JP6193097B2 - Puncture needle cartridge, puncture device for mounting the puncture needle cartridge, and method for mounting the puncture needle cartridge to the puncture device - Google Patents

Description

The invention, for example, a puncture needle cartridge for puncture to drain blood the needle body in order to measure blood glucose level, a puncture device for mounting it to the mounting how to puncture device of the puncture needle cartridge It is related.

The puncture needle cartridge is mounted on a puncture device, and then the puncture needle cover is removed, and then a puncture operation is performed toward the puncture location.
That is, this kind of puncture needle cartridge includes a lancet body having a connection portion to the puncture device on the rear end side, a puncture needle cover portion on the front end side, and a breakage portion in the middle portion, and before and after the breakage portion of the lancet body. A puncture needle embedded in the lancet body and a lancet case provided on the outer periphery of the lancet body are provided (for example, Patent Document 1 below).

JP 2004-33440 A

In the above-described conventional example, when the puncture needle cartridge is mounted on the puncture device, the rupture portion is broken by rotating the rear side of the lancet main body constituting the puncture needle cartridge with the puncture device. It has become.
Therefore, after that, if the puncture needle cover is pulled out, the puncture needle is exposed, and the puncture operation can be performed in this state.

In such a configuration, the problem is that in the operation of attaching the puncture needle cartridge to the puncture device, a state occurs in which the rear side of the lancet main body constituting the puncture needle cartridge cannot be rotated. As a result, the puncture needle cover cannot be pulled out, and the subsequent puncture operation cannot be performed.
That is, since the puncture device is provided with a rotation mechanism for rotating the lancet body of the puncture needle cartridge, the rotation mechanism may not operate properly depending on the state in which the puncture needle cartridge is mounted on the puncture device. As a result, the puncture needle cover cannot be pulled out, and the subsequent puncture operation cannot be performed.

  Therefore, an object of the present invention is to attach the puncture needle cartridge to a puncture device so that the rupture portion of the lancet main body is reliably broken, and the subsequent puncture operation is appropriately performed.

  In order to achieve this object, the puncture device of the present invention includes a lancet body having a connection portion to the puncture device on the rear end side, a puncture needle cover portion on the front end side, and a break portion in the middle portion, and a break portion of the lancet body. A puncture needle embedded in the lancet body across the lancet body and a lancet case attached to the outer periphery of the intermediate portion of the lancet body, and a guide protruding toward the outer periphery of the puncture needle cover portion of the lancet body A protrusion is provided and a spiral guide is provided by the guide protrusion to receive a turning force from the front end of the lancet case toward the rear. The lancet case is provided with a sliding groove for guiding the sliding protrusion in the front-rear direction, and A separation body is provided at the front end of the lancet body to separate the front side of the rupture portion of the lancet body from the rear side of the rupture portion of the lancet body. The base surface portion in a direction perpendicular to the lancet body, the side surface portions extended to the lancet body side on both sides of the base surface portion, and movable from the rear end side to the inward side of the both side surface portions. A movable surface portion that is bent into two and a mounting portion that is movably attached to the inner side of the left and right movable surface portions, and the inner side of the left and right movable surface portions is inclined toward the lancet body side Then, the lancet body is integrated with the mounting portion, and the rear end side of the side surface portion of the separator is configured to be elastically deformable outward, and the left and right movable surface portions of the separator are provided with Left and right The connection beam connecting the movable surface portion is provided, the connection beam is a structure in which breaking portions of the lancet body is broken after being broken, thereby is to achieve the intended purpose.

  As described above, the present invention includes a lancet body having a connection portion to the puncture device on the rear end side, a puncture needle cover portion on the front end side, and a breakage portion in the intermediate portion, and the front and rear of the breakage portion of the lancet body. A puncture needle embedded in the lancet body, and a lancet case mounted on the outer periphery of the intermediate portion of the lancet body, and provided with a guide protrusion protruding toward the outer periphery on the puncture needle cover portion of the lancet body, and From the front end of the lancet case to the rear, a spiral guide portion is provided for receiving a turning force by the guide protrusion, and the lancet body protrudes toward the outer circumference in the rear side of the rupture portion of the lancet body. A sliding protrusion was provided, and a sliding groove for guiding the sliding protrusion in the front-rear direction was provided in the lancet case.

For this reason, by attaching the puncture needle cartridge to the puncture device, the rupture portion of the lancet main body can be surely broken, whereby the subsequent puncture operation can be appropriately performed.
In other words, the puncture needle cartridge of the present invention has a rotating mechanism that causes the rupture portion of the lancet body to rotate rearward with the operation of mounting the puncture needle cartridge on the puncture device, thereby breaking the break portion. Is a puncture needle cartridge itself.

For this reason, the back side of the lancet body is surely rotated without being affected by the state of the puncture needle cartridge mounted on the puncture device, and as a result, the rupture portion is reliably broken, and thereafter It is possible to appropriately perform the puncturing operation.
Furthermore, the puncture needle cartridge of the present invention is provided with a separating body for separating the front side from the rupture portion of the lancet body from the rear side from the rupture portion of the lancet body at the front end of the lancet body. Is a base surface portion in a direction orthogonal to the lancet body on the front end side of the lancet body, a side surface portion extended to the lancet body side on both sides of the base surface portion, and a rear end side of these both side surface portions. A movable surface portion that is bent movably from the inner side to the inner side, and an attachment portion that is movably attached to the inner side of the left and right movable surface portions, and the inner side of the left and right movable surface portions is In a state in which the lancet body is inclined, the lancet body is integrated with the mounting portion, and a rear end side of the side surface portion of the separator is elastically deformable outward. It was.

  For this reason, when the puncture needle cartridge is attached to the puncture device, when the puncture device is pushed down toward the puncture needle cartridge after the breakage portion is broken, the attachment portion of the separator is pushed down via the lancet case. In the separating body, the inner side of the left and right movable surface portions to which the mounting portion is attached is deformed from a state where the inner surface is inclined toward the lancet main body side to a state opposite to the lancet main body side. By this deformation operation, the puncture needle cover part is pulled out, and the puncture needle is exposed at the breakage part.

As a result, the puncture needle cover portion can be easily pulled out from the puncture needle at the break portion.
Furthermore, in the puncture needle cartridge of the present invention, the left and right movable surface portions of the separator are provided with connection beams that connect the left and right movable surface portions, and the connection beams are formed after the fracture portion of the lancet body is broken. It was set as the structure fractured | ruptured.
For this reason, when the puncture needle cartridge is attached to the puncture device, the separation body provided at the front end of the lancet body is in a state where the left and right movable surface portions are connected by the connecting beams. Therefore, the breakage part of the lancet body can be broken by the above-mentioned rotation mechanism in a stable state where the movable part of the separator is connected.

  After that, when the puncture device is further pushed down toward the puncture needle cartridge, the connecting beam is pushed down and pulled outward through the lancet case, the attachment portion, and the left and right movable surface portions, and as a result, Finally, the connecting beam is broken. When the connecting beam is broken, the left and right movable surface portions are individually movable, so that the above-described deformation operation can be performed. By this deformation operation, the puncture needle cover part is pulled out, and the puncture needle is exposed at the fractured part.

  In other words, according to the present invention, the puncture needle can be reliably exposed at the fracture portion, so that the subsequent puncture operation can be appropriately performed.

The perspective view of the puncture device which concerns on the example 1 of a premise of this invention The perspective view of the puncture needle cartridge with which the puncture device is mounted The figure which shows the use condition of a puncture device The figure which shows the use condition of a puncture device The figure which shows the use condition of a puncture device Same as above, exploded perspective view of puncture needle cartridge (A) Same as above, front view of puncture needle cartridge (b) Same as above, top view of puncture needle cartridge Same as above, exploded view of the main part of the puncture needle cartridge (A) Same as AA sectional view of FIG. 7 (b) Same as FIG. 7, AA sectional view of FIG. 7 during operation (c) Same as FIG. The exploded perspective view of the puncture device The exploded perspective view of the puncture device Same part perspective view of puncture device Cross section of the puncture device Cross section of the puncture device Cross section of the puncture device Cross section of the puncture device Cross section of the puncture device Cross section of the puncture device Cross section of the puncture device Cross section of the puncture device Cross section of the puncture device The figure which shows the use condition of a puncture needle cartridge similarly An exploded sectional view of a puncture needle cartridge according to Premise Example 2 of the present invention Sectional view of the puncture needle cartridge (A) Sectional view of the puncture needle cartridge The perspective view of the puncture needle cartridge which concerns on the example 3 of a premise of this invention Side view of essential parts of puncture needle cartridge and puncture device Cross section of the puncture device The principal part perspective view of the puncture needle cartridge based on Embodiment 1 of this invention Sectional view of the puncture needle cartridge Side view of essential parts of puncture needle cartridge

Hereinafter, an embodiment of the present invention will be described. Prior to the description of this embodiment, a presupposed configuration will be described.
(Assumption 1)
FIG. 1 shows a puncture device 1 of this example, which is a device that punctures a human body and causes blood to flow out, for example, in order to measure a blood glucose level. The puncture device 1 performs puncture by attaching the puncture needle cartridge 4 of FIG. 2 to the front end opening 3 of the long cylindrical main body case 2. The operation related to the puncture includes three operations, that is, a puncture needle cartridge 4 mounting operation, a puncture operation, and a puncture needle cartridge 4 disposal operation.

