Source: http://www.google.com/patents/US20050065476?ie=ISO-8859-1&dq=6,064,942
Timestamp: 2015-04-18 05:55:43
Document Index: 767251740

Matched Legal Cases: ['art 21', 'art 21', 'art 21', 'art 21', 'art 21', 'art 21', 'art 21', 'art 21', 'art 21', 'art 21', 'art 21']

Patent US20050065476 - Safety needle assembly - Google PatentsSearch Images Maps Play YouTube News Gmail Drive More »Sign inAdvanced Patent SearchPatentsThe invention relates to a safety needle assembly for injecting a fluid into a human body comprising a cylindrical housing with a bottom surface supporting a needle cannula and a shield telescopically movable relative to the housing. A spring located within the housing urges the shield in a distal needle...http://www.google.com/patents/US20050065476?utm_source=gb-gplus-sharePatent US20050065476 - Safety needle assemblyAdvanced Patent SearchPublication numberUS20050065476 A1Publication typeApplicationApplication numberUS 10/978,760Publication dateMar 24, 2005Filing dateNov 1, 2004Priority dateNov 30, 2001Also published asCA2468243A1, CA2468243C, CN1294997C, CN1596138A, DE60208933D1, DE60208933T2, DE60230933D1, EP1448256A1, EP1448256B1, EP1557191A2, EP1557191A3, EP1557191B1, US6855129, US7553293, US8728027, US20030120209, US20050107740, US20090227950, US20110021988, US20150038903, WO2003045480A1Publication number10978760, 978760, US 2005/0065476 A1, US 2005/065476 A1, US 20050065476 A1, US 20050065476A1, US 2005065476 A1, US 2005065476A1, US-A1-20050065476, US-A1-2005065476, US2005/0065476A1, US2005/065476A1, US20050065476 A1, US20050065476A1, US2005065476 A1, US2005065476A1InventorsKarsten Jensen, Niels NymarkOriginal AssigneeKarsten Jensen, Niels NymarkExport CitationBiBTeX, EndNote, RefManReferenced by (9), Classifications (17), Legal Events (1) External Links: USPTO, USPTO Assignment, EspacenetSafety needle assembly
BRIEF DESCRIPTION OF THE DRAWINGS The invention will be explained more fully below in connection with a preferred embodiment and with reference to the drawings in which: FIG. 1 Shows a perspective view of the safety needle assembly according to the invention. FIG. 2 Shows an exploded view of the safety needle assembly according to the invention. FIG. 3 Shows a perspective view of the needle shield. FIG. 4 Shows a perspective view of the locking element. FIG. 5 Shows a perspective view of the body of the housing. FIG. 6 Shows a schematically view of the body of the housing. FIG. 7 Shows a schematically view of the safety needle assembly according to the invention. FIG. 8 Shows a schematically view of the safety needle assembly according to the invention, with a part of the housing cut away. FIG. 9 Shows the locking protrusion in its first position. FIG. 10 Shows the locking protrusion in or moving towards its second position. FIG. 11 Shows the movement of the locking protrusion moving from the second to the third position. FIG. 12 Shows the locking protrusion in the third position. FIG. 13 Shows a perspective view of an embodiment of the safety needle assembly according to the invention. FIG. 14 Shows a part of the housing of an embodiment of the safety needle assembly according to the invention. FIG. 15 Shows an exploded view of the safety needle assembly according to the invention. FIG. 16 Shows a perspective view of the safety needle assembly stored in a container. The figures are schematic and simplified for clarity, and they just show details, which are essential to the understanding of the invention, while other details are left out. Throughout, the same reference numerals are used for identical or corresponding parts. DETAILED DESCRIPTION OF EMBODIMENT Initially it may be convenient to define that, the term �distal end� is meant to refer to the end of the safety needle assembly inserted into the patient, whereas the term �proximal end� is meant to refer to the end connected to the injection device. FIG. 1 shows a safety needle assembly comprising a housing 1 and a shield 2, the housing 1 is made up from a hub 3 and a body 4. The hub 3 and the body 4 is normally glued or welded together. The connecting surface 5 between the hub 3 and the body 4 is in the figures shown in a specific position, but could off cause be located as wanted. The hub 3 and the body 4 could even be moulded as one piece closed at the top surface 6 by a lit. The top surface 6 is provided with an opening 8 through which the shield 2 appears. The shield 2 is provided with a needle outlet 7 through which the needle cannula 30 can penetrate. The proximal end of the shield 2 is, as shown in FIG. 2, provided with eight outwardly projecting studs 10, which studs 10 has a planar fore front 11 and an angled back front 