JP6919795B2 - Needle assembly - Google Patents

Description

The present invention relates to a needle assembly that is punctured into the skin during blood collection, blood transfusion, infusion, etc., and is housed and protected in a housing after use.

Conventionally, needle assemblies used for infusion, blood collection, and hemodialysis have been known. This needle assembly includes a hollow needle, and the base end of the hollow needle is fixed to the needle hub. When such a needle assembly is punctured into a patient's blood vessel, infusion, blood collection, and hemodialysis are performed through an external conduit such as a canula connected to a needle hub.

By the way, some needle assemblies are provided with a housing that protects the needle tip after use for the purpose of preventing erroneous puncture and reuse, facilitating disposal, and the like. For example, as a needle assembly provided with such a housing, there is one described in US Pat. No. 5,779,679 (Patent Document 1).

That is, the needle assembly described in Patent Document 1 includes a hollow needle, a needle hub that fixedly supports the hollow needle, and a substantially tubular housing that is externally and externally movable to the needle hub in the axial direction. ing. Then, in the initial state before use, these needle hubs and the housing engage with each other to compress the urging member (spring) provided in the housing, and the hollow needle protrudes from the housing. It is held in. In this state, the hollow needle is punctured into the patient's blood vessel to perform the treatment, and then the needle hub and the housing are disengaged by an external operation, and the hollow needle and the needle hub are based on the housing by the urging force of the spring. By moving it to the end side, the hollow needle can be safely disposed of while being housed in the housing.

In the needle assembly described in Patent Document 1, when the needle hub is moved toward the proximal end side with respect to the housing, the contact projection (40) protruding outward in the axially intermediate portion of the needle hub is the housing (main body). It was regulated by entering the opening (48) at the base end portion of the portion 12) and contacting the engaging shoulder portion (47) with each other. That is, the inner diameter of the main body is substantially constant over the entire length.

However, since the inner diameter of the main body is substantially constant over the entire length, the contact protrusion of the needle hub is not locked to the engaging shoulder, and the hollow needle and the needle hub may be affected by the urging force of the spring. , There was a risk of popping out from the main body.

It is conceivable to provide a protrusion protruding inward on the inner surface of the main body, but if such a structure is adopted, the structure of the molding mold of the housing may become complicated and the manufacturing efficiency may decrease.

U.S. Pat. No. 5,779,679

The present invention has been made in the background of the above circumstances, and a solution thereof is to move the needle hub toward the proximal end side with respect to the housing without providing a protrusion protruding inward with respect to the housing. The purpose is to provide a needle assembly with a new structure that can be reliably regulated.

Hereinafter, aspects of the present invention made to solve such problems will be described. The components adopted in each of the following aspects can be adopted in any combination as much as possible.

In the first aspect of the present invention, the needle hub of the hollow needle is interpolated so as to be movable in the axial direction with respect to the tubular housing, and the hollow needle protrudes from the housing at a position where the hollow needle protrudes. It is provided with an engaging mechanism for positioning the needle hub and an urging means for urging the hollow needle with respect to the housing in the pull-in direction, and when the engaging mechanism is released, the hollow needle moves to the housing. In the needle assembly that is retracted and accommodated, a locking hole that opens on the inner surface of the housing is provided, while a locking protrusion that elastically protrudes from the needle hub toward the inner surface of the housing is provided. At the position where the hollow needle is pulled into the housing, the locking protrusion is locked in the locking hole to prevent the hollow needle from re-protruding from the housing. The inner surface of the housing on which the locking protrusion slides toward the locking hole as the hollow needle is pulled into the housing is at least the inner surface on the tip side in the axial direction of the locking hole. At the opening edge of the housing, the locking hole is located on the outer peripheral side of the inner surface of the locking hole on the axially proximal end side, and is located on the distal end side of the locking hole in the axial direction of the housing. Guidance for guiding the locking protrusion into the locking hole with an inclined surface in which the inner surface to which the locking protrusion is slidably contacted gradually expands toward the outer peripheral side toward the axial base end side where the locking hole is located. It is characterized by being a surface.

A second aspect of the present invention is the needle assembly according to the first aspect, wherein the housing is provided with a deformable flexible wall portion located on the tip side in the axial direction with respect to the locking hole. The locking protrusion that slides into the inner surface of the housing and moves toward the locking hole when the hollow needle is pulled in is pressed against the flexible wall portion, and the flexible wall portion is outward. By deforming toward, the position of the inner surface of the locking hole on the tip side in the axial direction at the opening edge is set.

A third aspect of the present invention is the needle assembly according to the second aspect, wherein the flexible wall portion is formed by partially thinning the peripheral wall portion of the housing. be.

According to the needle assembly having a structure according to the present invention, when the locking protrusion is introduced into the locking hole, the inner surface (guide surface) on the axially front side of the locking hole is axially rearward. since it is located on the outer peripheral side than the inner surface of the side, to the engaging hole engaging projections, it is sealed more reliably engaged, jump out from the housing of the hollow needle and needle hub are effectively prevented obtain.

The plan view which shows the needle assembly as 1st Embodiment of this invention in use state. FIG. 1 is a sectional view taken along line II-II in FIG. FIG. 2 is a sectional view taken along line III-III in FIG. The plan view which shows the needle assembly shown in FIG. 1 in the housed state of a hollow needle. FIG. 4 is a sectional view taken along line VV in FIG. FIG. 5 is a sectional view taken along line VI-VI in FIG. The front view which shows the needle assembly as the 2nd Embodiment of this invention in use state. FIG. 7 is a plan view of the needle assembly shown in FIG. FIG. 7 is a cross-sectional view taken along the line IX-IX in FIG. The front view which shows the needle assembly shown in FIG. 7 in the housed state of a hollow needle. FIG. 10 is a plan view of the needle assembly shown in FIG. FIG. 10 is a cross-sectional view taken along the line XII-XII.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

