JP2022105107A - Needle disposal container - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a needle disposal container capable of disposing a plurality of kinds of needle units by detachment from syringes with a single operation.

SOLUTION: A needle disposal container includes a lid body 102 having an opening 121 for allowing a needle unit to fall into a storage part. The lid body 102 has a movement part 131. The movement part 131 is combined with the opening 121 so as to form an insertion hole 123 into which a needle hub of the needle unit can be inserted. The movement part or the opening has a rotation prevention part 125 for preventing rotation of the needle hub inserted into the insertion hole 123. The rotation prevention part includes two projections 126 where a first rotation prevention part for preventing the rotation of the first needle hub is formed on an external side wall of the two projections and a second rotation prevention part for preventing the rotation of the second needle hub is formed on an internal side wall.

SELECTED DRAWING: Figure 7

COPYRIGHT: (C)2022,JPO&INPIT

Description

The present disclosure relates to a container for needle disposal.

Conventionally, in order to prevent accidental puncture by a medical worker, various needle disposal containers have been studied in which the needle is safely separated from the syringe and discarded without touching the needle attached to the syringe. In recent years, self-injection of insulin by diabetic patients has been performed, and it may be necessary for a person other than a trained healthcare professional to handle the needle. Therefore, there is a demand for a needle disposal container that is easier to operate and has higher safety.

For self-injection of insulin, it is common to use a dedicated syringe called a pen-type injector. A common standard needle unit is attached to a normal pen-type injector. This needle unit is a screw-in type, and in order to separate the needle unit from the pen-type injector, it is necessary to fix one of the needle unit and the pen-type injector and rotate the other. For this reason, a needle disposal container for a pen-type injector has been proposed, which is provided with a hold portion that holds a needle unit so as not to rotate by sandwiching a rib provided on the needle hub of the needle unit (for example, a patent). See Document 1). The needle unit can be dropped into the container by rotating the pen-type injector while holding the needle unit to separate the needle unit from the pen-type injector and then releasing the hold.

Japanese Unexamined Patent Publication No. 2016-32557

However, the needle unit of the pen-type injector is sold by multiple manufacturers, and although they meet the common standard for the internal thread structure, the external shape of the needle hub is not the same. .. Therefore, the hold unit corresponding to a specific needle unit cannot hold another needle unit, and it is necessary to prepare a needle disposal container for each needle unit.

It is also conceivable to provide a plurality of types of hold portions in the needle disposal container to support a plurality of types of needle units, or to replace the hold portions to support a plurality of types of needle units. However, when multiple hold parts are provided, the operator needs to select the correct hold part according to the needle unit, and when the diabetic patient himself disposes of the needle, the operation is confusing and cannot be done well. There is. Further, when the hold portion is a replaceable type, a complicated replacement operation is required.

An object of the present disclosure is to realize a needle disposal container in which a plurality of types of needle units can be removed from a syringe and disposed of by the same operation.

One aspect of the needle disposal container includes an accommodating portion for accommodating the needle unit separated from the main body of the syringe, and a lid having an opening for dropping the needle unit into the accommodating portion. It has a moving part that can move between the position and the second position, and in the first position, the moving part is combined with the opening to form an insertion hole into which the needle hub of the needle unit can be inserted. , In the second position, combined with the opening to form a drop hole, the moving part or opening has a rotation blocking part that blocks the rotation of the needle hub inserted in the insertion hole, and the rotation blocking part , Has two protrusions formed at intervals from each other, and the outer side wall of the two protrusions can regulate the relative rotation between the first needle hub and the insertion hole by abutting on the first needle hub. The inner side wall of the two convex portions forms a first rotation blocking portion, and the second needle hub and the insertion hole are formed by contacting the second needle hub having an external shape different from that of the first needle hub. A second rotation blocking portion that can regulate the relative rotation of the needle is formed.

With such a configuration, a plurality of needle units can be held by a kind of engaging structure. Then, regardless of whether the needle unit attached to the syringe body is the first needle hub or the second needle hub having an external shape different from that of the first needle hub, the user is not aware of the difference. It can be easily removed from the needle body and safely disposed of.

