JP2008264030A - Valve connector for medical line - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To overcome the drawbacks of a conventionally known valve connector. <P>SOLUTION: A valve connector for medical infusion lines includes an external tubular body 1 with an inlet end 4 and an outlet end 24, an internal hollow spike 2 and an intermediate sealing member 3. The sealing member 3 has a head 35 with pre-slit 38 and an elastic hollow element 36. The elastic hollow element 36 is formed with fluid-tight members 47 and 48 in contact with the hollow spike 2 and with an elastic thrust means. The thrust means tends to maintain the elastic head 35 in a condition of closing. The elastic thrust means comprises a base part 37 joined to the elastic hollow element 36 of the sealing member 3 through a generally transverse annular wall 45. The wall 45, during axial displacement of the elastic head 35 from the condition of closing to the condition of opening, bends within an annular chamber 50 defined between the base part 37 and a portion with a conical surface 29 of the hollow spike 2. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a valve connector for use in a medical line, for example, an infusion line for introducing a fluid infusion substance by an introducer, typically, for example, a luer connector or a luer lock connector of a needleless syringe.

  This type of valve connector is known, for example, from US Pat. Nos. 5,242,342, 5,676,346, 6,706,022, 5,700,288, and 6,682,509.

  In particular, US Pat. Nos. 5,700,288 and 6,682,509 describe a valve connector of the preamble of claim 1, wherein an inlet end provided for engaging a cavity and a liquid introducer. And a tubular body having an outlet end. A hollow spike is set axially within the cavity of the tubular body and has a closed tip set opposite the inlet end of the tubular body and spaced away from it by an axial distance. The hollow spike is in communication with the outlet end of the tubular body and has at least one side hole set at a distance from the closed tip for communicating with the cavity of the tubular body. Yes. The connector further comprises an elastic sealing member, which has an elastic head with a pre-slit, which is normally closed (or released) within the inlet end of the tubular body. In this state, the pre-slit is closed. The resilient head moves axially to interact with this tip towards the closed tip of the hollow spike when the introducer is inserted into the inlet end of the tubular body, and elastically deforms. In this state, the pre-slit opens. The sealing member of the valve connector further includes an elastic hollow element connected to the head, which is set between the tubular body and the hollow spike and has sealing means for contacting the hollow spike, whereby the head is When set to the undeformed closed state, the at least one side hole is isolated from the cavity of the tubular body. The elastic hollow element includes elastic thrust means, which tend to keep the head of the sealing member closed as described above.

  These types of valve connectors must meet a range of basic requirements, since their use often has critical implications for the survival of patients who utilize them.

  First, closing the inlet end of the tubular body, as performed by the head of the sealing member, ensures a complete antibacterial barrier even after repeated opening and closing of the valve connector. Should be substantially fluid tight.

  Second, the action of opening and closing the connection between the inlet and outlet ends of the connector at the moment of inserting and removing the introducer is very reliable and repeatable. There should be no risk of malfunctions that are required and lead to serious risks for the patient connected to the valve connector. For this purpose, the number of moving mechanical members of the valve connector must be as small as possible.

  Third, the connectors must be able to effectively support the overpressure that may be generated in their use during use, and in the closed (or released) state, they are effective. It must be possible to ensure good fluid tightness at positive and negative pressure.

  Finally, the valve connector should be easy to clean and sterilize at the inlet end, typically using a cotton swab soaked in a sterilizing agent.

  In the case of the valve connectors known from the above mentioned US Pat. Nos. 5,700,288 and 6,682,509, between the inlet and outlet ends of the tubular body through one or more side holes of the hollow spike when the introducer is engaged. Is opened after the tip of the hollow spike has passed through the pre-slit of the elastic head. For example, in other embodiments known from WO-2005 / 011799 and WO-2006 / 013433 (filed in the name of the Applicant), the closed tip of the hollow spike is conversely pre- -It is made into the shape which makes the head of a sealing member the above-mentioned open state, without passing a slit.

  In all the above known solutions, the elastic thrust means of the elastic hollow element of the sealing member typically has a wavy or compressive shape that when compressed axially causes a contraction like that of the concertina. It has a bellows-like wall or a wall that is not wavy but shrinks in the axial direction anyway. When the elastic hollow element is axially compressed or contracted in this way, the elastic head of the sealing member moves along the hollow spike with a corresponding sealing means between the cavity of the tubular body and one or more side holes of the hollow spike. Slide until opening communication between the inlet end and the outlet end of the tubular body.

