JP5855531B2 - Metered syringe type ejector - Google Patents

Description

  The present invention relates to a quantitative syringe-type ejector including a syringe having a finger hook and a plunger that can be pushed into the syringe, and relates to a technique for pushing the plunger in stages.

  Some syringe-type ejectors, for example, push a plunger into a syringe and take out contents such as a chemical solution (see, for example, Patent Document 1).

JP 7-213612 A

  However, since the conventional syringe-type ejector only pushes the plunger into the syringe, it is difficult to divide the contents into small portions and eject them.

  An object of the present invention is to provide a novel metering syringe type ejector that can divide the contents and eject them.

  The present invention is a metering syringe type ejector comprising a syringe having a finger hook and a plunger that can be pushed into the syringe, wherein the plunger can slide a piston holding member having a piston at the tip and the piston holding member. And a plunger operating member that is disposed at the rear end of the piston holding member and has a pressing portion that presses the piston holding member. A pressure receiving portion that is pressed against the plunger operating member via a torsion spring portion that can be deformed and restored around the axis line is provided integrally with the rear end of the holding portion main body that holds the The sleeve member has a crank that guides the protrusion provided on the pressure receiving portion. The crank includes a torsion path that applies torsion to the torsion spring portion when the piston holding member is pressed, a first indentation path that allows the piston holding member to be pressed while maintaining the torsion applied to the torsion spring portion, and a piston holding There is a restoring path for restoring the torsion spring part by releasing torsion applied to the torsion spring part together with the release of the pushing of the member, and a second pushing path for allowing the piston holding member to be pushed through the restoring path. It is characterized by being.

  In the present invention, a retracting portion for releasably hooking the protrusion provided on the pressure receiving portion can be formed between the restoring path and the second pushing path in the crank.

  Moreover, it is preferable to provide a rotation prevention means for preventing the rotation of the piston holding member around the axis line on each of the sleeve member and the piston holding member. Further, according to the present invention, the crank can be disposed at at least one position of the sleeve member, but is preferably disposed at two positions facing each other across the axis.

  The piston holding member can be provided with a space that allows the piston pressing member to be pushed back, and the piston holding member and the piston pressing member can be provided with a locking portion that holds and holds the piston pressing member.

  In addition, according to the present invention, a spray nozzle can be provided at the tip of the syringe.

  In the present invention, when the pressure receiving portion of the piston holding member is pushed in using the plunger operating member, the protrusion of the pressure receiving portion moves along the first pushing path from the twisting path of the crank, so that the piston holding member is pushed and twisted. After twisting the spring portion, the piston holding member can be pushed in while maintaining the twist applied to the torsion spring portion. For this reason, the plunger can be ejected for the first time until the end point of the first pushing path.

  Next, when the pushing of the plunger operating member is loosened, the pressure against the pressure receiving portion is released. Therefore, the torsion spring portion is restored by releasing the twist applied to the torsion spring portion, so that the protrusion of the pressure receiving portion is Move along the restoration path from the indentation path. For this reason, the protrusion of the pressure receiving portion moves to the end point of the restoring path, and thus the piston holding member can be pushed again to the end point of the second pushing path through the second pushing path. As a result, after the plunger operating member is released, the second operation can be performed by pressing the plunger operating member again.

  Therefore, according to the present invention, the contents can be taken out in small portions. Further, in the present invention, since the second ejection can be performed only by loosening the pushing of the plunger operation member, it is not necessary to hold it when performing the second ejection. For this reason, the user can perform subdivision of the contents with one-hand operation.

1 is a nasal spray spray device according to an embodiment of the present invention, in which (a) is a side view showing a partial cross section of an initial state before the operation, and (b) is an XX of (a). It is sectional drawing. It is a perspective view which shows typically the piston holding member based on the embodiment from the back in the state accommodated in the sleeve member. It is another side view which shows the initial state before operation of FIG. 1 in a partial cross section. In the embodiment, (a) is an enlarged cross-sectional view showing a state where the first spray is completed from one side surface, and (b) is an enlarged cross-sectional view showing the state from the other side surface. (A) is the expanded sectional view which shows the state after releasing pushing of a plunger in order to start the 2nd spraying from the one side, and (b) is the other state in the embodiment. It is an expanded sectional view shown from the side. In the embodiment, (a) is an enlarged cross-sectional view showing a state where the second spray is made from one side surface, and (b) is an enlarged cross-sectional view showing the state from the other side surface.

