JP5161622B2 - Needle removal device - Google Patents

Description

The present invention relates to needle removal equipment removable needle used in the syringe.

  Conventionally, syringes are used for blood tests and drug solution administration, and after a test or the like is performed, the syringe needle is separated from the used syringe and discarded. In addition, in a pen-type syringe used for insulin administration or the like, it is required to replace the needle with a new one for each injection. When removing this injection needle, there is a risk that a doctor or nurse may accidentally stab himself.

  In order to solve such a problem, a needle removal device that is removable without directly touching the injection needle is known.

  The injection needle removing device includes, for example, a cylindrical needle housing portion and a needle removing portion screwed into the needle housing portion, and the needle removing portion has a removal structure so as to face the opening of the lid member. Is rotatably provided. Then, by inserting the syringe into the syringe receiving portion of the removal structure, a pair of jaws cam-drives the syringe, and then the removal structure rotates to remove the injection needle from the syringe. (See, for example, Patent Document 1).

  An injection having a claw member capable of holding an injection needle, and driving the drive mechanism including a motor in a state where the claw member holds the injection needle to swing and displace the injection needle up and down. A needle removal device is known (see, for example, Patent Document 2).

JP-A-8-38560 JP-A-5-269174

  However, in the conventional technique according to Patent Document 1 described above, since the cam mechanism is used as the holding means for holding the syringe, the structure becomes complicated, leading to an increase in size of the apparatus having the removal structure and an increase in manufacturing cost. There is a problem of end up.

  Moreover, in the prior art which concerns on patent document 2, although the drive mechanism containing a motor is provided and it is set as the structure which removes an injection needle electrically, there exists a problem that a structure will become complicated and a weight will increase. .

The present invention has been made in consideration of such problems, it aims to provide a simple and inexpensive configuration, the which can be removed safely and conveniently the needle from the syringe needle removal equipment And

In order to achieve the above-mentioned object, the present invention provides a needle removal apparatus that can remove a needle screwed into a syringe.
An insertion part into which the syringe is inserted;
A holding means provided facing the insertion portion and holding an injection needle of the syringe;
A rotating means for rotating and holding the holding means in a state where the injection needle is held;
With
The injection needle is held by the holding means and the holding means is rotated by the rotating means by a thrust force for inserting the syringe into the insertion portion.

  According to the present invention, the syringe needle of the syringe is held by the holding means provided so as to face the insertion portion by inserting and pushing the syringe into the insertion portion constituting the injection needle removing device, and thereafter The holding means is rotated by the rotating means together with the injection needle. Thereby, the injection needle screwed into the syringe is removed from the syringe.

  Therefore, a doctor, a nurse, or the like can safely and reliably remove the injection needle by a simple operation of inserting and pushing the syringe into the insertion portion of the injection needle removal device. In addition, since the thrust at the time of pushing the syringe into the injection needle removal device is used, for example, it is not necessary to provide a drive source such as a motor to remove the injection needle, compared with the case where the drive source is provided, The structure of the injection needle removing device can be simplified and manufactured at low cost, and the size and weight can be reduced.

  The holding means includes a pair of sliders that are disposed opposite to each other with the injection needle as a center, and that are displaceable in a direction orthogonal to the axis of the injection needle, and the sliders are displaced in a direction approaching each other by thrust. By holding the needle, the slider can be displaced toward the injection needle using the thrust force when the syringe is inserted into the insertion portion, so that the holding operation of the injection needle can be performed reliably and easily. It becomes.

  Further, the rotating means is formed of a cylindrical body that is housed in a cylindrical housing and is engaged with a spiral groove that is spirally formed along the peripheral surface of the housing, and the cylindrical body is moved to the housing by the thrust. By rotating the inside of the tube along the axial direction, the cylindrical body can be rotated and displaced using the thrust force when the syringe is inserted into the insertion portion. It can be reliably and easily removed from the syringe.

  Furthermore, by providing a pair of inclined walls having an inclined surface that engages with the slider at the end of the cylinder, the slider is moved closer to and away from the injection needle by the inclined surface under the displacement action of the cylinder. It can be displaced in the direction.

  Furthermore, a release means capable of releasing the holding state of the injection needle by the holding means, the release means having a spring force that is displaceable in a direction to separate the sliders from each other against the thrust. By removing the injection needle after the removal of the injection needle is completed, the holding state of the injection needle by the holding means can be easily released under the elastic action of the spring, and can be detached from the syringe. Is possible.

  Still further, the rotating means is provided on a peripheral surface of the cylindrical housing, and is provided on a rack extending along the axial direction and a cylindrical body that is displaceable along the inside of the housing, and holds the injection needle. And a rotatable holding gear, a transmission gear provided so as to be orthogonal to the holding gear, and having a first tooth portion meshing with the holding gear and a second tooth portion meshing with the rack. The transmission gear meshed with the rack is rotated by displacing the cylindrical body by the thrust, and the holding gear is rotated in accordance with the rotation of the transmission gear. As a result, the injection needle held by the holding gear is rotationally displaced with respect to the syringe, and is removed from the syringe.

  According to the present invention, the following effects can be obtained.

