JP2019131233A - Application container for measuring and applying contents - Google Patents

Abstract

To prevent inclination of an application plug relatively to a cylindrical measuring member upon an end part of the application plug positioned at an application position is brought into contact with an application target part.SOLUTION: An application container comprises: a container main body 2; an inner plug member 4; a cylindrical measuring member 7 and an application plug 9. The application plug is arranged in a movable manner in a container axis direction between a measuring position where communication between an ejection hole 8 and a measuring chamber 6 is shut out and communication between the measuring chamber and a communication hole 5 is established and an application position where the application plug is positioned at a side of a bottom part 2a of the container main body along container axis O direction rather than the measuring position, and communication between the measuring chamber and the communication hole is shut out and communication between the ejection hole and the measuring chamber is established. Either of a section on a peripheral surface of the application plug 9 which is positioned inside of the ejection hole 8 under the application position or an inner peripheral surface of the ejection hole 8 is provided with a guide projection 21 which projects in a radial direction so as to contact to or approach the other one.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a coating container.

  Conventionally, the following application containers are known. The coating container includes a bottomed cylindrical container main body in which contents to be applied to the application portion are accommodated, an inner plug member that is attached to the mouth of the container main body and has a communication hole that communicates with the container main body. In addition to forming a measuring chamber that communicates with the inside plug member through the communication hole in the container body, a measuring cylinder member having a discharge hole that communicates with the measuring chamber at the top, and a measuring chamber, And a coating plug that protrudes from the discharge hole to the outside of the measuring chamber. The application plug blocks the communication between the discharge hole and the measuring chamber, and is positioned below the measuring position where the measuring chamber communicates with the communicating hole and below the measuring position, and the communication between the measuring chamber and the communicating hole is blocked. In addition, it is disposed so as to be movable in the container axial direction between an application position where the discharge hole communicates with the measuring chamber.

Japanese Patent No. 5229542

  However, in the conventional application container, when the tip of the application plug located at the application position is brought into contact with the application part, the application plug is inclined with respect to the measuring cylinder member, and the outer peripheral surface of the application plug and the discharge hole are When the size of the gap between the inner peripheral surface and the inner peripheral surface changes, a large amount of contents may unexpectedly flow out from the discharge hole to the application portion.

  The present invention has been made in view of the above-described circumstances, and the application plug is inclined with respect to the measuring cylinder member when the tip of the application plug located at the application position is brought into contact with the application portion. The purpose is to suppress.

In order to solve the above problems, the present invention proposes the following means.
The application container according to the present invention has a bottomed cylindrical container main body in which contents to be applied to the application target part are accommodated, and a communication hole that is attached to the mouth of the container main body and communicates with the container main body. A measuring tube in which a measuring chamber communicating with the inside of the container body through the communication hole is formed between the inner plug member formed and the inner plug member, and a discharge hole communicating with the measuring chamber is formed at the top. And a coating plug provided at the measuring chamber and having a tip protruding from the discharge hole to the outside of the measuring chamber. The coating plug communicates with the discharge hole and the measuring chamber. A measuring position that blocks and connects the measuring chamber and the communication hole, and is positioned closer to the bottom of the container body along the container axial direction than the measuring position, and communicates between the measuring chamber and the communication hole. And the discharge hole is connected to the weighing chamber. Between the application position and the application position to be moved in the container axial direction, and on the outer peripheral surface of the application plug, the portion located inside the discharge hole when positioned at the application position, and the inside of the discharge hole Any one of the peripheral surfaces is formed with a guide protrusion that protrudes in the radial direction and abuts or approaches the other.

According to this invention, the outer peripheral surface of the coating plug is in contact with or close to one of the portion located inside the discharge hole when positioned at the application position and the inner peripheral surface of the discharge hole. The guide protrusion is formed on the outer peripheral surface of the application plug even if an external force is applied to the application plug located at the application position. And the other of the inner peripheral surfaces of the discharge holes. Therefore, it is possible to prevent the coating plug from being inclined with respect to the measuring cylinder member when the tip of the coating plug located at the coating position is brought into contact with the coated portion, and a large amount of contents are unexpectedly generated. It is possible to suppress the outflow from the discharge hole to the application portion.
Moreover, since the guide protrusion is disposed in the discharge hole, when the above-described external force is applied to the application plug located at the application position, the guide protrusion is immediately inserted into the outer peripheral surface of the application plug and the discharge hole. It is possible to make it contact with either one of the inner peripheral surfaces of the liquid, and the size of the gap between the outer peripheral surface of the coating plug and the inner peripheral surface of the discharge hole changes, that is, the cross-sectional shape of the flow path Can be reliably suppressed.

  Here, a plurality of the guide protrusions may be arranged at intervals in the circumferential direction around the container axis.