In this example, first, in the first mounting operation, as shown in FIG. 3, the user holds the puncture device 1 with, for example, the right hand and faces the puncture needle cartridge 4 in which the front end opening 3 of the puncture device 1 is upright. Press down. Then, the puncture needle cartridge 4 is attached to the puncture device 1.
Next, in the second puncturing operation, as shown in FIG. 4, the user presses the puncture needle cartridge 4 against, for example, the finger of the left hand and the operation button 5 of the main body case 2 with the thumb of the right hand holding the puncture device 1. When is pushed, puncture is performed, and blood flows out to the punctured site.

Finally, in the third disposal operation, as shown in FIG. 5, the puncture needle cartridge 4 is discarded from the puncture device 1 when the user presses the operation button 5 again.
Thus, in this example, a series of puncture-related operations (attachment operation, puncture operation, disposal operation) can be performed with only one button while holding the puncture device 1 with one hand. As a result, the operability of a series of puncture-related operations can be improved.

Hereinafter, the puncture needle cartridge 4 will be described first with reference to FIGS. 6 to 9, and then the puncture device 1 will be described with reference to FIGS. 10 to 12.
As shown in FIG. 6, the puncture needle cartridge 4 includes a substantially cylindrical lancet body 6 and a substantially cylindrical lancet case 7.
The cylindrical lancet body 6 is made of resin, and has a connecting portion 8 to the puncture device 1 on the rear end side, a cylindrical puncture needle cover portion 9 on the front end side, and a breaking portion 10 on the intermediate portion. A puncture needle 11 (also shown in FIGS. 17 to 21) is embedded in the lancet body 6 across the rupture portion 10 of the body 6. Further, on the outer periphery of the puncture needle cover portion 9 of the lancet body 6, two (plural) guide protrusions 12 projecting in the outer peripheral direction are provided at positions opposed to each other by 180 degrees.

A cylindrical resin lancet case 7 is placed on the columnar lancet body 6 from the side of the connecting portion 8 provided at the rear end of the lancet body 6, and as shown in FIG. Attached to the outer periphery of the intermediate part.
On the inner surface of the cylindrical lancet case 7, as shown in FIG. 6, a spiral guide portion 13 is provided from the front end toward the rear to receive a turning force by the guide protrusion 12. Two (a plurality) guide portions 13 are provided at positions corresponding to the two guide protrusions 12, that is, at positions facing the guide protrusions 12 by 180 degrees.

FIG. 8 is a development view of the inner surface side of the lancet case 7 and shows a spiral guide portion 13 portion. The guide portion 13 is provided on the inner surface of the cylindrical lancet case 7 from the front end of the lancet case 7 toward the rear at an interval of 180 degrees.
For this reason, when the lancet case 7 is slid in the forward direction (the direction of arrow C in FIGS. 7 and 8), the spiral guide portion 13 slides on the guide projection 12 in the direction of the arrow D. A turning force around the lancet 6 can be generated.

In addition, as shown in FIG. 6, on the rear side of the rupture portion 10 of the lancet body 6, two sliding projections 14 projecting toward the outer peripheral direction are provided so as to face each other by 180 degrees (a plurality), The lancet case 7 is provided with two (a plurality) of slide grooves 15 that slide the slide protrusions 14 in the front-rear direction so as to face each other by 180 degrees.
For this reason, when the lancet case 7 slides in the forward direction, the two sliding protrusions 14 slide backward in the respective sliding grooves 15.

Further, as shown in FIG. 2, an annular recess 7a that opens toward the connection portion 8 is provided on the outer peripheral portion of the front end side of the lancet case 7, and an annular contact surface 7b is provided at the bottom of the recess 7a. .
For this reason, during the mounting operation of the puncture needle cartridge 4, the front end portion of the puncture device 1 can be inserted into the annular recess 7a, and the abutment surface 7b can be pushed by this front end portion.
Then, as shown in FIG. 9A, the lancet case 7 is slid in the forward direction (the direction of arrow C in FIG. 9), and on the inner surface side, as shown in FIGS. 9B and 9C. As described above, since the spiral guide portion 13 slides on the guide projection 12, the lancet case 7 can generate a clockwise turning force (in the direction of arrow B). In other words, the lancet case 7 rotates in the clockwise direction around the lancet body 6 by sliding in the forward direction.

9B shows a state where the lancet case 7 is rotated 90 degrees clockwise from the state shown in FIG. 9A, and FIG. 9C shows a state where the lancet case 7 is rotated 180 degrees.
Using the turning force of the lancet case 7, the breaking portion 10 is threaded and broken to expose the puncture needle 11.
Specifically, the lancet case 7 that rotates clockwise rotates the sliding protrusion 14 of the lancet body 6 clockwise via the sliding wall surface 15a of the sliding groove 15 shown in FIG. 9B. . The sliding protrusion 14 rotates the rear side of the lancet body 6 from the breaking portion 10 in the clockwise direction.

On the other hand, as shown in FIGS. 9B and 9C, the lancet case 7 that slides in the forward direction has its spiral guide portion 13 that pushes the guide projection 12 of the lancet body 6 so that the lancet body 6 The front side of the breaking portion 10 is rotated counterclockwise (the direction opposite to the rotation direction of the guide portion 13 and the direction opposite to the arrow B direction).
Therefore, when the lancet case 7 slides in the forward direction, the fractured portion 10 in which the puncture needle 11 is embedded receives the rotational force in the reverse direction by the front and rear connecting portions, and threading starts from the state of FIG. Then, it breaks in a state where it shifts from FIG. 9 (b) to (c).

  That is, the puncture needle cartridge 4 of the present example rotates clockwise behind the breaking portion 10 of the lancet body 6 in the puncture needle cartridge 4 in accordance with the operation of mounting the puncture needle cartridge 4 on the puncture device 1. And rotate the front side counterclockwise. The puncture needle cartridge 4 itself has a turning mechanism that breaks the breaking portion by turning in the two opposite directions.

For this reason, the front end opening 3 of the puncture device 1 held with one hand can be attached to the puncture device 1 at the connection portion 8 simply by pushing down the front end opening 3 toward the puncture needle cartridge 4 that is upright. A force in the reverse direction can be generated at the connecting portions before and after the broken portion 10, so that the broken portion 10 can be reliably broken.
Therefore, the puncture needle cover portion 9 can be easily removed from the puncture needle cartridge 4, and the puncture needle 11 can be exposed to the lancet body 6.

As a result, the subsequent puncturing operation can be appropriately performed.
Further, as described above, during the mounting operation, the puncture needle cartridge 4 itself rotates the front and rear portions of the breaking portion 10 in the reverse direction. There is no need to keep it fixed. As a result, it is easy to use.

Furthermore, the lancet body 6 has a disk-shaped base 16 at its front end as shown in FIG. Two base springs 17 (an example of an elastic body) are sandwiched between the base portion 16 and the front end of the lancet case 7 with the cylindrical puncture needle cover portion 9 interposed therebetween. Provided integrally.
For this reason, at the end of the mounting operation, as shown in FIG. 9C, the broken portion 10 is completely threaded, and the two leaf springs 17 of the base 16 are connected to the front end of the lancet case 7 and the base. It will be in the state which was pinched | interposed into the part 16 and was accumulated.

At this time, the leaf spring 17 pushes up the base portion 16 rearward (upward in FIG. 9) to notify the user of the end of the mounting operation and also to the user for the next operation, that is, lifting the pushed puncture device 1 The operation can be guided and it is easy to use.
When the user lifts the puncture device 1, the accumulated force of the leaf spring 17 of the base portion 16 is released, and by this release force, the puncture needle cover portion 9 is already threaded as shown in FIG. It is removed so that it can play from the part 10 part. Then, the puncture needle 11 is exposed at the front end portion of the lancet body 6.

