JP4740173B2 - Coating material extrusion container - Google Patents

Description

  The present invention relates to a coating material extrusion container for extruding and using a coating material.

  Conventionally, the technique of the following patent document 1 is known as an application filler extrusion container for extruding and using an application filler. The technique described in Patent Document 1 includes a filling member that has a cylindrical shape and has a discharge port at the tip and is filled with a filling material for coating. A moving body for piston that discharges from a discharge outlet and a female thread that engages with a male screw of the moving body for piston and that engages with the filling member in the rotational direction and the front-rear direction and is integrated. A body cylinder having a body, an internal shape of the piston moving body and an external shape that engages in the rotational direction, and a piston body and a shaft body that forms a rotation preventing portion. When the main body cylinder and the front cylinder constituting the container front part are relatively rotated in one direction, a screwing part (second screwing part) constituted by the male screw and the female screw serves as a filling member. The moving body for piston moves forward, and the filling for application is discharged from the discharge port of the filling member. On the other hand, when the main body cylinder and the front cylinder are relatively rotated in the other direction, which is the opposite direction of one direction, the screwing portion (second screwing portion) works to move the piston moving body against the filling member. Retreat.

In this filling filler extruding container, the piston moving body includes a click engaging groove that crosses the male screw of the piston moving body in the front-rear direction and is juxtaposed in the circumferential direction. The body is provided with slits from the tip and is divided into four along the circumferential direction. Each body is provided with a female screw on the arcuate inner peripheral surface of one of the opposed divided pieces, and the arcuate shape of the other opposed divided piece. Click engagement protrusions that click-engage with the click engagement grooves are provided on the inner peripheral surface of each of the inner peripheral surfaces, and the click mechanism that includes these click engagement grooves and click engagement protrusions allows the degree of relative rotation and the movement of the moving body. The movement is made to be perceived by the user. In addition, a technique using a ratchet mechanism including a ratchet groove and ratchet teeth at the same position as the click mechanism instead of the click mechanism is also disclosed.
JP 2006-305299 A

  Here, the extrusion container has a configuration in which grooves and protrusions (teeth) are provided in a part of the part that forms the screw, so that it is difficult to form and a good click feeling cannot be realized stably. was there.

  The present invention has been made to solve such a problem, and provides a coating material extrusion container that can easily form a click mechanism, has high component accuracy, and can stably realize a good click feeling. With the goal.

  The coating material extruding container according to the present invention has a cylindrical filling member having an opening at the tip and filled with the coating material, and a male screw on the outer peripheral surface, and the coating material is extruded from the extrusion opening by moving forward. A moving body to be engaged, a female screw that engages with a male screw of the moving body, a female screw member that engages with the filling member in the rotational direction around the axis, An anti-rotation member having a shape portion that engages movably in the axial direction, and includes a male screw and a female screw by relative rotation of the filling member, the female screw member, the anti-rotation member, and the moving body. An application material extruding container in which a moving body moves with respect to the filling member by working the screwed portion, wherein the female screw member includes at least a cylindrical portion opened toward the rear side, and the rotation prevention member includes at least Open to the front side, circle of female screw member Click having a cylindrical portion disposed so as to have an overlap section that is engaged with the section in an axial direction so as to protrude inward or outward from the cylindrical section of the female screw member in the overlap section Synchronized with the relative rotation by engaging the click tooth portion facing the click tooth portion of the female screw member that protrudes inward or outward from the cylindrical portion of the rotation stop member within the overlap section. And a click mechanism for providing a click feeling.

  According to such an application material extruding container, the cylindrical portion opened toward at least the rear side of the female screw member and the cylindrical portion opened toward at least the front side of the rotation stopper member overlap in the axial direction. A click tooth portion provided in the overlap section of the cylindrical portion of the female screw member and protruding outward or inward, and an overlap section of the cylindrical portion of the rotation preventing member, which has an overlapping section to be engaged The click teeth provided inside and projecting inward or outward form a click mechanism, and these click teeth are synchronized with the relative rotation of the filling member, the female screw member, the anti-rotation member, and the moving body. Are engaged to provide a click feeling. Therefore, the click mechanism can be easily formed, the component accuracy is high, and a good click feeling can be stably realized.

  Here, a screwing part different from the screwing part is provided, and by the relative rotation of the container front part and the container rear part constituting the container, another screwing part works and the filling member moves, and further in the same direction. It is preferable to adopt a configuration in which the threaded portion works by relative rotation, the moving body moves relative to the filling member, and the click tooth portions engage with each other when the threaded portion works.

  When such a configuration is adopted, a click feeling is not generated when the filling member is moved, and a click feeling is generated only when the moving body is moved. Therefore, the filling member is fed out from the container front portion and the container rear portion. In the case of relative rotation in the direction, it is possible to quickly advance the filling member without a click feeling, and the relative rotation in the same direction causes a click feeling while the moving body moves forward. It is possible to push out the coating material moderately by the feeling, preventing excessive application of the coating material, and when the relative rotation of the container front part and the container rear part in the direction of rewinding the filling member is accompanied by a click feeling It is possible to quickly retreat the filling member without any problems, and a further click in the same direction causes a click feeling while the moving body moves backward. Back too much of a moving object can be prevented.

  Further, as a configuration that effectively exhibits the above-described operation, specifically, the click tooth portion of the female screw member or the click tooth portion of the rotation preventing member has any relative positional relationship between the female screw member and the rotation stopping member. Even if it exists, the structure which has an axial direction long dimension which can be engaged with the other party click tooth | gear part is mentioned.

  Thus, according to the coating material extruding container according to the present invention, the click mechanism can be easily formed, the component accuracy is high, and a good click feeling can be stably realized.

  Hereinafter, a preferred embodiment of a coating material extruding container according to the present invention will be described with reference to FIGS. In each figure, the same symbols are attached to the same elements, and duplicate descriptions are omitted.

  1 to 13 show the first embodiment of the present invention, and FIGS. 14 to 25 show the second embodiment of the present invention. FIGS. 1 to 7 show the first embodiment of the present invention. FIG. 8 is a cross-sectional perspective view taken along line VIII-VIII in FIG. 1, FIGS. 9 and 10 are views showing a rotation stop member, and FIGS. 13 is a view showing a female screw member, and the coating material extruding container of the present embodiment accommodates the coating material and can be pushed out by a user's operation as appropriate.

  Here, as the coating material, for example, lip gloss, lip, eye color, eyeliner, cosmetic liquid, cleaning liquid, nail enamel, nail care solution, nail remover, mascara, anti-aging, hair color, hair cosmetics, oral care, Includes liquids such as massage oil, square plug loosening liquid, foundation, concealer, skin cream, marking pen and other writing instruments, liquid medicines, mud, etc., jelly, gel, and paste It is possible to use semi-solid such as kneaded or soft solid.