  In this case, a plurality of guide projections are arranged at intervals in the circumferential direction around the container axis, so that the application plug positioned at the application position is the measuring cylinder member regardless of the direction of the external force applied to the application plug. It can suppress that it leans to.

  Further, the guide projection is directed from one of a portion located inside the discharge hole when positioned at the application position on the outer peripheral surface of the coating plug and an inner peripheral surface of the discharge hole to the other. And a projecting end projecting from the base toward the other. The base and the projecting end are each formed in a vertical rib shape extending in the container axial direction, and the base is configured to project the projecting end. The circumferential width along the container axis may be wider.

In this case, since the base portion and the protruding end portion of the guide protrusion are each formed in a vertical rib shape, the guide protrusion can be provided with high rigidity against the external force in the radial direction, and is located at the application position. When the tip of the coating plug is brought into contact with the portion to be coated, it is possible to reliably suppress a change in the gap between the outer peripheral surface of the coating plug and the inner peripheral surface of the discharge hole.
In addition, since the guide protrusion includes the base portion, it is possible to further reliably suppress the guide protrusion from being deformed with respect to the aforementioned external force. Furthermore, since the base is not in sliding contact with the other, it is possible to set the size of the flow path cross-sectional area by adjusting the size of the base without considering the sliding resistance. Restrictions can be suppressed.
In addition, since the guide protrusion includes not only the base portion but also the protruding end portion, when the application plug moves in the container axial direction, the guide protrusion is either the outer peripheral surface of the application plug or the inner peripheral surface of the discharge hole. Even if it is slidably contacted, the sliding area can be suppressed, and the sliding resistance generated in the coating plug can be suppressed.

  ADVANTAGE OF THE INVENTION According to this invention, when the front-end | tip part of the application | coating plug located in an application position contact | abuts to a to-be-coated part, it can suppress that an application | coating plug inclines with respect to a measurement cylinder member.

It is a partial longitudinal cross-sectional view of the application container which concerns on one Embodiment of this invention. It is an enlarged view of the application container shown in FIG. It is an enlarged view of the application container concerning one embodiment of the present invention, and is a partial longitudinal section in the state where the application stopper was pulled up to the measurement position. FIG. 3 is a cross-sectional view taken along line AA in FIG. 2. It is an enlarged view of the application container concerning one embodiment of the present invention, and is a partial longitudinal section in the state where the application stopper was located in the application position.

  Hereinafter, an application container according to an embodiment of the present invention will be described with reference to FIGS. 1 to 5. The application container 1 contains contents such as a hair-restoring agent and a chemical solution applied to the application portion S such as the human scalp and skin.

  As shown in FIG. 1, a coating container 1 is mounted on a bottomed cylindrical container main body 2 in which contents to be applied to a portion to be coated S are accommodated, and a mouth 3 of the container main body 2. A measuring chamber 6 communicating with the inside of the container body 2 through the communicating hole 5 is formed between the inner plug member 4 in which the communicating hole 5 communicating with the inner plug member 4 is formed, and the measuring chamber 6 is formed at the top portion 19. A measuring cylinder member 7 having a discharge hole 8 communicating therewith, and a coating plug 9 provided in the measuring chamber 6 and having a distal end portion 26 protruding from the discharge hole 8 to the outside of the measuring chamber 6.

  Here, the central axis of each of the mouth portion 3 of the container body 2 and the measuring cylinder member 7 is arranged on a common axis. Hereinafter, this common axis is referred to as a container axis O, the bottom 2a side (lower side in FIG. 1) of the container body 2 along the container axis O direction is the lower side, and the mouth 3 side of the container body 2 along the container axis O direction. The upper side in FIG. 1 is referred to as the upper side. In addition, a direction intersecting the container axis O in a plan view viewed from the container axis O direction is referred to as a radial direction, and a direction around the container axis O is referred to as a circumferential direction.

  The mouth part 3 of the container body 2 has a smaller diameter than the body part 2 b, the bottom part 2 a, and the shoulder part 2 c other than the mouth part 3 in the container body 2. A male screw portion is formed on the outer peripheral surface of the mouth portion 3. This male thread portion may be a double thread, for example. The outer diameter of the upper end portion of the mouth portion 3 is smaller than the outer diameter of the portion located below the upper end portion of the mouth portion 3, and the outer peripheral surface of the upper end portion of the mouth portion 3 has a radially outer side. An annular or arcuate protrusion that extends in the circumferential direction and extends in the circumferential direction is formed. A detent rib 3b is formed at the lower end of the mouth 3 so as to project outward in the radial direction.