  That is, the syringe needle of the syringe is held by the holding means provided so as to face the insertion portion by inserting and pushing the syringe into the insertion portion constituting the injection needle removing device, and holding the injection needle By rotating the holding means with the rotating means, the injection needle screwed into the syringe can be removed from the syringe. As a result, it is possible to remove the injection needle safely and reliably with a simple operation of inserting and pushing the syringe into the insertion portion of the needle removal device, and because the thrust when pushing the syringe is used. For example, it is not necessary to provide a drive source such as a motor for removing the injection needle, and the configuration of the injection needle removing device can be simplified and manufactured at low cost, and the size and weight can be reduced.

Hereinafter, about the needle removal equipment according to the present invention the embodiments, it will be described with reference to FIGS. 1 to 11 of the accompanying drawings. Here, a case will be described in which the needle removal device is attached to a waste tank that is a syringe waste container.

  As shown in FIGS. 1 to 11, the injection needle removing device 10 according to the first exemplary embodiment of the present invention is mounted on the upper portion of a waste tank 12 and is freely rotatable inside the housing 14. A cylindrical body 16 that is held by the cylindrical body 16, a slider holder 18 that is slidably held with respect to the cylindrical body 16, a slider cover 20 that is displaced together with the slider holder 18, and between the slider holder 18 and the slider cover 20. A pair of sliders 22, 22 provided in a freely displaceable manner, a displacement body 28 provided above the slider cover 20 and holding the hub 26 of the injection needle 23, and a cover plate 30 provided above the displacement body 28. And a cylindrical cap 32 provided on the outer peripheral side of the cover plate 30, the displacement body 28 and the slider cover 20.

  The disposal tank 12 is a container that can accommodate a considerable number of injection needles 23, and has an open end 12a that opens at the upper end thereof, and the open needle 12a constitutes the injection needle removal device 10. A housing 14 is connected.

  The housing 14 is formed in a cylindrical shape having both ends opened, extends in a predetermined length along the axial direction, and has a main body portion 34 having a substantially constant diameter, and a radially outward direction with respect to the outer periphery of the main body portion 34. And a tank mounting portion 36 to which the waste tank 12 is mounted.

  A spiral spiral groove (spiral groove) 38 is formed inside the main body 34 along the axial direction, and from one end side (arrow A direction) to the other end side (arrow B direction) of the main body 34. It extends to. The spiral groove 38 has a rectangular cross section.

  A cap 32 having a collar is provided at one end of the main body 34, and the cap 32 is inserted so as to be in sliding contact with the inner peripheral surface of the main body 34, and the collar provided at the end. Is exposed to the outside of the main body 34 and covers the one end. A plurality of convex portions 40 are provided on the outer peripheral surface of the cap 32 and are engaged with the concave portions 42 provided on the inner peripheral surface of the main body portion 34. Thereby, the cap 32 is fixed to the main body portion 34 without being displaced in the axial direction. On the other hand, the other end of the main body 34 is inserted into the waste tank 12.

  On the other hand, the tank mounting portion 36 is provided at a substantially central portion along the axial direction of the main body portion 34, the other end portion is released, and a screw is engraved therein and provided at the upper end portion of the waste tank 12. Screwed into the open end 12a. As a result, the injection needle removing device 10 including the housing 14 is attached to the waste tank 12 and the open end 12a is closed.

  The cylindrical body 16 is formed in a cylindrical shape, and has a base portion 44 formed on one end side (in the direction of arrow A), and a predetermined length joined to the base portion 44 toward the other end side (in the direction of arrow B). And a pair of guide rollers 48 provided on the outer peripheral side of the base portion 44 and the cylindrical portion 46.

  The base portion 44 is formed in a disk shape having a predetermined thickness at one end surface and having a predetermined thickness. The base portion 44 is formed at a central portion thereof and communicates with the inside of the cylindrical portion 46. A pair of bolt holes 52, 52 provided at a predetermined distance from the first hole 50 as a center, and rotated about 90 ° with respect to the bolt holes 52, 52 around the first hole 50. And a pair of inclined walls 54, 54 provided at the position. In other words, the pair of bolt holes 52 and 52 and the inclined walls 54 and 54 are arranged in a cross shape with the first hole 50 as the center.

  The bolt holes 52, 52 are provided in a straight line across the first hole portion 50, and open at the center of the relief portion 56 that is recessed in a circular shape with respect to one end surface of the base portion 44. Bolts 58, 58 interposed between the slider holder 18 described later are screwed into the bolt holes 52, 52, respectively.

  The pair of inclined walls 54, 54 are erected at a predetermined height with respect to one end face of the base portion 44, and are substantially parallel to a virtual line connecting one bolt hole 52 and the other bolt hole 52. It is provided as follows. The inclined walls 54, 54 are formed so that the outer surface on the outer peripheral side of the base portion 44 is planar, and the inner surface on the inner peripheral side of the base portion 44 facing the first hole 50 is on the base portion 44 side. It is formed in a taper shape whose thickness gradually increases toward. That is, the inclined walls 54, 54 are formed so that the inner surface facing the first hole 50 is inclined at a predetermined angle with respect to the axis of the cylindrical body 16 including the base portion 44 and is opposed to each other. .