  As shown in FIG. 1, the coating material extruding container 100 includes a main body cylinder 1 constituting the rear part of the container, and a tip that constitutes the front part of the container and is connected to the main body cylinder 1 via the front cylinder holding member 2 so as to be relatively rotatable. The cylinder 3 is provided as an external configuration. The coating material extruding container 100 includes a filling member 4, a female screw member 5, a rotation stopper member 16, a moving body 6, a piston 7, a first screwing portion (another screwing portion) 8, A second screwing part (screwing part) 9 is roughly provided.

  The main body cylinder 1 is configured as a bottomed cylinder, and includes a plurality of protrusions 1f for mounting the rotation stop member 16 along the inner peripheral surface on the bottom side, as shown in FIGS. Yes. These protrusions 1 f are provided so as to extend from the bottom surface of the main body cylinder 1 to the middle in the axial direction of the main body cylinder 1 and to protrude from the inner peripheral surface of the main body cylinder 1 toward the axial center by a predetermined length.

  As shown in FIGS. 9 and 10, the rotation preventing member 16 includes a main body portion 16x configured in a bottomed cylindrical shape, and a shaft body erected at the center of the bottom portion of the main body portion 16x so as to face the front end side. 16y.

  The main body portion 16x is provided with an annular flange portion 16a at the bottom, and a gear-shaped uneven portion 16b having unevenness along the circumferential direction is provided on the peripheral surface of the flange portion 16a. It is provided to be engaged with the strip 1f in the rotational direction around the axis. In addition, a pair of openings 16c and 16c communicating between the inside and the outside is provided at a position opposed to the cylindrical portion 16z which is the peripheral wall of the main body portion 16x, and the inner side (axial center) An arc-shaped convex portion 16d that protrudes to the side) is provided as a locking portion that is locked to the female screw member 5 in the axial direction.

  A plurality of click tooth portions 16f, which are protrusions protruding inward (axial center side) and extending short in the axial direction, are provided on the inner peripheral surface of the arc-shaped convex portion 16d along the circumferential direction. The click tooth portion 16f is for click engagement with the female screw member 5 in the rotational direction around the axis, and the cross-sectional shape thereof is a shape such as an isosceles trapezoid.

  The shaft body 16y has a non-circular cross-sectional shape including a plurality of protrusions 16e arranged in the outer circumferential surface of the cylindrical body so as to project outward in the radial direction and extending in the axial direction. The protrusion 16e serves as a detent that constitutes one of the detents (detent mechanism) 50.

  Then, as shown in FIG. 1, the rotation preventing member 16 is inserted into the main body cylinder 1, and as shown in FIGS. 1 and 8, the protrusion 1f of the main body cylinder 1 enters the concave portion of the concave and convex portion 16b. It is engaged with the body cylinder 1 so as to be able to rotate synchronously and move in the axial direction.

  As shown in FIG. 1, the front tube 3 has a cylindrical shape having a flange portion 3 a at the rear end portion, and extends from a substantially axial center to a rear end of the inner peripheral surface of the front tube 3. The coupling mechanism) has a threading groove 3b as a female thread constituting one of the two. The front end 3f of the screw groove 3b is a forward limit of a later-described screw projection 5e of the female screw member 5, and corresponds to a forward limit of the filling member 4.

  The second half of the front tube 3 is inserted into the main body tube 1, and the rear end surface of the flange portion 3 a is abutted against the front end surface of the protrusion 1 f of the main body tube 1.

  The front tube pressing member 2 has a cylindrical shape including a flange portion 2a on the tip side, and has a spring portion 2d on the rear side and a main body portion 2x on the front side of the spring portion 2d.

  The front tube pressing member 2 is inserted into the main body tube 1 and is externally inserted into the front tube 3, and rotates synchronously with the main body tube 1 in a state where the rear end surface of the flange portion 2 a is abutted against the front end surface of the main body tube 1. It is mounted in such a way that it can be removed in the axial direction. Further, in this state, the front tube 3 has its front surface pressed against the rear end surface of the front tube pressing member 2 via the O-ring 99, and the spring portion 2d of the front tube pressing member 2 is pressed. , And the flange 3a is sandwiched between the front tube pressing member 2 and the O-ring 99 and the protrusion 1f of the main body tube 1 so that the front tube pressing member 2 is pressed against the main body tube 1. It is mounted so as to be capable of relative rotation and non-detachable in the axial direction. Due to the spring portion 2d and the O-ring 99 of the front tube pressing member 2, a better rotational resistance is generated in the front tube 3 and the main body tube 1.

  The movable body 6 is configured in a substantially cylindrical shape, and has a flange portion 6a on the outer surface on the distal end side, and a second screwing portion (screwing mechanism) 9 on the outer surface of a portion on the rear side of the flange portion 6a. A male screw 6b constituting one side is provided along the axial direction.

  A plurality of protrusions 6d extending in the axial direction are arranged on the inner peripheral surface extending from the front end to the rear end of the moving body 6 so as to protrude radially inward. And this protrusion 6d is used as the rotation stopper which comprises the other of the rotation prevention part (rotation prevention mechanism) 50. FIG.

  The moving body 6 is extrapolated to the shaft body 16y of the rotation stop member 16, and the protrusion 6d enters between the protrusions 16e and 16e of the shaft body 16y of the rotation stop member 16 and engages in the rotation direction around the axis. The rotation stop member 16 is mounted so as to be able to rotate synchronously and move in the axial direction.

  The piston 7 is attached to the tip portion, which is a portion on the front side of the flange portion 6a of the moving body 6, so as not to move in the axial direction.

  As shown in FIGS. 11 and 12, the female screw member 5 is configured in a stepped cylindrical shape including an outer diameter small diameter portion 5a at the tip and an outer diameter large diameter portion 5b following the rear end of the outer diameter small diameter portion 5a. ing. A flange portion 5c is provided in the middle of the outer diameter large diameter portion 5b in the axial direction, and a first screwing portion (screwing mechanism) is provided on the outer peripheral surface of the flange portion 5c at a plurality of positions along the circumferential direction. ) A threaded projection 5e is provided as a male screw constituting the other of 8).

  Further, on the outer peripheral surface of the rear end portion of the outer diameter large diameter portion 5b of the female screw member 5, an annular protrusion (locking portion) for locking the arc-shaped convex portion 16d of the rotation stopping member 16 in the axial direction. ) 5k is provided.