As shown in FIG. 2, the inner plug member 4 includes a bottomed cylindrical cylinder 12 disposed in the mouth 3 of the container body 2, and a support protruding upward from the bottom wall of the cylinder cylinder 12. A main fitting cylinder 13 that is formed larger than the body 11 and the cylinder cylinder 12, protrudes upward from the cylinder cylinder 12, and is fitted into the mouth 3 of the container body 2, and a main fitting cylinder 13 And an outer fitting cylinder 17 which is connected to the main fitting cylinder 13 and surrounds the upper part of the outer fitting from the outside in the radial direction.
In the present embodiment, the cylinder cylinder 12, the support 11, the main fitting cylinder 13 and the outer fitting cylinder 17 of the inner plug member 4 are integrally formed.

The support 11 is provided on the bottom wall of the cylinder cylinder 12 and is arranged coaxially with the container shaft O. The restricting portion 11b protrudes radially outward from the lower end of the guide shaft 11a. It is equipped with.
The guide shaft 11 a is disposed on the radially inner side of the cylinder tube 12, and the upper end portion of the guide shaft 11 a protrudes above the cylinder tube 12 and the main fitting tube 13.

The restricting portion 11b is a cylindrical body that continuously extends over the entire circumference. The restricting portion 11b is integrally connected to the bottom wall of the cylinder cylinder 12 and the guide shaft 11a. The inner peripheral surface of the restricting portion 11b is formed integrally with the outer peripheral surface of the guide shaft 11a. The upper end edge of the restricting portion 11 b is located below the upper end opening edge of the peripheral wall of the cylinder cylinder 12.
As the restricting portion 11b, for example, a configuration in which a plurality of vertically long ribs extending in the container axis O direction are arranged at intervals in the circumferential direction may be adopted. The restricting portion 11b may be formed separately from the guide shaft 11a and the cylinder cylinder 12.

The cylinder cylinder 12 is arranged coaxially with the container axis O. A plurality of communication holes 5 are formed in the cylinder cylinder 12 at intervals in the circumferential direction, and the inside of the cylinder cylinder 12 is communicated with the container body 2 through the communication holes 5. One communication hole 5 may be provided. The communication hole 5 is integrally formed over the peripheral wall and the bottom wall of the cylinder cylinder 12. Here, the restricting portion 11 b is disposed at the opening peripheral edge of the communication hole 5 in the bottom wall of the cylinder cylinder 12. Of the inner peripheral surface of the communication hole 5, the radial positions of the surface that is located on the inner side in the radial direction and faces the outer side in the radial direction, and the surface that faces the outer side in the radial direction among the surfaces of the restricting portion 11 b It is equivalent. Of the inner peripheral surface of the communication hole 5, the surface located on the peripheral wall of the cylinder tube 12 and facing downward is positioned below the upper end edge of the restricting portion 11 b.
A lower end portion of the application plug 9 is fitted to a portion of the inner peripheral surface of the peripheral wall of the cylinder cylinder 12 located above the communication hole 5 so as to be slidable up and down.

The upper part of the main fitting cylinder 13 protrudes upward from the mouth part 3 of the container body 2. The lower end portion of the main fitting tube 13 is connected to the upper end portion of the cylinder tube 12 via a flange portion.
The outer fitting cylinder 17 is connected to the outer peripheral surface of the upper part of the main fitting cylinder 13, and the lower end edge thereof is in contact with the upper end opening edge of the mouth portion 3 of the container body 2. An annular or arcuate protrusion is formed on the outer peripheral surface of the outer fitting cylinder 17 so as to protrude outward in the radial direction and extend in the circumferential direction.

The measuring tube member 7 includes a mounting tube portion 18 mounted on the mouth portion 3 of the container body 2, a cylindrical top portion 19 positioned above the mounting tube portion 18 and having an inner side as the discharge hole 8, and a mounting tube. It has a connection cylinder part 20 which is located between the part 18 and the top part 19, and connects these 18,19.
In the illustrated example, the diameter of the measuring cylinder member 7 is gradually reduced from the lower side toward the upper side in the order of the mounting cylinder part 18, the connecting cylinder part 20, and the top part 19.

  The mounting cylinder portion 18 has a top cylinder shape having an annular ceiling wall and a peripheral wall. The peripheral wall of the mounting cylinder part 18 is externally fitted to the upper end part of the mouth part 3 of the container body 2 and the outer fitting cylinder 17 of the inner plug member 4. Two annular or arcuate protrusions that protrude radially inward and extend in the circumferential direction are formed on the inner peripheral surface of the peripheral wall of the mounting cylinder portion 18 at intervals in the container axis O direction. . Of these two projections, the lower projection is undercut fitted into the projection of the mouth portion 3, and the upper projection is undercut fitted into the projection of the outer fitting cylinder 17. Yes.