First, FIGS. 1 to 3 show a needle assembly 10 as a first embodiment of the present invention in a used state. The needle assembly 10 includes a hollow needle 12 and a needle hub 14 that fixedly supports the proximal end side of the hollow needle 12, and the hollow needle 12 and the needle hub 14 are shafts with respect to a tubular housing 16. It is interpolated so that it can move in the direction. Then, as shown in FIGS. 1 to 3, in the used state, the needle tip 18 of the hollow needle 12 protrudes from the housing 16 toward the tip side, while after use, the hollow needle 12 and the needle hub 14 are attached to the housing 16. On the other hand, the needle tip 18 of the hollow needle 12 is accommodated and protected in the housing 16 by moving to the base end side. In the following description, the axial direction means the left-right direction in FIG. 1, which is the needle axial direction of the hollow needle 12. Further, the tip side and the front refer to the left side in FIG. 1 which is the needle tip 18 side of the hollow needle 12, while the base end side and the rear refer to the external conduit 20 such as a canula with respect to the needle hub 14. The right side in FIG. 1 which is the connected side. Further, the vertical direction means the vertical direction in FIG. 2, and the horizontal direction means the lower and upper direction in FIG.

More specifically, the hollow needle 12 is made of, for example, metal, and is made of stainless steel or the like. The needle tip 18 of the hollow needle 12 is tapered and has a sharp shape. A through hole may be formed in the needle tip 18 of the hollow needle 12 so that blood can easily flow into the hollow needle 12.

Further, the needle hub 14 has a substantially cylindrical shape as a whole, and is made of a hard synthetic resin or the like. An annular positioning protrusion 22 projecting toward the inner peripheral side is provided on the inner peripheral surface of the needle hub 14 in the intermediate portion in the axial direction. The base end side of the hollow needle 12 is inserted from the tip end side opening of the needle hub 14, and the base end of the hollow needle 12 and the positioning protrusion 22 come into contact with each other, whereby the base end of the hollow needle 12 is positioned. It has become so. Then, if necessary, the hollow needle 12 and the needle hub 14 are fixed to each other by means such as adhesion, so that the hollow needle 12 is fixedly supported at the tip of the needle hub 14.

On the other hand, a large diameter portion 24 having an increased inner diameter is provided at the base end portion of the needle hub 14, and an external conduit 20 such as a canula is inserted from the base end side opening of the large diameter portion 24. There is. Further, the outer conduit 20 is connected to the base end of the needle hub 14 by performing a process such as adhesion as necessary. The inner holes of the hollow needle 12, the needle hub 14, and the outer conduit 20 form a fluid flow path 26 through which the drug solution and blood flow when infusion or blood collection is performed.

Further, an annular protrusion 28 projecting to the outer peripheral side is provided on the outer peripheral surface of the needle hub 14 in the intermediate portion in the axial direction. In such a needle hub 14, the outer peripheral surface on the proximal end side of the annular protrusion 28 has a larger vertical dimension than the horizontal dimension. That is, on the outer peripheral surface of the needle hub 14, plate-shaped projecting plate portions 30 and 30 projecting outward are formed on both sides in the vertical direction, and the vertical dimension at the forming position of these projecting plate portions 30 and 30. Is substantially equal to the outer diameter dimension of the annular protrusion 28. In other words, on the outer peripheral surface of the needle hub 14, projecting plate portions 30 and 30 extending continuously from the annular protrusion 28 to the proximal end side are formed on both sides in the vertical direction.

Further, steps 32 and 32 are formed on the outer surfaces of the protruding plate portions 30 and 30, and the protruding plate portions 30 and 30 have a thickness dimension (vertical dimension) on the base end side of the step 32 and 32. However, it is made larger than the thickness dimension on the tip side.

On the other hand, on the outer peripheral surface of the needle hub 14, a pair of elastic projecting pieces 34, 34 extending outward are provided on the base end side of the annular projecting portion 28. These elastic projecting pieces 34, 34 are inclined in the axial direction from the outer peripheral surface of the needle hub 14 and extend toward the tip side on both sides in the left-right direction, and the protruding tip is further projected outward in the left-right direction. Stop portions 36, 36 are provided. The elastic projectiles 34, 34 including the locking projections 36, 36 can be elastically deformed in the direction perpendicular to the axis (left-right direction).

Further, the housing 16 has a substantially tubular shape including a peripheral wall portion 38 as a whole, and is formed as an integrally molded product made of a hard synthetic resin or the like. The tip portion of the housing 16 has a cylindrical shape having a smaller diameter than the axial intermediate portion and the base end portion, and the tip portion has an insertion hole 40 in the center and is an annular shape protruding inward. The front wall portion 42 is formed.

On the other hand, from the intermediate portion in the axial direction to the base end portion of the housing 16, the shape is horizontally long in which the dimension in the left-right direction is larger than the dimension in the vertical direction, and in the present embodiment, it is a substantially elliptical cylinder shape. .. The peripheral wall portion 38 of the housing 16 is formed by the peripheral walls of the cylindrical portion on the distal end side and the elliptical tubular portion on the proximal end side.

On the inner surface 44 of the peripheral wall portion 38 of the housing 16, steps 46, 46 are provided on both sides in the vertical direction of the intermediate portion in the axial direction, and the thickness dimension of the peripheral wall portion 38 on the tip side of the steps 46, 46. (Vertical dimension) is larger than the thickness dimension of the peripheral wall portion 38 on the proximal end side of the steps 46 and 46.

Further, at the base end portion of the housing 16, rectangular through windows 48, 48 penetrating the peripheral wall portion 38 are formed on both sides in the vertical direction. Then, elastic tongue pieces 50, 50 protruding toward the proximal end side are integrally formed from the inner peripheral edge portion on the distal end side of the through windows 48, 48. The elastic tongue pieces 50, 50 are elastically deformed in the vertical direction starting from the protruding base end (the inner peripheral edge portion on the tip side of the through windows 48, 48) without being connected to the peripheral wall portion 38 on three sides around the elastic tongue pieces 50, 50. It is possible. Further, engaging claws 52 and 52 projecting to the inner peripheral side are formed at the protruding tips (axially oriented base ends) of the elastic tongue pieces 50 and 50. In the single item state of the housing 16 in which the hollow needle 12 and the needle hub 14 are not assembled to the housing 16, the vertical separation dimension between the engaging claws 52 and 52 is the base end portion (protruding) of the needle hub 14. It is smaller than the vertical dimension in the plate portions 30 and 30 (the portion on the base end side of the step 32 and 32), and more specifically, the step 32 and 32 in the protruding plate portions 30 and 30 of the needle hub 14. It is substantially equal to the vertical dimension on the tip side (outer diameter dimension of the annular protrusion 28).