  The female screw member 5 is provided with a pair of slits 5n extending from the distal end of the outer diameter small diameter portion 5a to the distal end portion of the outer diameter large diameter portion 5b and communicating between the inside and the outside on both sides of the axis, On the inner surface of the front half of the portion 5a, a female screw 5j constituting the other of the second screwing portion (screwing mechanism) 9 is formed in a semicircular shape by slits 5n and 5n as shown in FIGS. It is provided so that it can be divided.

  Further, as shown in FIGS. 11 and 12, the female screw member 5 is mounted with the O-ring 11 shown in FIG. 1 on the outer peripheral surface on the distal end side of the outer diameter small diameter portion 5a which is the outer peripheral side of the female screw 5j. A groove portion 5m is provided so as to be divided into a semicircular arc shape by the slits 5n and 5n.

  Further, the rear side of the flange portion 5c of the outer diameter large diameter portion 5b of the female screw member 5 is a cylindrical portion 5t. The cylindrical portion 5t has a substantially rectangular shape extending in the axial direction in a side view and has an inner and outer portion. A plurality of communication openings 5p are provided along the circumferential direction. A click which is a projection that is arranged so that a substantially rectangular parallelepiped click tooth base 5q enters the opening 5p, and protrudes outwardly and extends in the axial direction on the surface of the click tooth base 5q. A tooth portion 5s is provided. The click tooth portion 5s is for click engagement with the click tooth portion 16f of the rotation stop member 16 in the rotational direction around the axis, and the cross-sectional shape thereof is a mountain shape having an ascending slope and a descending slope. . The click tooth base 5q having the click tooth portion 5s is connected to a pair of support portions 5r protruding from the peripheral surface of the opening 5p of the outer diameter large diameter portion 5b, and is flexible in the radial direction by the support portions 5r. It is supported to have.

  As shown in FIG. 1, the female screw member 5 is inserted into the moving body 6 and inserted into the rear portion of the front tube 3, and the cylindrical portion 5 t on the rear side of the flange portion 5 c is connected to the rotation stopper member 16. With the female screw 5j inserted therein and screwed into the male screw 6b of the moving body 6, the front end surface of the outer diameter small diameter portion 5a is abutted against the rear end surface of the flange portion 6a of the moving body 6 and the flange The rear end surface of the portion 5c is abutted against the front end surface of the cylindrical portion 16z (main body portion 16x) of the rotation stop member 16, and the screw projection 5e is screwed into the screw groove 3b of the front tube 3, and the annular projection 5k is spaced rearward in the axial direction with respect to the convex portion 16d of the rotation stop member 16, and is not engaged with the convex portion 16d. In this state, as shown in FIGS. 1 and 8, the click tooth portion 5 s of the female screw member 5 and the click tooth portion 16 f of the rotation preventing member 16 can be click-engaged in the rotation direction around the axis. Yes. That is, the cylindrical portion 5t of the female screw member 5 and the cylindrical portion 16z of the rotation preventing member 16 are configured to have an overlap section in the axial direction that overlaps in the axial direction and the click tooth portions 5s and 16f click-engage with each other. Yes.

  As shown in FIG. 1, an O-ring 11 is fitted in the groove 5 m of the female screw member 5, and the external force of the female screw member 5 is divided by the slits 5 n and 5 n by the elastic force of the O-ring 11. The small diameter portion 5a is tightened, whereby the operating resistance of the second screwing portion 9 constituted by the female screw 5j of the female screw member 5 and the male screw 6b of the moving body 6 is increased, and the female screw member 5 It is made higher than the operating resistance of the first screwing portion 8 constituted by the screwing protrusion 5e and the screwing groove 3b of the front tube 3.

  Further, in the first screwing portion 8 and the second screwing portion 9, the lead of the first screwing portion 8 is made larger than the lead of the second screwing portion 9. Here, the lead is a distance that advances in the axial direction when the screw is rotated once.

  The filling member 4 has a cylindrical shape and a shape in which the tip is closed, and the coating material L is filled therein. The outer surface of the front end portion of the filling member 4 is an application portion, and a discharge port (opening) 4c that communicates the inside and the outside is provided in the application portion.

  The filling member 4 is inserted into the front tube 3, and a rear portion thereof is externally inserted into the female screw member 5. The female member 5 is engaged with the female screw member 5 in the rotational direction around the axis and in the axial direction. The screw member 5 is mounted so as to be able to rotate synchronously and not to move in the axial direction, and is integrated with the female screw member 5. In this state, the screw member 5 is accommodated in the front tube 3. The cap 10 is detachably engaged with the front tube pressing member 2 so that the front tube 3 containing the filling member 4 is covered and protected.

  In the initial state of the coating material extruding container 100 having such a configuration, as shown in FIG. 1, the filling member 4, the female screw member 5, the moving body 6, and the rotation stopper member 16 are positioned at the retreat limit, The filling member 4 is accommodated in the cylinder 3 and the rear end surface of the rotation stopping member 16 is in contact with the bottom surface of the main body cylinder 1.

  In the initial state of the coating material extruding container 100, when the cap 10 is removed by the user and the main body cylinder 1 and the front cylinder 3 are relatively rotated in the feeding direction which is one direction, the second Since the operating resistance of the screwing portion 9 is higher than the operating resistance of the first screwing portion 8, the screwing action of the first screwing portion 8 operates and engages with the main body cylinder 1 so as to be able to rotate synchronously. The movable body 6 and the piston 7 together with the female screw member 5 and the filling member 4 by cooperation with the rotation preventing portion 50 constituted by the protrusion 16e of the shaft body 16y of the rotation stopping member 16 and the protrusion 6d of the moving body 6. Advances, and the tip of the filling member 4 emerges from the opening at the tip of the front tube 3.

  When the female screw member 5 moves forward by a predetermined amount, specifically, an axial distance between the annular protrusion 5k of the female screw member 5 and the convex portion 16d of the rotation stop member 16, the annular shape of the female screw member 5 is increased. When the protrusion 5k locks the protrusion 16d of the rotation stop member 16 in the axial direction, and the main body tube 1 and the front tube 3 are subsequently rotated relative to each other in the extending direction, the annular protrusion 5k and the protrusion 16d The female screw member 5 moves forward with the anti-rotation member 16 by the locking, and the amount of protrusion from the front tube 3 at the tip of the filling member 4 increases. The screw projection 5e of the member 5 advances to the forward limit located at the tip 3f of the screw groove 3b of the front tube 3. At this time, the front surface of the concavo-convex portion 16b of the rotation preventing member 16 is in contact with the rear end surface of the flange portion 3a of the front tube 3, or is positioned in the vicinity of the rear end surface of the flange portion 3a.