  The lower surface of the top wall of the mounting cylinder portion 18 is close to the upper end opening edge of the main fitting cylinder 13 in the inner plug member 4 and is in contact with the upper end opening edge of the outer fitting cylinder 17. The positions in the radial direction of the inner peripheral surfaces of the top wall of the mounting cylinder portion 18 and the main fitting cylinder 13 are equal to each other. On the top wall of the mounting cylinder portion 18, a cylindrical body that protrudes downward and is inserted between the outer fitting cylinder 17 and the upper part of the main fitting cylinder 13 is formed. This cylindrical body is fitted to at least one of the main fitting cylinder 13 and the outer fitting cylinder 17 to ensure the liquid tightness of the connecting portion between the inner plug member 4 and the measuring cylinder member 7 in the measuring chamber 6. ing.

The connection cylinder part 20 has comprised the top cylinder shape which has a cyclic | annular top wall and a surrounding wall. The peripheral wall of the connecting cylinder part 20 protrudes upward from the inner peripheral edge part of the top wall of the mounting cylinder part 18. The radial position on the inner peripheral surface of the peripheral wall of the connecting cylinder part 20 is equivalent to the radial position of the inner peripheral surface of each of the top wall of the mounting cylinder part 18 and the main fitting cylinder 13.
The top portion 19 is formed in a cylindrical shape and protrudes upward from the inner peripheral edge portion of the top wall of the connecting tube portion 20. A connecting portion between the inner peripheral surface of the top portion 19 and the lower surface of the top wall of the connecting cylinder portion 20 is formed in a curved shape protruding toward the inside in the radial direction. Note that the top portion 19 may be formed in, for example, a rectangular tube shape. Further, the inner peripheral edge of the annular top wall of the connecting cylinder part 20 may be used as the discharge hole 8 without providing the top part 19. That is, the top of the measuring cylinder member 7 may be the top wall of the connecting cylinder part 20.
In the present embodiment, the space defined by the connecting tube portion 20 of the measuring tube member 7 and the main fitting tube 13 of the inner plug member 4 is the measuring chamber 6. That is, the inner peripheral surface of the measuring chamber 6 is constituted by the inner peripheral surface of the main fitting tube 13 of the inner plug member 4 and the inner peripheral surface of the peripheral wall of the connecting tube portion 20 of the measuring tube member 7.

The application plug 9 blocks the communication between the discharge hole 8 and the measurement chamber 6 and connects the measurement chamber 6 and the communication hole 5 (for example, the state shown in FIG. 3), and below the measurement position ( It is located on the bottom side of the container main body along the container axial direction, blocks communication between the measurement chamber 6 and the communication hole 5, and allows the discharge hole 8 and the measurement chamber 6 to communicate (here, "to communicate"). Means that it includes both the meanings of “communicating or enabling communication”) between the application position (for example, the state shown in FIGS. 1, 2, and 5) and the container axis O direction (vertical direction). ) Is movably disposed.
In the illustrated example, the contents in the measuring chamber 6 can be discharged through the gap between the outer peripheral surface of the application plug 9 and the inner peripheral surface of the discharge hole 8 with the application plug 9 positioned at the application position. Yes.

  The coating plug 9 extends downward from the top wall of the sealing cylinder 24 disposed in the measuring cylinder member 7 and from the top wall of the sealing cylinder 24, and is surrounded from the outside in the radial direction by the peripheral wall of the sealing cylinder 24. And the cylindrical tip portion 26 erected on the top wall of the seal cylinder 24. The seal cylinder 24, the extrapolation cylinder 25, and the distal end portion 26 are arranged coaxially with the container axis O and are integrally formed.

As shown in FIG. 3, the upper portion of the seal cylinder 24 is slidably fitted inside the discharge hole 8 when the application plug 9 is located at the measurement position. Block communication. The lower end portion of the seal cylinder 24 is slidably fitted inside the cylinder cylinder 12 when the application plug 9 is positioned at the application position as shown in FIGS. In the illustrated example, the thickness of the lower end portion of the seal cylinder 24 is thinner than the thickness of other portions.
When such a seal cylinder 24 is located in the application position, it fits into the cylinder cylinder 12 and blocks communication between the measuring chamber 6 and the communication hole 5, while when positioned in the measurement position, the cylinder cylinder 12 The measurement chamber 6 and the communication hole 5 are communicated with each other by separating upward from the inside.

  The application plug 9 includes a stopper step 24c that protrudes outward in the radial direction. The stopper step portion 24 c is formed at an intermediate portion in the container axis O direction on the outer peripheral surface of the seal cylinder 24. The stopper step 24c is formed in an annular shape extending along the circumferential direction. As shown in FIG. 3, the stopper step portion 24 c can come into contact with the peripheral edge portion of the discharge hole 8 in the measuring cylinder member 7 from below when the application plug 9 is positioned at the measuring position. . In the illustrated example, the stopper step portion 24 c can be brought into contact with the inner peripheral edge portion of the top wall of the connecting tube portion 20 of the measuring tube member 7 from below.