Further, in the peripheral wall portion 38 of the housing 16, positioning holes 54 and 54 penetrating the peripheral wall portion 38 are formed in the axial intermediate portions on both sides in the left-right direction. The left-right width dimension of the portion of the inner surface 44 of the housing 16 adjacent to the base end side of the positioning holes 54, 54 is the maximum width in the left-right direction of the locking protrusions 36, 36 in the used state shown in FIG. It is smaller than the dimensions.

Then, in the peripheral wall portion 38 of the housing 16, a pair of flexible pieces 56, 56 that are inclined in the axial direction and extend toward the tip side are provided on both sides in the left-right direction on the outer peripheral surface on the proximal end side of the positioning holes 54, 54. It is formed. These flexible pieces 56, 56 can be flexed and deformed inward in the left-right direction, and in the present embodiment, elastic deformation is possible.

Furthermore, pressing protrusions 58, 58 are formed at the tips of the flexible pieces 56, 56 so as to project inward in the left-right direction. These pressing protrusions 58, 58 are formed in a size smaller than the positioning holes 54, 54, and are located at positions facing the positioning holes 54, 54, that is, outside the lateral direction from the outer openings 60, 60 of the positioning holes 54, 54. It is provided at a position separated by a predetermined distance.

On the other hand, in the peripheral wall portion 38 of the housing 16, a pair of locking holes 62, 62 that open to the inner surface 44 at the base end portions on both sides in the left-right direction, that is, at positions separated from the flexible pieces 56, 56 toward the base end side. In this embodiment, these locking holes 62 and 62 are formed so as to penetrate the peripheral wall portion 38. In particular, in the present embodiment, the locking holes 62, 62 have a substantially rectangular shape, and the inner surface of the locking holes 62, 62 on the proximal end side gradually inclines toward the outer peripheral side toward the proximal end side. The inclined surfaces are 64 and 64.

Here, on both sides of the housing 16 in the left-right direction, the peripheral wall portion 38 is gradually expanded toward the proximal end side on the distal end side (axially forward side) of the locking holes 62 and 62. That is, on both left and right sides of the housing 16, inclined wall portions 66, 66 that gradually incline toward the outer peripheral side toward the proximal end side are provided on the proximal end side of the flexible pieces 56, 56, and other inclined wall portions 66, 66 on the peripheral wall portion 38. It is formed with substantially the same thickness as the portion, and among the inner surfaces 44 of the housing 16, the inner surfaces of the inclined wall portions 66, 66 gradually have an inner diameter dimension (an elliptical shape which is a cross section of the housing 16) toward the proximal end side. It is said that the inclined surfaces 68 and 68 have a large distance from the center of the above. Further, the locking holes 62, 62 are located adjacent to the base end side of the inclined wall portions 66, 66. As a result, on both sides of the housing 16 in the left-right direction, the inner surfaces (inclined surfaces 68, 68) on the tip side (axially forward side) of the locking holes 62, 62 are locked holes over a predetermined axial distance. It is located on the outer peripheral side of the inner surface on the proximal end side (rear side in the axial direction) of 62 and 62. That is, the inclined surfaces 68, 68 located on the tip side of the locking holes 62, 62 have an inner diameter larger than that of the inner surface located on the proximal end side of the locking holes 62, 62 in the left-right direction. ing.

On the inside of the inclined wall portions 66, 66 (inward side in the left-right direction) of the peripheral wall portion 38, through holes 70, 70 penetrating in the vertical direction, which is the width direction of the inclined surfaces 68, 68, are formed. The inclined surfaces 68 and 68 form an outer peripheral side surface on the inner surface of the through holes 70 and 70. That is, the through holes 70, 70 are formed so as to extend on the inclined surfaces 68, 68 in the width direction of the inclined surfaces 68, 68. These through holes 70, 70 have a triangular shape in a plan view, and the opening width (width in the left-right direction) of the through holes 70, 70 gradually increases toward the proximal end side. The through holes 70, 70 communicate with the locking holes 62, 62 in the axial direction on both the left and right sides of the housing 16.

Further, a wing-shaped portion 72 is attached to the tip end portion of the housing 16 of the present embodiment. That is, the wing-shaped portion 72 is configured to include the tubular portion 74 and the wing main bodies 76, 76 protruding from the tubular portion 74 on both sides in the left-right direction, and the tubular portion 74 is outside the tip portion of the housing 16. By being fitted, the wing-shaped portion 72 is attached to the housing 16. A positioning convex portion 78 extending toward the tip end is provided on the upper side of the housing 16, and a positioning recess 80 opening on the proximal end side is provided on the upper side of the tubular portion 74 in the wing-shaped portion 72. By inserting the positioning convex portion 78 into the positioning concave portion 80, the wing-shaped portion 72 is positioned in the circumferential direction with respect to the housing 16.

The needle assembly 10 of the present embodiment is configured by interpolating and assembling the hollow needle 12 and the needle hub 14 into the housing 16 having the above-mentioned structure. That is, the hollow needle 12 fixedly supported by the needle hub 14 is inserted from the base end side opening 82 of the housing 16, and is provided on the front wall portion 42 of the housing 16 in the used state shown in FIG. The tip of the needle hub 14 and the hollow needle 12 project from the tip of the housing 16 through the insertion hole 40.