In one aspect of the needle disposal container, the distance between the outer side walls of the two protrusions can be greater than 1.1 mm and less than 2.8 mm. With such a width configuration that has never existed in the past, it becomes easier to remove the first needle hub.

In one aspect of the needle disposal container, the first rotation blocking portion regulates each of the outer side walls of the two protrusions so that the first needle hub and the insertion hole cannot rotate in either of the circumferential directions. Has a rotation blocking part. With such a configuration, each rotation blocking portion comes into contact with each facing side surface forming the recess of the first needle hub, so that wobbling between the needle hub and the insertion hole can be prevented.

In one aspect of the needle disposal container, the distance between the rotation blocking portions may be larger than 1.1 mm and less than 2.8 mm. With such a width configuration that has never existed in the past, it becomes easier to remove the first needle hub.

In one aspect of the needle disposal container, the first rotation blocking portion and the second rotation blocking portion are formed on the same circumference. With such a configuration, it is possible to facilitate the formation of the first rotation blocking portion and the second rotation blocking portion.

In one aspect of the needle disposal container, the two protrusions extend in the axial direction, and the distance between the outer side walls of the two protrusions may be gradually reduced from the lower part to the upper part. With such a configuration, the first needle hub can be inserted into the insertion hole more smoothly.

In one aspect of the needle disposal container, the insertion hole may have a stopper portion that prevents the inserted needle hub from moving below a predetermined position. With such a configuration, when the needle hub is inserted into the insertion hole, the needle hub can be prevented from coming off downward.

In one aspect of the needle disposal container, the rotation blocking portion is located at a position facing each other in the moving direction of the moving portion at the portion forming the insertion hole of the moving portion and the portion forming the insertion hole of the opening. It may be formed. With such a configuration, the removed needle unit can be easily dropped into the accommodating portion.

In one aspect of the needle disposal container, the two convex portions provided in the moving portion are formed of a material having a higher hardness than the two convex portions provided in the portion forming the insertion hole of the opening. May be good. With such a configuration, the convex portion on the moving portion side can be made less likely to be worn, and the life of the needle disposal container can be extended.

According to the needle disposal container of the present disclosure, a plurality of types of needle units can be removed from the syringe and disposed of by the same operation.

FIG. 1 is a perspective view showing an example of a syringe. FIG. 2 is a perspective view showing an example of the first needle hub. FIG. 3 is a plan view seen from the tip side showing an example of the first needle hub. FIG. 4 is a perspective view showing an example of the second needle hub. FIG. 5 is a plan view seen from the tip side showing an example of the second needle hub. FIG. 6 is a perspective view showing a needle disposal container according to an embodiment. FIG. 7 is a plan view showing an insertion hole of the needle disposal container according to the embodiment. FIG. 8 is an end view showing the moving portion. FIG. 9 is a plan view showing a state in which the first needle hub is inserted into the insertion hole. FIG. 10 is a plan view showing a state in which the second needle hub is inserted into the insertion hole. FIG. 11 is a plan view showing a modified example of the insertion hole. FIG. 12 is a front view showing a modified example of the rotation blocking portion. FIG. 13 is a front view showing a modified example of the rotation blocking portion. FIG. 14 is a plan view showing a modified example of the insertion hole. FIG. 15 is a plan view showing a modified example of the lid. FIG. 16 is a plan view showing a modified example of the lid.

In this embodiment, as shown in FIG. 1, an example in which the syringe 200 is a so-called pen-type injector for injecting insulin will be described. The syringe 200, which is a pen-type injector, has a syringe body 201 and a needle unit 202. The needle unit 202 of the present embodiment has a needle body 221 for puncture and a needle hub 222 for holding the needle body 221. The needle hub 222 has a connecting female screw that engages with a connecting male screw provided at the tip of the syringe body 201, and the needle unit 202 is screw-connected to the syringe body 201. When the needle unit 202 is connected to the syringe body 201, the back needle portion 223 extending toward the proximal end side of the needle body 221 punctures the seal of the drug solution container (not shown) contained in the syringe body 201.

