FIG. 15 shows an enlarged view of the hub 14 when screwed onto the adapter and held in position by the threaded collar 24. The internal thread 56 grips the flange 40 on the hub 14. It is clear from this view that in this embodiment there is a minimal amount of thread 56 on the collar 24. This allows a quick and easy attachment of the hub 14 to the device since it is only necessary to turn it through a small angle. In situations where a stronger connection is required, for example where the pressures involved are higher, the collar 24 may be provided with more turns of thread 56
[0127] FIG. 16 shows another view of all the components of FIG. 1 together in a locked position. It can be seen that the adapter 10 has been slid onto the chamber 4 of the syringe 2. FIG. 17 is a sectional view on line A..A of FIG. 16. It is possible to see how the axle portions 32 engage with sockets 60 on the lever member 12 providing a pivot axis. Also the protrusions 34 and recesses 38, which form the locking mechanism, can be seen.
[0128] FIG. 18 is an enlarged view the circled area of FIG. 17 showing the protrusions 34 on the adapter 10 engaging with the recesses 38 on the side walls 22 of the lever member 12. It may be seen that the protrusion 34 is a relatively loose fit in the recess 38 to ensure that the protrusion 34 is reliably received in the recess 38 without becoming caught on the edge thereof. The small amount of play this permits is not sufficient to dislodge the hub 14. The Applicant has appreciated that several variations in the shape of the protrusion, and a tight/loose fit in the corresponding recess enable adjusting the design to an optimal function.
[0129] FIGS. 19 to 21 correspond to FIGS. 16-18 for the case where the lever rear portion 20 is pressed down to release the lever 12. FIG. 19 shows the hub 14 disengaged and pushed away from its friction fit with the tip and so partially disconnected from the device as described above with reference to FIG. 13.
[0130] FIG. 20 shows how the side surfaces 22 of the lever member 12 expand to disengage the engagement means. Applying a force to the top surface 20 of the lever member 12 causes the protrusions 34 to press against the sides of the recesses 38. The force being applied therefore goes towards expanding the side surfaces 22 causing the lever member 12 to deform. This causes the sides 22 to bow out so that the recesses 38 separate away from the protrusions 34. Once the protrusions 34 and recesses 38 are out of engagement, the lever member 12 is free to rotate further.
[0131] Also visible in FIG. 20 are sockets 60 on the lever member 12 in the form of elongated slots. The slots 60 receive the axle portions 32 on the adapter 10. The slots 60 are elongated so as to accommodate the relative movement between the lever member 12 and the adapter 10 when the lever is depressed without the axles portions 32 becoming disengaged from the slots 60.
[0132] FIG. 21 shows an enlarged cross sectional view of the protrusions 34 and recesses 38 when the lever member 12 is in the unlocked position. It is clear that the sidewalls 22 of the lever member have expanded and the lever member 12 is free to pivot about the axle portions 32. As the lever member 12 pivots, the protrusions 34 move along the inside surface of the side walls 22. Although in the embodiment described the protrusions 34 pass along the inside surface, a groove may be provided on the inside surface of the sidewalls 22 to assist in directing the motion of the protrusion 34 and thus the lever member 12.
[0133] As described above, the hub 14 is typically attached to the device by pushing it onto the tip 6 whilst at the same time screwing it into the threaded collar 24. As an alternative method it is also possible first to depress the lever member rear portion 20, which disengages the protrusions 34 and recesses 38 and causes the lever member to pivot. The threaded collar 24 is pivoted away from the tip 6. The hub 14 can then be pushed onto the tip 6 and the lever member 12 can be released. The resilience of the lever member 12 causes it to return to its original locked position. The threaded collar 24 also returns to engage the flange 40 of the hub. The hub 14 can then be rotated a small amount to screw it into its final position. This method is advantageous as it requires minimal turning of the hub which may be difficult in instances where the hub is attached to a needle, or in instances where the hub is already attached to a living subject.
[0134] FIG. 22 shows an alternative embodiment of an adapter 10. This embodiment provides extra gripping means 62 on the adapter 10 to reduce the risk of the adapter being made to slip on the barrel 4 when a hub 14 is screwed onto the device. It can be seen that there are four high-friction gripping fingers 62 provided around the circumference of the adapter 10, however the number of and placement of these may vary depending on the application. The gripping fingers 62 are moulded as part of the adapter 10 and decrease its effective internal diameter to make a tighter fit. There also have clip sections 64 which may provide further grip or may lock into corresponding grooves on the barrel 4 of the device 2. The adapter 10 also comprises a lipped section 66 which abuts against the front surface of the fluid transfer device 2 when it is fully on the device.