Thus, since the puncture needle cover part 9 can be removed automatically, it is convenient from this point of view.
Since the base portion 16 of this example is configured to be larger than the puncture needle cover portion 9, the puncture needle cartridge 4 can be stably erected and the mounting operation is facilitated.
Next, the puncture device 1 to which the puncture needle cartridge 4 is attached will be described.

FIG. 10 is an exploded view of the cylindrical puncture device 1 in the axial direction.
The main body case 2 of the puncture device 1 in this example is a cylindrical body having a front end opening 3 and a rear end opening 18, and includes a case piece 2a and a case piece 2b. The components housed in the main body case 2 will be described with reference to FIG.
The largest component among the components housed in the main body case 2 is a main rod 19 having a holder insertion cylinder 20 on the front end side.

An injection rod 21 having a lancet holder 22 is attached to the front side of the main rod 19. The injection rod 21 has a cylindrical lancet holder 22 on the front end side for mounting the lancet body 6 of the puncture needle cartridge 4 of FIG.
The injection rod 21 is provided with a long plate-shaped operating rod 23 on the case piece 2a side. The operating rod 23 has a lock claw 24 on the rear end side. FIG. 12 is a view of the state where the operating rod 23 is attached to the injection rod 21 as viewed from the case piece 2a side.

The injection rod 21 of this example has an operating rod 23 slidably mounted in the front-rear direction of the main body case 2, and the operating rod 23 is attached to the lock body 28 of FIG. 10 by an operating spring 27 (an example of a biasing body). Energized in the direction.
More specifically, two long holes 25 that are long in the front-rear direction are provided on the front end side and the rear end side of the operating rod 23, and the long holes 25 are engaged with the two shaft portions 26 of the injection rod 21. The operating rod 23 is slidable in the front-rear direction of the main body case 2. Further, the front end portion of the operating rod 23 and the rear end portion of the injection rod 21 are connected by the operating spring 27, and the operating rod 23 is urged rearward, that is, urged toward the lock body 28 in FIG. .

Moreover, as shown in FIG. 11, the injection rod 21 has the axial support part 31 of the puncture cam 30 fitted in the axial part 29 of the rear end side by the case piece 2b side.
As shown in FIG. 10, when the lancet holder 22 on the front end side of the injection rod 21 is inserted into the holder insertion cylinder 20 of the main rod 19, the injection rod 21 is slidable in the front-rear direction of the main body case 2 by the main rod 19. Retained. In FIG. 10, a part of the holder insertion cylinder 20 is notched and displayed so that the state of the tip side of the lancet holder 22 inserted into the holder insertion cylinder 20 can be clearly understood.

The main rod 19 is provided with a main spring 34 (an example of a biasing body) that biases the injection rod 21 toward the front side (front end opening 3 side) of the main body case 2.
More specifically, a shaft portion 32 is provided on the puncture cam 30 on the injection rod 21, the shaft portion 32 and the shaft portion 33 on the front end side of the main rod 19 are connected by a main spring 34, and the injection rod 21 is moved forward. Energize. For this reason, the injection rod 21 slides toward the front end opening 3 by the urging force of the main spring 34, whereby a puncturing operation is performed.

The main body case 2 includes operation buttons 5 that are slidably provided inside and outside the rear end opening 18 of the main body case 2. The operation button 5 has an operation body 35 at the front end, and includes a button spring 36 in the cylindrical portion on the rear end side.
In the operation button 5 of the present example, the operation body 35 is provided with a flat portion 50 in contact with the push-out claw 40 of the lock body 28 in the center portion on the front end side, and the upper side to the rear side adjacent to the flat portion 50. An inclined surface portion 51 and a lower inclined surface portion 52 are provided.

For this reason, when the operation button 5 is operated, the lock body 28 on the front side can be operated by the operation body 35.
The lock body 28 is a characteristic part of the present example, and the lock body 28 switches between the “puncture operation” and the “discard operation” by operating the operation button 5.
Specifically, the lock body 28 is rotatably supported by a shaft portion 37 provided on the rear side of the main rod 19 between the operation button 5 and the injection rod 21. Further, the lock body 28 has a fan shape as shown in FIGS. 10, 11, and 13 to 21, and has a shaft support portion 38 at a main portion thereof. The shaft support portion 38 is operated on the fan side. 5 is fitted to the shaft portion 37 of the main rod 19.

Further, as shown in FIGS. 10 and 11, the lock body 28 is engaged with the lock claw 24 of the operation rod 23 on the operation rod 23 side (hereinafter also referred to as the fan lower side) on the front end side of the fan. It has a claw 39, and has a push-out claw 40 that contacts the front end side of the operation button 5 on the side opposite to the operating rod 23 (hereinafter also referred to as the fan upper side) on the front end side of the fan.
Further, the locking body spring 41 (the biasing body of the biasing body) biases the engagement claw 39 of the locking body 28 in the direction of the locking claw 24 of the operating rod 23 (clockwise direction in FIG. 10 and hereinafter referred to as clockwise direction). An example) is formed of a coil spring and attached to the shaft support 38 of the lock body 28.

In FIG. 10, the engagement claw 39 of the lock body 28 is engaged with the lock claw 24, and the forward sliding (injection) of the injection rod 21 is locked.
The lock body 28 is rotated to switch between the puncturing operation and the discarding operation. This switching operation will be described in detail later.
A cylindrical bush 42 is attached to the front end side of the main body case 2 so as to be rotatable about the axis of the main body case 2. Specifically, a rotating ring 43 provided on the rear side of the bush 42 is inserted into the groove 44 of the main body case 2 and is rotatably mounted on the main body case 2. The holder insertion cylinder 20 of the main rod 19 is inserted into the bush 42.

In this state, the case piece 2a and the case piece 2b are matched.
In the above configuration, the “mounting operation” will be described below with reference to FIGS. 13 to 17, the “puncture operation” will be described with reference to FIG. 18, and the “discarding operation” will be described with reference to FIGS. 19 to 21. Will be explained.
FIG. 13 is a diagram illustrating an initial state of the main body case 2.
The initial state is a state when the user holds the puncture device 1 and pushes down the puncture device 1 toward the puncture needle cartridge 4 in an upright position as shown in FIG.

  When the rear side of the puncture needle cartridge 4 is inserted into the main body case 2 from the front end opening 3 of the puncture device 1, the main rod 19 is moved to the front side by the button spring 36 included in the operation button 5 in the main body case 2. Has been pushed. The main rod 19 is stopped at a position where the case stopper contact 45 of the injection rod 21 attached to the main rod 19 contacts the front case stopper 46 of the main body case 2.

At the center of the main rod 19, the main spring 34 pulls the puncture cam 30 of the injection rod 21 forward. For this reason, the puncture cam 30 rotates counterclockwise (in the counterclockwise direction in FIG. 13 and hereinafter referred to as the counterclockwise direction in FIG. 13) about the shaft support portion 31, and the stop pawl 47 is moved to the rib 48 of the injection rod 21. Stop with contact.
The main spring 34 pulls the injection rod 21 forward through the puncture cam 30. The injection rod 21 stops with respect to the main rod 19 at a position where the puncture cam 30 contacts the puncture cam stopper 49 of the main rod 19.

When the lock body 28 pivotally supported on the rear side of the main rod 19 in this example is rotated clockwise (the urging direction of the lock body spring 41), the push-out pawl 40 of the lock body 28 has the operation button. 5 is provided with a lock piece lower stopper 53 (an example of a stopper portion) that stops the rotation at a position facing the flat portion 50 of the fifth portion.
For this reason, the lock body 28 rotated clockwise by the lock body spring 41 stops the pushing claw 40 on the upper side of the fan abutting against the lock piece lower stopper 53.

FIG. 14 is a view showing a state in which the puncture needle cartridge 4 is pushed into the main body case 2.
The state of the puncture needle cartridge 4 in FIG. 14 corresponds to that in FIG.
When the puncture needle cartridge 4 is pushed into the main body case 2, the lancet main body 6 is engaged with the lancet holder 22 of the injection rod 21 at the connecting portion 8. Thereby, the puncture needle cartridge 4 is attached to the puncture device 1.

  Thereafter, when the puncture needle cartridge 4 is further pushed into the main body case 2, the lancet main body 6 pushes the injection rod 21 rearward. When the injection rod 21 pushes the main rod 19 backward via the puncture cam 30 and the main spring 34, the main rod 19 has a rear end portion 54 of the main rod of the main body case 2 as shown in FIG. Stops after coming into contact with the stopper 55. Then, the state shown in FIG. 14 is obtained.

When the injection rod 21 is further pushed, the injection rod 21 slides backward in the stopped main rod 19. For this reason, the puncture cam 30 of the injection rod 21 extends the main spring 34, and a puncture force (that is, a radiant output for puncture) is fed to the main spring 34.
On the other hand, in the puncture needle cartridge 4, threading is started at the broken portion 10 portion.