  When the filling member 4 (female screw member 5) moves forward, the lead of the first screwing portion 8 is made larger than the lead of the second screwing portion 9, so that the filling member 4 and The female screw member 6 quickly reaches the use position which is the forward limit. Then, when the screw projection 5e of the female screw member 5 reaches the tip 3f of the screw groove 3b of the front tube 3, the advancement is blocked, and the screwing action of the first screwing portion 8 is stopped.

  When the filling member 4 moves forward, the screwing action of the second screwing portion 9 does not operate, and the female screw member 5 and the rotation stop member 16 rotate synchronously, so that a click feeling does not occur. Therefore, the filling member 4 can be rapidly advanced without a click feeling.

  Subsequently, when the main body cylinder 1 and the front cylinder 3 are relatively rotated in the feeding direction, since the screwing action of the first screwing part 8 is stopped, the screwing action of the second screwing part 9 is stopped. The movable body 6 and the piston 7 move forward as shown in FIG. At this time, since the lead of the second threaded portion 9 is made smaller than the lead of the first threaded portion 8, the piston 7 is slowly fed out so that the coating material L is appropriately discharged from the filling member 4. It discharges from the outlet 4c and appears to be used.

  When the moving body 6 moves forward (when the moving body 6 moves forward with respect to the filling member 4), the screwing action of the first screwing portion 8 does not operate, and the female screw member 5 and Since the rotation stop member 16 is relatively rotated in the feed-out direction, the click tooth portion 5s of the female screw member 5 and the click tooth portion 16f of the rotation stop member 16 repeat locking and releasing in the rotation direction, and the click feeling is felt. The degree of relative rotation and the degree of advancement of the moving body 6 are sensed by the user. Accordingly, the coating material L can be appropriately pushed out by the click feeling, and excessive application of the coating material L is prevented.

  After use, when the main body tube 1 and the front tube 3 are relatively rotated in the rewinding direction which is the opposite direction of one direction, as described above, compared to the operating resistance of the first screwing portion 8. Since the operating resistance of the second screwing portion 9 is increased, the screwing action of the first screwing portion 8 works first, and as shown in FIG. The moving body 6 and the piston 7 move backward together with the female screw member 5 and the filling member 4. At this time, the rotation stop member 16 may be retracted together with the female screw member 5 by its own weight, or may be brought into contact with the flange portion 5c of the female screw member 5 that is retracted and retracted by the flange portion 5c.

  Then, as the filling member 4 moves backward, the leading end of the filling member 4 is sunk from the opening at the tip of the front tube 3 (see FIG. 5), and the rear end surface of the rotation preventing member 16 contacts the bottom surface of the main body tube 1. The rear end surface of the flange portion 5c of the female screw member 5 comes into contact with the front end surface of the cylindrical portion 16z (main body portion 16x) of the rotation stopping member 16, and the filling member 4 and the female screw member 5 reach the retreat limit.

  When the filling member 4 (female screw member 5) is retracted, the lead of the first screwing portion 8 is made larger than the lead of the second screwing portion 9, so that the filling member 4 is , It is repeated quickly. When the filling member 4 reaches the retreat limit, further retreat of the screw projection 5e of the female screw member 5 is prevented, and the screwing action of the first screwing portion 8 is stopped.

  When the filling member 4 is retracted, the screwing action of the second screwing portion 9 does not operate, and the female screw member 5 and the rotation stop member 16 rotate synchronously, so that a click feeling does not occur. Therefore, the filling member 4 can be quickly retracted without a click feeling.

  Here, when the main body cylinder 1 and the front cylinder 3 are further rotated relative to each other in the retraction direction, the screwing action of the first screwing part 8 is stopped, so that the screwing of the second screwing part 9 is stopped. The combined action works, and the movable body 6 and the piston 7 retreat as shown in FIG. At this time, since the lead of the second screwing portion 9 is made smaller than the lead of the first screwing portion 8, the piston 7 is slowly retracted.

  Then, by the retraction of the piston 7, the coating material L is sucked into the filling member 4 from the discharge port 4 c of the filling member 4, and a predetermined space A is formed inside the discharge port 4 c of the filling member 4. Even if the coating material L and the air mixed in the coating material L expand due to a change in temperature or pressure, the space A prevents the coating material L from leaking from the discharge port 4c.

  When the movable body 6 is retracted (when the movable body 6 is retracted relative to the filling member 4), the screwing action of the first screwing portion 8 does not operate, and the female screw member 5 and Since the rotation stop member 16 is relatively rotated in the retraction direction, the click tooth portion 5s of the female screw member 5 and the click tooth portion 16f of the rotation stop member 16 repeat the locking in the rotation direction and release thereof, and the click feeling The degree of relative rotation and the retreating state of the moving body 6 are detected by the user. Therefore, the moving body is prevented from returning too much due to the click feeling.

  When the coating material L remains in the filling member 4, the main body tube 1 and the front tube 3 are rotated relative to each other in the feeding direction again by the user so that the coating material L is put into use. The operation is the same as described above, and such an operation is repeated.

  Further, when the female screw member 5 and the moving body 6 advance to the maximum by the relative rotation of the main body tube 1 and the front tube 3 in the extending direction, the piston 7 moves to the tip of the filling member 4 as shown in FIG. The coating material L is almost used up in contact with the inner surface.

  Then, when the filling member 4 and the female screw member 5 reach the retreat limit due to the relative rotation of the main body tube 1 and the front tube 3 in the retraction direction, the filling member 4 is accommodated in the front tube 3, and FIG. It will be in the state shown.

  Thus, according to the coating material extruding container 100 of the present embodiment, the overlap section in which the cylindrical portion 5t of the female screw member 5 and the cylindrical portion 16z of the rotation stopper member 16 are overlapped in the axial direction and click-engaged. The click tooth portion 5 s provided in the overlap section of the cylindrical portion 5 t of the female screw member 5 and projecting outward is provided in the overlap section of the cylindrical portion 16 z of the rotation stopper member 16. The click tooth portion 16f protruding inward constitutes a click mechanism, and these click tooth portions 5s, 16f are relative to the filling member 4, the female screw member 5, the rotation stopper member 16, and the movable body 6. Since it is configured to click and engage with the rotation in synchronization with the rotation, the click mechanism is easy to mold, the parts accuracy is high, and a good click feeling can be realized stably. It can be.

  Further, according to the present embodiment, the filling member 4 and the female screw member 5 are moved forward / backward by the action of the first screwing part 8, and at this time, the rotation stopper member 16 is given by the action of the first screwing part 8. Therefore, the moving distance of the filling member 4 due to the screwing action of the first screwing portion 8 and the moving distance of the moving body 6 due to the screwing action of the second screwing portion 9 are the same as those of the moving body. For example, it is possible to increase the amount of the coating material L used, as compared with the case where the rotation stopper does not move in the axial direction.