[0135] Also shown in FIG. 22 is an alternative form of protrusion 34. It can be seen that the protrusion 34 has a fin-like shape with a tapered edge 70 tapering towards the bottom of the adapter 10 and a horizontal edge 72. Such a protrusion 34 is advantageous as the horizontal edge 72 ensures that the lever can not be pivoted downwards when the hub is being screwed on. It is only possible to dislodge the lever member 12 from the edge 72 when there is a significant force applied to the top surface 22 of the lever member 12. Furthermore the tapered face 70 ensures that when the pressure to the lever member 12 is removed, the recess on the lever member 12 can easily slide over the protrusion 34 and return to its locked position. This ensures that the device is always in a locked position when no force is being applied to the lever member 12.
[0136] FIG. 23 shows an enlarged view of the additional gripping fingers 62 provided on the adapter 10. It is seen that the gripping fingers 62 are provided on the lipped section 66 at the end of the adapter. The adapter 10 is typically made from plastic, this allows the gripping means 62 to flex towards the wall of the adapter 10 during attachment to a device. This flexibility ensures that a strong grip is achieved with the fluid transfer device 2, and it also allows the adapter 10 to be used with devices that have slightly varying diameters
[0137] In the embodiments shown the protrusions and axles are located on the adapter or fluid transfer device. However it is appreciated the both the axles and/or protrusions may be provided on the lever member and corresponding recesses may be provided on the adapter or fluid transfer device. Indeed there are many other possible ways in which engagement features could be provided to inhibit movement between the lever member and adapter.
[0138] It will be appreciated that it is not essential for an adapter to be providedthe invention could be implemented using a specially designed fluid transfer device. Moreover it is not essential to use a pivoting lever memberother forms of disconnecting member are contemplated such as a linearly sliding disconnecting member.
[0139] Whilst the lever members seen in previous Figures all have a threaded collar mounted on the front surface of the lever member which may lock onto the hub, it will be appreciated that this may not always be the case. FIGS. 24-27 provide further examples of a lever member which does not comprise a threaded collar.
[0140] There may be seen in FIG. 24 an embodiment of a disconnecting mechanism similar to that of FIG. 1 for a fluid transfer device taking the form of a syringe 2. The syringe 2 generally comprises a fluid barrel 4 in communication with a male tip 6. The tip 6 is tapered from its aft end, proximal to the barrel 4, to its forward end according to the standard Luer slip design i.e. a 6% taper (equivalent to around 3.43). Fluid in the barrel 4 can be transferred through the tip 6 by pushing or pulling a plunger 8 inserted in the barrel 4. However, although a syringe 2 is shown in each of the embodiments for simplicity, such a Luer slip tip could equally be part of another fluid transfer device such as a drip, a hose connector or an extension bridge connector, as mentioned earlier.
[0141] FIG. 24 demonstrates how the syringe 2 can be connected with a body member in the form of an adapter 10, a lever member 112 and a female hub 14. In this embodiment the lever member 112 is attached, e.g. pivotally mounted, to the adapter 10. This adapter 10 can then be positioned on the syringe 2. The male connector tip 6 may be connected to a corresponding female hub 14 in order to transfer fluid to a needle 16 or other cannula mounted on the hub 14. Although not shown, the needle 16 might already be inserted into a living subject, for example for IV therapy with the hub 14 providing an IV port for the injection and/or removal of various fluids.
[0142] The tapered tip 6 is inserted into the hub 14 and forms a friction fit that is fluid-tight. As will be appreciated from the description above, the lever member 112 can be manually operated to move relative to the male tip 6 between a first position, proximal to the syringe barrel 4 and a second position spaced from the first position towards the distal end of the male tip 6 so as to push against the hub 14. Operation of the lever member 112 therefore acts to disconnect the syringe hub 14 from the tip 6 without a user needing to pull or tug the syringe hub 14 to release the friction fit of the Luer slip connection.
[0143] In the embodiment of FIG. 24 the lever member 112 is pivotally mounted to the adapter 10 which is attached to the syringe barrel 4. The adapter 10 can be held on the syringe 2 by any suitable means. This may be a friction fit or there may be locking features that hold the adapter on the syringe barrel 4. Alternatively the adapter 10 may comprise an internal thread and the syringe 2 may comprise an external thread to allow the adapter 10 to be screwed onto the syringe 2.