  The known solutions described above are not without drawbacks. That is, in some cases, there are drawbacks with regard to reliability and repeatability when the sealing member recovers a closed state after the introducer is removed from the connector, and in some other cases, There are drawbacks regarding the persistence of positive or negative pressure in the connector after being closed again as described above. Furthermore, because of the form of the elastic thrust means of the sealing member, the body of the known connector usually has a fairly long axial extension, but this is rather desirable to avoid.

  The object of the present invention is to overcome the above-mentioned drawbacks. This object is achieved essentially by the fact that the elastic thrust means of the sealing member comprises the base of an elastic hollow element. The base has a generally cylindrical axial wall and is set a certain radial distance away from the spike, thereby forming an annular chamber with the spike. The base is connected to the elastic hollow element through a generally transverse annular wall, the wall being moved in the axial direction from the closed to the open state of the elastic head. Bend in the chamber.

  Conveniently, the generally transverse wall bends while undergoing deformation due to tensile stress.

  Thanks to the idea of this solution, according to the valve connector of the present invention, the degree of reliability is improved, and it is ensured that the sealing member quickly returns to the closed state even after the sealing member is repeatedly opened. The axial dimension is considerably reduced. The valve connector is constructed with a minimum number of parts, so that it can be manufactured in a relatively simple and inexpensive manner and, furthermore, thanks to several further solutions that will be revealed later, During the transition phase between the closed state and the closed state, excessive or negative pressure can be substantially eliminated.

  In one embodiment, the tubular body of the inventive connector is advantageously formed with a tubular side Y-shaped connector.

  The present invention will now be described in detail with reference to the accompanying drawings, which merely illustrate non-limiting embodiments.

  The first embodiment of the valve connector for a medical infusion line of the present invention basically has three elements, namely, an outer tubular body 1 and a cavity of the tubular body 1 as shown in FIGS. An inner hollow spike 2 and an elastic sealing member 3 which are set in the axial direction are provided. Typically, the tubular body 1 and the hollow spike 2 are made of a hard molded plastic material, and the sealing member 3 is made of an elastic material, for example, silicone rubber.

  As shown in detail in FIGS. 13-15, the tubular body 1 is a female luer lock connection for engaging the male luer lock connection member of a fluid introducer in a generally conventional manner. It has an inlet end 4 formed like a member. The male luer lock connecting member is constituted by, for example, a needleless syringe, and a part of the needleless syringe is generally indicated by S in FIGS. The inlet end 4 is connected to a generally cylindrical intermediate portion 5 followed by a widened final portion 6 which is also generally cylindrical.

  The inner side surface of the inlet end 4 has a head position cylindrical portion 7. The head cylinder 7 is formed with a series of axial channels 8 that are semi-curved into a portion having the shape of a truncated cone 9. The inner surface of the intermediate portion 5 is continuously directed toward the final portion 6 in the first cylindrical portion 10, the portion 11 having a truncated cone shape, the second cylindrical portion 12, and the portion 13 having a truncated cone shape. , A third cylindrical part 14, a part 15 having a frustoconical shape, and a fourth cylinder that terminates in a front axial projection 17 facing the inside of the enlarged terminal part 6 and arranged annularly A shaped portion 16 is provided. A radially projecting and annularly arranged axial projection 18 is formed on the inner surface of the enlarged end portion 6, and its free end defines an annular shoulder, indicated by 27. ing. Its function will be clarified in later explanation.

  The cavity of the tubular body 1 is indicated generally by 19.

  The hollow spike 2 has a base, indicated generally at 20, as shown in more detail in FIG. A holding ring 21 is formed outside the base portion 20. The inside of the base 20 is shaped like a male luer lock connection member. The base 20 has a central tubular shank 22 having a somewhat conical outer surface and an outer shell 23 with threads formed therein. The connecting members 22, 23 define the outlet end of the valve connector 1, indicated generally by 24.