  In other words, the inclined walls 54, 54 are formed so that the thickness gradually decreases in the direction away from the base portion 44 (arrow A direction), and one inclined wall 54 and the other inclined wall 54 Is also formed so as to increase in accordance with the separation distance from the base portion 44.

  Note that the pair of inclined walls 54 and 54 are set so that the height from the end surface of the base portion 44 and the inclination angle of the inner surface are the same.

  The cylindrical portion 46 is formed in a cylindrical shape having a diameter substantially the same as that of the base portion 44, and one end thereof is joined to the other end surface of the base portion 44. A flange portion 60 is provided on the outer peripheral surface of the cylindrical body 16 so as to be spaced from the one end portion by a predetermined distance along the axial direction. The flange portion 60 expands radially outward, and the outer peripheral diameter of the base portion 44 is increased. And substantially the same diameter.

  A return spring 62 is interposed between the flange portion 60 and the other end portion of the housing 14, and the cylinder 16 is separated from the other end portion of the housing 14 under the elastic action of the return spring 62 (arrow). (A direction).

  Further, between the flange portion 60 and the base portion 44, a pair of joining walls 64 a and 64 b that join the end face of the flange portion 60 and the end face of the base portion 44 are provided. The joining walls 64 a and 64 b are respectively provided at positions that are in line with the pair of bolt holes 52 provided in the base portion 44.

  The pair of guide rollers 48 are rotatably supported by a support shaft 66 provided on the outer peripheral surface of the base portion 44 and a support shaft 66 provided on one joining wall 64a. These support shafts 66, 66 are provided on a plane including a pair of bolt holes 52, 52 provided in the base portion 44, and have a predetermined distance along the axial direction (arrow A, B direction) of the cylindrical body 16. The base portion 44 protrudes from the outer peripheral surface of the base portion 44 and the joining wall 64a with a predetermined length. That is, one guide roller 48 and the other guide roller 48 are provided apart from each other by a predetermined distance along the axial direction of the cylindrical body 16.

  The guide rollers 48 and 48 are inserted into the spiral groove 38 when the cylindrical body 16 is disposed inside the housing 14, and the cylindrical body 16 is under the guide action of the guide rollers 48 and 48 and the spiral groove 38. Is displaced in the axial direction (in the directions of arrows A and B) along the inside of the housing 14 while rotating. At this time, the guide rollers 48, 48 abut against the inner wall surface of the spiral groove 38 and are displaced while rotating around the support shafts 66, 66, so that the displacement along the axial direction of the cylindrical body 16 is smoothly guided. The

  In other words, the cylindrical body 16 functions as a power conversion mechanism (rotating means) 68 capable of converting a linear force applied along the axial direction of the cylindrical body 16 into a rotational force.

  The slider holder 18 is provided above the base portion 44 constituting the cylindrical body 16, and is formed in a substantially circular shape having substantially the same diameter as the outer peripheral diameter of the base portion 44. The slider holder 18 includes a second hole 70 formed substantially at the center, a pair of bolt insertion holes 72 and 72 provided in the radially outward direction around the second hole 70, and the second hole And a set of notches 74 and 74 provided at positions spaced apart from each other by a predetermined distance about 70 and rotated about 90 ° with respect to the bolt insertion holes 72 and 72. The bolt insertion holes 72 and 72 are joined on the outer peripheral side of the second hole portion 70 and communicate with each other.

  Further, the slider holder 18 has a first slider groove 76 that is recessed in a concave shape so as to connect between the one notch 74 and the other notch 74, and at a position facing the notches 74, 74. Sliders (holding means) 22 and 22 are provided, respectively.

  The slider holder 18 is arranged so that the second hole portion 70 is coaxial with the first hole portion 50 of the cylindrical body 16 and communicates with each other, and is a bolt screwed into the base portion 44 of the cylindrical body 16. 58 and 58 are inserted into the bolt insertion holes 72 and 72, respectively. That is, the bolt insertion holes 72 and 72 are arranged so as to face the bolt holes 52 and 52. Further, the inclined walls 54 and 54 of the cylindrical body 16 are inserted into the notches 74 and 74 of the slider holder 18, respectively.

  As a result, the slider holder 18 is supported by the base portion 44 of the cylindrical body 16 through a pair of bolts 58 and 58 so as to be displaceable along the axial direction (arrows A and B directions), and is relative to the rotational direction. It is regulated so as not to be displaced.

  A cylindrical collar 78 is inserted into the outer periphery of the bolt 58, and a release spring (release means) 80 is inserted into the outer periphery of the collar 78. The release spring 80 is made of, for example, a coil spring, and is interposed between the slider holder 18 inserted through the bolt 58 and the escape portion 56 of the base portion 44. Thereby, the slider holder 18 is urged in a direction away from the cylindrical body 16 (in the direction of arrow A) under the elastic action of the release spring 80.

  The slider cover 20 is formed in a ring shape having ribs on the outer peripheral portion, and is provided above the slider holder 18. Then, the protrusion 82 formed on the end surface of the slider cover 20 is inserted into the hole formed on the upper surface of the slider holder 18, so that the relative rotational displacement of the slider cover 20 with respect to the slider holder 18 is restricted. Is done. That is, the slider cover 20 is rotationally displaced integrally with the slider holder 18.