In this embodiment, an example in which the needle hub 222 is either the first needle hub 222A or the second needle hub 222B will be described. As shown in FIGS. 2 to 5, the first needle hub 222A has four pointed arch-shaped first needle hub recesses 224 on the outer peripheral surface at equal intervals, and the second needle hub 222B has an outer peripheral surface. It has a plurality of columnar second needle hub protrusions 225 provided on the surface. In the figure, the first needle hub recess 224 has a shape in which the width gradually narrows toward the proximal end side, the maximum width w1max is 2.8 mm, and the second needle hub convex portion 225 has 0. An example is shown in which the width is constant at 9 mm. The maximum width w1max of the first needle hub recess 224 is larger than the width w2 of the second needle hub convex portion 225 (w1max> w2), and the maximum outer diameter φmax1 of the first needle hub 222A is that of the second needle hub 222B. Larger than the maximum outer diameter φmax2. Further, the outer diameter of the first needle hub recess 224 is smaller than the outer diameter of the second needle hub convex portion 225.

As shown in FIG. 6, the needle disposal container of the present embodiment has an accommodating portion 101 for accommodating the needle unit 202 separated from the syringe body 201, and an opening 121 for dropping the needle unit 202 into the accommodating portion 101. It has a lid 102 and a lid 102. A moving portion 131 that can move between the first position P1 and the second position P2 is assembled to the lid 102 with respect to the opening 121.

As shown in FIGS. 7 and 14, in the moving portion 121, at the first position P1, the engaging recess 146 engages with the flexible piece 147 provided on the lid 120 and is fixed to the first position P1. be able to. At the first position P1, the moving portion 131 is combined with the opening 121 to form the insertion hole 123. The maximum inner diameter φmax3 of the insertion hole 123 is larger than the maximum outer diameter φmax1 of the first needle hub 222A, and both the first needle hub 222A and the second needle hub 222B can be inserted.

As shown in FIG. 7, when the engaging recess 146 and the flexible piece 147 are disengaged and the moving portion 131 is moved to the second position P2 along the slide groove 148, the moving portion 131 opens. Combined with the portion 121, it forms a drop hole with sufficient space for the needle hub 222 to drop into the accommodating portion 101. If the gravity of the needle hub 222 is larger than the frictional force with the moving portion 131 or the opening portion 121, the needle hub 222 falls from the drop hole to the accommodating portion 101 by its own weight.

As shown in FIG. 8, a moving portion curved wall 134 extending in the axial direction is provided at the end of the moving portion 131, and the opening portion is curved at the portion of the opening 121 facing the moving portion curved wall 134. A wall 124 is provided. The moving portion curved wall 134 and the opening curved wall 124 are combined to form the insertion hole 123. If the axial length (height) of the moving portion curved wall 134 and the opening curved wall 124 is made longer than the height of the first needle hub 222A and the second needle hub 222B, the user can use the back of the disposal container. The needle hub 222 can be pushed in until. Therefore, the fulcrum when preventing the relative rotation between the needle hub 222 and the insertion hole 123 can be lowered, and the sense of stability when the syringe 200 and the disposal container are relatively stable can be improved.

The insertion hole 123 is provided with a rotation blocking portion 125 for blocking the rotation of the inserted first needle hub 222A and the second needle hub 222B. In the present embodiment, the rotation blocking portion 125 is provided at the central portion of the moving portion curved wall 134 and the opening curved wall 124, respectively. As shown in FIGS. 7 and 8, the rotation blocking portion 125 has two convex portions 126 extending in close proximity to each other and having a constant width in the axial direction. It should be noted that the two convex portions 126 may have a function of abutting the first needle hub concave portion 224 and the second needle hub convex portion 225, which is a function as a rotation blocking portion 125. For example, the protruding direction tips of the two convex portions 126 are the rotation blocking portions 125 that abut with the first needle hub 222A and the second needle hub 222B, and the protruding direction base ends of the two convex portions 126 are the first needle hub 222A and the second needle hub 222A. It may be configured so as not to come into contact with the 2-needle hub 222B. Further, the intermediate portion in the protruding direction and the base end in the protruding direction of the two convex portions 126 can be used as the rotation blocking portion 125. The two convex portions 126 may not be separated from each other in a portion other than the rotation blocking portion 125 as long as the insertion of the needle hub 222 is not affected, and even if some of the two convex portions 126 have different separation distances. good.