  A larger diameter first annular flange 25 attached to the base 20 as shown in FIGS. 3-12 for connection to the free end edge of the widened end portion 6 of the tubular body 1. And a smaller diameter annular flange 26, whose function will be clarified later. From the annular flange 26, in an integrated state, the tubular post 28 branches, preferably but not necessarily, coaxially with the shaft 22 and in communication therewith. The post 28 has an initial portion 29 in a conical plane extending towards the outlet end 24 of the connector, followed by one or more side holes, for example in the form of an elongated slot. And a cylindrical portion 30 in which 31 is formed. The cylindrical portion 30 was placed at its free end facing the inlet end 4 of the tubular body 1 (visible more clearly in FIGS. 3-12) and away from it by an axial distance. , Having a closed tip 32. Protruding from the closed tip 32 is a radial and axial projection 33 which is set and spaced annularly by an angular distance, between which an axial and radial channel 34 of the flow. Is defined. The end face facing the inlet end 4 of the projection 33 is preferably flat or slightly rounded.

  A conical annular surface 32 a is formed below the closed tip 32.

  The sealing member 3 is shown in more detail in FIGS. This is one component, and includes an elastic head 35, an elastic hollow element 36, and an elastic base 37. The general shape of the sealing member 3, particularly the outer shape thereof, substantially matches the shape of the cavity 19 of the tubular body 1, and the sealing member 3 is accommodated in the cavity 19. Therefore, as shown in FIGS. 3 and 4, the elastic head 35 has a little play in the radial direction, that is, it can be accommodated in the closed state where the head 35 is hardly deformed and can be accommodated with little trouble. It has a cylindrical outer surface that is complementary to the inner surface 7 of the inlet end 4.

  A pre-slit, that is, an axial notch 38 is formed so as to penetrate the head 35. It is maintained in a tightened state as a result of the elasticity of the head 35 in the undeformed state where the elastic head 35 in the inlet end 4 is closed. In this state, an antibacterial protection barrier is formed between the inside and the outside of the valve connector, and at the same time, the possibility of effective cleaning by a cotton swab soaked in a disinfectant as usual is guaranteed.

  The head 35 is connected to the elastic hollow element 36 through a frustoconical part 39 complementary to the conical surface 9 of the tubular body 1. The outer surface of the elastic hollow element 36 has a first cylindrical part 40 which is semi-curved into a second cylindrical part 41 through a part 42 having a frustoconical shape. The second cylindrical portion 41 is semi-curved into the elastic base 37 through the portion 43 having a truncated cone shape and the subsequent cylindrical portion 44. These portions 40, 42, 41, 43, 44 have a complementary shape to those of the inner surface portions 10, 11, 12, 13, 14-16 of the tubular body 1.

  The elastic base 37 has a generally cylindrical shape, and its outer diameter is substantially the same as that defined by the annular protrusion 18 arranged annularly inside the terminal portion 6 of the tubular body 1. Match. The elastic base 37 is semi-curved into the cylindrical portion 44 of the elastic hollow element 36 through a generally lateral wall 45, which is deformed from the sealing member 3 shown in FIGS. In the absence, it has a truncated cone shape.

  The elastic base 37 terminates on the opposite side of the elastic head 35 to the outer annular flange 46, whereby the elastic base 37 is gripped and in the manner shown in FIGS. Between the annular shoulder 26 of the base 25 of the hollow spike 2 and the annular shoulder 27 of the end portion 6 of the tubular body 1, it is sealed off in the axial direction in a liquid-tight manner.

  The elastic base 37 and the lateral wall 45 preferably have a generally smaller wall thickness than that of the other parts of the sealing member 3.

  Inside, the sealing member 3 is formed with a first annular protrusion 47 and a second annular protrusion 48, which are set to be separated from each other by a certain distance in the axial direction. Each is designed to define a first fluid sealing member and a second fluid sealing member in a manner as will be revealed later.