  Further, since the female screw member 5 includes the annular protrusion 5k that locks the rotation stop member 16 in the axial direction, the filling member 4 including the moving body 6 by the screwing action of the first screwing portion 8 is provided. According to the movement, the rotation stop member 16 moves reliably.

  It is also possible to eliminate the locking portion 5k of the female screw member 5 and move the anti-rotation member 16 by its own weight, for example, by the user inverting the container, or by friction or screwing.

  Further, the female screw member 5 moves forward by a predetermined amount from the retreat limit while leaving the rotation stop member 16 functioning as a detent, and then further moves forward with the rotation stop member 16. It is also possible to adopt a configuration in which the stoppers are brought into contact with the rotation stopper member 16 from the beginning by abutting the stoppers in the axial direction in advance.

  14 to 16 are longitudinal sectional views showing respective states of the coating material extruding container according to the second embodiment of the present invention, FIG. 17 is an exploded perspective view of the coating material extruding container, and FIGS. FIG. 20 and FIG. 21 are perspective views showing the rotation stopper member, FIGS. 22 to 24 are views showing the female screw member, and FIG. It is a perspective view which shows this female screw member.

  As shown in FIG. 14, in the coating material extruding container 200 of the second embodiment, the screwing portion is one screwing portion 109, and the filling member 104 filled with the coating material L is in the axial direction. The front cylinder 3 and the front cylinder pressing member 2 are eliminated, and the moving body 106 is configured to move forward / backward by the screwing action of the single screwing portion 109.

  That is, the coating material extruding container 200 includes a main body cylinder 101 constituting the rear part of the container and a filling member 104 constituting the front part of the container as outer configurations, and the intermediate member 102, the rotation stopper member 116, the female member are contained in the container. A screw member 105, a moving body 106, and a piston 107 are roughly provided.

  Specifically, as shown in FIGS. 17 and 18, the main body cylinder 101 is configured as a bottomed cylinder, and includes an engaging claw piece 101 a that protrudes forward at the bottom. The engaging claw pieces 101a are provided at four equal positions along the circumferential direction around the axis on the bottom of the main body cylinder 101, and the claw bulging outward in the radial direction is provided at the tip of the engaging claw pieces 101a. The portion 101c is provided for mounting the rotation stop member 116. The bottom of the base portion of the engaging claw piece 101a on the outer side in the radial direction is provided with a recess 101b that extends outward in the radial direction and is recessed backward in the axial direction. The engaging claw piece 101a is flexible in the radial direction. It is set as the structure which has. Here, the main body cylinder 101 is made of a transparent material, and the internal intermediate member 102 can be visually observed.

  The intermediate member 102 is formed in a bottomed cylindrical shape, and its outer shape is a shape that substantially matches the inner shape of the main body cylinder 101. At the bottom of the intermediate member 102, an opening 102a for passing the engaging claw piece 101a of the main body cylinder 101 in the axial direction is provided. Here, the intermediate member 102 is colored in the same color as the coating material L.

  As shown in FIGS. 20 and 21, the rotation preventing member 116 includes a main body portion 116 x configured in a bottomed cylindrical shape, and a shaft body erected at the center of the bottom portion of the main body portion 116 x toward the front end side. 116y.

  The latter half portion of the main body portion 116x is a cylindrical portion 116z, and the engaging claw piece 101a of the main body cylinder 101 can be entered into the bottom portion 116r, and the engaging claw piece 101a is moved around the axis of the rotation stopper member 116. An opening 116a for engaging in the rotation direction is opened at a position corresponding to the engaging claw piece 101a.

  In addition, the body portion 116x is provided with four slits 116b extending inward in a parallel state from a position at the periphery of the bottom portion 116r and sandwiching the pair of opposed openings 116a, 116a from both sides. The bottom portion 116c sandwiched between the slits 116b is provided on the front side of the bottom portion 116c so as to be separated from the cylindrical portion 116z in the axial direction, and has a notch-like portion 116d provided continuously to the adjacent slit 116b. . The bottom portion 116c is a peninsula portion that is supported so as to be flexible in the axial direction by a portion 116p excluding the bottom portion 116c and the slit 116b at the periphery of the bottom portion 116r. An arc-shaped convex portion 116s protruding rearward is provided on the peripheral edge portion of the rear end surface of the peninsula portion 116c.

  Further, as shown in FIG. 21, on the inner circumferential surface in the middle of the axial direction of the cylindrical portion 116z of the main body portion 116x, a click tooth portion 116f that is a protrusion protruding inward (axial center side) and extending in the axial direction, A plurality are provided along the circumferential direction. The click tooth portion 116f is for click engagement with the female screw member 105 in the rotational direction around the axis.

  The rear peripheral wall of the front half of the main body 116x is provided with a front annular step surface 116g on its inner peripheral surface, and a rear annular shape at a position behind the front annular step surface 116g. A step surface 116h is provided, and the inner peripheral surface of the main body 116x has a smaller diameter as it goes rearward through the annular step surfaces 116g and 116h. In addition, a pair of front openings 116i communicating between the inside and the outside are provided on the rear peripheral wall of the front half of the main body 116x so as to face each other, and the inside and outside communicate with each other at positions separated from the rear side of the pair of front openings 116i. A pair of rear openings 116j are provided to face each other. The front opening 116i is opened so that the rear end surface thereof is flush with a part of the front annular step surface 116g, and the rear opening 116j is a part of the rear annular step surface 116h having the rear end surface. It is opened so that it can be connected to the same plane.

  Further, a front-side arc-shaped convex portion 116k projecting inward (axial center side) is provided on the peripheral wall portion along the inner edge on the front end side of the front opening 116i, and along the inner edge on the front end side of the rear opening 116j. The peripheral wall portion is provided with a rear-side arc-shaped convex portion 116m projecting inward. The front arcuate convex portion 116k is for engaging the filling member 104 in the axial direction, and the rear arcuate convex portion 116m and the rear annular step surface 116h are axially connected to the female screw member 105. For engaging in a direction.

  In addition, the cylindrical portion on the distal end side of the main body portion 116x has a shape in which the inner and outer diameters are enlarged through the inner peripheral step surface 116n and the outer peripheral step surface with respect to the rear cylindrical portion. This inner circumferential step surface 116n is for engaging the filling member 104 in the axial direction.

  The shaft body 116y has the same configuration as that of the shaft body 16y of the first embodiment, and a plurality of protrusions 116e provided in the circumferential direction and extending in the axial direction constitute one of the rotation prevention portions (rotation prevention mechanisms) 150. It is a detent.