12. The housing 1 has a bottom surface 9 in the centre of which the needle cannula 30 is mounted. The needle cannula 30 can either be mounted such that a part of needle cannula 30 projects from the bottom surface 9 in the proximal direction, which is preferred for use with cartridges, or it can be mounted without this so called back needle, which is preferred for hypodermic syringes. Adjacent the bottom surface 9, at the proximal end of the housing 1, means are provided for mounting the safety needle assembly on to an injection device. These means would normally be a thread 35 such that the safety needle assembly can be screwed onto a pen syringe. FIG. 3 shows the shield 2 seen from the proximal end. The eight studs 10 are separated from each other by eight equally sized spaces 26. The angular back front 12 of the studs 10 forms together with the shield 2 a toothed ring 13 where the centre of the studs 10 forms the tops and the shield 10 within the spaces 26 forms the valleys. The locking element 16 seen in FIG. 2 is on the proximal outside surface provided with four locking protrusions 17. These locking protrusions 17 have, as shown in FIG. 4, an angled fore front 18 and a planar back front 19. The body 4 of the housing 1 is in FIG. 5 shown in perspective and in FIG. 6 in a sectional view. The body 4 is provided with four windows 20 and one longitudinal rib 21 for each window 20. The ribs 21 are provided on the inside surface of the body 4. These longitudinal ribs 21 extend through the entire length of the body 4 although divided into two parts (21 a, 21 b) by the windows 20. The distal part of this rib 21 is moulded uniform with a collar 24 provided at the distal end of the body 4 and terminates in a planar surface 14 at the distal end of the window 20. The proximal part of the rib 21 terminates at the proximal end of the window in a blocking surface 15, the use of which will be explained later. At the distal end of the body 4 there is provided four fins 22. These fins 22 is moulded uniform with the collar 24 at the distal end of the body 4, and has at the proximal end an angled surface 23 which terminates approximately in a position adjacent the middle of the windows 20. Although the embodiment here described has eight studs 10, four locking protrusions 17 and four windows 20, these parts could be provided in a different number, as shown in FIG. 15. When the safety needle assembly shown in FIG. 2 is assembled, a spring 25 is cocked between the bottom surface 9 of the housing 1 and the locking element 16 urging the locking element 16 and the shield 2 in a distal direction. The planar forefront 11 on the studs 10 abuts the collar 24 such that the shield 2 is connected to the body 4 of the housing 1. The assembled safety needle assembly is shown in FIGS. 7 and 8. FIG. 8 illustrates the inside of the safety needle assembly with the body 4 cut away. The shield 2 is located such within the body 4 of the housing 1 that each rib 21 and each fin 22 is located in the space 26 between two studs 10. The upper part 21 a of the ribs 21 are however not shown in FIG. 8, since this upper rib 21 a is not entirely necessary. The locking element 16 is thereafter mounted such that the angular forefront 18 on each locking protrusion 17 abuts the angled back front 12 on four of the studs 10 of the shield 2, whereby the side surface of the locking protrusion 17 and the side surface of the studs 10 forms a straight line which line abuts the side surface of the fins 22 of the body 4 of the housing 1. Once the shield 2 and the locking element 16 is correctly mounted within the body 4 of the housing 1, the spring 25 is located around the needle cannula 30 and the body 4 and the hub 3 are sealed together, rendering the safety needle assembly ready for use. The movement of the locking protrusion 17 is schematically shown in FIG. 9-12, showing the relative position of one of the locking protrusion 17 on the locking element 16, two of the studs 10 on the shield 2, one of the fins 22 on the inside surface of the body 4 of the housing 1 and one of the ribs 21 also located on the inside surface of the body 4 of the housing 1. FIG. 9 illustrates the safety needle assembly in its initial position, as shown in FIG. 8, with the shield 2 in its distal position where the shield 2 covers the needle cannula 30. When the shield 2 is pressed towards the skin of a user, the shield 2 and with it the studs 10, are moved in a proximal direction as indicated with the arrow 27. This movement also moves the locking protrusion 17 on the locking element 16 in the proximal direction against the force F of the spring 25. Once the locking protrusions 17 is moved free