  The slider cover 20 is provided at a predetermined distance from the slider holder 18, and a second slider groove 84 for guiding the slider 22 is formed on the lower surface of the slider cover 20 facing the slider holder 18. .

  The second slider groove 84 is formed so as to face the first slider groove 76 in the cylindrical body 16, and the sliders 22, 22 are sandwiched between the first and second slider grooves 76, 84. It is guided so as to be displaceable in a direction perpendicular to the 20 axis lines (directions of arrows C1 and C2).

  The pair of sliders 22, 22 is formed in a block shape made of an elastic material such as rubber, for example, and is provided to be displaceable along the first and second slider grooves 76, 84 in the slider cover 20 and the slider holder 18. .

  The slider 22 is formed on one side surface thereof, is formed in a curved portion that is recessed in a curved shape and can hold the hub 26 of the injection needle 23, and is formed on a side surface opposite to the holding portion 86, and is inclined at a predetermined angle. And a tapered portion 88 having an inclined surface. The slider 22 has a holding portion 86 on the second hole 70 side (in the direction of arrow C1) of the slider holder 18 and a tapered portion 88 on the outer peripheral side of the slider holder 18 so as to contact the inclined wall 54. One slider groove 76 is disposed. That is, one slider 22 and the other slider 22 are arranged so that the holding portions 86 and 86 face each other.

  Further, the holding portion 86 is provided with a plurality of bulging portions 90 that bulge with respect to the side surfaces and are spaced apart from each other by a predetermined distance. The bulging portion 90 is formed in a grip groove 92 (described later) formed on the outer peripheral surface of the hub 26 when the hub 26 (described later) constituting the injection needle 23 is held by the pair of sliders 22 and 22. Engaged.

  On the other hand, the inclination angle of the tapered portion 88 is set to be the same as the inclination angle of the inclined wall 54 facing the tapered portion 88.

  The displacement body 28 is provided on an upper portion of the slider cover 20 having a rib, and protrudes outward from the outer periphery of the slider cover 20 via a plurality of shaft portions 96 that are spaced apart at equal intervals along the circumferential direction. A slide roller 94 is rotatably supported. The slide roller 94 abuts against the end surface of the slider cover 20 when the displacement body 28 is provided on the upper portion of the slider cover 20 so that the displacement body 28 and the slider cover 20 can rotate relatively.

  That is, when the slider cover 20 and the slider holder 18 rotate together with the cylindrical body 16, the displacement body 28 and the cover plate 30 do not rotate.

  On the other hand, a holding hole 100 in which a part of a casing 98 constituting a syringe 24 described later is inserted and held is formed inside the displacement body 28, and the holding hole 100 is formed at the center of the holding hole 100. A hub hole 102 having a smaller diameter than the hole 100 is formed. The hub hole 102 is inserted into the hub 26 when a part of the syringe 24 is held by the displacement body 28 and is coaxial with the first hole 50 of the cylindrical body 16 and the second hole 70 of the slide holder. Provided in communication with each other.

  The cover plate 30 is formed in a plate shape having an opening 104 at the center, and is provided on the upper portion of the displacement body 28. When the cover plate 30 is attached to the displacement body 28, the plurality of slide rollers 94 are positioned in the recess formed on the displacement body 28 side, and the three protrusions provided on the lower surface of the cover plate 30 are displaced. It fits into three holes on the top surface of the body 28. Accordingly, the cover plate 30 is rotationally displaced together with the displacement body 28 without being relatively displaced in the rotational direction. The opening 104 and the holding hole 100 of the displacement body 28 function as an opening (insertion portion) 106 into which the syringe 24 is inserted in the injection needle removing device 10.

  The cover plate 30, the displacement body 28, the slider cover 20, and the slider holder 18 described above are provided inside the cap 32 so as to be freely displaceable in the axial direction.

  Next, the syringe 24 from which the injection needle 23 is removed by the above-described injection needle removing apparatus 10 will be briefly described with reference to FIG.

  This syringe 24 has a casing 98 in which a chemical cartridge (not shown) is mounted, and an injection needle comprising a needle 108 and a hub 26 to which the needle 108 is fixed on the distal end side of the casing 98. 23 is mounted. The casing 98 is formed in a cylindrical shape having a predetermined length, and a chemical liquid cartridge filled with a chemical liquid is inserted into the casing 98. The needle 108 is a double-ended needle, and one end communicates with the inside of the chemical cartridge by inserting a rubber member provided on the end face of the chemical cartridge.

  The hub 26 of the injection needle 23 is formed in a bottomed cylindrical shape whose diameter is reduced with respect to the casing 98, and is screwed into the tip end portion of the casing 98, and a hollow needle 108 is formed on one end surface serving as a bottom portion. It is provided so as to protrude in both directions. A plurality of grip grooves 92 are formed at equal intervals on the outer peripheral surface of the hub 26 in parallel with the axis. Then, the hub 26 can be attached to and detached from the casing 98 by being screwed with respect to the tip end portion of the casing 98.