When the first needle hub 222A is inserted into the insertion hole 123, two protrusions 126 are located inside the first needle hub recess 224, as shown in FIG. Therefore, when attempting to rotate the first needle hub 222A, one of the outer side walls 127 of the two convex portions 126 abuts on the side wall of the first needle hub recess 224, and the rotation of the first needle hub 222A is performed. Stop. The side walls of the two convex portions 126 facing each other are referred to as the inner side wall 128, and the side walls opposite to the inner side wall 128 are referred to as the outer side wall 127. As described above, at least a part of the outer side wall 127 becomes a first rotation blocking portion that blocks the rotation of the first needle hub 222A.

When the second needle hub 222B is inserted into the insertion hole 123, the second needle hub convex portion 225 is located between the two convex portions 126 as shown in FIG. Therefore, when the second needle hub 222B is to be rotated, one of the inner side walls 128 of the two convex portions 126 facing each other abuts on the side wall of the second needle hub convex portion 225, and the second needle hub The rotation of 222B is blocked. In this way, at least a part of the inner side wall 128 becomes a second rotation blocking portion that blocks the rotation of the second needle hub 222B.

As shown in FIGS. 9 and 10, when the first needle hub 222A or the second needle hub 222B is inserted into the insertion hole 123, the distance t1 between the outer side walls 127 of the two protrusions 126 is the first needle hub. The recess 224 has a distance smaller than or equivalent to the maximum width w1max. Considering that in the present embodiment, the maximum width w1max of the first needle hub concave portion 224 is 2.8 mm, and the distance t2 between the two convex portions 126 must be larger than the width w2 of the second needle hub convex portion 225. t1 is preferably smaller than 2.8 mm, larger than 1.1 mm, and preferably larger than 1.4 mm in consideration of molding accuracy. However, since the resin needle hub is deformed by pressing, t1 may be equal to or slightly larger than 2.8 mm. In the present embodiment, of the two convex portions 126, the portion that abuts on the first needle hub concave portion 224 and regulates rotation is the tip angle of the outer side wall 127 of the two convex portions 126 extending in the axial direction. Is one of. The distance between the tip angles of the outer side wall 127 is the width of the first rotation blocking portion, that is, the width of the first rotation blocking portion is larger than 1.1 mm, preferably larger than 1.4 mm and less than 2.8 mm. Is preferable. The values of the interval t1 and the interval t2 are the values of the interval in the plan view (viewpoint of FIG. 9) of the needle disposal container.

The axial length of the convex portion 126 is not particularly limited, but a longer one is advantageous for preventing the rotation of the second needle hub 222B. Further, as shown in FIG. 11, for each of the outer side walls 127 of the two convex portions 126, a part thereof is prevented from rotating so as to come into contact with a part of each side surface forming the pointed arch shape of the first needle hub concave portion 224. By providing the portion 129, the needle hub 222 can be restricted from rotating in any of the radial directions so that the needle hub 222 does not wobble with respect to the insertion hole 123. Specifically, in the present embodiment, the tip angles of both the outer side walls 127 of the two convex portions 126 are set as rotation blocking portions 129, and the user inserts the first needle hub 222A into the insertion hole 123. The first needle hub 222A is designed so that the corresponding tip angle, which is the rotation blocking portion 129, abuts on a part of each side surface constituting the pointed arch shape. Therefore, in the present embodiment, the needle hub is restricted from rotating in any of the radial directions, and at the same time, the needle hub insertion depth is specified.

When the first rotation blocking portion for the first needle hub 222A and the second rotation blocking portion for the second needle hub 222B are separately provided in the insertion hole 123, one of the rotation blocking portions becomes. There is a possibility that the insertion of the other needle hub may be hindered, or the self-weight drop of the needle hub may be hindered when the moving portion 131 is moved, but the two convex portions 126 provided side by side face each other. By using the outer side wall 127 that is not used to prevent the rotation of the first needle hub 222A and the inner side walls 128 that face each other to prevent the rotation of the second needle hub 222B, the possibility of the above inhibition can be reduced. .. In the present embodiment, the first rotation blocking portion and the second rotation blocking portion are formed on the same circumference, but the first rotation blocking portion is formed in the height direction (vertical direction in FIG. 8). And the second rotation blocking portion may be different.