A coil spring 84 is provided between the needle hub 14 and the housing 16 as a urging means for urging the hollow needle 12 and the needle hub 14 toward the proximal end side in the pulling direction into the housing 16. .. That is, the coil spring 84 is extrapolated to the tip portion of the needle hub 14, the base end of the coil spring 84 is fixed to the annular protrusion 28 of the needle hub 14, and the tip of the coil spring 84 is the housing. It is fixed to the front wall portion 42 of 16. Then, in the used state shown in FIG. 1 and the like, the coil spring 84 is arranged in a compressed state between the annular protrusion 28 and the front wall portion 42 in the axial direction, and the coil spring 84 is elastic. The hollow needle 12 and the needle hub 14 are urged toward the proximal end side with respect to the housing 16 due to the favorable restoring force.

In the assembled state of the housing 16 and the needle hub 14, the locking protrusions 36, 36 provided on the needle hub 14 elastically project toward the inner surface 44 of the housing 16 and are provided on the housing 16. It protrudes outward through the positioning holes 54 and 54. Then, the locking protrusions 36, 36 and the inner peripheral edges on the base end side of the positioning holes 54, 54 come into contact with each other, so that the locking protrusions 36, 36 are locked to the positioning holes 54, 54. There is. As a result, in the usage state shown in FIG. 1 and the like, the displacement of the hollow needle 12 and the needle hub 14 toward the base end side with respect to the housing 16 is regulated. Therefore, an engaging mechanism is configured in which the hollow needle 12 and the needle hub 14 are positioned and held at the use position protruding from the housing 16 by the engaging action of the locking protrusions 36, 36 with the positioning holes 54, 54. .. Further, the hollow needle 12 and the hollow needle 12 and the hollow needle 12 and the step 32, 32 provided on both the vertical and vertical sides of the inner surface 44 of the housing 16 are engaged with each other in the vertical direction. The displacement of the needle hub 14 toward the tip of the housing 16 is restricted.

Further, in such an assembled state, the vertical separation distance between the engaging claws 52 and 52 provided in the housing 16 is smaller than the vertical dimension of the base end portion of the needle hub 14, so that the housing 16 The elastic tongue pieces 50, 50 provided on both sides of the base end portion in the vertical direction are elastically expanded by being pressed toward the outer peripheral side by the base end portion of the needle hub 14. As a result, an elastic restoring force toward the inner peripheral side acts on the elastic tongue pieces 50, 50, and the elastic tongue pieces 50, 50 and the engaging claws 52, 52 are urged toward the inner peripheral side. The displacement of the elastic tongue pieces 50, 50 and the engaging claws 52, 52 toward the inner peripheral side is limited by the mutual contact between the engaging claws 52, 52 and the outer peripheral surface of the needle hub 14.

In the needle assembly 10 having the above structure, blood or a drug solution is allowed to flow in the fluid flow path 26 by puncturing the skin of the patient with the hollow needle 12, and blood is collected or infused. Then, after blood collection or infusion, the hollow needle 12 and the needle hub 14 are moved toward the proximal end side with respect to the housing 16, so that the needle tip 18 of the hollow needle 12 becomes the housing 16 as shown in FIGS. 4 to 6. Contained and protected within, the needle assembly 10 can be safely disposed of.

That is, after the blood collection or infusion is completed, the flexible pieces 56, 56 provided in the housing 16 are pressed inward in the left-right direction, and the pressing protrusions 58, 58 are projected from the positioning holes 54, 54. , 36, the elastic protrusions 34, 34 including the locking protrusions 36, 36 are elastically deformed to the inner peripheral side. As a result, the engagement mechanism composed of the locking protrusions 36, 36 and the positioning holes 54, 54 is disengaged, and the hollow needle 12 and the needle hub 14 are attached to the housing 16 according to the urging force of the coil spring 84. On the other hand, it is automatically moved to the proximal end side, and the hollow needle 12 and the needle hub 14 are pulled into the housing 16 and accommodated. At that time, an elastic restoring force to the outer peripheral side acts on the locking protrusions 36, 36, and the housing 16 is slid toward the base end side while being in contact with the inner surface 44 of the housing 16.

Then, when the locking protrusions 36, 36 reach the locking holes 62, 62 provided at the base end portion of the housing 16, the elastic protrusions 34, 34 are restored and deformed to the outer peripheral side, and the locking protrusions 34, 34 are restored and deformed. The locking protrusions 36, 36 enter the locking holes 62, 62, and the locking protrusions 36, 36 come into contact with the inclined surfaces 64, 64, which are the inner surfaces of the locking holes 62, 62 on the base end side. The portions 36, 36 are locked in the locking holes 62, 62. As a result, at the retracted position of the hollow needle 12 and the needle hub 14 shown in FIGS. 4 to 6 into the housing 16, the movement of the hollow needle 12 and the needle hub 14 with respect to the housing 16 toward the proximal end side is restricted.

Further, in such a housed state (retracted state), the engaging claws 52 and 52 of the housing 16 are restored and deformed to the inner peripheral side by passing through the steps 32 and 32 provided on the outer surface of the needle hub 14. As a result, as shown in FIG. 5, the engaging claws 52, 52 come into contact with the outer surface on the tip side of the step 32, 32 of the protruding plate portions 30, 30 of the needle hub 14, and the engaging claws 52, By engaging the 52 and the steps 32 and 32 in the axial direction, the movement of the hollow needle 12 and the needle hub 14 toward the tip end side with respect to the housing 16 is restricted, and the hollow needle 12 is prevented from re-protruding from the housing 16. It is supposed to be done.