  When injection is performed using the syringe 24, the needle 108 is punctured into the living body, and the button 110 provided on the rear end portion of the casing 98 is pressed, so that the drug solution is generated from the drug cartridge through the needle 108. Injected into the body.

The injection needle removing apparatus 10 according to the first embodiment of the present invention is basically configured as described above, and the operation and effects thereof will be described next. Here, as shown in FIG. 1, the injection needle removing device 10 is attached to the open end 12 a of the disposal tank 12, and the syringe 24 is not pushed into the injection needle removing device 10. The state will be described as an initial state.

  First, in this initial state, a doctor, a nurse, or the like holds the used syringe 24 that has been punctured into the living body, and the needle 108 of the injection needle 23 is moved downward (in the direction of arrow B) to remove the injection needle 10. Is inserted into the opening 106 (see FIG. 7).

  As a result, as shown in FIG. 7, the shoulder portion of the casing 98 constituting the syringe 24 abuts against the end surface of the holding hole 100 in the displacement body 28, and the hub 26 passes through the hub hole 102 and the second portion of the slider holder 18. It is inserted into the hole 70. Then, the outer peripheral surface of the hub 26 is in a state of facing the pair of sliders 22 and 22.

  Then, as shown in FIG. 8, the displacement body 28 is pressed downward by further pushing the syringe 24 toward the injection needle removing device 10 (in the direction of arrow B), and accordingly, the slider cover 20. The slider holder 18 is displaced toward the cylindrical body 16 (arrow B direction) against the elastic force of the release spring 80. As a result, the slider holder 18 approaches the base portion 44 of the cylindrical body 16, and the inclined walls 54 and 54 are gradually inserted into the pair of cutout portions 74 and 74, respectively.

  The tapered portions 88 and 88 of the sliders 22 and 22 are in contact with the inner surfaces of the inclined walls 54 and 54, respectively, and the slider holder 18 holding the sliders 22 and 22 is further directed toward the cylinder 16 (in the direction of arrow B). By displacing, the pair of sliders 22 and 22 are pushed and displaced by the inclined walls 54 and 54 in the direction in which they approach each other (arrow C1 direction). At this time, the slider 22 is guided by the first and second slider grooves 76 and 84 in a direction orthogonal to the axis of the cylindrical body 16 and the slider holder 18 (in the direction of arrow C1).

  As a result, the outer peripheral surface of the hub 26 is clamped from both sides by the holding surfaces of the pair of sliders 22, 22, and the bulging portion 90 provided on the holding surface is a grip groove 92 formed on the outer peripheral surface of the hub 26. And is securely held by the mutual adhesion.

  When the syringe 24 is further pushed toward the injection needle removing device 10 (arrow B direction), the release spring 80 is completely compressed, and the cover plate 30, the displacement body 28, the slider cover 20, the slider holder 18, and the cylinder are compressed. The body 16 is integrally displaced downward while the hub 26 is held by the pair of sliders 22 and 22. Since the cylindrical body 16 is engaged with the spiral groove 38 of the housing 14 via a guide roller 48 provided on the outer peripheral side, the cylindrical body 16 gradually moves downward (in the direction of arrow B) while rotating inside the housing 14. It will be displaced. At this time, since the syringe 24 is held by a nurse or the like, the syringe 24 is not rotated together with the cylinder 16 and is held in a state where the rotational displacement is restricted.

  As a result, as shown in FIGS. 9 and 10, the hub 26 held by the pair of sliders 22 and 22 rotates together with the slider holder 18, and the hub 26 screwed into the casing 98 is screwed. The As a result, the hub 26 gradually loosens from the distal end portion of the casing 98, and the clamped state with respect to the distal end portion is released by further pushing of the syringe 24, and finally comes off from the casing 98. Since the pitch number of the spiral groove 38 is larger than the pitch number of the screw portion at the tip of the syringe 24 to which the injection needle 23 is screwed, the screwed state of the injection needle 23 is surely released.

  Next, as shown in FIG. 11, the downward movement of the syringe 24 is stopped, and the displacement body 28 is displaced by moving the syringe 24 upward (in the direction of arrow A) in order to pull it out of the injection needle removing device 10. Thus, the downward pressing force applied to the slider holder 18 is released, so that the compressed release spring 80 is extended, and the elastic force of the slider holder 18 is pressed upward. As a result, the pressing force (thrust force) from the inclined walls 54, 54 against the pair of sliders 22, 22 is extinguished, and the holding force of the hub 26 by the sliders 22, 22 is released.

  As a result, the injection needle 23 falls downward (in the direction of arrow B) through the inside of the cylinder 16 and the housing 14 under the action of gravity, and the open end of the waste tank 12 connected to the lower part of the injection needle removal device 10. It is accommodated in the inside via the part 12a.

  Then, by pushing down the syringe 24 downward by a doctor, a nurse or the like and pulling it upward, the cylinder 16 is biased upward (in the direction of arrow A) under the resilient action of the return spring 62, The cylindrical body 16 is gradually displaced upward while rotating in the opposite direction to the above while engaging with the spiral groove 38 again. Accordingly, the slider holder 18, the slider cover 20, the displacement body 28, and the cover plate 30 are integrally displaced upward, and the upper surface of the cover plate 30 is aligned with the upper end of the cap 32. The completed syringe 24 is inserted, and the injection needle 23 is returned to the initial state where it can be removed.