  In the assembled state of the valve connector according to the invention, the tubular body 1 is arranged coaxially in the cylindrical part 5 at a position corresponding to the annular flange 25 of the base 20 of the hollow spike 2 as already described. Along with the extending tubular post 28, it is fixed to the hollow spike 2. The sealing member 3 is housed in the tubular body 1, the elastic head 35 is set in the inlet end 4 in the manner previously described, and the elastic hollow element 36 is in the hollow part 5 in the cylindrical part 5. The elastic base 37 is accommodated in the end portion 6 of the tubular body 1 so as to surround the two tubular posts 28. As already mentioned, the annular end flanges 46 of the elastic base 37 are each clamped axially between the shoulder 26 of the hollow spike 2 and the shoulder 27 of the tubular body 1, so that the elastic base 37 The wall rests against an axial collar 18 arranged in a ring. The lateral wall 45 is adjacent to the annular front projection 17 and is therefore generally flat, i.e. in a radial state (shown in FIGS. 3 and 4). A little elastically deformed. The first inner fluid sealing member 47 of the sealing member 3 is hollow due to the interaction between the outer cylindrical surfaces 40, 41 of the elastic hollow element 36 and the complementary inner cylindrical surfaces 10, 12 of the hollow body 1. The conical surface 32a of the tip 32 of the spike 2 is set in contact with the fluid seal, while the second fluid sealing member 48 is complementary to the outer cylindrical surface 44 of the elastic hollow element 36 and the hollow body 1. Thanks to the interaction with the typical inner cylindrical surface 14, the smaller diameter area of the conical portion 29 is set in contact with the fluid seal. The elastic hollow element 36 and the elastic head 35 of the sealing member 3 are usually kept slightly axially preloaded in the tubular body 1, and the side holes 31 of the hollow spike 2 are connected to the inlet end 4 of the connector. Thus, the communication between the inlet end 4 and the outlet end 24 is thus closed.

  An annular chamber 50 is thus defined between the elastic base 37 and the wall 35 on one side and the part 29 having the frustoconical shape of the hollow spike 2 on the other side. This communicates with the exterior of the valve connector through one or more passages 51 formed in the base 20 of the hollow spike 2.

  Since the annular chamber 50 communicates with the outside through the passage 51, the internal pressure is clearly atmospheric pressure.

  The state described above corresponds to a state in which the valve connector is closed in a fluid-tight manner.

  When the end of the needleless syringe or introducer S is placed in front of the elastic head 35 and inserted into the inlet connector 4 in the manner shown in FIGS. Due to the elastic deformation of the sealing member 3, it is pushed axially towards the inside of the connector, in particular due to the deflection of the wall 45 of the elastic base 37 in the annular chamber 50.

  As the introducer S continues to be inserted, the wall 45 continues to bend in the annular chamber 50 and is subjected to tensile stress, as shown in FIGS. 5, 6, 7, 8, and 9, 10, respectively. Due to this, it undergoes deformation in stages. Here, the introducer S is omitted in order to simplify the illustration.

  As a result of the deflection due to the tensile stress of the wall 45, the elastic base 37 is compressed and in the region semi-curved into the wall 45, indicated generally at 45a in FIG. 19, in FIGS. 10, and as shown schematically in FIGS. 11 and 12, there is a tendency to “roll up” toward the inside of the annular chamber 50.

  The elastic head 35 and the elastic hollow element 36 of the sealing member 3 move in the direction in which the first fluid sealing member 47 moves away from the conical surface 32 a of the tip 32, but the second fluid sealing member 48 is the conical portion 29. Are gradually slid along the tubular post 28 of the hollow spike 2 in the tubular body 1 so as to slide while maintaining fluid tightness.

  At the same time, the protrusion 33 of the hollow spike 2 begins to interact with the elastic head 35 from the inside (FIGS. 9, 10) which is elastically deformed, ie radially expanded outward. As a result, the pre-slit 38 is opened.

  When the insertion of the introducer S is completed (FIGS. 11 and 12), the pre-slit 38 is fully opened, but the first fluid sealing member 47 moves to the lower side of the side hole 31 of the hollow spike 2. The second fluid sealing member 48 slides to a larger diameter region of the conical portion 29 of the hollow spike 2 and the wall 45 is fully deflected and widened in the annular chamber 50. It becomes a state. The valve connector is thus opened, and as a result, the inlet end 4 (and hence the introducer S) is discharged through the pre-slit 38, the axial and radial channel 34, the side hole 31, the tubular post 28, and the shaft 22. Communicate with end 24.

  When the introducer S is pulled out from the inlet end 4, the elastic return of the wall 45 and the sealing member 3 is integrated to quickly restore the closed shape of the valve connector. In this state, the elastic head 35 returns to an undeformed state in the inlet end 4, closes the pre-slit 38 again, and the side holes 31 are again isolated by the fluid sealing members 47, 48. .