Here, when the locking protrusions 36, 36 move toward the base end side while sliding in contact with the inner surface 44 of the housing 16 as the hollow needle 12 and the needle hub 14 are pulled into the housing 16, the inner surface 44 of the housing 16 Of these, the inner surfaces of the inclined wall portions 66, 66 are inclined surfaces 68, 68 that gradually incline toward the outer peripheral side toward the base end side, so that the locking protrusions 36, 36 are the inclined surfaces 68, When passing through 68, it gradually moves to the proximal end side while being restored and deformed to the outer peripheral side. Since the inner surface on the tip side (inclined surfaces 68, 68) has a larger inner diameter in the left-right direction than the inner surface on the base end side than the locking holes 62, 62, the locking protrusion Before reaching the locking holes 62 and 62, the dimensions 36 and 36 are made larger in the left-right direction than the left-right inner diameter dimension on the inner surface on the proximal end side of the locking holes 62 and 62. As a result, the locking protrusions 36, 36 can be more reliably introduced into the locking holes 62, 62, and in the present embodiment, the locking protrusions 36, 36 are inserted into the locking holes 62, 62. The guide surface for guiding to 62 is composed of inclined surfaces 68 and 68. By adopting such inclined surfaces (guide surfaces) 68 and 68, even if the hollow needle 12 and the needle hub 14 vigorously move toward the base end side with respect to the housing 16 according to the urging force of the coil spring 84, the locking protrusions The portions 36, 36 are more reliably locked in the locking holes 62, 62, avoiding the risk of the needle hub 14 coming out of the housing 16 without being restricted from moving the needle hub 14 to the base end side, for example. Can be done.

As described above, the inner surfaces of the locking holes 62 and 62 on the tip end side are inclined surfaces 68 and 68 that gradually incline toward the outer peripheral side toward the proximal end side, so that the hollow needle 12 and the needle hub 14 are formed. Moves toward the tip side with respect to the housing 16 so that the hollow needle 12 easily re-projects from the housing 16, but in the present embodiment, the engaging claws 52, 52 and the steps 32, 32 are engaged in the axial direction. Therefore, the movement of the hollow needle 12 and the needle hub 14 toward the tip side with respect to the housing 16 is restricted. As a result, the hollow needle 12 and the needle hub 14 cannot be displaced not only to the proximal end side but also to the distal end side with respect to the housing 16, and the accommodation state of the hollow needle 12 in the housing 16 is stable. Can be maintained.

In the needle assembly 10 having the above structure, the movement of the hollow needle 12 and the needle hub 14 toward the base end side with respect to the housing 16 is provided with a protrusion on the inner surface of the housing as described in Patent Document 1. It is not regulated by the above, but is regulated by locking the locking protrusions 36, 36 provided on the needle hub 14 into the locking holes 62, 62 provided on the peripheral wall portion 38 of the housing 16. Therefore, it is avoided that the diameter dimension in the proximal end portion of the needle hub 14 and the external conduit 20 connected to the proximal end portion of the needle hub 14 becomes small, and blood or a chemical solution through the fluid flow path 26 is prevented. Flow can be stably realized.

Further, since the elastic projection pieces 34, 34 protruding from the needle hub 14 to the outer peripheral side are elastically deformed inward in the left-right direction when moving in the housing 16 to the proximal end side, the needle hub 14 and the housing 16 are formed. It is possible to prevent the needle assembly 10 from becoming large in size by avoiding the increase in the lateral dimension of the needle assembly 10.

Further, since the inclined wall portions 66, 66 constituting the inclined surface (guide surface) 68, 68 of the present embodiment have substantially the same thickness dimension as other portions of the peripheral wall portion 38 of the housing 16. For example, it is possible to avoid a decrease in strength at the forming positions of the inclined surfaces (guide surfaces) 68 and 68. Further, since the through holes 70 and 70 penetrating in the vertical direction are formed inside the inclined wall portions 66 and 66 (inward in the left-right direction), the through holes are formed when the housing 16 is manufactured by molding. It can be die-cut through 70, 70, and the housing 16 can be formed as an integrally molded product. Further, by forming the through holes 70 and 70 at positions that overlap with the locking holes 62 and 62 in the axial direction, for example, the locking holes 62 and 62 of the locking protrusions 36 and 36 are formed through the through holes 70 and 70. It is also possible to visually recognize the locked state to the outside.

Furthermore, in the present embodiment, the engaging mechanism for positioning the hollow needle 12 at the position of use protruding from the housing 16 includes locking protrusions 36, 36 and positioning holes 54, 54. The locking protrusions 36, 36 can be skillfully used not only to prevent the hollow needle 12 and the needle hub 14 from moving toward the proximal end side, but also to hold the hollow needle 12 and the needle hub 14 at the position of use. Therefore, the structure can be simplified. In particular, since the coil spring 84 for urging the hollow needle 12 and the needle hub 14 to the base end side of the housing 16 is provided between the needle hub 14 and the housing 16, the pressing protrusions 58 and 58 are left and right. The hollow needle 12 can be accommodated in the housing 16 with one touch by pushing inward in the direction to release the engagement between the locking protrusions 36, 36 and the positioning holes 54, 54.

Next, FIGS. 7 to 9 show a needle assembly 90 as a second embodiment of the present invention. In the present embodiment, the shape of the housing 92 is different from that of the first embodiment, while the shapes other than the housing 92 are the same as those of the first embodiment. In the present embodiment, the members and parts substantially the same as those in the first embodiment are designated by the same reference numerals as those in the first embodiment in the drawings, and detailed description thereof will be omitted. ..

That is, in the housing 92 of the present embodiment, a pair of locking holes 96, 96 are formed through the peripheral wall portion 94 on both left and right sides of the base end portion of the peripheral wall portion 94. These locking holes 96, 96 have a substantially rectangular shape when viewed from the front, and the flexible wall portion 98, which protrudes toward the proximal end side from the inner peripheral edge portion on the distal end side of the locking holes 96, 96, 98 is formed. That is, the base end side of the flexible wall portions 98 and 98 is the locking holes 96 and 96 that substantially penetrate the peripheral wall portion 94. The three sides of the flexible wall portions 98 and 98 are not connected to the peripheral wall portion 94, and the flexible wall portions 98 and 98 are flexed and deformed in the left-right direction starting from the protruding base end (the inner peripheral edge portion on the tip side of the locking holes 96 and 96). In this embodiment, elastic deformation is possible. In particular, in the present embodiment, the inner surface 100 of the peripheral wall portion 94 has a substantially constant shape in the axial direction, while the flexible wall portions 98, 98 are made thinner from the outside than the other portions of the peripheral wall portion 94. As a result, elastic deformation in the left-right direction is possible. Also in this embodiment, the housing 92 is an integrally molded product made of a hard synthetic resin.