  As described above, in the first embodiment, the syringe 24 is inserted into the hole of the cover plate 30 from above the injection needle detaching apparatus 10 and moved downward with the casing 98 in contact with the displacement body 28. By pushing, the pair of sliders 22 and 22 can be displaced toward the hub 26 side (in the direction of arrow C1) and gripped by the displacement action of the slider holder 18. Then, while the hub 26 is held by the sliders 22 and 22, the cylindrical body 16 is gradually displaced downward while rotating along the inner peripheral surface of the housing 14, so that it is held by the sliders 22 and 22. The removed hub 26 is removed by rotating with respect to the casing 98 constituting the syringe 24. Then, by releasing the gripping state by the sliders 22, 22, the injection needle 23 is dropped downward and accommodated in the waste tank 12.

  In this way, a doctor, a nurse, or the like can safely and reliably remove the injection needle 23 by a simple operation of inserting and pushing the syringe 24 into the upper portion of the injection needle removal apparatus 10.

  Further, since a force for pushing the syringe 24 into the injection needle removing apparatus 10 by a doctor or a nurse is used, no special power for removing the injection needle 23 is required. For example, a driving source such as a motor Need not be provided separately. Therefore, compared with the case where a drive source is provided, the configuration of the injection needle removing device 10 can be simplified and manufactured at a low cost, and the size and weight can be reduced.

  Further, a disposal tank 12 is attached to the lower part of the injection needle removing device 10, and the inside of the injection needle removing device 10 and the inside of the disposal tank 12 communicate with each other, and therefore the injection needle 23 removed from the syringe 24. Is accommodated in the waste tank 12 under the action of gravity. Therefore, a nurse or the like can be disposed without touching the used injection needle 23.

  Furthermore, since the needle removal device 10 can be easily attached and detached by screwing it into the open end 12a of the waste tank 12 through the tank mounting portion 36, for example, the waste tank 12 is discarded. Even when the injection needle 23 is full, it can be easily exchanged and attached to a new waste tank 12 for use.

  Furthermore, after the injection needle 23 is removed from the syringe 24, the slider holder 18 including the sliders 22, 22, the displacement body 28, and the cylinder body 16 are returned by a simple operation of displacing the syringe 24 upward. Under the elastic action of the spring 62, it is possible to quickly return to the initial state before the syringe 24 is pushed.

  In the injection needle removing device 10 described above, a guide roller 48 is provided on the outer periphery of the cylinder 16, and the guide roller 48 is moved along a spiral groove 38 formed on the inner peripheral surface of the housing 14. Thus, the cylindrical body 16 is displaced downward while rotating, and the injection needle 23 can be detached from the syringe 24 using the rotational force. However, the means for rotating the cylindrical body 16 is limited to this. Is not to be done.

  For example, a spiral ball groove may be provided on the outer peripheral surface of the cylindrical body 16 and the inner peripheral surface of the housing 14, and a ball screw structure in which a plurality of balls (steel balls) are interposed in the ball groove may be employed. In this case, the cylindrical body 16 can be smoothly rotated and displaced with respect to the housing 14 via the ball.

Next, an injection needle removing apparatus 150 according to the second embodiment is shown in FIGS. The same components as those in the needle removal device 10 according to the first embodiment described above are denoted by the same reference numerals, and detailed description thereof is omitted.

  In the injection needle removing apparatus 150 according to the second embodiment, as shown in FIGS. 12 to 15, the force in the linear direction (arrows A and B directions) when pushing the syringe 24 is applied in the rotational direction. Unlike the injection needle removing apparatus 10 according to the first embodiment, a power conversion mechanism (rotating means) 152 that converts force into a force includes a rack 154, a holding gear 156, and a transmission gear 158. Yes.

  The injection needle removing device 150 includes a cylindrical housing 160, a cylindrical body 162 that is displaceably provided in the housing 160, a power conversion mechanism 152 that is provided on an upper portion of the cylindrical body 162, and the housing 160. And a cap 164 covering the upper end.

  The housing 160 is formed in a cylindrical shape having both ends opened, and one end thereof is screwed into the opening end 12a of the waste tank 12, and the other end is opened upward. Further, on the inner peripheral surface of the housing 160, a rack 154 having a tooth portion 176 at a position facing a power conversion mechanism 152, which will be described later, and a rotation stopper 166 for restricting the rotational displacement of the cylindrical body 162 are provided.

  The cylindrical body 162 includes a cylindrical portion 168 provided on the disposal tank 12 side, and a base portion 170 that is formed at an end portion of the cylindrical portion 168 and has a diameter that is increased radially outward with respect to the cylindrical portion 168. A return spring 172 is inserted through the outer periphery of the cylindrical portion 168. The return spring 172 is formed of, for example, a coil spring, and is interposed between one end of the housing 160 and the base portion 170 of the cylindrical body 162, and is a direction in which the cylindrical body 162 is separated from the waste tank 12 (direction of arrow A). ). The base portion 170 is provided with a power conversion mechanism 152 on the end surface opposite to the end surface to which the tube portion 168 is joined.