of the fins 22, as shown in FIG. 10, the angled fore front 18 of the locking protrusions 17 will slide along the angled back front 12 of the studs 10 and the angled fore front 23 of the fins 22 as indicated with the arrow 28. This movement will move the locking protrusions 17 into contact with the valleys of the toothed ring 13. Further movement of the shield 2 and thereby the studs 10 in the direction of the arrow 27 will only move the locking protrusions 17 further in the proximal direction. The injection is then executed with the shield 2 in its most proximal direction. The position of the fins 22 and the ribs 21 is such that the studs 10 are always guided either by the fins 22 or by the ribs 21. When the injection is over, the needle cannula 30 is retracted from the skin of the user, which will cause the shield 2 with the studs 10 and the locking element 16 with the locking protrusion 17 to move in the distal direction due to the impact of the force F executed by the spring 25. The arrow 29 in FIG. 11 indicates this movement. FIG. 12 illustrates how the force F of the spring 25 urges the locking element 16 with the locking protrusion 17 and the shield 2 with the studs 10 in the distal direction. When the angled fore front 23 on the fins 22 aligns the angled back front 12 of the studs 10, such that the two angled fore fronts 23, 12 form a diagonal line, the angled fore front 18 of the locking protrusion 17 will slide along this line into a position where the locking protrusion 17 is located between the upper part 21 a and the lower part 21 b of the ribs 21 i.e. between the planar surface 14 of the upper part 21 a of the ribs 21 and the blocking surface 15 of the lower part 21 b of the ribs 21. In this position the locking protrusion 17 and hence the locking element 16 and the shield 2 is irreversible locked. At the proximal end of the locking protrusion 17, the planar back front 19 will abut or at least be blocked by the blocking surface 15 on the ribs 21 of the body 4 of the housing 1, thereby rendering it impossible to move the shield 2 in the proximal direction. At the distal end, the angled fore front 18 of the locking protrusion 17 will abut the toothed ring 13 of the shield 2 and since the planar forefront 11 of the studs 10 on the shield 2 abuts the collar 24 of the body 4 of the housing 1 it will not be possible to move the shield 2 in the distal direction. Sideways the studs 10 of the shield 2 will be arrested between the upper part 21 a of the ribs 21 and the fins 22. As a result of this it will be impossible to move the shield 2 in any direction. Instead of having the angled fore front 18 of the locking protrusion 17 in abutment with the toothed ring 13 of the shield when the injection is over, the front end 36 of the locking element 16 can be design to abut the inner top end 37 of shield 2 once the locking protrusion 17 is in the locking position. This will make it virtually impossible to squeeze the angled fore front 18 of the locking protrusion 17 by pushing the shield 2 in the proximal direction. The body 4 of the housing 1 is provided with four windows 20 which windows 20 divides each of the four ribs 21 into an upper part 21 a and a lower part 21 b. When the safety needle assembly has been used, the locking protrusion 17 on the locking element 16 will be located between the upper part 21 a and the lower part 21 b of the ribs 21, and will thus be visible through the window 20. The locking protrusion 17, or a part of it, could be coloured in an inflammatory colour, or provided with another indication, which will render it very easy for a user to visibly inspect whether the safety needle assembly has been used or not just by glancing at the windows 20. The windows 20 could e.g. be provided as openings in the wall of the body 4. Prior to use, the safety needle assembly is delivered to the user sterilized and contained as is shown in FIG. 7. The container 31 is closed at the distal surface 32 and open at the proximal surface 33. The proximal surface 33 is sealed by a not shown removable seal. The container 31 has on the inside surface not shown ribs that mates ribs 34 located on the outside surface of the housing 1 preferably on the hub 3, such that the safety needle assembly can be screwed on and off a pen syringe without removing the container 32 from the safety needle assembly. Further the container could on the inside surface be provided with a number of not shown raised points supporting the safety needle assembly in a somewhat floating position making it easier for the steam or gas to fully surround the safety needle assembly during sterilization in case this type of sterilization is used. The