  Specifically, on the front end side of the main body case 2, an annular pressing surface 42a provided at the front end of the bush 42 is inserted into the annular recess 7a of the lancet case 7 and contacts the annular contact surface 7b shown in FIG. Touch. When the puncture needle cartridge 4 is pushed into the main body case 2, the pressing surface 42 a of the bush 42 presses the contact surface 7 b and slides the lancet case 7 toward the base portion 16. By this sliding, as described above, the guide portion 13 on the inner surface of the lancet case 7 slides spirally on the guide projection 12 and generates a reverse force at the connecting portions before and after the fracture portion 10 of the lancet body 6. Then, threading is started at the broken portion 10 portion.

The bush 42 also rotates as the lancet case 7 rotates.
FIG. 15 is a view showing a state where the lancet case 7 is turned 90 degrees with respect to the lancet body 6 (state b in FIG. 9).
At this time, in the puncture needle cartridge 4, the broken portion 10 is in a state just before the thread cutting.

In the puncture device 1, the injection rod 21 moves to the rear side, and the lock claw 24 on the rear side of the operating rod 23 contacts the engagement claw 39 of the lock body 28.
The actuating rod 23 of this example rotates the engaging claw 39 of the lock body 28 in the direction opposite to the urging direction by the lock body spring 41 by the lock claw 24 on the rear end side. Then, in order to prevent the engaging claw 39 from rotating in the biasing direction by the lock body spring 41, the surface of the actuating rod 23 facing the engaging claw 39 of the lock body 28 is provided with a rotation preventing portion. 23a.

  For this reason, when the injection rod 21 moves backward from the state shown in FIG. 15, the lock claw 24 pushes up the engagement claw 39 below the fan of the lock body 28, and the engagement claw 39 rotates counterclockwise. . Thereafter, as shown in FIG. 16, when the lock claw 24 pushes over the engagement claw 39, the engagement claw 39 rotates clockwise, but is brought into contact with the rotation preventing portion 23 a of the operating rod 23 and rotated. The movement can be stopped.

FIG. 16 is a diagram showing a state where the lancet case 7 is turned 180 degrees with respect to the lancet body 6 (state c in FIG. 9).
The injection rod 21 slides backward in the stopped main rod 19 and stops when the case stopper contact 45 abuts the rear case stopper 56 of the main body case 2. The main spring 34 is extended to the maximum, and the puncture force is in a state of being fed.

In the puncture needle cartridge 4, the breaking portion 10 is completely threaded. In addition, the two leaf springs 17 of the base portion 16 are sandwiched between the front end of the lancet case 7 and the base portion 16 so as to be stored.
FIG. 17 is a diagram illustrating the completion of the mounting operation of the puncture needle cartridge 4.
When the user lifts the puncture device 1 that has been pushed down, the accumulated force of the leaf spring 17 of the base portion 16 is released, and the puncture needle cover portion 9 can be repelled from the already broken portion 10 by the opening force. To be removed. As a result, the puncture needle 11 can be exposed at the front end portion of the lancet body 6.

That is, in the mounting operation, when the puncture device 1 held with one hand is pushed down toward the upright puncture needle cartridge 4, the puncture force is fed to the main spring 34 in the puncture device 1, and the puncture needle cartridge 4 has a breaking portion. 10 breaks. Thereafter, when the puncture device 1 is lifted, the puncture needle cover portion 9 is removed and the puncture needle 11 is exposed.
Therefore, the attaching operation of the puncture needle cartridge 4 can be performed simply by grasping the puncture device 1, pushing down toward the puncture needle cartridge 4, and lifting it.

When the puncture device 1 is lifted, the pushing force to the injection rod 21 by the puncture needle cartridge 4 disappears, and the injection rod 21 is pulled by the main spring 34 and moves forward. For this reason, the lock claw 24 of the actuating rod 23 is also moved forward from the state of FIG. 16, and the lock claw 24 and the engagement claw 39 are engaged to form a lock state as shown in FIG.
In this locked state, the injection rod 21 is prevented from sliding (injecting) toward the front end opening 3 and preparation for puncture is completed. That is, when the engagement between the engagement claw 39 and the lock claw 24 is released, the locked state is released, and the injection rod 21 is injected forward.

A protrusion 57 is provided on the portion of the main body case 2 opposite to the engaging claw 39 across the operating rod 23, and the protrusion 57 supports the operating rod 23.
FIG. 18 is a diagram showing a puncturing operation.
As shown in FIG. 17, the actuating rod 23 of this example is configured such that when the lock claw 24 of the actuating rod 23 is engaged with the engaging claw 39 on the fan lower side of the lock body 28, The pushing claw 40 is arranged at a position facing the upper inclined surface portion 51 of the operation button 5.

Therefore, as shown in FIG. 18, when the user pushes (operates) the operation button 5 forward, the upper inclined surface portion 51 of the operation body 35 comes into contact with the push-out claw 40 and the push-out claw 40 is pushed up. Then, the lock body 28 is rotated counterclockwise. Then, the engaging claw 39 rotates to disengage from the lock claw 24, and the locked state can be released.
When the locked state is released, the injection rod 21 is pulled by the main spring 34 and is ejected vigorously toward the front end opening 3 side.

The injection rod 21 slides until the case stopper contact 45 comes into contact with the front case stopper 46. On the front side of the puncture device 1, the puncture needle 11 of the lancet body 6 engaged with the ejection rod 21 is ejected from the front end of the puncture needle cartridge 4, and puncture is performed.
While the injection rod 21 is sliding, the center portion of the puncture cam 30 abuts against the puncture cam stopper 49 and rotates clockwise to extend the main spring 34. At the next moment, the main spring 34 re-contracts. As a result, the injection rod 21 is pulled toward the rear end opening 18 as shown in FIG. 19 after puncturing, and the puncture needle 11 is moved into the lancet case 7. It is pulled back.

Returning to FIG. 18, in the main body case 2 of this example, the pushing pawl 40 of the lock body 28 is counterclockwise by the upper inclined surface portion 51 of the operation button 5 (that is, the direction opposite to the urging force of the lock body spring 41). The lock piece upper stopper 58 (an example of a stopper portion) is provided to stop the rotation in the opposite direction when the lever is rotated.
For this reason, when the user further pushes the operation button 5, the push-out claw 40 rotates and comes into contact with the lock piece upper stopper 58. In this contact state, the operation button 5 cannot be pushed, so that the user can recognize the end of the puncture.

Therefore, the user stops pressing the operation button 5 and releases his / her finger from the operation button 5. As a result, the puncturing operation can be performed simply by pressing the operation button 5.
Furthermore, in this example, the main body case 2 has a long cylindrical shape, and on the axis of the main body case 2, an operation button 5 that is slidable inside and outside the rear end opening 18 of the main body case 2 is provided. The operation button 5 was slid on the axis of this, and thereby a puncture operation was performed.

Therefore, as shown in FIG. 4, during the puncturing operation, the long cylindrical body case 2 is held and stabilized with the palm in a state where the puncture needle cartridge 4 is pressed against the finger. Can be pushed toward the puncture position on the axis of the main body case 2.
As a result, the puncture can be performed in an extremely stable state, which is easy to use.

FIG. 19 is a diagram illustrating a completion state of the puncturing operation, and is a diagram illustrating the beginning of the discarding operation.
When the user removes his / her finger from the operation button 5, the operation button 5 is returned to the position before the puncture operation by the restoring force of the included button spring 36.
As described above, when the lock body 28 is rotated in the clockwise direction (the urging direction of the lock body spring 41), the push-out pawl 40 of the lock body 28 is attached to the main rod 19 of this example. A lock piece lower stopper 53 (an example of a stopper portion) that stops rotation at a position facing the flat surface portion 50 is provided.

For this reason, the pushing pawl 40 of the lock body 28 stops rotating at a position facing the flat portion 50 of the operation button 5 by the lock piece lower stopper 53. Therefore, when the operation button 5 is pushed again, the operation body 35 can operate the lock body 28 via the push-out claw 40 at the flat surface portion 50.
FIG. 20 is a diagram illustrating a discarding operation of the puncture needle cartridge 4.

In the lock body 28 of this example, the shaft support portion 38 to the main rod 19 is positioned at a portion corresponding to the upper inclined surface portion 51 inclined from the flat portion 50 of the operation button 5.
For this reason, when the operation button 5 is pressed, the flat surface portion 50 of the operation body 35 comes into contact with the push-out claw 40 of the lock body 28. Is located on the upper inclined surface portion 51 side, the push-out claw 40 tends to rotate clockwise. However, the push-out claw 40 is in contact with the lock piece lower stopper 53 and stopped from rotating. Therefore, when the operation button 5 is pressed, the main rod 19 can be slid forward together with the lock body 28 via the push-out pawl 40 and the shaft portion 37 of the lock body 28.