  The power conversion mechanism 152 includes a holding gear 156 that is rotatably provided at the center of the base portion 170 and a bracket 174 that is engaged with the holding gear 156 and is erected on the base portion 170. It includes a supported transmission gear 158 and a rack 154 that is provided on the inner peripheral surface of the housing 160 and has a tooth portion 176 that meshes with the transmission gear 158.

  The holding gear 156 is provided on the axis of the cylindrical body 162 in the base portion 170, and is supported rotatably about the axis. A holding hole 178 into which the hub 26 constituting the injection needle 23 can be inserted and held is formed at the center of the holding gear 156.

  The holding gear 156 is a bevel gear having gear teeth 180 formed on the outer peripheral portion thereof. The gear teeth 180 are engraved at a predetermined angle with respect to the axis so as to face upward.

  The transmission gear 158 is provided so that its axis is orthogonal to the axis of the holding gear 156, and has first gear teeth 182 that mesh with the holding gear 156 and second gear teeth 184 that mesh with the rack 154. . The first and second gear teeth 182 and 184 are provided on the opposite sides across a portion pivotally supported by the bracket 174.

  The rack 154 is formed in a block shape having a predetermined length, is provided so as to be parallel to the axis along the inner peripheral surface of the housing 160, and a tooth portion 176 formed on the side surface of the rack 154 includes the first gear 176. The two gear teeth 184 are arranged so as to be able to mesh with each other.

  The cap 164 is formed in a cylindrical shape, and an insertion hole 186 into which the end of the syringe 24 is inserted is formed at the center thereof, so that the insertion hole 186 faces the holding gear 156 constituting the power conversion mechanism 152. Is provided. That is, the distal end portion of the syringe 24 is inserted into the holding hole 178 of the holding gear 156 through the insertion hole 186. Since the cap 164 is fixed to the base portion 170 of the cylindrical body 162, the cap 164 is integrally displaced when the cylindrical body 162 is displaced along the axial direction.

  In the injection needle removing apparatus 150 according to the second embodiment, the syringe 24 is moved to the injection needle 23 side in the initial state in which the cylindrical body 162 and the cap 164 are biased upward under the elastic action of the return spring 172. Is inserted into the insertion hole 186 of the cap 164 and then inserted into the holding hole 178 of the holding gear 156. As a result, the hub 26 is held by the inner peripheral surface of the holding hole 178 and is held in a state where displacement in the rotational direction is restricted.

  Then, by pushing the syringe 24 toward the waste tank 12 (in the direction of arrow B), the cylindrical body 162 is pressed downward against the elastic force of the return spring 172 together with the holding gear 156, and the cylindrical body 162. Both of the transmission gears 158 provided in are also displaced downward. As a result, the transmission gear 158 is displaced downward while rotating under meshing action with the rack 154, and the holding gear 156 is rotationally displaced together with the rotational action of the transmission gear 158. At this time, since the cylindrical body 162 is engaged with the rotation stopper 166 provided on the inner peripheral surface of the housing 160, the cylindrical body 162 is prevented from being rotationally displaced together with the holding gear 156.

  That is, the cylindrical body 162 is displaced downward by pushing the syringe 24, the transmission gear 158 is rotated under meshing action with the rack 154 that is displaced together, and the holding gear 156 meshed with the transmission gear 158 is rotated. It becomes possible to make it.

  As a result, the hub 26 held in the holding hole 178 of the holding gear 156 is displaced while rotating with respect to the casing 98, so that the tightening of the hub 26 starts to loosen gradually and the tightening state is further increased by further pushing of the syringe 24. Completely released. As a result, the injection needle 23 is detached from the distal end portion of the casing 98. Then, after the holding state by the holding hole 178 is released, the hub 26 falls downward (in the direction of arrow B) under the action of gravity through the cylindrical portion 168 of the cylindrical body 162 and the inside of the housing 160, and the injection needle removing device 150. Is housed in a waste tank 12 connected to the lower part of the tank.

  Finally, after the injection needle 23 is removed from the syringe 24, the pushing of the syringe 24 is stopped, and the cylinder 162 and the cap 164 are moved upward (in the direction of arrow A by the elastic force of the return spring 172). ) And the transmission gear 158 and the holding gear 156 constituting the power conversion mechanism 152 are gradually displaced upward while rotating in the opposite direction as the cylinder 162 is displaced upward. . As a result, the injection needle removing device 150 returns to the initial state in which the next used syringe 24 can be inserted and the injection needle 23 can be removed.

  As described above, in the second embodiment, by providing the power conversion mechanism 152 including the holding gear 156, the transmission gear 158, and the rack 154, the pressing force (thrust) applied via the syringe 24 is applied to the rack 154. The transmission gear 158 and the holding gear 156 can be easily converted into a rotational force, and the rotational force can be preferably used for removing the injection needle 23 including the needle 108 and the hub 26.

Note that the needle removal equipment according to the present invention is not limited to the above embodiments without departing from the gist of the present invention, it is should be understood that various configurations and combinations.