  Hereinafter, with reference to drawings, nasal spray sprayer 10 which is one embodiment of the present invention is explained in detail.

In FIG. 1, the code | symbol 20 is a synthetic resin metering syringe which can be filled with the nasal spray N as a content. The syringe 20 has a hollow body portion 21, and a distal end portion 23 is integrally connected to the body portion 21 via a shoulder portion 22. The tip portion 23 has a smaller diameter than the body portion 21. In addition, the body 21 is provided with a finger hook 24 separately at the rear end facing the front end 23. The finger hook 24 is formed with an opening that allows the inside of the syringe 20 to communicate with the outside. The finger hook portion 24 can also be provided integrally with the trunk portion 21.

  Reference numeral 30 denotes a synthetic resin plunger housed in the syringe 20. The plunger 30 includes a piston holding member 40, a sleeve member 50 that slidably arranges the piston holding member 40, and a plunger operation member 60 that is arranged behind the piston holding member 40.

The piston holding member 40 includes a holding body 41 that holds the piston P. As shown in FIG. 2, the holding portion main body 41 is integrally formed with four vertically long plate portions 41 a and a disc portion 41 b. A through hole A3 is formed in the disk portion 41b. The through hole A3 communicates with an open space S formed by cutting out the plate portion 41a. As shown in the figure, the through hole A3 is formed by a tapered surface whose inner peripheral surface 41b ₁ of the disk portion 41b is reduced in diameter toward the tip (piston P).

  Further, a pressure receiving portion 42 pressed by the plunger operating member 60 is disposed at the rear end of the holding portion main body 41 with an interval in the direction of the axis O. The pressure receiving part 42 is provided integrally with the disk part 41 b via a plurality of torsion spring parts 43. The torsion spring portion 43 has a semi-spiral shape that rises around the axis O from the disk portion 41b. For example, in this embodiment, the torsion spring portion 43 is configured such that the fixed end 43a of the torsion spring portion 43 rising from the disk portion 41b to the fixed end 43b of the pressure receiving portion 42 is 45 degrees around the axis O. ing. The torsion spring portion 43 is twisted around the axis O with respect to the pressure from the upper end face 42 f of the pressure receiving portion 42, and the torsional deformation is restored by releasing the pressure from the pressure receiving portion 42. In this embodiment, the torsion spring portion 43 is disposed at a position facing the through hole A3.

  In this embodiment, the pressure receiving part 42 is configured as a hollow ring part. The upper end surface 42f of the pressure receiving portion 42 is configured as a flat surface. A lateral projection 44 is integrally provided on the side surface of the pressure receiving portion 42. In this embodiment, the protrusions 44 are also arranged at positions facing each other across the through hole A3. In this embodiment, the protrusion 44 is arranged at a position aligned with the fixed end 43 a of the torsion spring portion 43.

  The sleeve member 50 has a body portion 51 disposed in the syringe 20. A peripheral wall 53 stands integrally at the upper end of the body portion 51 via a flat annular projecting portion 52. Further, an annular convex portion 51 p is integrally provided on the outer periphery of the body portion 51. The sleeve member 50 is held against the finger hook portion 24 between the protruding portion 52 and the convex portion 51p.