The injection rod 21 is also pulled by the main spring 34 and slides forward together with the main rod 19.
The main rod 19 of this example is provided with a holder insertion cylinder 20 that houses the lancet holder 22 of the injection rod 21 on the front end side thereof, and a lancet extrusion surface 59 is provided at the front end of the holder insertion cylinder 20.

Therefore, when the main rod 19 slides forward, the lancet pushing surface 59 comes into contact with the rear end of the lancet case 7 and the puncture needle cartridge 4 can be pushed out of the main body case 2.
During this pushing operation, the injection rod 21 has its case stopper contact 45 abutted against the front case stopper 46 and stops sliding with respect to the main body case 2. The operating rod 23 attached to the injection rod 21 also stops.

When the operation button 5 is further pressed, the main rod 19 and the lock body 28 slide forward, and the engagement claw 39 on the fan lower side of the lock body 28 comes into contact with the lock claw 24 of the operating rod 23 stopped.
The lock body 28 of this example is provided with a pressing surface 60 that pushes the lock claw 24 of the operating rod 23 toward the front side of the main body case 2 on the front side of the engagement claw 39 on the fan lower side.

Further, as described above, the injection rod 21 of the present example has the operating rod 23 slidably mounted in the front-rear direction of the main body case 2 and is attached to the lock body 28 by the operating spring 27. Rush.
For this reason, as shown in FIG. 21, even when the injection rod 21 is stopped, the pressing surface 60 can push the lock claw 24 and slide the operating rod 23 forward. As a result, the main rod 19 and the lock body 28 can continue to slide forward.

FIG. 21 is a diagram illustrating a completion state of the discard operation.
When the operation button 5 is further pressed, the lancet pushing surface 59 pushes the lancet case 7 forward on the front side of the main body case 2. The lancet case 7 pulls the lancet body 6 forward through the sliding protrusion 14 and is pulled out from the lancet holder 22 of the injection rod 21 in which the connecting portion 8 of the lancet body 6 is stopped. When the lancet pushing surface 59 completely pushes the lancet case 7 out of the main body case 2, the disposal operation is completed.

As a result, the puncture needle cartridge 4 can be discarded simply by pressing the operation button 5.
Thereafter, when the user removes his / her finger from the operation button 5, the main rod 19 is pulled back by the restoring force of the main spring 34, and the initial state shown in FIG. 13 is restored.
That is, in the puncturing operation and the discarding operation, the lock body 28 of this example arranges the push-out claw 40 at a position facing the upper inclined surface portion 51 of the operating body 35 as shown in FIG. 17 before the puncturing operation. On the other hand, before the discarding operation, as shown in FIG. 20, the push-out pawl 40 is arranged at a position facing the flat portion 50 of the operation button 5.

For this reason, the lock body 28 can switch the operation of the operation button 5 to two operations, that is, a puncture operation and a discard operation.
Therefore, as shown in FIGS. 3 to 5, once the user grasps the central portion of the main body case 2, the attaching operation of the puncture needle cartridge 4 without changing the grip in that state, A puncture operation and a discard operation can be performed. Moreover, the puncturing operation and the discarding operation can be operated with one operation button 5.

As a result, a series of puncture operations can be performed with one hand, which is extremely convenient and can improve the operability of a series of puncture-related operations.
In the puncture needle cartridge 4, as shown in FIG. 17, the sliding protrusion 14 is elastically deformed and almost entirely enters the sliding groove 15 before the puncturing operation. When the puncture is performed as shown in FIG. 19, the tip of the sliding projection 14 is once removed from the sliding groove to the front side, and is pulled back again as shown in FIG. It enters the sliding groove 15.

After that, as shown in FIG. 20, when the puncture needle cartridge 4 is discharged, the sliding protrusion 14 spreads the tip side to the outside of the sliding groove 15 and slides in the sliding groove 15.
In the lancet case 7 of the present example, as shown in FIGS. 20 and 21, the front side inner peripheral portion thereof is located behind the tip of the lancet case 7 and on the back side of the length of the puncture needle 11. When the lancet body 6 slides forward, a slide receiver 61 is provided to abut the tip of the sliding projection 14 of the lancet body 6.

For this reason, after the puncture needle cartridge 4 is discharged, the puncture needle 11 stops at the position where the tip of the sliding projection 14 and the slide receiver 61 abut, and the puncture needle 11 does not protrude from the puncture needle cartridge 4. Absent.
Now, when a user who has not yet become accustomed to the operation of mounting the puncture needle cartridge 4 performs the mounting operation with the thumb placed on the operation button 5, the operation button 5 is pushed in the middle of the mounting operation. There is. Specifically, as shown in FIG. 14, there are times when the operation button 5 on the rear side is pushed in from the state in which the front lancet body 6 is engaged with the injection rod 21 via the lancet holder 22. At this time, since the operation button 5 slides the lock body 28 forward through the flat portion 50 and the push-out claw 40, the engagement claw 39 of the lock body 28 hits the lock claw 24 on the front side. The lock claw 24 is pushed toward the injection rod 21.

That is, the injection rod 21 receives the force of the lancet body 6 from the front and the force of the operation button 5 from the rear.
Therefore, the injection rod 21 of this example is mounted with the operating rod 23 slidably in the front-rear direction of the main body case 2.
Therefore, when the operation button 5 is further pushed, the pressing surface 60 of the engaging claw 39 pushes the operating rod 23 forward through the lock claw 24, and the operating rod 23 moves forward on the injection rod 21. Slide. That is, the injection rod 21 can receive a force from the front-rear direction by sliding the operation rod 23. Accordingly, the injection rod 21 itself does not receive a large force, and an inappropriate state such as breakage is not generated.

  Furthermore, since the injection rod 21 does not receive a large force, it is possible to reduce the thickness and weight while maintaining a sufficient strength. Since this light injection rod 21 can be punctured with a small radiant output, the urging force to the front side of the main spring 34 can be small, and therefore the puncture cam 30 pulled by the main spring 34 during the puncture operation It is possible to reduce a loud collision sound generated by collision with the rib 48.

As a result, the user's fear of puncture is alleviated, and this is also convenient.
As described above, the puncture needle cartridge 4 of this example includes the lancet body 6 having the connection portion 8 to the puncture device 1 on the rear end side, the puncture needle cover portion 9 on the front end side, and the breaking portion 10 on the intermediate portion, and the lancet. A puncture needle 11 embedded in the lancet body 6 and a lancet case 7 attached to the outer periphery of the intermediate portion of the lancet body 6 are provided before and after the breaking portion 10 of the body 6.

The puncture needle cover portion 9 of the lancet body 6 is provided with a guide projection 12 that protrudes toward the outer periphery, and the lancet case 7 receives a turning force from the front end of the lancet case 7 toward the rear. The guide part 13 is provided.
The lancet body 6 is provided with a slide projection 14 projecting in the outer peripheral direction on the rear side of the fracture portion 10, and the lancet case 7 is provided with a slide groove 15 that slides and guides the slide projection 14 in the front-rear direction. It has been provided.

For this reason, the operativity at the time of mounting | wearing operation | movement can be improved.
That is, the puncture needle cartridge 4 of the present example is rotated rearward from the breaking portion 10 of the lancet body 6 in the puncture needle cartridge 4 in accordance with the operation of mounting the puncture needle cartridge 4 on the puncture device 1. Thus, the puncture needle cartridge 4 itself has a turning mechanism for breaking the breaking portion 10.

  Therefore, the puncture needle cartridge 4 is attached to the puncture device 1 by simply pushing down the front end opening 3 of the puncture device 1 grasped with one hand toward the puncture needle cartridge 4 that is upright, and the breakage thereof. The part 10 is broken and the puncture needle 11 is exposed. As a result, the fracture portion 10 can be reliably fractured so that the subsequent puncturing operation can be performed appropriately.

  Further, in the puncture device 1 to which the puncture needle cartridge 4 of this example is attached, the lock body 28 is pivotally supported by the main rod 19 portion between the operation button 5 and the ejection rod 21. The lock body 28 includes an engagement claw 39 that engages with the lock claw 24 of the operating rod 23 and a push-out claw 40 that abuts on the front end side of the operation button 5, and locks the engagement claw 39 of the lock body 28. A lock body spring 41 that biases the claw 24 in the direction is provided.