In a state where the application plug 9 is located at the measurement position, the stopper step 24c of the application plug 9 abuts the peripheral edge of the discharge hole 8 in the measurement cylinder member 7 from below, so that Even when an external force is applied to move the applicator plug 9 upward, the applicator cap 9 positioned at the measuring position is restricted from moving further upward.
Here, an annular or arcuate first engagement protrusion 24a is formed on the outer peripheral surface of the upper portion of the seal cylinder 24 so as to protrude outward in the radial direction and extend in the circumferential direction. The first engagement protrusion 24a climbs upward over the second engagement protrusion 8a formed on the inner peripheral surface of the discharge hole 8 when the application plug 9 moves from the application position to the metering position. The engaging protrusion 8a is engaged from below the first engaging protrusion 24a. In addition, the 1st engagement protrusion 24a and the 2nd engagement protrusion 8a do not need to mutually engage over a perimeter.

  The outer insertion cylinder 25 is inserted on the guide shaft 11a of the inner plug member 4 so as to be movable up and down. In the illustrated example, the extrapolation cylinder 25 moves up and down in a non-contact state with the guide shaft 11 a of the inner plug member 4. Thereby, the coating stopper 9 can be moved up and down smoothly. Further, the lower end opening edge of the extrapolation cylinder 25 is located below the lower end opening edge of the seal cylinder 24.

  As shown in FIG. 2, the lower end opening edge of the outer insertion tube 25 is in contact with the upper end edge of the restriction portion 11 b of the support body 11 in a state where the application plug 9 is located at the application position, and the restriction portion 11 b of the support body 11. Is supported from below. At this time, a gap in the container axis O direction is provided between the upper end edge of the guide shaft 11 a of the support 11 and the top wall of the seal cylinder 24. Instead of this, the upper end edge of the guide shaft 11a and the top wall of the seal cylinder 24 may be brought into contact with each other to restrict further downward movement of the coating plug 9.

With the application plug 9 positioned at the application position, the distal end portion 26 of the application plug 9 is disposed in the top portion 19 of the measuring cylinder member 7. The outer diameter of the distal end portion 26 is smaller than the outer diameter of the upper portion of the seal cylinder 24 fitted inside the discharge hole 8 when the application plug 9 is located at the measurement position. In the state where the application plug 9 is located at the application position, the outer peripheral surface of each of the upper end portion and the distal end portion 26 located above the first engagement protrusion 24 a and the inner peripheral surface of the discharge hole 8 in the seal cylinder 24. And a gap through which the contents can be distributed is provided. The inside of the measuring chamber 6 communicates with the outside of the container through this gap.
An annular or arcuate engaged portion 26 a that protrudes inward in the radial direction and extends in the circumferential direction is formed on the inner peripheral surface of the upper end portion of the distal end portion 26.

The application container 1 includes a cap body 10 that is detachably attached to the mouth portion 3 of the container body 2 and covers the discharge hole 8 and the distal end portion 26 of the application plug 9.
The cap body 10 has a top tube shape, and an internal thread portion that is screwed to the external thread portion of the mouth portion 3 is formed on the inner peripheral surface of the lower portion of the peripheral wall. The female thread portion may be, for example, a double thread.
Instead of the cap body 10 being detachably screwed to the mouth portion 3, for example, the smooth outer peripheral surface of the mouth portion 3 is detachably fitted to the smooth inner peripheral surface of the cap body 10. Or, the cap body 10 may be appropriately changed such that the cap body 10 is detachably fitted into the mouth portion 3. Further, instead of attaching the cap body 10 to the mouth portion 3, for example, the cap body 10 may be attached to the measuring cylinder member 7.

  The top wall of the cap body 10 is formed with a lifting cylinder 31 that protrudes downward and has a lower end portion detachably fitted in the distal end portion 26 of the application plug 9 located at the application position. . On the outer peripheral surface of the lifting cylinder 31, an annular or arc-shaped lifting protrusion 31 a that protrudes outward in the radial direction and extends in the circumferential direction is formed. The lifting protrusion 31 a is undercut fitted to the engaged portion 26 a of the distal end portion 26 of the application plug 9. As the cap body 10 moves upward with respect to the mouth portion 3 and the measuring cylinder member 7, the application plug 9 is moved. Pulled up and moved from the application position to the weighing position.