By adopting the housing 92 as described above, the engagement between the locking protrusions 36, 36 and the positioning holes 54, 54 is released, and the hollow needle 12 and the needle hub 14 are moved to the proximal end side with respect to the housing 92. When the locking protrusions 36, 36 are brought into sliding contact with the inner surface 100 of the housing 92 to reach the flexible wall portions 98, 98, the locking protrusions 36, 36 are elastic outward in the left-right direction. The flexible wall portions 98, 98 are pressed outward in the left-right direction by the locking protrusions 36, 36 according to the restoring force. As a result, the flexible wall portions 98, 98 are deformed outward in the left-right direction, and among the inner surfaces 100 of the peripheral wall portion 94, the inner surfaces 102, 102 of the flexible wall portions 98, 98 have an inner diameter dimension in the left-right direction. Be enlarged. That is, when the flexible wall portions 98, 98 are deformed outward in the left-right direction, the inner surfaces 102, 102 of the flexible wall portions 98, 98 are left and right from the inner surface on the base end side of the locking holes 96, 96. A diameter-expanded surface with a large inner diameter is configured.

Then, the flexible wall portions 98, 98 are deformed outward in the left-right direction, so that the locking protrusions 36, 36 have an elastic restoring action, and the width dimension in the left-right direction is the basis of the locking holes 96, 96. It is made larger than the inner surface on the end side. In this state, the locking protrusions 36 and 36 enter the locking holes 96 and 96 as shown in FIGS. 10 to 12 by being further displaced toward the base end side, and the locking protrusions 36 and 36 enter the locking protrusions 36 and 36. And the inclined surfaces 64, 64, which are the inner surfaces of the locking holes 96, 96 on the proximal end side, come into contact with each other, so that the hollow needle 12 and the needle hub 14 can be prevented from moving toward the proximal end side with respect to the housing 92. That is, when the hollow needle 12 and the needle hub 14 move toward the proximal end side with respect to the housing 92, the locking protrusions 36 and 36 are placed in the locking holes 96 and 96 and the inner surfaces of the flexible wall portions 98 and 98 ( The guide surface is guided by the enlarged diameter surface) 102, 102, and in the present embodiment, the guide surface is formed by the inner surface (diameter expanded surface) 102, 102.

In the present embodiment, since the flexible wall portions 98, 98 have elasticity, it is possible after passing through the inner surfaces (diameter-expanded surface, guide surface) 102, 102 of the locking protrusions 36, 36. The flexible wall portions 98, 98 are restored and deformed to the initial shape, and the protruding tip surface (axial base end surface) of the flexible wall portions 98, 98 restored to the initial position and the locking protrusions 36, 36 Abuts in the axial direction to prevent the hollow needle 12 and the needle hub 14 from moving toward the tip of the housing 92. As a result, the hollow needle 12 is prevented from re-protruding from the housing 92, and the hollow needle 12 is stably housed and protected in the housing 92.

The needle assembly 90 of the present embodiment having the above-mentioned structure can also exhibit the same effect as the needle assembly 10 of the first embodiment.

Although the embodiments of the present invention have been described above, the present invention is not limitedly interpreted by the specific description in the embodiments, and various changes, modifications, improvements, etc. are made based on the knowledge of those skilled in the art. It can be carried out in the form of adding.

For example, in the first embodiment, the guide surface is composed of inclined surfaces 68, 68 that gradually incline toward the peripheral end side toward the proximal end side, but gradually spreads outward toward the proximal end side. It may be like this.

Further, in the first embodiment, the housing 16 is provided with inclined wall portions 66, 66 between the flexible pieces 56, 56 and the locking holes 62, 62 in the axial direction, and the inner surface thereof (inclined surface 68, The guide surface is configured by 68), and in the second embodiment, the flexible wall portions 98 and 98 are provided at the base end portion of the housing 92, and the guide surface is configured by the inner surfaces 102 and 102 thereof. However, the present invention is not limited to this, and for example, a guide surface may be provided over a substantially overall length on the tip side of the locking hole. That is, on the inner surface of the housing on the tip side of the locking hole, at least the opening edge of the locking hole may be provided with a guide surface located on the outer peripheral side of the inner surface on the base end side of the locking hole.

Further, also in the first embodiment, as in the second embodiment, when the locking protrusions come into contact with each other from the inner peripheral side, the locking protrusions are bent and deformed (elastically deformed) toward the outer peripheral side. May be good.

Further, in the above-described embodiment, the engaging mechanism for holding the hollow needle 12 and the needle hub 14 at the used position is configured by locking the locking protrusions 36, 36 to the positioning holes 54, 54. However, the present invention is not limited to this, and for example, an engaging mechanism may be provided separately without using the locking protrusion.

Furthermore, in the second embodiment, the flexible wall portions 98 and 98 are configured by forming the housing 92 as an integrally molded product and making it thinner than the other portions of the peripheral wall portion 94. For example, the flexible wall portion may be formed as a separate body with a material that is easily deformed, and may be post-fixed to the housing. In such a case, the thickness dimension of the flexible wall portion may be made equal to that of the peripheral wall portion.

Further, in the second embodiment, the flexible wall portions 98, 98 can be elastically deformed, but the present invention is not limited to this mode, and the diameter-expanded surface (guidance) of the locking protrusion is not limited. After passing through the surface), the flexible wall portion does not have to be restored to its initial position. In such a case, by separately adopting a mechanism for preventing the hollow needle and the needle hub from moving toward the tip side with respect to the housing, such as the engaging claws 52 and 52 of the first embodiment, the hollow needle housing can be used. Re-protrusion can be prevented. However, in the first embodiment, the base ends of the inclined wall portions 66, 66 and the locking protrusions 36, 36 abut in the axial direction, so that the hollow needle 12 and the needle hub 14 move toward the tip end side with respect to the housing 16. If the movement of the hook is prevented, the engaging claws 52, 52 and the like may not be provided.