  For this reason, first, the lock body 28 is rotated by the operation of the operation button 5, and when the engagement between the engagement claw 39 and the lock claw 24 is released by this rotation and the injection rod 21 is ejected, the puncture is performed. The operation is performed. Next, by operating the operation button 5, the lock body 28 is pushed to the front end opening 3 side via the push-out claw 40, and when the pushed lock body 28 pushes the main rod 19 via the shaft support portion, the puncture needle The discarding operation of the cartridge 4 is performed.

In other words, the operation of one operation button 5 can be switched between two operations, that is, the “locking operation” of the lock body 28 and the “discarding operation” of the puncture needle cartridge.
As a result, it is extremely easy to use and the operability of a series of puncture-related operations can be improved.
(Assumption 2)
In the premise example 2, the puncture needle cartridge 4 is devised in the premise example 1 to further facilitate handling after the discarding operation.

In the lancet case 7 of the premise example 1 described above, the tip of the sliding projection 14 provided on the lancet body 6 when the lancet body 6 slides forward in the state of being discarded through FIGS. There is provided a slide receiver 61 for abutting.
For this reason, after the puncture needle cartridge 4 is discharged, when the tip of the sliding protrusion 14 and the sliding receiver 61 come into contact with each other, the lancet body 6 is prevented from sliding forward. Therefore, the puncture needle 11 does not protrude from the puncture needle cartridge 4, and the puncture needle cartridge 4 can be handled in a safe state.

However, as indicated by the arrow in FIG. 22, the lancet body 6 may be pushed forward by the user with full force. At this time, the sliding protrusion 14 is not able to resist the user's force and is spread outward, then bends backward, so that the lancet body 6 advances forward and the puncture needle 11 is punctured. There was a possibility that the needle cartridge 4 would come out.
Therefore, as shown in FIG. 23, the sliding protrusion 14 of the lancet body 6 in this example has a long shape, and the sliding protrusion 14 includes a protruding portion 62 that protrudes outward from the lancet body 6. A connecting portion 63 connected to the projecting portion 62 and a stopper portion 64 extending from the connecting portion 63 to the front side (the breaking portion 10 side) and abutting against the sliding receiver 61 of the lancet case 7 are provided. Further, the connecting portion 63 connects the stopper portion 64 so as to be rotatable in a direction perpendicular to the axis of the lancet body 6. That is, since the connecting portion 63 is thin and flexible, the stopper portion 64 is rotatable in a direction perpendicular to the axis of the lancet body 6.

FIG. 24 shows that the lancet body 6 is pushed forward by the user with full force, the sliding protrusion 14 cannot resist the user's force, and the stopper portion 64 is spread outward and then moved backward. A state is shown in which the stopper portion 64 is bent and overlapped on the protruding portion 62.
At this time, the puncture needle cartridge 4 of this example has a distance D1 from the outer surface of the lancet body 6 to the slide receiver 61 of the lancet case 7 in a state where the stopper portion 64 is folded on the protrusion 62. Is smaller than the height D2 protruding from the lancet body 6 plus the thickness D3a of the stopper portion 64 in the direction perpendicular to the axis of the lancet body 6.

  Therefore, from FIG. 24, even if the user further pushes the lancet body 6 forward, the distance D1 from the outer surface of the lancet body 6 to the sliding receiver 61 of the lancet case 7 is the folded stopper. Since the size is smaller than the thickness D3a of the portion 64 plus the height D2 of the protruding portion 62, the lancet body 6 does not advance further forward. Therefore, the puncture needle 11 does not come out of the puncture needle cartridge 4.

As a result, the puncture needle cartridge 4 after the discarding operation can be handled in a safe state. Moreover, the long-shaped sliding protrusion 14 in this example made the bending strength of the connection part 63 part weaker than the protrusion part 62 part and the stopper part 64 part.
Specifically, as shown in FIG. 23, the thickness D4 of the connecting portion 63 portion in the direction perpendicular to the long axis of the sliding protrusion 14 is perpendicular to the long axis of the sliding protrusion 14 of the stopper portion 64 portion. The thickness D3 in this direction and the thickness 62 of the projecting portion 62 were thinner than the thickness D5 in the direction perpendicular to the long axis of the sliding projection 14. Due to this thinning, the bending strength of the connecting portion 63 portion is made weaker than the protruding portion 62 portion and the stopper portion 64 portion.

For this reason, since the sliding protrusion 14 can bend the stopper part 64 outward and rearward at the connection part 63 portion that is weakest, the stopper part 64 and the protruding part 62 can be folded. Therefore, the puncture needle 11 does not come out of the puncture needle cartridge 4.
Further, as shown in FIG. 23, the sliding protrusion 14 of this example is bent in parallel to the lancet body 6 from the connection portion 63 toward the fracture portion 10, and the front side is extended outward from the lancet body 6. Thus, a stopper portion 64 is formed.

  For this reason, as shown in FIG. 24, when the stopper portion 64 and the projecting portion 62 are folded over, the tip of the portion that spreads outward from the middle portion to the front side of the stopper portion 64 is the lancet body 6. To form a bridge. Therefore, the stopper portion 64 and the protruding portion 62 can be appropriately folded, and the puncture needle 11 does not come out of the puncture needle cartridge 4.

  Furthermore, in this example, as shown in FIG. 25 (a), the stopper 64 of the sliding projection 14 provided on the lancet body 6 is in contact with the sliding receiver 61 of the lancet case 7. As shown in FIG. 25 (b), the guide protrusion 12 of the lancet body 6 is in contact with the spiral guide portion 13 of the lancet case 7. Thereby, the spiral guide part 13 slides reliably on the guide protrusion 12.

More specifically, the puncture needle cartridge 4 has the following manufacturing process when manufactured, and is manufactured.
First, the lancet case 7 is put on the outer periphery of the lancet body 6 and pushed down, and the spiral guide portion 13 of the lancet case 7 is brought into contact with the guide protrusion 12 of the lancet body 6. From this state, the lancet case 7 is pushed down while being rotated, whereby torsion is started at the fracture portion 10.

  Thereafter, for example, at a position where the lancet case 7 is rotated 30 degrees, the slide receiver 61 of the lancet case 7 is lowered to the lower side of the sliding projection 14 of the lancet body 6 as shown in FIG. Release the lancet case 7. Then, the restoring force due to the torsion of the broken portion 10 tries to push up the lancet case 7 in the reverse direction, but the sliding projection 14 brings the stopper portion 64 into contact with the sliding receiver 61 and pushes the lancet case 7. Stop.

For this reason, the lancet case 7 can be stopped at the position where the spiral guide portion 13 rides on the guide protrusion 12 appropriately due to the elasticity of the sliding protrusion 14.
As a result, when the puncture needle cartridge 4 is handled, the guide portion 13 is not detached from the guide projection 12, and the spiral guide portion 13 is appropriately moved on the guide projection 12 in the subsequent mounting operation. Can be slid.

(Assumption 3)
The puncture needle cartridge 4 in this example is shown in FIG. This puncture needle cartridge 4 is the same as the puncture needle cartridge 4 according to the first example shown in FIG. 2, except that the base portion 16 is replaced by a substantially rectangular separator 65.
As shown in FIG. 26 (a), the separator 65 is formed from a state in which the center portion of the upper surface to which the puncture needle cover portion 9 is connected projects toward the upper puncture needle cover portion 9 side, as shown in FIG. As shown in FIG. 5, the deformation operation is performed in a state of being lowered downward, that is, toward the side opposite to the puncture needle cover 9 side.

The puncture needle cover portion 9 connected to the upper surface center portion can be pulled out from the puncture needle 11 by the deformation operation of the separation body 65, that is, the operation of deforming the upper surface center portion of the separation body 65 from the upper side to the lower side.
More specifically, in the puncture needle cartridge 4 of this example, the front end of the lancet body 6 is located on the front side (lower side in FIG. 26) of the lancet body 6 and the lancet body 6 is broken. A separating body 65 that separates from the rear side (upper side in FIG. 26) of the part 10 is provided.

  The separating body 65 has a square thin plate-shaped base surface portion 66 in a direction perpendicular to the axis of the lancet body 6 on the front end side (lower side in FIG. 26) of the cylindrical lancet body 6. On both the left and right sides of the base surface portion 66, a square thin plate-shaped side surface portion 67 extended toward the lancet body 6 side is provided. Further, the separating body 65 has a rectangular thin plate-shaped movable surface portion 68 that is bent movably from the rear end side (upper side in FIG. 26) of the left and right side surface portions 67 toward the inner side. On the inner side of the movable surface portion 68, there is a long rod-shaped attachment portion 69 that is movably attached to the left and right movable surface portions 68.

