JP6391093B2 - Metering container - Google Patents

Description

  The present invention relates to a quantitative application container.

In Patent Document 1, a large-diameter cylinder is fitted into the mouth-neck portion of the container body, and the lower portion of the cap with a crest is fitted to the outer surface of the mouth-neck portion, and an opening is formed at the center of the cap top wall. From the back side of the plug hole, the applicator is urged upward to protrude, and when the applicator is pressed against the target surface with the container body facing downward, the applicator is retracted and the internal liquid is discharged and applied. Containers are known.
This container further has an overcap that is screwed onto the outer surface of the cap so as to cover the outside of the cap, and a stopper rod is suspended from the top wall of the overcap, and when the overcap is screwed into the cap. The plug bar is provided so as to push down the applicator against the upward biasing force. Then, the piston inserted in the cylinder moves up and down in conjunction with the applicator so that a certain amount of liquid is sucked into the cylinder from the container and guided to the plug hole.

JP2003-191999

  The container of Patent Document 1 is troublesome because the overcap has to be attached and detached each time a weighing operation is performed.

  An object of the present invention is to propose an easy-to-use quantitative application container that can measure by moving an operating member up and down by rotating an operation cylinder.

The first means is
A container body 4 that stands up the mouth-and-neck part 8, and a container part 2 having a cap-like member 10 fitted to the outer surface of the mouth-and-neck part;
A cylinder 32 suspended from the mouth and neck 8 into the container body 4;
In the cylinder 32, the plunger 52, which is the lower half, is urged upward to be slidably brought into sliding movement, and the application head 60, which is the upper half, is attached to the plunger 52, and the application port 82 is provided inside the application head. An actuating member 50 provided with a continuous measuring chamber R ;
An operation cylinder 84 that is rotatably fitted to the upper part of the container part 2;
A guide groove G including an inclined groove portion GI is formed on one of the operation tube 84 and the coating head 60, and an engaging convex portion 70 is slidably inserted into the guide groove G on the other side. 84 is provided so that the actuating member 50 is moved up and down by a certain width by rotating 84 with respect to the container part 2;
The liquid in the container body 4 is sucked into the cylinder 32 through the first check valve V1 by the vertical movement of the operating member 50 with a certain width, and the coating head 60 is moved from the cylinder 32 through the second check valve V2. A fixed amount of liquid was taken into the measuring chamber R and was configured to be discharged from the coating port 82.

  As shown in FIG. 1 or FIG. 5, this means is configured such that an operation tube 84 is rotatably fitted on the upper portion of the container portion 2, and a guide groove G is provided on one side of the coating head 60 and the operation tube 84, and a guide groove is provided on the other side. Engaging protrusions 70 are formed so as to be slidably inserted into G, and the operating cylinder 84 is rotated so that the operating member 50 moves up and down a certain width. Due to this vertical movement, a fixed amount of liquid enters the measuring chamber R and can be applied from the application port 82.

The second means includes the first means, and the head body 61 in which the connection cylinder part 76 is erected from the periphery of the communication port 72 having the coating head 60 on the upper surface, and the connection cylinder part 76 is detachable. The nozzle hole of the nozzle cylinder 80 is used as the coating port 82, and the inside of the nozzle cylinder 80 is used as the measuring chamber R.

  In this means, as shown in FIG. 1 or FIG. 5, a nozzle cylinder 80 is provided in the head main body 61 of the coating head 60, and a measuring chamber R is formed inside the nozzle cylinder 80.

The third means includes the second means, and the operation cylinder 84 is arranged from the upper end of the outer cylinder part 88a that contacts the outer surface of the enclosure cylinder 85 with respect to the enclosure cylinder 85 surrounding the upper part of the container part 2. A double cylinder 88 having an inner cylindrical portion 88b suspended from the inner surface upper portion of the surrounding cylinder 85 is assembled, and a partitioning rib 86 is attached to the inner surface of the surrounding cylinder 85 at a certain distance from the lower end of the inner cylindrical portion 88b. The hanging length of the inner cylinder portion 88b is configured to change in the circumferential direction so that the above-described guide groove G is formed between the partition rib 86 and the lower end of the inner cylinder portion 88b. .

  In this means, the operation cylinder 84 is formed by the enclosing cylinder 85 shown in FIG. 1 and the double cylinder 88 assembled to the enclosing cylinder. This configuration makes it easy to ensure the depth of the guide groove G when each member is molded.