It is an external appearance perspective view of the injection needle removal apparatus and injection needle disposal container which concern on the 1st Embodiment of this invention. It is a disassembled perspective view of the injection needle removal apparatus shown in FIG. It is a longitudinal cross-sectional view of the injection needle removal apparatus shown in FIG. It is a longitudinal cross-sectional view orthogonal to the cross section of FIG. It is an expansion disassembled perspective view which shows the slider, slider holder, and cylinder in the injection needle removal apparatus of FIG. It is a top view of the syringe used for the injection needle removal apparatus of FIG. It is an expanded sectional view which shows the state by which the front-end | tip of the syringe was inserted in the opening part of the injection needle removal apparatus shown in FIG. FIG. 8 is an enlarged cross-sectional view showing a state in which the syringe is pushed toward the waste tank and the slider is in contact with the inclined wall in the injection needle removing device of FIG. 7. FIG. 9 is an enlarged cross-sectional view showing a state in which the syringe is further pushed toward the waste tank and the hub of the syringe is screwed with respect to the casing in the needle removal device of FIG. 8. FIG. 10 is an enlarged vertical cross-sectional view of the injection needle removing device of FIG. 9 viewed from the same cross section as that of FIG. 3. FIG. 10 is an enlarged cross-sectional view showing a state where the syringe is pulled upward after the syringe needle is removed from the syringe in the syringe needle removing device of FIG. 9. It is a whole longitudinal cross-sectional view of the injection needle removal apparatus and injection needle disposal container which concern on the 2nd Embodiment of this invention. It is a disassembled perspective view of the injection needle removal apparatus shown in FIG. It is a top view which shows the state which removed the cap from the injection needle removal apparatus shown in FIG. It is a longitudinal cross-sectional view which shows the state which the syringe was pushed in with respect to the injection needle removal apparatus of FIG. 1, and the cylinder was displaced below.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10, 150 ... Injection needle removal apparatus 12 ... Waste tank 14, 160 ... Housing 16, 162 ... Cylindrical body 18 ... Slider holder 20 ... Slider cover 22 ... Slider 23 ... Injection needle 24 ... Syringe 26 ... Hub 28 ... Displacement body 30 ... Cover plate 32, 164 ... Cap 38 ... Spiral groove 44, 170 ... Base 46 ... Tube 48 ... Guide roller 50 ... First hole 54 ... Inclined wall 58 ... Bolt 62, 172 ... Return spring 66 ... Support shaft 68, 152 ... Power conversion mechanism 70 ... Second hole 80 ... Release spring 86 ... Holding part 88 ... Tapered part 98 ... Casing 100 ... Holding hole 106 ... Opening part 108 ... Needle 154 ... Rack 156 ... Holding gear 158 ... Transmission gear 178 ... Holding hole

Claims (5)

In the needle removal device that can remove the injection needle screwed into the syringe,
An insertion part into which the syringe is inserted;
A holding means provided facing the insertion portion and holding an injection needle of the syringe;
A rotating means for rotating and holding the holding means in a state where the injection needle is held;
With
The thrust for inserting the syringe into the insertion portion holds the injection needle by the holding means and rotational displacement of the holding means by the rotating means, and the rotating means is housed in a cylindrical housing. And a cylindrical body engaged with a spiral groove formed in a spiral shape along the peripheral surface of the housing, and the cylindrical body is displaced along the axial direction while rotating inside the housing by the thrust. A needle removal device characterized by that. In the needle removal device that can remove the injection needle screwed into the syringe,
An insertion part into which the syringe is inserted;
A holding means provided facing the insertion portion and holding an injection needle of the syringe;
A rotating means for rotating and holding the holding means in a state where the injection needle is held;
With
The holding needle holds the injection needle and the rotation means rotates the holding means by the thrust force for inserting the syringe into the insertion portion, and the rotating means is arranged around the cylindrical housing. A rack that is provided on the surface and extends along the axial direction; a cylinder that is displaceable along the interior of the housing; and a holding gear that holds the injection needle and is rotatable; and the holding A transmission gear provided to be orthogonal to the gear and having a first tooth portion meshing with the holding gear and a second tooth portion meshing with the rack; and the cylindrical body is displaced by the thrust. Accordingly, the transmission gear meshed with the rack rotates, and the holding gear rotates as the transmission gear rotates . The injection needle removing device according to claim 1 or 2 ,
The holding means includes a pair of sliders that are arranged opposite to each other with the injection needle as a center and that can be displaced in a direction orthogonal to the axis of the injection needle,
2. The injection needle removing device according to claim 1, wherein the slider is displaced in a direction in which the sliders approach each other by the thrust, thereby pinching the injection needle. The injection needle removing device according to claim 1 ,
An injection needle removing device comprising a pair of inclined walls having inclined surfaces that engage with the slider at an end of the cylindrical body. In needle removal device according to claim 1 or 2 Symbol placement,
Release means capable of releasing the holding state of the injection needle by the holding means,
2. The injection needle removing apparatus according to claim 1, wherein the release means comprises a spring having a resilient force that can be displaced in a direction to separate the sliders from each other against the thrust.

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