That is, the left and right movable surface portions 68 form the upper surface of the separator 65, and the attachment portion 69 is attached to the central portion of this upper surface.
The left and right movable surface portions 68 are inclined inwardly toward the lancet body 6, thereby causing the attachment portion 69 at the center of the upper surface of the separator 65 to protrude toward the lancet body 6, and this protruding attachment portion A puncture needle cover 9 of the lancet body 6 is connected to 69. The base surface portion 66, the side surface portion 67, the movable surface portion 68, and the attachment portion 69 constituting the separating body 65 are integrally formed with the lancet body 6 using synthetic resin, and the separating body 65 and the lancet body 6 are integrated.

Further, the thin plate-shaped side surface portion 67 formed integrally with the separating body 65 can elastically deform the rear end side, that is, the upper surface portion side of the separating body 65 toward the outside by using its elasticity. It is configured as possible.
For this reason, since the side surface portion 67 of the separating body 65 is elastically deformed outward, the upper surface central portion of the separating body 65 can be deformed from above to below. This deformation operation will be described in detail later.

Further, a thin portion is provided between the side surface portion 67 and the movable surface portion 68 and between the movable surface portion 68 and the mounting portion 69. For this reason, since these thin portions can smoothly bend (move) between the side surface portion 67 and the movable surface portion 68 and between the movable surface portion 68 and the attachment portion 69, the separating member 65 can be easily deformed. .
The operation of the above configuration will be described below with reference to FIG. FIG. 27 is a side view of a main part of the puncture needle cartridge 4 and the puncture device 1, and the puncture device 1 and the lancet case 7 are shown in cross section for easy understanding.

As shown in FIG. 27 (a), when the rear side of the puncture needle cartridge 4 is inserted from the front end opening 3 of the puncture device 1, the tip of the main body case 2 pushes the lancet case 7, and the lancet case 7 is separated. Slide toward 65. By this sliding, as described above, threading is started at the broken portion 10 portion.
Then, as shown in FIG. 27 (b), when the front end side of the lancet case 7 slides to the position of the mounting portion 69 from which the separator 65 protrudes, the broken portion 10 is threaded.

  As shown in FIG. 27 (c), when the main body case 2 is further lowered, the front end side of the lancet case 7 comes into contact with the convex portion 70 provided on the upper surface of the movable surface portion 68 of the separator 65. The convex portion 70 protrudes toward the lancet case 7, and the lancet case 7 in contact with the convex portion 70 pushes the left and right movable surface portions 68 downward through the convex portion 70. The left and right movable surface portions 68 move so that the inward inclination of the movable surface portion 68 becomes small, and push the side surface portions 67 on both sides outward.

Then, as shown in FIG. 27 (d), when the left and right movable surface portions are no longer inclined and become a flat surface, the puncture needle cover portion 9 is substantially the same as the protruding portion 70 is protruded. It will be in the state pulled out from the front end. For this reason, the puncture needle 11 covered with the puncture needle cover portion 9 is exposed by the same amount as the protrusion of the convex portion 70.
Further, when the main body case 2 is lowered, the left and right movable surface portions 68 incline the inner sides thereof toward the base surface portion 66 side (lower side in FIG. 27). At this time, the side surface portion 67 that has been spread outwardly rapidly returns to its original shape due to its elastic return force. For this reason, as shown in FIG. 27E, the inner side of the movable surface portion 68 is pulled down to the base surface portion 66 side, whereby the mounting portion 69 is also rapidly pulled down to the base surface portion 66 side. Then, the puncture needle cover part 9 is completely removed from the broken part 10 part. That is, the puncture needle cover portion 9 is removed from the puncture needle 11, and as a result, the puncture needle 11 can be exposed at the front end portion of the lancet body 6 (however, at this time, Since the puncturing operation has not yet been performed, the puncture needle 11 is in a state of being present in the lancet case 7). Thereby, the deformation | transformation operation | movement of the separation body 65 is completed, and the separation body 65 hold | maintains the state after this deformation | transformation after this.

The operation in which the inner side of the movable surface portion 68 is pulled down to the base surface portion 66 side is abruptly performed by the elastic restoring force of the side surface portion 67, so that the movement is accompanied by a so-called click feeling. Therefore, the user can recognize that the mounting operation of the puncture needle cartridge 4 is completed by this click feeling.
Thereafter, when the main body case 2 is lifted, the deformed attachment portion 69 is separated from the puncture needle cartridge 4 as shown in FIG. Thereby, the mounting operation of the puncture needle cartridge 4 is completed.

That is, by simply grasping the main body case 2, pushing down toward the puncture needle cartridge 4, and lifting the puncture needle cartridge 4, the puncture needle cartridge 4 can be easily mounted, and the subsequent puncture operation can be performed appropriately.
Although the puncture needle cartridge 4 is attached to the puncture device 1 by the above-described attachment operation, the puncture operation is performed and discarded by the discard operation. However, as shown in FIG. The body 65 may be reattached to the puncture needle cartridge 4 and stored until disposal.

Therefore, as described above, the puncture needle cartridge 4 of this example has a structure that deforms the separator 65 once used.
For this reason, since the used puncture needle cartridge 4 shown in FIG. 26 (b) and the unused puncture needle cartridge 4 shown in FIG. 26 (a) can be easily discriminated, the user can In the next measurement, an unused puncture needle cartridge 4 can be used.

Furthermore, in this example, even when the user mistakenly tries to use the used puncture needle cartridge 4, the reuse can be prevented.
That is, as described above, the puncture needle cartridge 4 of this example has a structure that deforms the separator 65 once used.
For this reason, as shown in FIG. 28, even if the user mistakenly inserts the used puncture needle cartridge 4 into the main body case 2, the separated body 65 is deformed, and the mounting portion 69 is the base surface portion 66. The puncture needle cover portion 9 connected to the mounting portion 69 is pulled out by the reuse prevention amount A from the front end of the lancet case 7 toward the base surface portion 66 side. ing.

That is, the amount of pushing is made short by the reuse prevention amount A with respect to the original pushing amount (that is, the pushing amount of the injection rod 21 to the rear side by the lancet body 6 when an unused puncture needle cartridge 4 is used). The state is formed.
Due to the insufficient push-in amount, the movement distance to the rear side of the lock claw 24 behind the injection rod 21 in the main body case 2 is insufficient, and the lock claw 24 is engaged with the engagement claw 39 of the lock body 28. Absent. Therefore, the main spring 34 does not reduce the puncturing force and the puncturing operation is not performed.

As a result, improper reuse of the used puncture needle cartridge 4 can be prevented.
In this example, the reuse prevention amount A is larger than the exposed length of the puncture needle 11 exposed from the lancet body 6.
For this reason, even if the used puncture needle cartridge 4 is mistakenly inserted into the main body case 2 and the puncture needle cover portion 9 does not cover the puncture needle 11 as shown in FIG. Since the use prevention amount A is made larger than the exposed length of the puncture needle 11, the movement distance of the lock claw 24 behind the injection rod 21 in the main body case 2 can be made short. The engaging claw 39 is not engaged.

  As described above, in the configuration that is the premise of the present invention, the puncture needle 11 is exposed by cutting the puncture needle cartridge 4 by the breaking portion 10 and then separating the puncture needle cover portion 9. it can. In the present invention, the puncture needle 11 is easily exposed by cutting the breaking portion 10 and separating the puncture needle cover portion 9, and this point will be described below with reference to an embodiment.

(Embodiment 1)
The puncture needle cartridge 4 according to the present embodiment includes a connecting beam 71 that connects the left and right movable surface portions 68 to the base portion 16 of the puncture needle cartridge 4 according to the third example of the premise shown in FIG. Is provided. In FIG. 29, the lancet case 7 is omitted for easy understanding of the invention.

In the puncture needle cartridge 4, the left and right movable surface portions 68 of the separating body 65 are provided with connection beams 71 that connect the left and right movable surface portions, and the connection beams 71 are formed after the fracture portion 10 of the lancet body 6 is broken. It was set as the structure fractured | ruptured.
For this reason, when the puncture needle cartridge 4 is attached to the puncture device 1, the separating body 65 provided at the front end of the lancet body 6 is in a state where the left and right movable surface portions 68 are connected by the connecting beams 71. Therefore, the breakage portion 10 of the lancet body 6 can be broken by the above-described rotation mechanism in a stable state where the movable surface portion 68 of the separator 65 is connected.

  Thereafter, when the puncture device 1 is further pushed down toward the puncture needle cartridge 4, the connection beam 71 is pushed down through the lancet case 7, the attachment portion 69, and the left and right movable surface portions 68 of FIG. As a result, the connecting beam 71 is finally broken. When the connecting beam 71 is broken, the left and right movable surface portions 68 are individually moved, so that the above-described deformation operation can be performed. By this deformation operation, the puncture needle cover portion 9 is pulled out, and the puncture needle 11 is exposed at the breaking portion 10.