  As shown in FIG. 18, the intermediate member 102 and the rotation stopper member 116 are inserted into the main body cylinder 101, and as shown in FIG. 19, the bottom portion of the intermediate member 102 is positioned with respect to the bottom of the main body cylinder 101. The engagement claw piece 101a of the main body cylinder 101 passes through the opening 102a of the intermediate member 102 in a state where the arcuate convex portion 116s of the rotation stop member 116 is in contact with the bottom of the intermediate member 102, and the engagement claw When the claw 101c enters the opening 116a of the anti-rotation member 116 while the piece 101a bends inward (axially), the engaging claw 101a is flexible when the claw 101c passes through the opening 116a of the anti-rotation member 116. The claw portion 101c comes into close contact with the front surface of the intermediate member 102 to engage the intermediate member 102 in the axial direction and the engaging claw piece 101a is the opening 1 of the rotation stop member 116. It engages in the axial about the rotation direction 6a, thereby, the rotation stopping member 116 and intermediate member 102 is rotatably and axially undetachable mounted synchronized to the main body tube 101.

  Here, the peninsula portion 116c of the rotation stop member 116 is configured to be flexible in the axial direction by providing the rotation stop member 116 with a notch 116d and a slit 116b. By this, the main body cylinder 101 is pressed without backlash.

  As shown in FIGS. 14 and 17, the moving body 106 is configured in a substantially cylindrical shape, and has a flange portion 106 a on the outer peripheral surface on the distal end side, similarly to the moving body 6 of the first embodiment. A male screw 106b that constitutes one of the screwing portions (screwing mechanism) 109 is provided along the axial direction on the outer peripheral surface on the rear side of 106a, and protrudes radially inwardly on the inner peripheral surface. A plurality of protrusions 106 d that are arranged and extend in the axial direction are provided as rotation stoppers that constitute the other of the rotation stopper (rotation prevention mechanism) 150.

  As shown in FIG. 14, the moving body 106 is externally inserted into the shaft body 116 y of the rotation preventing member 116, and the protrusion 106 d enters between the protrusions 116 e and 116 e of the shaft body 116 y of the rotation stopping member 116. It is engaged with the rotation stop member 116 so as to be able to rotate synchronously and move in the axial direction.

  The piston 107 is attached to the tip of the moving body 106 through the piston support member 108 so as not to move in the axial direction.

  As shown in FIGS. 22 to 24, the female screw member 105 includes an outer cylindrical portion 105a configured in a substantially cylindrical shape, and as shown in FIG. 24, the female screw member 105 is connected to the distal end side of the outer cylindrical portion 105a. An inner tube portion 105b having a smaller diameter than the portion 105a is provided.

  As shown in FIGS. 22 and 23, on the outer peripheral surface of the distal end portion of the outer cylindrical portion 105a of the female screw member 105, a protrusion 105f extending in the axial direction engages the filling member 104 in the rotational direction around the axis. As a thing, multiple are provided along the circumferential direction.

  Further, as shown in FIG. 24, a pair of slits 105n extending in the axial direction and extending in the axial direction to divide the inner cylindrical portion 105b into two parts are provided on both sides of the axial line, as shown in FIG. It has been. On the inner peripheral surface of the front half of the inner cylinder portion 105b divided into two by the slits 105n and 105n, a female screw 105j constituting the other of the screwing portion (screwing mechanism) 109 is formed in a semicircle by the slits 105n and 105n. It is provided so as to be divided into arcs.

  Further, as shown in FIGS. 22 to 24, on the outer peripheral surface in the middle of the axial direction of the outer cylindrical portion 105a of the female screw member 105, an arcuate convex portion 116m on the rear side of the rotation stopping member 116 and a circular circle on the rear side. A flange 105c for axially engaging the annular step surface 116h is provided, and a groove 105m for mounting the O-ring 111 shown in FIG. 14 is provided on the outer peripheral surface behind the flange 105c. ing.

  Further, the rear side of the groove portion 105m of the outer cylindrical portion 105a of the female screw member 105 is a cylindrical portion 105t having a click tooth portion 105s. Specifically, in substantially the same manner as in the first embodiment, the click tooth base 105q having a click tooth portion 105s extending in the axial direction and having a cross-sectional shape having a climbing slope and a descending slope has a cylindrical portion. A plurality of openings 105p are provided along the circumferential direction of 105t, and are configured to be supported so as to have flexibility in the radial direction by support portions 105r protruding from the circumferential surface of the opening 105p.

  Then, as shown in FIG. 14, the female screw member 105 is externally inserted into the moving body 106 and inserted into the anti-rotation member 116, and the female screw 105j of the inner cylinder portion 105b is inserted into the male screw 106b of the moving body 106. The front end surface of the inner cylinder portion 105 b is abutted against the rear end surface of the flange portion 106 a of the moving body 106, and the flange portion 105 c of the outer cylinder portion 105 a is a circle on the rear side of the rotation stop member 116. By entering between the arc-shaped convex portion 116m and the rear annular step surface 116h and engaging the anti-rotation member 116 in the axial direction, the anti-rotation member 116 is mounted so as to be relatively rotatable and non-movable in the axial direction. Yes. In this state, the click tooth portion 105s of the female screw member 105 and the click tooth portion 116f of the rotation stopping member 116 are in a state in which click engagement is possible in the rotation direction around the axis. That is, the cylindrical portion 105t of the female screw member 105 and the cylindrical portion 116z of the rotation stopper member 116 are configured to have an overlap section in the axial direction that overlaps in the axial direction and the click tooth portions 105s and 116f click-engage with each other. Yes. Here, the click tooth portions 105s of the female screw member 105 are provided at four circumferentially equal portions, the click tooth portions 116f of the rotation stopper member 116 are provided at 16 circumferentially equal portions, and the number of clicks per rotation is determined. Although it is 16 times, various click tooth portions can be appropriately selected to adjust the discharge amount of the coating material L with one click.

  An O-ring 111 is fitted in the groove 105 m of the female screw member 105, and the main body cylinder 101 connected to the filling member 104 and the rotation stopper member 116 connected to the female screw member 105 by the O-ring 111. , Better rotation resistance occurs.

  As shown in FIGS. 14 and 17, the filling member 104 is configured in the same manner as the filling member 4 of the first embodiment except for the rear end portion and the intermediate portion in the axial direction. A discharge port (opening) 104c is provided.

  At the rear end portion of the filling member 104, an annular protrusion 104a for engaging with the arcuate convex portion 116k on the front side of the rotation stopper member 116 in the axial direction is provided. In addition, an annular protrusion 104b for axially engaging the inner peripheral step surface 116n of the rotation stopper member 116 is provided on the outer peripheral surface of the intermediate portion of the filling member 104.