  20 to 26 show a modification of the valve connector of the present invention. In this variant, parts that are the same or similar to those already described above are denoted by the same reference numerals. The tubular body 1 of the valve connector is provided with a tubular side Y-shaped connector 55. The side connector 55 is formed integrally with the cylindrical terminal portion 6 of the tubular body 1 and is substantially formed at the height of the base 20 of the tubular spike 2. The base 20 is formed with a circumferential groove 56 that is fluid-tightly closed on the outside by the wall of the cylindrical end portion 6, and the base 20 is in this variant. Has an axial extension slightly larger than that of the embodiment described above. The groove 56 thus defines an annular chamber, on the one hand communicating with the side connector 55 through the hole 57 and on the other hand through one or more radial passages 58 with the cavity and shaft 22 of the spike 2. That is, in communication with the outlet end 24 of the connector.

  The operation of the valve connector having the Y-shaped connector 55 is exactly the same as described above with reference to FIGS.

  In both of the above-described embodiments, the valve connector of the present invention has a series of important advantages compared to similar known valve connectors. That is, even after the sealing member is repeatedly opened, the degree of reliability is improved in that it quickly returns to the closed state. Also, the overall axial dimension is significantly reduced. In addition, it is assembled with a minimum number of parts, so that it can be manufactured by a relatively simple and inexpensive method. In addition, it can be ensured that excessive or negative pressure is not substantially generated inside the valve connector at the stage of transition between the open state and the closed state.

  Of course, details of construction and embodiments may be varied over a wide range of what has been described and illustrated herein without departing from the scope of the invention as defined in the following claims. .

1 is a schematic perspective view of a medical line valve connector according to a first embodiment of the present invention. It is an elevation view of a valve connector. It is an axial section schematic diagram of the valve connector of the 1st state. FIG. 4 is a view similar to that of FIG. 3 but rotated by 90 degrees. FIG. 4 is a view similar to FIG. 3 showing the valve connector in a different operating state. FIG. 5 is a view similar to FIG. 4 showing the valve connector in a different operating state. FIG. 4 is a view similar to FIG. 3 showing the valve connector in a different operating state. FIG. 5 is a view similar to FIG. 4 showing the valve connector in a different operating state. FIG. 4 is a view similar to FIG. 3 showing the valve connector in a different operating state. FIG. 5 is a view similar to FIG. 4 showing the valve connector in a different operating state. FIG. 4 is a view similar to FIG. 3 showing the valve connector in a different operating state. FIG. 5 is a view similar to FIG. 4 showing the valve connector in a different operating state. It is an axial sectional view of the 1st element of a valve connector. FIG. 14 is a perspective view from below of the element of FIG. 13. FIG. 14 is a plan view from below of the elements of FIG. 13. FIG. 6 is a perspective view of a second element of the tubular connector. FIG. 6 is a perspective view of a third element of the tubular connector. FIG. 18 is an elevational view of the elements of FIG. 17. FIG. 19 is an axial cross-sectional view of the element of FIG. It is an elevation view of a modification of the valve connector of the present invention. It is an axial sectional view of the modification of FIG. It is a perspective view of the modification of FIG. FIG. 23 is a perspective view from above of the second element of the valve connector of FIGS. FIG. 24 is a perspective view from below of the element of FIG. 23. FIG. 25 is an axial cross-sectional view of the second element of FIGS. 23 and 24. FIG. 23 is a perspective view from below of the first element of the valve connector of FIGS.

Claims (19)