  A piston holding member 40 is slidably disposed along the axis O inside the sleeve member 50. As shown in FIG. 1, the piston holding member 40 and the sleeve member 50 are provided with a detent means C that prevents the piston holding member 40 from rotating around the axis O. In this embodiment, as shown in FIG. 1B, two guide protrusions 52 are integrally provided on the inner side of the distal end of the body portion 51. The two guide protrusions 52 guide the plate portion 41a in the direction of the axis O between them. That is, in this embodiment, as shown in the figure, the anti-rotation means C includes a plate portion 41a that constitutes the holding portion main body 41 and two guide protrusions 52 that guide the plate portion 41a in the direction of the axis O. ing. Thereby, the piston holding member 40 can be slid along the axis O without rotating around the axis O. In this embodiment, the anti-rotation means C is provided at two positions facing each other across the axis O. However, according to the present invention, the anti-rotation means C is at least one of the plate portions 41a. Should be provided.

  In addition, as shown in FIG. 2, the sleeve member 50 has a crank 54 that guides a protrusion 44 provided on the pressure receiving portion 42. In this embodiment, the crank 54 is disposed at two positions facing each other with the axis O interposed therebetween. Further, the crank 54 is formed as a slit that penetrates the body 51 as shown in FIG. The protrusion 44 can move along the crank 54 as shown in FIG.

  In this embodiment, the crank 54 has a twist path 54a. After entering along the axis O, the torsion path 54a is inclined in the pushing direction with respect to the axis O, thereby allowing the piston holding member 40 to be pushed in and twisting the torsion spring portion 43. However, the approach path along the axis O in the twist path 54a can be omitted. Further, the twisting path 54a communicates with the first pushing path 54b. The first pushing path 54b extends along the axis O, thereby allowing the piston holding member 40 to be pushed in while maintaining the twist applied to the torsion spring portion 43.

  The first pushing path 54b leads to the restoration path 54c. The restoring path 54c is inclined to the same side as the torsion path 54a in the drawing direction (the direction opposite to the pushing direction) with respect to the axis O, thereby releasing the pushing of the piston holding member 40 and adding to the torsion spring portion 43. The torsion spring 43 is restored by releasing the twist.

  The restoration path 54c leads to the second pushing path 54d. The second pushing path 54d extends along the axis O from the restoring path 54c, thereby enabling the piston holding member 40 to be pushed. In this embodiment, the crank 54 has a retracting portion 54e between the restoration path 54c and the second push-in path 54d. The retracting portion 54e can hook the protrusion 44 so as to be releasable by slightly extending the restoring path 54c with respect to the second pushing path 54d.

  On the other hand, the plunger operation member 60 has an operation part main body 61, and a plunger operation part 62 for a user to push the plunger 30 is integrally provided at the rear end thereof. The operation unit body 61 has a cylindrical shape. As shown in FIG. 4, the distal end portion of the operation portion main body 61 constitutes a pressing portion 63 that presses the piston holding member 40. The pressing part 63 is shaped as a flat pressing part.

Further, as shown in FIG. 4, a shaft 64 is integrally provided in the operation portion main body 61. The shaft 64 has a shaft body 64 a having a smaller diameter than the pressing portion 63. The shaft main body 64 a extends forward along the axis O from the pressing portion 63. A head 64b having a larger diameter than the shaft main body 64a is integrally provided at the tip of the shaft main body 64a. As shown in the figure, the head 64b has an inclined surface 64f that tapers toward the tip. The shaft 64 is fitted and held in a through hole A3 formed in the piston holding member 40. The through hole A3 has an inner diameter that is larger than that of the shaft body 64a and smaller than that of the head 64b. As shown in the figure, the through hole A3 penetrates the shaft body 64a and holds the head 64b. The head 64 b and the inner peripheral surface 41 b ₁ of the disk portion 41 b function as a locking portion that holds the piston holding member 40 against the plunger operating member 60. In particular, in this embodiment, the inner peripheral surface 41b ₁ is configured by a tapered surface that decreases in diameter toward the rear. Thereby, the head 64b can be easily assembled | attached to the lower end surface (end surface near piston P) of the disk part 41b. The open space S formed by cutting out the plate portion 41a forms a play space in which the head 64b can be moved back and forth along the axis O. Thereby, the piston holding member 40 and the plunger operating member 60 can be connected to each other so as to be movable along the axis O.

  As shown in FIG. 1, the piston P is provided at the distal end portion of the holding portion main body 41 and is accommodated in the syringe 20. The piston P is made of an elastic material such as rubber, for example, and is slidably held on the inner peripheral surface 21f of the syringe barrel 21.