  Further, on the inner peripheral surface of the rear end portion of the filling member 104, a knurl 104 e that extends over a predetermined length toward the tip end in the axial direction and is densely arranged along the circumferential direction is protruded from the female screw member 105. It is provided on the strip 105f so as to engage in the rotational direction around the axis.

  As shown in FIG. 14, the filling member 104 has a rear portion inserted into the rotation stopper member 116 and inserted into the distal end portion of the female screw member 105, and a ridge 105f of the female screw member 105 is inserted into the knurled 104e. Is engaged with the female screw member 105 so as to be able to rotate synchronously, and the front side surface of the annular protrusion 104a is located behind the arcuate convex portion 116k on the front side of the rotation stop member 116. The end surface is engaged with the end surface in the axial direction, and the rear end surface of the annular protrusion 104b is engaged with the inner peripheral step surface 116n of the rotation stop member 116 in the axial direction. It is installed so that it cannot move. That is, the filling member 104 and the female screw member 105 are rotatable relative to the main body cylinder 101 and are not movable in the axial direction. A cap 110 is detachably attached to the tip of the rotation stop member 116, and the filling member 104 is covered and protected by the cap 110.

  In the initial state of the coating material extruding container 200 having such a configuration, as shown in FIG. 14, the moving body 106 is in the retracted limit state, and the intermediate member 102 of the intermediate member 102 is passed through the body cylinder 101 made of a transparent material. The color is visible.

  In the coating material extruding container 200 in the initial state, when the cap 110 is removed by the user and the main body cylinder 101 and the filling member 104 are relatively rotated in the feeding direction, the screwing portion 109 is screwed. In cooperation with the rotation stopper 150 constituted by the protrusion 116e of the shaft body 116y and the protrusion 106d of the movable body 106 of the rotation stop member 116 that engages with the main body cylinder 101 so as to be able to rotate synchronously, As shown in FIG. 15, the moving body 106 and the piston 107 move forward, the coating material L is discharged from the discharge port 104 c of the filling member 104, and is put into use.

  When the moving body 106 moves forward, the click tooth portion 105s of the female screw member 105 and the click tooth portion 116f of the rotation stop member 116 repeatedly lock and release in the rotation direction, and a click feeling is generated, thereby causing relative rotation. The degree of advancement and the degree of advancement of the moving body 106 are detected by the user, and the coating material L can be appropriately pushed out by the click feeling, so that excessive application of the coating material L is prevented.

  After use, when the main body cylinder 101 and the filling member 104 are relatively rotated in the retraction direction, the screwing portion 109 works, and the movable body 106 and the piston are cooperated with the rotation preventing portion 150. 107 moves backward.

  When the moving body 106 is retracted, the click tooth portion 105s of the female screw member 105 and the click tooth portion 116f of the rotation stop member 116 repeatedly lock and release in the rotation direction, and a click feeling is generated, thereby causing relative rotation. The degree of the movement and the retreating state of the moving body 6 are detected by the user, and the moving body 106 is prevented from returning too much by the click feeling. By moving the moving body 106 backward, a predetermined space A is formed inside the ejection port 104c of the filling member 104, as in the first embodiment.

  When the coating material L remains in the filling member 104, the main body cylinder 101 and the filling member 104 are relatively rotated again in the feeding direction by the user in order to put the coating material L into a use state. The operation is the same as described above, and such an operation is repeated.

  Further, when the movable body 106 and the piston 107 are advanced to the maximum by the relative rotation of the main body cylinder 101 and the filling member 104 in the feeding direction, the piston 107 is brought into contact with the inner surface of the front end portion of the filling member 104 as shown in FIG. The coating material L is almost used up.

  Thus, according to the coating material extruding container 200 of the second embodiment, similarly to the first embodiment, the cylindrical portion 105t of the female screw member 105 and the cylindrical portion 116z of the rotation preventing member 116 are arranged in the axial direction. A click tooth portion 105 s that is provided in the overlap section of the cylindrical portion 105 t of the female screw member 105 and that protrudes outwardly, and a cylinder of the rotation stopper member 116 are configured to have an overlap section that overlaps and click-engages. The click tooth portion 116f provided in the overlap section of the portion 116z and projecting inward constitutes a click mechanism, and these click tooth portions 105s, 116f are rotated together with the filling member 104 and the female screw member 105. Since the click engagement is performed in synchronization with the relative rotation between the member 116 and the moving body 106 to provide a click feeling, High molding easy part accuracy of mechanisms can be implemented stably good clicking feeling.

  Note that a click tooth base 105q (see FIG. 25) that extends to the base side of the click tooth base 105q shown in FIG. 22 and also serves as the support part 105r is used, whereby the click tooth 105s can be flexed in the radial direction. Needless to say, even if the female screw member 205 having a structure to be supported is used, the same operation and effect can be obtained.

  Incidentally, in the second embodiment, the anti-rotation member 116, the intermediate member 102, and the main body cylinder 101 are separated, but the anti-rotation member 116 is assembled by integrating the main body cylinder 101 and the intermediate member 102, or the main body cylinder 101, The intermediate member 102 and the rotation stopper member 116 may be integrated. Also, the intermediate member 102 can be colored as one part by two-color injection molding, the body tube 101 can be transparent, or the body tube 101 can be made of a soft material to enhance the texture. Further, even in the first embodiment, the anti-rotation member 16 is attached to the main body cylinder 1 so as not to move in the axial direction, or the anti-rotation member 16 and the main body cylinder 1 are integrated, and the main body cylinder is used as the anti-rotation member. It is good also as combined use.

  The present invention has been specifically described above based on the embodiment. However, the present invention is not limited to the above embodiment, and in the above embodiment, the click tooth portion 5s of the female screw member 5, 105, 205 is used. , 105s are supported so as to have flexibility in the radial direction, but the click tooth portions 5s, 105s of the female screw members 5, 105, 205 and the click tooth portions 16f, 116f of the rotation stop members 16, 116 are provided. It is good also as a structure which reverses a structure and supports the click tooth | gear part of a rotation stop member so that it may have flexibility in a radial direction. From the above, in the first embodiment, the click tooth portion 5 s of the female screw member 5 or the click tooth portion 16 f of the rotation prevention member 16 has any relative relationship between the female screw member 5 and the rotation prevention member 16. Even in the positional relationship, a configuration having an axial length that can be engaged with the click tooth portion on the other side is adopted. In the above-described embodiment, the cylindrical portions 16z and 116z of the rotation stopper members 16 and 116 are positioned outside the cylindrical portions 5t and 105t of the female screw members 5, 105 and 205. The cylindrical portions 16z and 116z of the 116 may be positioned inside the cylindrical portions 5t and 105t of the female screw members 5, 105, and 205. In this case, the click tooth portion of the rotation stop member protrudes outward. The click tooth portion of the female screw member protrudes inward.