The insertion hole 123 can have all the portions other than the rotation blocking portion 125 larger than the maximum diameter φmax1 of the first needle hub 222A. By doing so, the first needle hub 222A can be inserted into the insertion hole 123.

In the present embodiment, an example is shown in which one rotation blocking portion 125 is provided for each of the moving portion curved wall 134 and the opening curved wall 124. When the moving portion 131 is moved to the second position P2 by providing the rotation blocking portion 125 on the moving portion curved wall 134 and the opening curved wall 124 so as to face each other in the moving direction of the moving portion 131. It is possible to reduce the situation where the rotation blocking portion 125 holds the needle hub 222 too tightly and the needle hub 222 does not fall into the accommodating portion 101, and more reliably the first needle hub 222A and the second needle hub. The rotation of 222B can be prevented. However, the rotation blocking portion 125 may be provided on at least one of the moving portion curved wall 134 and the opening curved wall 124.

In the needle disposal container of the present embodiment, it is preferable that the needle hub 222 is pressed in the radial direction when the needle hub 222 is inserted into the insertion hole 123. By doing so, the rotation of the needle hub 222 can be more reliably prevented. Further, by being pressed, the back needle portion 223 does not come off from the seal cap of the chemical solution container when the syringe main body 201 is pulled upward after the screw engagement between the syringe main body 201 and the needle unit 202 is released. Can be less likely to occur.

The radial pressing of the needle hub 222 is preferably performed by abutting the radial end of the convex portion 126 with the outer wall of the needle hub 222. In the case where the entire inner wall surface or most of the inner wall surface of the insertion hole 123 is in contact with and pressed against the needle hub 222, even if the moving portion 131 is moved from the first position P1 to the second position P2, the needle hub 222 is still on the wall surface. There is a risk that it will not come off. However, when only the convex portion 126 is in pressure contact, the needle hub 222 can be easily dropped by moving the moving portion 131 to the second position P2.

Further, if the insertion hole 123 is configured such that the portion exceeding ½ of the circumference thereof is composed of the moving portion curved wall 134 or the opening curved wall 124, the moving portion 131 can be moved from the first position P1 to the second position P1. The needle hub 222 can be more easily dropped when it is moved to the position P2.

The moving portion 131 can be formed of the same material as the other portions of the lid 102. Further, the moving portion 131 can be formed of a material harder than the other portions of the lid 102. For example, the moving portion 131 can be formed of acrylonitrile-butadiene-styrene (ABS) resin, polycarbonate resin, polyacetal resin, or the like, and the other portion can be formed of polyethylene, polypropylene, or the like. By doing so, the durability of the moving portion 131 can be improved. Further, the lid 102 other than the moving portion 131 and the accommodating portion 101 can be integrally molded.

When the two convex portions 126 of the rotation blocking portion 125 are provided on both the moving portion curved wall 134 and the opening curved wall 124, the two convex portions 126 provided on the moving portion curved wall 134 are provided with the opening. It can be formed of a material having a hardness higher than that of the two convex portions 126 provided on the curved wall 124. If the two convex portions 126 on the moving portion curved wall 134 side are formed of a hard material, even if the two convex portions 126 on the opening curved wall 124 side are worn, the rotation of the needle hub 222 is prevented. The needle hub 222 can be removed, and the life of the needle disposal container can be extended. The moving portion 131, which is a small part as compared with the entire lid 102, has a wide range of material selection and can be easily formed of a hard material.

FIG. 8 shows an example in which the distance t1 between the outer side walls 127 of the two convex portions 126 is substantially constant. However, as in the modified example shown in FIG. 12, the interval t1 may be formed to gradually increase from the upper part (insertion port side) to the lower part (container container side) of the insertion hole 123. By doing so, it becomes possible to align the outer side wall 127 of the two protrusions 126 along the side surface of the pointed arch-shaped first needle hub recess 224. As a result, the rotation blocking portion 129 that abuts on the side surface of the first needle hub recess 224 on the outer side wall 127 can be increased, and the rotation of the first needle hub 222A can be more reliably regulated. Further, since the rotation blocking portion 129 becomes large, the force applied to the rotation blocking portion 129 is dispersed, so that the durability of the rotation blocking portion 125 can be improved.