A space R1 is formed between the syringe 20 and the piston P. The nasal spray N is filled in the space R1. The nasal spray N filled in the space R1 is pumped into the through-hole A1 formed in the distal end portion 23 by pushing the piston P.

In FIG. 1, reference numeral 70 is a nozzle attached to the syringe tip 23. The nozzle 70 incorporates the spray tip 71, and can spray the nasal spray N pumped through the through hole A1 from the ejection hole A4.

Here, the usage method of this embodiment is demonstrated.
In the state shown in FIG. 3, the user first places the index finger and the middle finger on the finger hook 24 and presses the plunger operation part 62 with the thumb to insert the nozzle 70 into one of the nostrils, and then pushes in the plunger operation member 60. . Then, as shown in FIG. 4A, the pressing portion 63 of the plunger operating member 60 presses the upper end surface 42 f of the pressure receiving portion 42 of the piston holding member 40, so that the piston holding member 40 is pushed together with the plunger operating member 60. It is. At this time, the protrusion 44 of the pressure receiving portion 42 moves along the torsion path 54a of the crank 54 inclined with respect to the axis O, so that the torsion spring portion 43 is twisted around the axis O along with the pushing of the piston holding member 40. Add. Next, the protrusion 44 moves from the twist path 54a of the crank 54 along the first push path 54b, so that the piston holding member 40 can be further pushed in while maintaining the twist applied to the torsion spring portion 43. Become. As a result, as shown in FIG. 6B, the plunger 30 causes the nasal spray N to be ejected from the ejection hole A4 to the nose hole until the projection 44 comes into contact with the end point of the first push-in path 54b. Can do.

When the protrusion 44 comes into contact with the end point of the push-in path 54b, the plunger 30 cannot be pushed in, so the first ejection ends with the nasal spray N left in the space R1. The capacity of the space R1 at this time can be appropriately selected according to the purpose of use, but is, for example, half the capacity of the space R1 before the ejection starts.

Next, when the pushing of the plunger operating member 60 is loosened, the pressure against the pressure receiving portion 42 is released, so that the torsion spring portion 43 is released by releasing the twist applied to the torsion spring portion 43 as shown in FIG. Restore it. As a result, as shown in FIG. 5B, the protrusion 44 of the pressure receiving portion 42 moves along the restoring path 54c from the first pushing path 54b. For this reason, the protrusion 44 can push the piston holding member 40 again by moving to the second pushing path 54d along the restoring path 54c. As a result, after the plunger operating member 60 is released, the second operation can be performed by pressing the plunger operating member 60 again.

In this embodiment, the protrusion 44 is hooked on the retracting portion 54e as shown in FIG. The retracting portion 54e can further release the protrusion 44 by pushing the plunger operating member 60. Thereby, in this embodiment, after loosening the pushing of the plunger operating member 60 and then pushing more strongly, as shown in FIG. 6B, until the protrusion 44 contacts the end point of the second pushing path 54d, The remaining nasal spray N can be ejected from the ejection hole A4 into the nostril. As described above, in this embodiment, after the plunger operation member 60 is pushed back, the plunger operation member 60 is strongly pressed again to enable the second ejection.

Therefore, when the plunger operating member 60 is loosened and the plunger operating member 60 is pushed back, as shown in FIG. 5, the nozzle 70 is inserted into the other nostril and the plunger operating member 60 is pushed in strongly. As shown in FIG. 6, the nasal spray N remaining in the space R1 can be ejected from the ejection hole A4 into the nostril.

  According to the present invention, the rotation of the piston holding member 40 around the axis O can be prevented by dynamic frictional force around the axis O between the piston P and the syringe inner peripheral surface 21f. In addition, if the anti-rotation means C is provided separately, the two-stage ejection according to the present invention can be reliably performed by causing the piston holding member 40 to operate stably along the crank 54.