The fourth means includes any one of the first means to the third means, and the cap-shaped member 10 faces inward from the upper end of the mounting cylinder portion 12 fitted to the outer surface of the mouth neck portion 8. The flange 16 protrudes inward, and the flange 34 at the upper end of the cylinder 32 is provided so as to be sandwiched between the inward flange 16 and the mouth neck portion 8, and the outward flange 20 is provided from the outer surface of the mounting cylinder portion 12. The auxiliary cylinder portion 22 is suspended, and a cut 24 is formed in the auxiliary cylinder portion 22, and a pushing piece 26 having a distal end portion as a push button 28 is formed inside the cut,
A through hole 92 is formed in the operation cylinder 84 so that the push button 28 can be pushed through the through hole 92, and the push button 28 is engaged with the through hole 92 when the push button 28 is not pushed. It provided so that rotation of the pipe | tube 84 might be prevented.

  In this means, as shown well in FIG. 6 and FIG. 7, the pushing piece 26 is formed by drilling the slit 24 around a part of the auxiliary cylinder portion 22 except the base end portion 27 side. The push button 28 formed at the tip of the push piece 26 is provided so as to be pushed through a through hole 92 formed in the operation tube 84. When the push button 28 is not pushed in, it cannot engage with the through hole 92 and rotate the operation cylinder 84. By pressing the push button, the engagement is released and the operation cylinder 84 can be rotated.

The fifth means includes any one of the first means to the fourth means, and the guide groove G is formed in a saw blade shape in which the inclined groove portions GI and the vertical groove portions GV are alternately repeated, A lateral groove GL was provided between the inclined groove GI and the vertical groove GV.

  In this means, as shown in FIG. 2, the guide hole has a saw blade shape including the vertical groove portion GV. Thereby, the vertical groove part GV is equiangularly arranged, and since the lateral groove part GL is provided between the inclined groove part GI and the vertical groove part GV, when the fixed angle is turned, the engaging convex part remains in the horizontal groove part, The lock is applied to the up and down movement.

The sixth means includes any one of the first means to the third means, and the guide groove G is formed in a wave shape in which the inclined groove portion GI and the lateral groove portion GL are continuous.

  In this means, as shown in FIG. 8, the above-mentioned guide groove is formed in a gradually changing wave shape. This is a structure suitable for raising and lowering the actuating member 50 several times.

According to the first aspect of the invention, the guide groove G and the engaging convex portion 70 convert the rotational force applied to the operating cylinder 84 into a force that lowers the operating member 50, so that it is easy to use.
According to the invention relating to the second means, the connecting cylinder part 76 is erected from the periphery of the communication port 72 provided on the upper surface of the head body 61 of the coating head 60, and the transparent or semi-transparent fitting with the connecting cylinder part 76 is performed. Since the measuring chamber R is formed in the nozzle cylinder 80, it is easy to visually recognize the liquid in the nozzle cylinder 80. According to the third aspect of the invention, the operation cylinder 84 is attached to the inner surface of the surrounding cylinder 85. Since the guide groove G is formed between the partitioning rib 86 and the lower end of the inner cylinder portion 88b of the double cylinder 88 assembled to the surrounding cylinder 85, a sufficient groove depth can be secured.
According to the fourth aspect of the invention, since the operation cylinder 84 does not rotate in a state where the push button 28 at the tip of the pushing piece 26 is not pushed, erroneous operation can be prevented.
According to the fifth aspect of the invention, the guide groove G has a saw-tooth shape, and is locked when turned at a certain angle.
According to the sixth aspect of the invention, since the guide groove G is formed in a wave shape, when the operating cylinder 84 continues to rotate so as to raise and lower the operating member 50 several times, the lowering process and the rising process of the operating member Switching is smooth.

It is the longitudinal cross-sectional view which looked at the fixed quantity application | coating container which concerns on 1st Embodiment of this invention from the front. It is an expanded view of the principal part of the fixed quantity application container of FIG. It is an effect | action explanatory surface which shows the operation member lowering process of the fixed quantity application | coating container of FIG. It is an effect | action explanatory surface which shows the operation member raising process of the fixed quantity application | coating container of FIG. It is the longitudinal cross-sectional view which looked at the fixed quantity application | coating container which concerns on 2nd Embodiment of this invention from the front. It is the figure which abbreviate | omitted and partially drew the cross section of the fixed quantity application | coating container of FIG. It is the longitudinal cross-sectional view which looked at the fixed quantity application | coating container of FIG. 6 from the side. It is an expanded view of the principal part of the fixed quantity application container of FIG. FIG. 7 is an operation explanatory view showing a lowering process of the operation member of the quantitative application container of FIG. 6. FIG. 7 is an operation explanatory view showing an operation member rising process of the quantitative application container of FIG. 6.