  The cylindrical portions 16z and 116z of the rotation stop members 16 and 116 only need to be opened at least on the front side, and the cylindrical portions 5t and 105t of the female screw members 5, 105 and 205 are opened at least on the rear side. It should be.

  In the above embodiment, the coating material L is particularly suitable when the coating material L is a semi-solid or soft solid such as a liquid, a jelly, a gel, or a paste including a paste. Although the containers 100 and 200 are described, the coating material is, for example, various rod-shaped cosmetics such as an eyeliner, eyebrow, lip liner, lipstick and the like, and a rod-shaped body such as a rod-shaped core such as a writing instrument. It is applicable to cases. In this case, the opening at the tip of the filling member is an opening having a size substantially the same as the size of the rod-shaped body.

  In addition, the male screw and the female screw may function in the same manner as a screw thread, such as an intermittently arranged projection group or a spiral and intermittently arranged projection group. The mating protrusion may be a continuous screw thread.

  In addition, the click mechanism of this invention can also be used as the ratchet mechanism which accepts the rotation of only one direction, combining the shape of a click tooth | gear part with an obtuse angle and an acute angle. Also in this case, at the time of rotation in one direction, the tooth portions repeat locking and releasing in the rotation direction, and a click feeling is generated.

It is a longitudinal cross-sectional view which shows the initial state of the coating material extrusion container which concerns on 1st embodiment of this invention. It is a longitudinal cross-sectional view when a filling member advances to the maximum by a user's operation from the state shown in FIG. It is a longitudinal cross-sectional view when a mobile body advances from the state shown in FIG. 2 by a user's operation, and is made into a use state. FIG. 4 is a longitudinal sectional view when the filling member is retracted from the state shown in FIG. 3 by a user operation. FIG. 5 is a longitudinal sectional view when the filling member is retracted to the maximum by the user's operation from the state shown in FIG. 4 and then the movable body is retracted to the maximum. It is a longitudinal cross-sectional view when a filling member advances to the maximum by a user's operation from the state shown in FIG. 1, and then the moving body advances to the maximum. FIG. 7 is a longitudinal sectional view when the filling member is retracted to the maximum by a user operation from the state shown in FIG. 6. It is a cross-sectional perspective view which follows the VIII-VIII line of FIG. It is a perspective view which shows the rotation stopping member in FIGS. It is a longitudinal cross-sectional view of the rotation stopping member shown in FIG. It is a perspective view which shows the female screw member in FIGS. It is a longitudinal cross-sectional view of the female screw member shown in FIG. FIG. 13 is a left side view of the female screw member shown in FIG. 12. It is a longitudinal cross-sectional view which shows the initial state of the coating material extrusion container which concerns on 2nd embodiment of this invention. It is a longitudinal cross-sectional view when a mobile body advances from the state shown in FIG. 14 by a user's operation, and is made into a use state. It is a longitudinal cross-sectional view when a mobile body advances the maximum by operation of the user from the state shown in FIG. It is a fracture | rupture exploded perspective view of the coating material extrusion container shown in FIG. It is a fracture | rupture exploded perspective view of the main body cylinder of the coating material extrusion container shown in FIG. 14, an intermediate member, and a rotation stop member. It is a fracture | rupture perspective view of the main body cylinder of the coating material extrusion container shown in FIG. 14, an intermediate member, and a rotation stop member. It is a perspective view which shows the rotation stopping member in FIGS. FIG. 21 is a cutaway perspective view of the rotation stop member shown in FIG. 20. It is a perspective view which shows the female screw member in FIGS. It is a front view of the female screw member shown in FIG. It is a XXIV-XXIV arrow line view of FIG. It is a perspective view which shows another female screw member.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1,101 ... Main body cylinder (container rear part), 3 ... Lead cylinder (container front part), 4,104 ... Filling member, 4c, 104c ... Opening, 5, 105, 205 ... Female screw member, 5j, 105j ... Female screw 5s, 105s ... click tooth part of female screw member, 5t, 105t ... cylindrical part of female screw member, 6, 106 ... moving body, 6b, 106b ... male screw, 6d, 106d ... detent of moving body, 8 ... 1st screwing part (another screwing part), 9 ... 2nd screwing part (screwing part), 16, 116 ... Anti-rotation member, 16e, 116e ... Anti-rotation of anti-rotation member (shape part) , 16f, 116f ... click tooth portion of the rotation stop member, 16z, 116z ... cylindrical portion of the rotation stop member, 50, 150 ... rotation prevention portion, 100, 200 ... application material extruding container, 109 ... screwing portion, L ... application Wood.

Claims (3)

A filling member having a cylindrical shape with an opening at the tip and filled with a coating material;
A moving body that has a male screw on the outer peripheral surface and pushes out the coating material by moving forward, and emerges from the opening;
A female screw member that has a female screw that engages with the male screw of the movable body, and that engages with the filling member in an axial rotation direction;
An anti-rotation member having a shape portion engaged with the movable body in the rotational direction around the axis and movably engaged in the axial direction;
When the filling member and the female screw member and the rotation stop member and the moving body rotate relative to each other, a screwing portion constituted by the male screw and the female screw works to move the moving body with respect to the filling member. Is a coating material extruding container that moves,
The female screw member includes a cylindrical portion that is open toward at least the rear side,
The rotation stop member includes a cylindrical portion that is open at least toward the front side and is disposed so as to have an overlap section that overlaps and engages with the cylindrical portion of the female screw member in the axial direction.
A click tooth portion projecting outward or inward from the cylindrical portion of the female screw member in the overlap section is inside or outward from the cylindrical portion of the anti-rotation member in the overlap section. A click mechanism that provides a click feeling in synchronization with the relative rotation by engaging with a click tooth portion that protrudes from the female screw member and faces the click tooth portion of the female screw member. Applying material extruding container. A screwing portion different from the screwing portion;
By the relative rotation of the container front part and the container rear part constituting the container, the another screwing part works and the filling member moves,
By the further relative rotation in the same direction, the screwing portion works and the moving body moves relative to the filling member,
The application material extruding container according to claim 1, wherein the click tooth portions engage with each other when the screwing portion is operated.   The click tooth portion of the female screw member or the click tooth portion of the anti-rotation member is connected to the click tooth portion on the other side regardless of the relative positional relationship between the female screw member and the anti-rotation member. The coating material extruding container according to claim 2, wherein the coating material extruding container has an axially long dimension capable of being engaged.

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