That is, since the puncture needle can be reliably exposed to the fracture portion 10, the subsequent puncture operation can be appropriately performed.
This will be described in detail below.
The left and right movable surface portions 68 of the separator 65 are provided with connecting beams 71 that connect the left and right movable surface portions 68 on the side opposite to the lancet body 6. The connecting beam 71 has a thin plate shape perpendicular to the left and right movable surface portions 68, and both ends of the thin plate-shaped connecting beam 71 are integrated with the left and right movable surface portions 68. The connecting beam 71 integrally connects the attachment portion 69 together with the left and right movable surface portions 68. Note that the base surface portion 66, the side surface portion 67, the movable surface portion 68, the mounting portion 69, and the connecting beam 71 constituting the separator 65 are integrally formed with the lancet body 6 from a synthetic resin.

FIG. 30 is a cross-sectional view of the puncture needle cartridge 4 and corresponds to FIG.
As shown in FIG. 27 (a), when the rear side of the puncture needle cartridge 4 is inserted from the front end opening 3 of the puncture device 1, the tip of the main body case 2 pushes the lancet case 7, and the lancet case 7 is separated. Sliding toward 65, threading is started at the breaking portion 10 portion. Then, as shown in FIG. 27 (b), when the front end side of the lancet case 7 slides to the position of the attachment portion 69, the broken portion 10 is threaded.

At this time, as shown in FIG. 30, the separating body 65 of the present embodiment is provided with a connecting beam 71 that connects the left and right movable surface portions 68, and the attachment portion 69 is integrally connected together with the left and right movable surface portions 68. Yes. That is, the movable part of the separator 65 is in a state where it cannot move.
For this reason, when the puncture needle cartridge 4 is attached to the puncture device 1, the left and right movable surface portions 68 and the attachment portion 69 do not move, so that the columnar lancet body 6 is swung from side to side. No. As a result, the breaking portion 10 of the lancet body 6 can be broken by the above-described rotation mechanism in a stable state where the movable portion of the separator 65 cannot move.

Further, as shown in FIG. 29, the connection beam 71 is provided with a notch (notch) 72 at the end of the separator 65 on the side facing the base surface portion 66, and this notch 72 is used as a break starting point.
Therefore, when the puncture device 1 is further pushed down toward the puncture needle cartridge 4 from the state shown in FIG. 30, the connecting beam 71 is moved downward via the lancet case 7, the attachment portion 69, and the left and right movable surface portions 68. While being pushed down, the separator 65 is pulled outward.

Then, with this pressing force and pulling force, the connecting beam 71 shown in FIG. 31A starts to break starting from the notch 72 portion. Specifically, as shown in FIG. 31B, a crack K runs from the notch 72 toward the mounting portion 69, and the connecting beam 71 is broken. When the connecting beam 71 is broken, the left and right movable surface portions 68 are individually movable.
Therefore, as described above, in the separator 65, as shown in FIG. 31 (c), the inner side of the left and right movable surface portions 68 to which the attachment portion 69 is attached is inclined toward the lancet body 6 side. Deformation operation is performed so that the lancet body 6 is inclined to the opposite side. By this deformation operation, the puncture needle cover portion 9 is pulled out, and the puncture needle 11 is exposed at the breaking portion 10.

As described above, in the present embodiment, the puncture needle 11 can be easily exposed by cutting the fracture portion 10 and separating the puncture needle cover portion 9, so that the subsequent puncture operation is appropriately performed. Can do.
FIG. 31 shows a state in which the lancet case 7 is removed in order to facilitate understanding of the invention.

Accordingly, the present invention is, for example, to measure blood glucose level, and the puncture needle cartridge is a puncture device for mounting it, those widely used as a method of mounting the puncture device of the puncture needle cartridge can be expected .

DESCRIPTION OF SYMBOLS 1 Puncture device 2 Main body case 2a Case piece 2b Case piece 3 Front end opening part 4 Puncture needle cartridge 5 Operation button 6 Lancet main body 7 Lancet case 7a Recessed part 7b Contact surface 8 Connection part 9 Puncture needle cover part 10 Breaking part 11 Puncture needle 12 Guide projection 13 Guide portion 14 Sliding projection 15 Sliding groove 15a Sliding wall surface 16 Base portion 17 Leaf spring 18 Rear end opening portion 19 Main rod 20 Holder insertion cylinder 21 Injection rod 22 Lancet holder 23 Actuation rod 23a Rotation prevention portion 24 Lock Claw 25 Long Hole 26 Shaft 27 Actuating Spring 28 Lock Body 29 Shaft 30 Puncture Cam 31 Shaft Support 32 Shaft 33 Shaft 34 Main Spring 35 Operating Body 36 Button Spring 37 Shaft 38 Shaft Support 39 Engaging Claw 40 Extrusion claw 41 Lock body spring 42 42a Pushing surface 43 Rotating ring 44 Groove 45 Case stopper contact 46 Front case stopper 47 Stop claw 48 Rib 49 Puncture cam stopper 50 Flat portion 51 Upper inclined surface portion 52 Lower inclined surface portion 53 Lock piece lower stopper 54 Rear end portion 55 Main rod stopper 56 Rear case stopper 57 Protrusion 58 Lock piece upper stopper 59 Lancet pushing surface 60 Pressing surface 61 Sliding support 62 Protruding portion 63 Connecting portion 64 Stopper portion 65 Separator 66 Base surface portion 67 Side surface portion 68 Movable surface portion 69 Mounting portion 70 Protruding portion

Claims (9)

A lancet body having a connection part to the puncture device on the rear end side, a puncture needle cover part on the front end side, and a breakage part in the middle part, and a puncture needle embedded in the lancet body across the breakage part of the lancet body And a lancet case attached to the outer periphery of the intermediate part of the lancet body,
The front end of the lancet body is provided with a separator that separates the front side of the rupture part of the lancet body from the rear side of the rupture part of the lancet body,
The separator includes a base surface portion in a direction perpendicular to the lancet body on the front end side of the lancet body, side surfaces extended to the lancet body side on the left and right sides of the base surface portion, and both side surface portions. A movable surface portion that is movably bent from the rear end side toward the inward side, and an attachment portion that is movably attached to the inner side of these left and right movable surface portions,
In the state where the inner side of the left and right movable surface part is inclined to the lancet body side, the mounting part is integrated with the lancet body,
The rear end sides of the side portions provided on the left and right of the separator are configured to be elastically deformable outward,
The left and right movable surface portions of the separator are provided with connecting beams that connect the left and right movable surface portions, and the connecting beams are configured to be broken after the broken portion of the lancet body is broken.   The puncture needle cartridge according to claim 1, wherein the connecting beam has a thin plate shape perpendicular to the left and right movable surface portions, and both ends of the thin plate-shaped connecting beam are integrated with the left and right movable surface portions.   The puncture needle cartridge according to claim 1 or 2, wherein the connection beam is provided with a breakage starting point portion at an end portion on the side facing the base surface portion of the separator.   The puncture needle cartridge according to claim 3, wherein the breaking start portion is a notch.   The puncture needle cartridge according to any one of claims 1 to 4, wherein a thin portion is provided between the side surface portion and the movable surface portion, and between the movable surface portion and the attachment portion.   The puncture needle cartridge according to any one of claims 1 to 5, wherein the base surface portion, the side surface portion, the movable surface portion, the attachment portion, and the connection beam constituting the separator are integrally formed of a synthetic resin.   The puncture needle cartridge according to claim 6, wherein the separator is integrally formed with the lancet body from a synthetic resin. A puncture device to which the puncture needle cartridge according to any one of claims 1 to 7 is attached,
A cylindrical main body case having a front end opening and a rear end opening, a main rod provided in the main body case, an injection rod mounted on the front side of the main rod and having a lancet holder on the front end side thereof A first urging body for urging the injection rod toward the front end opening of the main body case, and an operation button for operating the injection rod.
The puncture device pushes the lancet case of the puncture needle cartridge at its tip during the mounting operation of the puncture needle cartridge to the puncture device, and slides the lancet case from the intermediate portion of the lancet body to the separator. Let
Puncture device. A method for attaching the puncture needle cartridge according to any one of claims 1 to 7 to the puncture device according to claim 8,
By inserting the rear end side of the puncture needle cartridge from the front end opening of the main body case of the puncture device to the rear side, the connection portion of the puncture needle cartridge is attached to the lancet holder, and then the puncture needle cartridge Is further inserted rearward to remove the puncture needle cover part from the breakage part by the separator.
A method of attaching the puncture needle cartridge to the puncture device.

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