Further, in the above-described embodiment, the locking holes 62, 62 (96, 96) are formed through the peripheral wall portion 38 (94), but may have a bottomed hole shape that opens to the inner surface. ..

Furthermore, in the above-described embodiment, the elastic protrusions 34, 34, the locking protrusions 36, 36, the positioning holes 54, 54, the locking holes 62, 62 (96, 96), the pressing protrusions 58, 58, and the guide surface ( A pair of inclined surfaces 68, 68, inner surfaces 102, 102) and the like are provided, but each may be one.

Further, in the above-described embodiment, the wing-shaped portion 72 is attached to the housing 16 (92), but the wing-shaped portion is not essential in the present invention.

Further, in the above-described embodiment, the housings 16 and 92 are integrally molded products made of hard synthetic resin, but for example, the inclined wall portion and the flexible wall portion constituting the guide surface are formed separately to form the peripheral wall portion. It may be post-fixed, or the tip side and the base end side of the locking hole may be formed separately and post-fixed.

In the above embodiment, the housings 16 and 92 have a horizontally long substantially elliptical tubular shape, but may have a horizontally long substantially rectangular tubular shape, for example. In such a case, the wording "inner diameter" or "diameter" described in the second, third, and fifth aspects is left and right of the inner surface of the housing in the left-right direction and the center of the rectangular cylinder which is the cross section of the housing. Considered a directional distance. However, the housing is not limited to a horizontally long shape, and may be a cylindrical shape or a tubular shape having a square cross section.

The present invention originally includes the inventions described below, and the configuration and action / effect thereof will be added.
The present invention
(I) The needle hub of the hollow needle is inserted into the tubular housing so as to be movable in the axial direction, and the needle hub is positioned at the position where the hollow needle protrudes from the housing. The coupling mechanism and the urging means for urging the hollow needle in the pulling direction with respect to the housing are provided, and when the engaging mechanism is released, the hollow needle is pulled into the housing and accommodated. In the needle assembly, a locking hole that opens on the inner surface of the housing is provided, while a locking protrusion that elastically protrudes from the needle hub toward the inner surface of the housing is provided, and the hollow portion is provided. At the position where the needle is pulled into the housing, the locking protrusion is locked in the locking hole to prevent the hollow needle from re-protruding from the housing, and the hollow needle is prevented from re-protruding. The inner surface of the housing axially forward side of the locking hole, at which the locking protrusion slides toward the locking hole as it is pulled into the housing, is at least at the opening edge of the locking hole. The needle assembly is characterized in that it is located on the outer peripheral side of the inner surface on the axially rear side of the locking hole in the housing and is used as a guide surface for guiding the locking protrusion into the locking hole. ,
(Ii) In the housing, the inner surface of the housing located on the front side in the axial direction from the locking hole and to which the locking protrusion is slidably contacted is compared with the inner surface on the rear side in the axial direction of the locking hole. The needle assembly according to (i), wherein the guide surface is formed by forming a large inner diameter surface.
(Iii) In the housing, the guide surface located on the front side in the axial direction with respect to the locking hole and to which the locking protrusion is slidably contacted toward the rear side in the axial direction in which the locking hole is located. The needle assembly according to (ii), which has an inclined surface whose inner diameter gradually increases.
(Iv) In the peripheral wall portion of the housing, a through hole penetrating in the width direction of the guide surface, which is substantially perpendicular to the pull-in direction of the hollow needle, is provided extending on the guide surface (ii). ) Or the needle assembly according to (iii).
(V) In the housing, the guide surface located on the front side in the axial direction with respect to the locking hole and to which the locking protrusion is slidably contacted is formed of a deformable flexible wall portion. When the locking protrusion that slides in contact with the guide surface and moves toward the locking hole is pressed against the flexible wall portion, the flexible wall portion is formed as a diameter-expanded surface that deforms outward. The needle assembly according to any one of (i) to (iv).
(Vi) The needle assembly according to (v), wherein the flexible wall portion is formed by thinning the peripheral wall portion of the housing at a portion constituting the guide surface.
(Vii) In the housing, a portion located on the front side in the axial direction and a portion located on the rear side in the axial direction from the locking hole are integrally formed of a single part (i) to (vi). ), The needle assembly according to any one of the items.
(Viii) The needle hub is provided with a pair of elastic protrusions that are inclined in the axial direction and extend outward, and the locking protrusions are provided at the tip of each elastic protrusion. On the other hand, the peripheral wall portion of the housing is provided with a positioning hole at a position distant from the locking hole toward the tip end side in the axial direction, and the hollow portion is formed by the engaging action of the locking protrusion with the positioning hole. The needle assembly according to any one of (i) to (vii), wherein the engaging mechanism for holding the needle to the used position protruding from the housing is configured.
(Ix) While the positioning hole penetrates the peripheral wall portion of the housing, a flexible piece having a pressing protrusion facing the outer opening of the positioning hole is provided in the housing and is provided in the needle hub. By pushing the locking protrusion engaged with the positioning hole from the outer peripheral side of the housing with the pressing protrusion, the engaging of the locking protrusion with the positioning hole is released. The needle assembly according to (viii),
Including inventions related to.
In the invention described above SL (i), the locking projections towards the needle hub to the inner surface of the housing have elastically protrude, when the hollow needle is retracted into the housing, the locking projection is It is elastically deformed to the inner peripheral side and moves to the base end side while sliding contact with the inner surface of the housing. Then, when the locking protrusion reaches the locking hole provided in the housing, the locking protrusion is restored and deformed, and the locking protrusion is locked in the locking hole, so that the housing of the hollow needle It is designed to prevent re-protrusion from. In particular, the inner surface on the front side in the axial direction of the locking hole is located on the outer peripheral side of the inner surface on the rear side in the axial direction of the locking hole and is used as a guide surface for guiding the locking protrusion into the locking hole. Therefore, the locking protrusion is restored and deformed from the locking hole to the outer peripheral side before reaching the locking hole, and the hollow needle and the needle hub are vigorously moved to the proximal end side by the urging force of the urging member. Even so, locking of the locking protrusion to the locking hole can be achieved more reliably.
In the invention described in (ii) above, the inner diameter of the inner surface on the front side in the axial direction of the housing is larger than the inner diameter of the inner surface on the rear side in the axial direction of the locking hole. Before the locking protrusion reaches the locking hole, the locking protrusion can be more reliably restored and deformed to the outer peripheral side of the locking hole. In particular, when the guide surface is formed, for example, the wall thickness of the peripheral wall portion of the housing is not reduced, so that the strength of the housing can be sufficiently ensured.
In the invention described in (iii) above, since the guide surface is an inclined surface whose inner diameter gradually increases toward the rear side in the axial direction, the restoring deformation of the locking protrusion smoothly occurs, and the user The operation of pulling the hollow needle into the housing can be successfully achieved.
In the invention described in (iv) above, since the peripheral wall portion of the housing is provided with a through hole extending in the width direction of the guide surface on the guide surface, the housing is manufactured by molding. At this time, the molding die can be die-cut through the through hole, and the manufacturing efficiency of the housing and thus the needle assembly can be improved. Further, by appropriately adjusting the size of the through hole, it is possible to visually recognize the locked state of the locking protrusion with the locking hole from the outside through the through hole.
In the invention described in (v) above, the locking protrusion is pressed against the guide surface of the flexible wall portion, so that the flexible wall portion is deformed outward and the guide surface (diameter-expanded surface) is formed. The inner diameter dimension is made larger than the inner diameter dimension of the inner surface on the axially rear side of the locking hole. As a result, the locking protrusion is restored and deformed from the locking hole to the outer peripheral side before reaching the locking hole, and the locking of the locking protrusion to the locking hole can be achieved more reliably.
In the invention described in (vi) above, since the flexible wall portion is formed by making the portion of the peripheral wall portion of the housing that constitutes the guide surface thin, the flexible wall portion has a simple configuration. It can be formed to improve the manufacturing efficiency of the housing and thus the needle assembly.
In the invention described in the above (vii), since the portion located on the front side in the axial direction and the portion located on the rear side in the axial direction from the locking hole are integrally molded, the housing is composed of a single component. Can be formed with a small number of parts, and for example, the entire housing can be composed of a single part. In particular, for example, in Patent Document 1, since a mechanism for restricting the movement of the hollow needle and the needle hub by providing a protrusion on the inner surface of the housing is adopted, the housing is composed of two parts. Then, the number of parts can be reduced as compared with such a structure, and the manufacturing efficiency of the housing and the needle assembly can be improved.
In the invention described in (viii) above, the hollow needle is held at a position where it protrudes from the housing by the engaging action of the pair of locking protrusions and the pair of positioning holes. That is, in order to move the hollow needle from the used position to the accommodating position in the housing, it is necessary to disengage the engagement between the locking protrusions provided in pairs and the positioning holes. Compared to the case where only one positioning hole is provided, it is effective to prevent the hollow needle from being housed in the housing due to unintentional disengagement between the locking protrusion and the positioning hole. The hollow needle can be held more stably at the position of use.
In the invention described in (ix) above, the engagement between the locking protrusion and the positioning hole is released by pushing the locking protrusion toward the inner peripheral side with the pressing protrusion provided on the housing. In particular, since the needle assembly of this embodiment is provided with an urging means for urging the hollow needle in the pull-in direction, the hollow needle is automatically disengaged by disengaging the locking protrusion and the positioning hole. It will be pulled into the housing and can be operated with one touch.