spring 30 urging the locking element 16 and the shield 2 in the distal direction is preferably made from stainless non-corrosive steel such that the spring 30 will not be damaged during the steam sterilization process. A spring 30 particular suitable for this purpose is a 1.4462/SAF2205 spring. Another embodiment of the safety needle assembly according to the invention is disclosed in FIG. 13 and FIG. 14. FIG. 13 shows a housing 40 comprising of a hub 41 and body 42. Mounted inside the housing 40 are a shield 43 and a locking element 44. The shield 43 penetrates out of the housing 40 through an opening 45 located at the distal end of the housing 40 The shield 43 is provided with four studs 46 and ends at the proximal end in a toothed ring 38. This toothed ring 38 engages a second toothed ring 39 located on the locking element 44. The locking element 44 is further provided with a locking protrusion 49 located at the proximal end thereof. The needle cannula 30 is in FIG. 13 mounted in the bottom surface 50, which bottom surface 50 is provided in the housing 40, preferably in the hub 41. FIG. 13 shows the safety needle assembly with the shield 43 in the locked position, and FIG. 14 illustrates the inside surface of the housing 40 by showing the part of the housing 40 cut away in FIG. 13 seen from the backside. The four studs 46 on the shield 43 is guided in first horizontal tracks 51 provided on the inside surface of the housing 40. The locking protrusion 49 on the locking element 44 abuts a planar surface 48 in its initiate position and is guided in a second horizontal track 52 as the shield 43 is moved in the proximal direction. Once the shield 43 has been moved all the way back to its most proximal position and the injection is executed, a not shown spring positioned between the bottom surface 50 and the locking element 44 will urge the locking element 44 and hence the shield 43 in the distal direction. During this movement, the angled fore front 47 of the locking protrusion 49 will engage a diagonal track 53 also provided in the inside surface of the housing 40. While the shield 43 moves back to its initiate position, the locking element 44 and hence the locking protrusion 49 will rotate approximately 180 degrees in the diagonal track 53 and engage a locking chamber 54 provided at the distal end of the diagonal track 53, which locking chamber 54 has a blocking surface 55 that a planar back front 56 of the locking protrusion 49 will abut rendering further movement of the shield 43 impossible. The first toothed ring 38 of the shield 43 and the second toothed ring 39 of the locking element 44 support this movement due to mutual engagement of the angled surfaces of the two rings 38, 39. The shield 43 cannot be rotated relatively to the housing 40 due to the engagement of the studs 46 with the first horizontal tracks 51. Since rotation of the shield 43 is inhibited it is impossible to rotate the locking protrusion 49 of the locking element 44 backwards in the diagonal track 53, and the locking protrusion 49 will therefore remain in the locking chamber 54 thus rendering the safety needle assembly secured. A window could be provided in the housing 40 through which window the locking chamber 54 can be viewed, such that the user can get a visible indication whether the safety needle assembly has been used or not. An improved embodiment of the safety needle assembly disclosed in FIG. 1 to 12 is shown in FIG. 15 and in FIG. 16. In the following the numbers referring to the same element as in the previous figures has been given the same number plus one hundred. The safety needle assembly shown in FIG. 15 comprises a housing made up from a needle hub 103 and a body 104 both preferably injection moulded from PP. Both the hub 103 itself and the tower of the hub 103 is somewhat higher than shown in FIG. 2, while the body 104 is somewhat shorter. The needle cannula 130 is inserted in the tower of the hub 103 and glued to the hub 103 by a blob of glue 160. The body 104 is in this embodiment provided with three windows 120 and the locking element 116 is also provided with three locking protrusions 117. When the locking element 116 locks the safety needle assembly from reuse, the three locking protrusions 117 will be visible in the three windows 120 as earlier explained. The shield 104 which is preferably made from TPX can be transparent such that the tip of needle cannula 130 is visible for inspection by the user prior to injection, has on its proximal end six studs 110. The toothed ring 113 formed between these studs 110 is therefore in this embodiment only provided with six valleys. The locking element 116 which is preferably