In FIG. 12, an example in which the outer side wall 127 of the two convex portions 126 is formed in a straight line is shown, but it can also be formed in a curved shape in accordance with the side surface of the first needle hub recess 224. In FIG. 12, an example in which the width of the convex portion 126 is constant is shown, but the width of the convex portion 126 does not have to be constant. Further, the distance t2 between the inner side walls 128 of the two convex portions 126 can be made constant. For example, the width of the convex portion 126 may be narrow at the upper portion and wide at the lower portion so that the distance t2 between the inner side walls 128 of the two convex portions 126 is constant. By doing so, the distance between the outer side walls 127 of the two convex portions 126 gradually decreases from the lower portion to the upper portion, so that the first needle hub convex portion 224 can be inserted into the insertion slot 123 more smoothly. Further, the outer side wall 127 of the two convex portions 126 can be formed into a shape along the first needle hub convex portion 224, and the inner side wall 128 can be formed into a shape along the second needle hub convex portion 225. The 2-needle hub 222B can be rotated more reliably.

As shown in FIG. 13, when the needle hub 222 is inserted into the insertion hole 123, a stopper portion 141 protruding inward of the insertion hole 123 may be provided in order to prevent the needle hub 222 from coming off downward. can. In FIG. 13, the stopper portion 141 is provided below the rotation blocking portion 125, but the stopper portion 141 is not limited to such a configuration and is smaller than the maximum outer diameter of the needle hub 222, so that the needle hub 222 cannot pass through. Any configuration may be used as long as the portion can be provided in the insertion hole 123. For example, the stopper portion 141 can be provided over the entire circumference of the insertion hole 123 or partially in a flange shape. Further, the stopper portion 141 may be a convex portion provided at one place or a plurality of places. The stopper portion 141 may be provided only on the curved wall 124 side on the opening side, may be provided only on the curved wall 134 side on the moving portion side, or may be provided on both of them. The stopper portion 141 can be provided at the lower end of the insertion hole 123, but the position of the stopper portion 141 can be adjusted according to the depth of the insertion hole 123. The stopper portion 141 can also be provided in the case of the configuration as shown in FIG.

In the present embodiment, the portion of the peripheral wall of the insertion hole 123 between the two convex portions 126 is thicker than the other portions of the peripheral wall of the insertion hole 123, as shown in FIGS. 7 and 10. There is. With such a configuration, as shown in FIG. 10, the second needle hub convex portion 225 can be brought into contact with the wall surface between the two convex portions 126, so that the second needle hub 222B is inserted into the insertion hole 123. It can be made less rattling when inserted into.

Further, as shown in FIG. 14, a thick portion 143 having a thick peripheral wall can also be provided on the outer portion of the two convex portions 126 of the rotation blocking portion 125. By doing so, the strength of the convex portion 126 can be increased and the durability can be improved. Further, when the distance between the first needle hub 222A and the second needle hub 222B and the peripheral wall of the insertion hole 123 is made smaller, the first needle hub 222A and the second needle hub 222B are inserted into the insertion hole 123. It can also make it less likely to rattle. Further, the thick portion 143 or the convex portion 126 can be used as a hub urging portion that applies a force toward the inside of the hub. By providing a hub urging part so that the needle hub is held in a state where a force is applied toward the inside of the hub at the first position, it is possible to perform the hub rotation and when the syringe body is separated from the hub. It can be less likely to rattle. It is also possible to provide a wall thickness portion 144 in a portion other than the rotation blocking portion 125 as long as the first needle hub 222A and the second needle hub 222B can be inserted. The wall thickness portion 144 may have a shape in which the side surface 144a on the side close to the rotation blocking portion 125 is substantially parallel to the moving direction of the moving portion 131. By doing so, when the moving portion 131 moves from the first position to the second position, the thick portion 144 can be prevented from interfering with the first needle hub 222A and the second needle hub 222B.