10, 90: Needle assembly, 12: Hollow needle, 14: Needle hub, 16, 92: Housing, 34: Elastic protrusion, 36: Locking protrusion, 38, 94: Peripheral wall, 44, 100: Inner surface, 56: Flexible piece, 58: Pushing protrusion, 60: Outer opening, 62, 96: Locking hole, 68: Inclined surface (guide surface), 70: Through hole, 84: Coil spring (urging means), 98 : Flexible wall part, 102: Inner surface (diameter expansion surface, guide surface)

Claims (3)

An engaging mechanism in which the needle hub of the hollow needle is movably inserted into the tubular housing in the axial direction, and the needle hub is positioned at the position where the hollow needle protrudes from the housing. A needle assembly that is provided with an urging means for urging the hollow needle in the pull-in direction with respect to the housing, and the hollow needle is pulled into the housing and accommodated when the engaging mechanism is released. In
While a locking hole that opens on the inner surface of the housing is provided, a locking protrusion that elastically protrudes from the needle hub toward the inner surface of the housing is provided, and the hollow needle is provided on the housing. The locking protrusion is locked in the locking hole at the retracted position to prevent the hollow needle from re-protruding from the housing.
As the hollow needle is pulled into the housing, the inner surface of the housing whose locking protrusion slides toward the locking hole is at least the inner surface of the housing on the distal end side in the axial direction. The opening edge is located on the outer peripheral side of the inner surface of the locking hole on the axially proximal end side of the housing, and is located on the axially tip side of the locking hole in the housing. A guide surface on which the inner surface to which the locking protrusion is slidably contacted guides the locking protrusion into the locking hole with an inclined surface that gradually expands toward the outer peripheral side toward the axial base end side where the locking hole is located. A needle assembly characterized by being said to be. In the housing, a flexible wall portion that is located on the tip side in the axial direction from the locking hole and is deformable is provided, and when the hollow needle is pulled in, it slides into the inner surface of the housing and enters the locking hole. The locking protrusion that moves toward the surface is pressed against the flexible wall portion, and the flexible wall portion is deformed outward, so that the locking protrusion is axially tip-sided at the opening edge portion of the locking hole. The needle assembly according to claim 1, wherein the position of the inner surface is set. The needle assembly according to claim 2 , wherein the flexible wall portion is formed by partially thinning the peripheral wall portion of the housing.

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