Here, when the lifting protrusion 31 a of the cap body 10 is disengaged from the engaged portion 26 a of the application plug 9, the stopper step portion 24 c of the application plug 9 positioned at the measurement position is the opening of the discharge hole 8 in the measurement cylinder member 7. By abutting the peripheral edge from the lower side, the movement of the coating plug 9 further upward is restricted. Therefore, when the lifting protrusion 31a of the cap body 10 is disengaged from the engaged portion 26a of the coating plug 9, an elastic repulsive force directed downward is generated in the coating plug 9.
However, as described above, the first engagement protrusion 24a of the application plug 9 is engaged with the second engagement protrusion 8a of the measuring cylinder member 7 from below the first engagement protrusion 24a. Therefore, the downward movement of the coating plug 9 from the measuring position can be restricted.

The top wall of the cap body 10 is formed with an external fitting cylinder 28 that protrudes downward and is detachably fitted to the top portion 19 of the measuring cylinder member 7.
The cap body 10 includes a contact portion 27 that contacts the top portion 19 of the measuring cylinder member 7 from above. The contact portion 27 protrudes downward from the top wall of the cap body 10. The abutting portion 27 is disposed on a portion of the top wall of the cap body 10 that is located inside the outer fitting tube 28. A plurality of contact portions 27 are arranged at intervals in the circumferential direction, and are formed integrally with the inner peripheral surface of the outer fitting tube 28. The lower end edge of the contact part 27 is located above the lower end opening edge of the external fitting cylinder 28. The lower end edge of the contact portion 27 is in contact with the upper end opening edge of the top portion 19 of the measuring cylinder member 7. The contact portion 27 may be formed in an annular shape.
Moreover, you may form the protrusion which contact | abuts to the application | coating stopper 9 from the upper direction in the cap body 10. FIG. In this case, it is possible to prevent the application plug 9 from being displaced in the container axis O direction with the cap body 10 attached.

  On the inner peripheral surface of the lower end portion of the peripheral wall of the cap body 10, a step portion 32 having a wall surface facing the circumferential direction is formed. In a state where the cap body 10 is attached to the mouth portion 3 of the container main body 2, the stepped portion 32 can be brought into contact with the rotation preventing rib 3 b of the container main body 2 from the circumferential direction. When the stepped portion 32 abuts against the rotation preventing rib 3b from the circumferential direction, the cap body 10 is restricted from being excessively tightened into the mouth portion 3.

In the present embodiment, on the outer peripheral surface of the application plug 9, the portion that is located inside the discharge hole 8 when positioned at the application position protrudes outward in the radial direction to the inner peripheral surface of the discharge hole 8. Guide protrusions 21 that are in contact with or close to each other are formed.
As shown in FIG. 4, a plurality of guide protrusions 21 are arranged at intervals in the circumferential direction. In the illustrated example, six guide protrusions 21 are arranged at equal intervals in the circumferential direction.

  The guide protrusion 21 is formed on the outer peripheral surface of the distal end portion 26 of the coating plug 9. The guide protrusion 21 protrudes from the outer peripheral surface of the distal end portion 26 of the coating plug 9 toward the inner peripheral surface of the discharge hole 8, and protrudes from the base portion 21 a toward the inner peripheral surface of the discharge hole 8. A projecting end portion 21b. The projecting end portion 21 b abuts or approaches the inner peripheral surface of the discharge hole 8. Each of the base portion 21a and the protruding end portion 21b is formed in a vertical rib shape extending in the container axis O direction. The base 21a is wider in the circumferential direction than the protruding end 21b. The projecting end portion 21b is disposed at the central portion in the circumferential direction of the base portion 21a. The base 21a is formed in a rectangular parallelepiped shape that is long in the container axis O direction. The base 21 a has a top surface that faces the inner peripheral surface of the discharge hole 8. The protruding portion 21b is formed on the top surface of the base portion 21a. The protruding end 21b is formed in a protruding curved surface that bulges from the top surface of the base 21a. The radial size of the protruding end portion 21b is smaller than the radial size of the base portion 21a.

  The base portion 21 a is formed over the entire length in the container axis O direction on the outer peripheral surface of the distal end portion 26 of the application plug 9. The protruding end 21b is formed on the top surface of the base 21a over the entire length in the container axis O direction excluding the upper end. The guide protrusion 21 is in contact with or close to the inner peripheral surface of the discharge hole 8 in a state where the application plug 9 is located at the application position, and the top portion 19 of the measuring cylinder member 7 in a state where the application plug 9 is located at the measurement position. It is located higher and exposed outside the container. In the illustrated example, the lower end of the guide protrusion 21 is located above the lower end of the discharge hole 8 in a state where the application plug 9 is located at the application position.

  The applicator container 1 is provided with a cap body 10 after a metering applicator formed by assembling the inner plug member 4, the measuring cylinder member 7, and the applicator plug 9 is attached to the mouth 3 of the container body 2 filled with the contents. Is screwed into the mouth 3.