made from POM or PP is on the distal end surface provided with a serrated ring 161 which are used during the manufacturing process. When the safety needle assembly is being assembled a tool can enter the safety needle assembly through the needle outlet 107 in the shield 102 and engage this serrated ring 161 in order to rotate the locking element 116 to the correct position before the shield 102 and the locking element 116 is permanently encapsulated in the housing. For this purpose the needle outlet 107 needs to be large enough for the toll to pass through the needle outlet 107. In the embodiment shown in FIG. 10 there exist a slight possibility of rotating the shield 2 when the studs 10 are longitudinal located between the fins 22 and the lower part 21 b of the ribs 21. In order to prevent such accidental rotation, the studs 110 of the embodiment shown in FIG. 15 is provided with an additional guiding rib 162 which are guided in a number of not shown guiding tracks provided on the inside surface of the body 104 of the housing. Due to this no rotation between the shield 102 and the body 104 is possible, When the safety needle assembly is assembled the whole unit is packed in a container 131 which container 131 is sealed with a removable seal 163 and sterilized. The removable seal 163 is preferably made from paper. The distal part of the container 131 can be formed as a cup 164 holding a predetermined volume as shown in FIG. 16. The dosage of an injection device to be used with the safety needle assembly can thus be controlled by ejecting a predetermined number of doses into the cup 164 and verifying the expelled volume. This can be done either by filling the entire cup or by having indications printed on the cup 164. Some preferred embodiments have been shown in the foregoing, but it should be stressed that the invention is not limited to these, but may be embodied in other ways within the subject matter defined in the following claims. List of Parts: 1 Housing 2 Shield 3 Hub 4 Body 5 Connecting surface 6 Top surface 7 Needle outlet 8 Opening 9 Bottom surface 10 Stud 11 Planar ore front of studs 12 Angled back front of studs 13 Toothed ring 14 Planar surface 15 Blocking surface 16 Locking element 17 Locking protrusion 18 Angled front of locking protrusion 19 Planar back front of locking protrusion 20 Window 21 Rib 21 a Upper part of rib 21 b lower part of rib 22 Fin 23 Angled surface 24 Collar 25 Spring 26 Spaces on shield 27 Directional arrow 28 Directional arrow 29 Directional arrow 30 Needle cannula 31 Container 32 distal surface of container 33 proximal surface of container 34 Ribs on outside surface of housing 35 Thread 36 Front end of locking protrusion 37 Inner top end of shield 38 Toothed ring of shield 39 Second toothed ring of locking element 40 Housing 41 Hub 42 Body 43 Shield 44 Locking element 45 Opening 46 Studs 47 Angled fore front of locking protrusion 48 Planar surface 49 Locking protrusion 50 Bottom surface 51 First horizontal track 52 Second horizontal track 53 Diagonal track 54 Locking chamber 55 Blocking surface 56 Planar back front 102 Shield 103 Hub 104 Body 107 Needle outlet 110 Stud 113 Toothed ring 116 Locking element 117 Locking protrusion 120 Window 125 Spring 130 Needle cannula 131 Container 160 Glue 161 Serrated ring 162 Guiding rib 163 Seal 164 Cup Referenced byCiting PatentFiling datePublication dateApplicantTitleUS7708718 *Mar 14, 2007May 4, 2010Zehner John ASyringe shieldUS8425460Sep 1, 2006Apr 23, 2013Owen Mumford LimitedNeedle shroud assemblyUS8858510Apr 23, 2010Oct 14, 2014Shl Group AbSafety pen needle deviceUS20130053751 *Aug 30, 2012Feb 28, 2013Frank HolthamNeedle with an antiseptic swabUS20140048433 *Apr 27, 2012Feb 20, 2014Sanofi-Aventis Deutschland GmbhNeedle assembly storage systemCN102458537A *Apr 23, 2010May 16, 2012Shl集团有限责任公司Safety pen needle deviceEP2724740A4 *Jun 11, 2012Mar 4, 2015Suzuken KkPre-filled syringeWO2010126432A1 *Apr 23, 2010Nov 4, 2010Shl Group AbSafety pen needle deviceWO2011131778A1 *Apr 21, 2011Oct 27, 2011Sanofi-Aventis Deutschland GmbhCartridge holder and alignment interface* Cited by examinerClassifications U.S. Classification604/197, 206/365International ClassificationA61M5/00, B42D15/00, G09F1/04, A61M5/32Cooperative ClassificationB42D15/00, A61M5/002, A61M5/3271, G09F1/04, A61M2205/6063, A61M5/326, A61M2005/3247, A61M2005/3267European ClassificationG09F1/04, B42D15/00, A61M5/32C2H2FLegal EventsDateCodeEventDescriptionDec 10, 2012FPAYFee paymentYear of fee payment: 4RotateOriginal ImageGoogle Home - Sitemap - USPTO Bulk Downloads - Privacy Policy - Terms of Service - About Google Patents - Send FeedbackData provided by IFI CLAIMS Patent Services