In this embodiment, the lid 102 is shown to be substantially flat around the insertion hole 123. With such a configuration, there is an advantage that the formation is easy. On the other hand, as shown in FIG. 15, a recess 145 may be provided around the insertion hole 123 of the lid 102. By providing the recess 145 around the insertion hole 123, the operation becomes easy even when the diameter of the syringe body 201 is large.

In the present embodiment, the insertion hole 123 has a portion other than the rotation blocking portion 125, which is larger than the maximum diameter φmax1 of the first needle hub 222A. The configuration in which the 1-needle hub 222A can be inserted into the insertion hole 123 with almost no resistance is shown. However, as shown in FIG. 16, the maximum outer diameter of the insertion hole 123 when the first needle hub 222A is not inserted is made smaller than the maximum outer diameter of the first needle hub 222A, and the first needle hub 222A is inserted. When inserted into the hole 123, a slight gap is formed between the curved wall 124 on the opening side and the curved wall 134 on the moving portion side, and the insertion hole 123 may be deformed so as to expand in diameter.

As a method of deforming the insertion hole 123 so as to expand the diameter, for example, a method of adjusting the shape and strength of the flexible piece 147 holding the moving portion 131 at the first position P1 so as to allow the diameter expansion. Can be used.

The needle disposal container of the present disclosure is useful as a needle disposal container because a plurality of types of needle units can be removed from the syringe and disposed of by the same operation.

101 Accommodation 102 Lid 121 Opening 123 Insertion hole 124 Opening side curved wall 125 Rotation blocking part 126 Convex part 127 Outer side wall 128 Inner side wall 129 Rotation blocking part 131 Moving part 134 Moving part side curved wall 141 Stopper part 143 Thick part 144 Thick part 144a Side surface 145 Recess 146 Engagement recess 147 Flexible piece 148 Sliding groove 200 Syringe 201 Syringe body 202 Needle unit 221 Needle body 222 Needle hub 222A 1st needle hub 222B 2nd needle hub 223 Back needle Part 224 1st needle hub concave part 225 2nd needle hub convex part

Claims (9)

A housing unit that houses the needle unit separated from the syringe body,
The needle unit is provided with a lid having an opening for dropping into the accommodating portion.
The lid has a moving portion that can move between a first position and a second position.
The moving portion is combined with the opening at the first position to form an insertion hole into which the needle hub of the needle unit can be inserted, and is combined with the opening at the second position. Form a drop hole,
The moving portion or the opening has a rotation blocking portion that prevents the needle hub inserted into the insertion hole from rotating.
The rotation blocking portion has two convex portions formed at intervals from each other.
The outer side wall of the two protrusions forms a first rotation blocking portion that can regulate the relative rotation between the first needle hub and the insertion hole.
The inner side wall of the two protrusions forms a second rotation blocking portion that can regulate the relative rotation of the insertion hole and the second needle hub having an external shape different from that of the first needle hub. Container for. The needle disposal container according to claim 1, wherein the distance between the outer side walls of the two protrusions is larger than 1.1 mm and less than 2.8 mm. The first rotation blocking portion is claimed to have, on each of the outer side walls of the two convex portions, a rotation blocking portion that restricts the first needle hub and the insertion hole from rotating in either direction. Item 1 or 2 Needle disposal container. The needle disposal container according to claim 3, wherein the distance between the rotation blocking portions is larger than 1.1 mm and less than 2.8 mm. The needle disposal container according to any one of claims 1 to 4, wherein the first rotation blocking portion and the second rotation blocking portion are formed on the same circumference. The two protrusions extend in the axial direction and
The needle disposal container according to any one of claims 1 to 5, wherein the distance between the outer side walls of the two protrusions gradually narrows from the lower part to the upper part. The needle disposal container according to any one of claims 1 to 6, wherein the insertion hole has a stopper portion for preventing the inserted needle hub from moving below a predetermined position. The rotation blocking portion is formed at a position facing each other in the moving direction of the moving portion in each of the portion of the moving portion that forms the insertion hole and the portion of the opening that forms the insertion hole. The needle disposal container according to any one of claims 1 to 7. 8. The two convex portions provided in the moving portion are formed of a material having a hardness higher than that of the two convex portions provided in the portion of the opening forming the insertion hole. Needle disposal container described in.

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