A medical line valve connector for infusion via a fluid introducer (S),
A tubular body (1), a hollow spike (2), and a sealing member (3);
The tubular body (1) has a cavity (19), an inlet end (4) provided to engage the introducer (S), and an outlet end (24);
A hollow spike (2) is set axially in the cavity of the tubular body (1) and faces the inlet end (4) of the tubular body (1) and is set a distance away from it in the axial direction. Also having a closed tip (32), in communication with the outlet end (24), a distance from the closed tip (32) to communicate with the cavity (19) of the tubular body (1) Having at least one side hole (31) set apart only by
The sealing member (3) comprises an elastic head (35) and an elastic hollow element (36);
The elastic head (35) has a pre-slit (38) and is usually set closed in the inlet end (4) of the tubular body (1), in this closed state The pre-slit (38) is closed and the elastic head (35) interacts with the closed tip (32) to take an open state in which the pre-slit (38) is elastically deformed. Is movable axially relative to the closed tip (32) of the hollow spike (2) as a result of insertion into the inlet end (4) of the introducer (S);
An elastic hollow element (36) is connected to the head (35) and is set between the tubular body (1) and the hollow spike (2), and the head (35) is not deformed. With sealing means (47, 48) in contact with the hollow spike (2) for isolating at least one side hole (31) from the cavity of the tubular body (1) when set in the closed state; And elastic thrust means (36, 45) having a tendency to maintain the head (35) in the closed state,
The elastic thrust means comprises a base (37) of the sealing member (3),
The base (37) has a generally cylindrical axial wall and has a radial direction from the hollow spike (2) to define an annular chamber (50) with the hollow spike (2). Set apart by a distance and connected to the elastic hollow element (36) through a generally lateral annular wall (45), the elastic head (35) being pivoted from the closed state to the open state. Valve connector characterized in that it bends in an annular chamber (50) while moving in the direction.   2. A valve connector according to claim 1, characterized in that the generally transverse wall (45) bends while undergoing deformation due to tensile stress.   The sealing means of the elastic hollow element (36) of the sealing member (3) comprises a first inner annular protrusion (47) and a second inner annular protrusion (48), which are axially connected to each other. The elastic head (35) is set at a certain distance from the at least one side hole (31) of the hollow spike (2) in the closed state. The valve connector according to claim 1, wherein:   When the elastic head (35) is closed as described above, the first annular protrusion (47) is formed in a conical shape near the closed tip (32) of the hollow spike (2). 4. A valve connector according to claim 3, characterized in that in the face (32a) it is kept in fluid-tight contact with the annular projection.   A second inner annular protrusion (48) is set in fluid-tight sliding contact with a portion in the conical surface (29) of the hollow spike (2) and has an annular chamber inside. 4. A valve connector according to claim 3, characterized in that it defines (50) and extends towards the outlet end (24) of the connector.   The valve connector according to claim 1, characterized in that the annular chamber (50) is in communication with the outside of the connector.   The base (37) of the elastic thrust means of the sealing member (3) is sealed in the axial direction between the tubular body (1) and the base (20) of the hollow spike (2), The valve connector according to claim 5.   The elastic head (35) of the sealing member (3) is set in the inlet end (4) of the tubular body (1) substantially without trouble in the closed state. 1. The valve connector according to 1.   9. Valve connector according to claim 8, characterized in that the inlet end (4) of the tubular body (1) has an inner wall (7) in which an axial channel (8) is formed.   The elastic hollow element (36) of the sealing member (3) has an outer wall, which has a cylindrical surface (40, 41, 44) connected to each other by portions having a frustoconical shape. 2. An axial part, characterized in that the tubular body (1) has a complementary shaped inner surface in a region corresponding to the elastic hollow element (36). The described valve connector.   2. Valve according to claim 1, characterized in that the generally transverse annular wall (45) of the sealing member (3) has a thickness substantially less than that of the elastic hollow element (36). connector.   The base (37) of the sealing member (3) is widened in the tubular body (1), in which an axial protrusion (18) arranged radially and projecting radially towards the base (37) is formed. 2. The valve connector according to claim 1, wherein the valve connector is accommodated in a cylindrical portion.   An axial direction projecting at the front face toward the generally transverse annular wall (45) of the sealing member (3) and arranged annularly on the widened cylindrical part (6) of the tubular body (1) 13. A valve connector according to claim 12, characterized in that the protrusion (17) is formed.   The closed tip (32) of the hollow spike (2) is shaped to allow the elastic head (35) of the sealing member (3) to open without passing through the pre-slit (38). The valve connector according to claim 1, wherein:   The closed tips (32) of the hollow spikes (2) are set at an angular distance from each other and define a flow channel (34) facing the inlet end (4) of the tubular body (1). 15. A valve connector according to claim 14, characterized in that it has a plurality of axial projections (33).   2. Valve connector according to claim 1, characterized in that the outlet end (24) consists of a male luer-lock connection element (22, 23) formed integrally with the hollow spike (2).   17. A valve connector according to any one of the preceding claims, wherein a tubular side Y-shaped connector (55) is formed in the tubular body (1).   A tubular Y-shaped connector (55) communicates with the outlet end (24) of the connector through an annular chamber (56), the chamber (56) being a hollow spike (downstream from at least one side hole (31). The valve connector according to claim 17, wherein the valve connector is in communication with the inside of 2).   An annular chamber is formed by the circumferential groove (56) of the enlarged portion (20) of the hollow spike (2), closed at the outside by the tubular body (1), at least of the enlarged portion (20). 19. A valve connector according to claim 18, characterized in that it is connected to the outlet end (24) of the connector through one radial passage.

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