  Hereinafter, the operation of the application container 1 of the present embodiment will be described.

As shown in FIG. 2, before use of the application container 1, the lower end portion of the seal cylinder 24 of the application plug 9 is fitted inside the peripheral wall of the cylinder cylinder 12, so that the measurement chamber 6 and the communication hole 5 communicate with each other. Blocked.
In order to apply the contents in the container body 2 to the application portion S, first, the cap body 10 is moved upward to be detached from the mouth portion 3 of the container body 2, and the discharge holes 8 and the distal end portions of the application plugs 9. 26 is exposed outside the container. Here, when the cap body 10 is detached, the pulling protrusion 31a of the pulling cylinder 31 and the engaged portion 26a of the tip end portion 26 of the coating plug 9 are engaged with each other in the container axis O direction. The application plug 9 is pulled up by the cap body 10 and moved to the measuring position. At this time, since the male screw portion of the mouth portion 3 and the female screw portion of the cap body 10 are double-threaded screws, the lead of the screw is larger than that of the single-threaded configuration. For this reason, the amount of displacement in the container axis O direction with respect to the amount of rotation of the cap body 10 in the circumferential direction can be increased. As a result, the coating plug 9 can be quickly moved upward, and the cap body 10 can be quickly detached from the mouth 3 of the container body 2.

  As shown in FIG. 3, when the application plug 9 is moved to the measuring position, the upper part of the seal cylinder 24 of the application plug 9 is fitted inside the discharge hole 8, and the stopper step 24c of the application plug 9 is connected to the measurement cylinder. The first engaging protrusion 24 a of the application plug 9 is in contact with the top wall (opening peripheral edge of the discharge hole 8) of the connecting cylinder part 20 of the member 7, and the second engaging protrusion 8 a of the measuring cylinder member 7. The first engagement protrusion 24a is engaged with the second engagement protrusion 8a from below the first engagement protrusion 24a. At this time, the communication between the discharge hole 8 and the measuring chamber 6 is blocked. From this state, the cap body 10 further moves upward with respect to the mouth portion 3 of the container body 2, so that the lifting protrusion 31 a of the lifting cylinder 31 of the cap body 10 is engaged with the distal end portion 26 of the coating plug 9. The cap body 10 is removed from the container main body 2 and the application plug 9 over the portion 26a.

Next, the content in the container body 2 is caused to flow into the measurement chamber 6 through the communication hole 5 by placing the application container 1 in an inverted posture with the application plug 9 positioned at the measurement position. At this time, since the communication between the discharge hole 8 and the measuring chamber 6 is blocked by the application plug 9, a predetermined amount of content is measured in the measuring chamber 6.
Next, as shown in FIG. 5, when the distal end portion 26 of the application plug 9 located at the measurement position is pressed against the application portion S, the application plug 9 moves toward the application position. In this process, the gap between the outer peripheral surface of the application plug 9 and the inner peripheral surface of the discharge hole 8 is opened to the outside of the container, and the outer insertion cylinder 25 is abutted against the regulating portion 11b of the inner plug member 4, The lower end portion of the seal cylinder 24 is fitted inside the peripheral wall of the cylinder cylinder 12.
As a result, the application container 1 is disconnected from the measurement chamber 6 and the communication hole 5, and is connected to the discharge hole 8 and the measurement chamber 6, so that the inner peripheral surface of the discharge hole 8 and the tip of the application plug 9 are provided. The content can be applied to the application portion S through the gap between the outer peripheral surface 26 and the outer peripheral surface.

  After use (after application), the lower end portion of the lifting cylinder 31 of the cap body 10 is fitted into the distal end portion 26 of the coating plug 9, and the lifting protrusion 31 a of the lifting cylinder 31 is engaged with the distal end portion 26. With the female threaded portion of the cap body 10 screwed into the male threaded portion of the mouth portion 3 of the container body 2 with the mating portion 26a being in contact with the engaged portion 26a from above, the lifting protrusion 31a is The cap 26 is mounted on the mouth 3 of the container body 2 while the joint 26a is moved downward.

  As described above, according to the application container 1 according to the present embodiment, the outer peripheral surface of the application plug 9 is directed toward the outside in the radial direction toward the portion located inside the discharge hole 8 when located at the application position. Since the guide protrusion 21 that protrudes and abuts on or is close to the inner peripheral surface of the discharge hole 8 is formed, the application plug 9 is positioned in the radial direction with respect to the measuring tube member 7 at the application plug 9 positioned at the application position. Even if an external force for shifting is applied, the guide protrusion 21 can be brought into contact with the inner peripheral surface of the discharge hole 8. Therefore, it is possible to suppress the application plug 9 from being inclined with respect to the measuring cylinder member 7 when the distal end portion 26 of the application plug 9 located at the application position is brought into contact with the application portion S. The contents can be prevented from unexpectedly flowing out from the discharge hole 8 to the application portion S.