As described above, according to this embodiment, the nasal spray N can be subdivided and ejected. In the present embodiment, if the plunger operation member 60 is loosely pressed, the second ejection can be performed, so that it is not necessary to hold it when performing the second ejection. For this reason, the user can perform subdivision of the contents with one-hand operation.

  The above are various embodiments of the present invention, but various modifications are possible according to the present invention. For example, if the crank 54 is disposed at two positions facing each other across the axis O as in the present embodiment, the piston holding member 40 can be stably operated along the crank 54. Accordingly, it may be arranged in at least one place. Further, in this embodiment, the crank 54 is configured by a through hole. However, according to the present invention, the crank 54 can also be configured by a concave groove formed on the inner peripheral surface of the body portion 51. Further, by forming a plurality of cranks 54, it is possible to eject three or more stages. Although the syringe-type ejector has been described as a nebulizer, according to the present invention, the contents can be ejected in various forms, such as ejecting as a foam or ejecting as a normal liquid.

  The present invention can be adopted in various forms as long as it is a syringe type ejector provided with a syringe having a flange portion and a plunger that can be pushed into the syringe. Various contents can be adopted without being limited to nasal drops.

10 nasal spray sprayer (syringe type sprayer)
20 Syringe 21 Body 22 Shoulder 23 Tip 24 Finger Hook 30 Plunger 40 Piston Holding Member 41 Holding Body Main Body 42 Pressure Receiving Part 42f Upper End Surface 43 Torsion Spring Part 43a Disk Part Side Fixed End 43b Pressure Receiver Side Fixed End 44 Projection 50 Sleeve Member 51 Body 52 Overhang 53 Peripheral wall 54 Crank 54a Twisting path 54b First pushing path 54c Restoring path 54d Second pushing path 54e Retraction part 60 Plunger operating member 61 Operating part main body 62 Plunger operating part 63 Pressing part 64 Shaft 64a Shaft body 64b Head 70 Nozzle 71 Spray tip A1 Through hole A4 Nozzle ejection hole
C detent means
N nasal spray (contents)
R1 Filling space S Open space

Claims (6)

A metering syringe type ejector comprising a syringe having a finger hook and a plunger that can be pushed into the syringe,
The plunger includes a piston holding member having a piston at the tip, a sleeve member that is slidably disposed in the piston holding member, a sleeve member that is disposed inside the syringe, and a piston holding member that is disposed at the rear end of the piston holding member. A plunger operating member having a pressing portion for pressing,
The piston holding member is integrally provided with a pressure receiving portion that is pressed against the plunger operation member via a torsion spring portion that can be deformed and restored around the axis at the rear end of the holding portion main body that holds the piston. , A lateral projection is integrally provided on the pressure receiving portion,
The sleeve member has a crank for guiding a protrusion provided on the pressure receiving portion,
The crank includes a torsion path that applies torsion to the torsion spring portion when the piston holding member is pressed, a first indentation path that allows the piston holding member to be pressed while maintaining the torsion applied to the torsion spring portion, and a piston holding There is a restoring path for restoring the torsion spring part by releasing torsion applied to the torsion spring part together with the release of the pushing of the member, and a second pushing path for allowing the piston holding member to be pushed through the restoring path. A quantitative syringe-type ejector characterized by being a thing.   2. The metering syringe ejector according to claim 1, wherein the crank has a retracting portion that releasably hooks the protrusion provided on the pressure receiving portion between the restoring path and the second pushing path.   3. The quantitative syringe type ejector according to claim 1, wherein the sleeve member and the piston holding member are provided with a detent means for preventing rotation of the piston holding member around the axis.   The metering syringe injector according to any one of claims 1 to 3, wherein the crank is disposed at two positions facing each other across the axis.   5. The piston holding member according to any one of claims 1 to 4, wherein the piston holding member is formed with a space that allows the plunger operating member to be pushed back, and the plunger operating member is retained by the piston holding member and the plunger operating member, respectively. A metering syringe type ejector characterized in that a retaining portion for holding is provided.   The metering syringe type ejector according to any one of claims 1 to 5, wherein a spray nozzle is provided at a tip portion of the syringe.

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