[0144] The lever member 112 comprises a front surface 118 and rearwardly extending surface. The rearwardly extending surface comprises a top surface 120 and side surfaces 122. The lever member 112 in this Figure differs from the lever member 12 of FIG. 1 in that it it does not comprise a threaded collar 24. The lever member 112 still comprises a catch 126. The purpose of the catch 126 is to catch the hub 14 once it has been released from the male tip 6 by operation of the lever member 112.
[0145] The adapter 10 has the general form of an annular band 28 enabling it to be fitted onto the syringe 2. The band 28 has a smooth inner surface 30. This inner surface 30 could be tapered or stepped to allow the adapter 10 to be fitted on to syringe barrels or other devices which have different diameters. In this embodiment the adapter 10 is held on due to the frictional force between the adapter 10 and the outer surface of the syringe barrel 4.
[0146] The adapter 10 comprises two axle portions 32 integrally moulded at its forward end. These mount the lever member 112 to the adapter 10 so that it can pivot about an axis defined by the axle portions 32. The adapter 10 further comprises protrusions 34 extending from a rear part thereof.
[0147] FIG. 25 shows the fluid transfer device 2, adapter 10, lever member 112 and female hub 14 in normal use. The adapter 10 is positioned on the device 2 and the lever member 112 is pivotally mounted to the adapter 10 in such a way that pivotal movement is inhibited. The female hub 14 can be pushed onto the male connector 6 tip by applying a suitable force. The catch 126 on the lever member 112 prevents the hub 14 from being dangerously ejected from the device as previously explained.
[0148] As seen in FIGS. 24 and 25, the lever member 112 is formed in a shroud shape which extends rearwardly and partially surrounds the adapter 10 and syringe barrel 4 through an angle of approximately 270. Internal sockets (not shown) receive the axle portions 32 when the lever member 112 is clipped onto the adapter 10 to allow for pivotal movement between them. Whilst it cannot be seen in these Figures, the lever member 112 also comprises internal recesses, similar to the recesses 38 on the lever member illustrated in FIG. 4. It is these recesses which engage with the protrusions 34 on the adapter 10.
[0149] FIG. 26 shows a further embodiment in accordance with the present invention. Here it can be seen that an adapter 10 as seen in FIG. 22 is used with a corresponding lever member 212 and a typical syringe 2. The syringe 2, and hub 14 are the same as those described earlier with respect to FIGS. 1 and 24. The lever member 212 is formed for use with the adapter 10. Similarly to the lever member 112 in FIG. 24, the lever member 212 comprises a front surface 218, a top surface 220, side surfaces 222 and a catch 226. However, the lever member 212 differs in that it comprises an external protrusion 268. This external protrusion 268 is present on each side surface 222 of the lever member 212 and is formed directly within the side surface 222.
[0150] FIG. 27 shows a perspective view of the lever member 212. Here it can be seen that the protrusion 268 forms a recess 238 on the inside of the side surfaces 222. It is this recess 238 which engages with the protrusion 34 on the adapter 10 seen in FIG. 26. The recess 238 has a sharp defined edge 270. This edge 270 engages with the protrusion 34 and prevents any pivotal motion of the lever 212 until a sufficient force is applied to the lever member 212 which is sufficient to expand the side surfaces 222 of the lever member 212 so that this edge 270 no longer engages with the protrusion 34. After this force is applied the lever member 212 is then able to pivot about the axle portions 32.
[0151] Also shown in FIG. 27 are the mounting points 272 for the lever member 212. These mounting points accommodate the axle portions 32 on the adapter 10. An elongated slot 274 is also formed on the internal side of the side walls 222. This elongated slot 274 allows the lever member 212 to be slid onto the adapter 10 and mounted to the axle portions 32 and minimises the expansion of the side walls 222 of the lever member 212. It is appreciated that the side walls 222 need to be partially expanded to accommodate the axle portions 32 in the mounting points 272 to ensure that the lever member 212 cannot easily become separated from the adapter 10. The slot 274 minimises the extent to which the side walls 222 need to expand during attachment and thus prevents any undesired expansion and potential damage. The elongated slots 274 also assist in guiding the lever member 212 onto the adapter 10 and thus assist in generally assembling the device.