  In addition, since the guide protrusion 21 is disposed in the discharge hole 8, when the above-described external force is applied to the application plug 9 located at the application position, the guide protrusion 21 is immediately inserted into the discharge hole 8. It is possible to make contact with the peripheral surface, and it is ensured that the size of the gap between the outer peripheral surface of the coating plug 9 and the inner peripheral surface of the discharge hole 8 changes, that is, the cross-sectional shape of the flow path changes. Can be suppressed.

  Further, since a plurality of guide protrusions 21 are arranged at intervals in the circumferential direction, the application plug 9 positioned at the application position is inclined with respect to the measuring cylinder member 7 regardless of the direction of the external force applied to the application plug 9. Can be suppressed.

In addition, since the base portion 21a and the protruding end portion 21b of the guide protrusion 21 are each formed in a vertical rib shape, the guide protrusion 21 can be provided with high rigidity against an external force in the radial direction. The gap between the outer peripheral surface of the application plug 9 and the inner peripheral surface of the discharge hole 8 is reliably suppressed when the tip end portion 26 of the application plug 9 located at the position abuts the application target S. Can do.
Moreover, since the guide protrusion 21 includes the base portion 21a, it is possible to further reliably suppress the guide protrusion 21 from being deformed by the above-described external force. Furthermore, since the base portion 21a is not in sliding contact with the inner peripheral surface of the discharge hole 8, the size of the flow path cross-sectional area can be set by adjusting the size of the base portion 21a without considering the sliding resistance. This is possible, and design constraints can be reduced.
In addition, since the guide protrusion 21 includes not only the base portion 21a but also the protruding end portion 21b, even if the guide protrusion 21 slides on the inner peripheral surface of the discharge hole 8 when the application plug 9 moves in the container axis O direction, The sliding area can be suppressed, and the sliding resistance generated in the coating plug 9 can be suppressed.

  The technical scope of the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.

For example, by forming at least a part of the application plug 9 with a soft material or the like, it is possible to make the application feel of the application plug 9 less irritating and comfortable and comfortable.
In the above embodiment, the guide protrusion 21 is formed on the outer peripheral surface of the coating plug 9, but it may be formed on the inner peripheral surface of the discharge hole 8.
Moreover, in the said embodiment, although the structure provided with the base 21a and the protrusion part 21b as the guide protrusion 21 was shown, not only this but the structure provided with any one or the structure formed in plate shape etc. are employ | adopted, for example. You may change suitably.

  In addition, it is possible to appropriately replace the constituent elements in the embodiment with known constituent elements without departing from the spirit of the present invention, and the above-described modified examples may be appropriately combined.

DESCRIPTION OF SYMBOLS 1 Application | coating container 2 Container body 2a Bottom part 3 Portion part 4 Middle stopper member 5 Communication hole 6 Measuring chamber 7 Measuring cylinder member 8 Discharge hole 9 Application | coating stopper 19 Top part 21 Guide protrusion 21a Base part 21b Protrusion part 26 Tip part O Container axis S Part

Claims (3)

A bottomed cylindrical container body in which the content to be applied to the application part is stored;
An inner plug member attached to the mouth of the container body and having a communication hole communicating with the container body;
A measuring cylinder member formed between the inner plug member and a measuring chamber communicating with the inside of the container body through the communication hole, and having a discharge hole communicating with the measuring chamber at the top,
An application stopper that is provided in the measurement chamber and has a distal end projecting from the discharge hole to the outside of the measurement chamber;
The application plug is
A measurement position that blocks communication between the discharge hole and the measurement chamber and connects the measurement chamber and the communication hole;
An application position that is located on the bottom side of the container body along the container axial direction from the measurement position, blocks communication between the measurement chamber and the communication hole, and connects the discharge hole and the measurement chamber. , Are arranged to be movable in the container axial direction,
Either one of the outer peripheral surface of the coating plug positioned inside the discharge hole when positioned at the application position and the inner peripheral surface of the discharge hole protrudes in the radial direction and contacts the other. An applicator container, wherein a guide protrusion is formed in contact with or close to.   The applicator container according to claim 1, wherein a plurality of the guide protrusions are arranged at intervals in a circumferential direction around the container axis. The guide protrusion protrudes from one of a portion located inside the discharge hole when positioned at the application position and an inner peripheral surface of the discharge hole on the outer peripheral surface of the coating plug. A base portion that protrudes from the base portion toward the other side, and
The base portion and the protruding end portion are each formed in a longitudinal rib shape extending in the container axial direction, and the base portion has a width in the circumferential direction around the container axis wider than the protruding end portion. The coating container according to 1.

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