  1 to 4 show a quantitative application container according to a first embodiment of the present invention. This fixed quantity application container is constituted by the container part 2, the pump device 30, the operation cylinder 84, and the overcap 100. Each of these members can be made of, for example, synthetic resin or metal.

  The container part 2 is formed of a container body 4 and a cap-shaped member 10.

  The container body 4 stands from the trunk 6 to the mouth and neck 8. The upper half of the body 6 shown in the drawing is provided so that the diameter of the first reduced diameter part 6a, the second reduced diameter part 6b, and the third reduced diameter part 6c is sequentially reduced from the bottom to the top. The structure can be changed as appropriate.

  The cap-shaped member 10 has a mounting cylinder portion 12 fitted (screwed in the illustrated example) to the outer surface of the mouth-and-neck portion 8, and projects an inward flange 16 from the upper end portion of the mounting cylinder portion 12. . A guide tube portion 18 is erected from the inner peripheral portion of the inward flange 16. Further, in the illustrated example, the mounting cylinder portion 12 is extended upward to form an extension cylinder portion 13, and the first engagement protrusion 14 is provided vertically from the outer surface of the extension cylinder portion 13 to the upper outer surface of the mounting cylinder portion 12. ing. The auxiliary cylinder part 22 protrudes downward from the vertical middle part of the mounting cylinder part 12 via the outward flange 20. The auxiliary cylinder part 22 shown in the figure is formed by suspending a large-diameter lower cylinder part 22c from a small-diameter upper cylinder part 22a through a medium-diameter intermediate cylinder part 22b. The intermediate cylindrical portion 22b is fitted to the third reduced diameter portion 6c or the lower cylindrical portion 22c to the second reduced diameter portion 6b. A retaining rib 23 is provided laterally on the outer surface of the intermediate cylinder portion 22b.

  The pump device 30 is formed by a cylinder 32, a retaining member 42, and an operating member 50.

  The cylinder 32 is inserted into the container body 4 by sandwiching a flange 34 attached to the upper end of the cylinder tube wall between the mouth neck portion 8 and the inward flange 16 of the cap-shaped member 10. . A lower portion of the cylinder tube wall is a tapered wall portion 36, and a suction pipe 38 is suspended from the tapered wall portion via a suction pipe fitting cylinder portion. A ball valve is disposed on the inner surface of the tapered wall portion to form the first check valve V1. As a preferred embodiment, a rod member (not shown) may be erected from the upper side of the ball valve and inserted into a plunger 52 described later. The lower part of the rod member may be supported on the inner surface of the cylinder.

  The retaining member 42 is a tubular member fitted to the inner surface of the upper end portion of the cylinder 32 and prevents the operating member 50 from coming off.

  The operating member 50 protrudes upward from a plunger 52 having a cylindrical piston (not shown) that slides on the inner peripheral surface of the cylinder 32 at the lower portion. The plunger of the illustrated example is formed by a first tubular body 52a and a second tubular body 52b that is fitted to the upper portion of the first tubular body 52a and extends upward.

  An application head 60 is attached to the upper part of the second tubular body 52b. The coating head 60 is formed by the head main body 61 and the nozzle cylinder 80.

  The head main body 61 hangs a small-diameter fitting cylinder portion 64 and a large-diameter hanging cylinder portion 66 from the center of the back surface of the top plate 62 into a double cylinder shape, and hangs a head peripheral wall 68 from the outer peripheral portion of the top plate 62. Yes. The fitting cylinder part 64 is fitted to the upper part of the second tubular body 52b, and the hanging cylinder part 66 is arranged to be guided by the inner surface of the guide cylinder part 18. An engaging projection 70 is provided at the lower outer surface of the head peripheral wall 68. Further, a second engagement protrusion 69 is provided vertically on the inner surface of the head peripheral wall 68. The second engaging ridge 69 abuts on the first engaging ridge 14 and functions as a detent means for the head main body 61.

  In a preferred embodiment, a communication port 72 is opened in the top plate portion inside the fitting tube portion 64, and a second check valve V <b> 2 is formed in the communication port 72. In the illustrated example, the holding cylinder part 73 projects upward from around the communication port 72, and the valve member 74 is held by the holding cylinder part 73. The valve member 74 has a shape in which a large-diameter cap-shaped portion 74b is attached to the upper end of a columnar main body 74a, and the columnar main body is loosely fitted in the holding cylinder portion with a gap. At that time, the cap-like portion 74 b is placed on the upper surface of the holding cylinder portion 73 as a valve plate, and closes the cylinder hole of the holding cylinder portion 73. When the internal pressure of the head main body 61 rises, the valve member 47 is pushed up, and the cap-like portion 74b is separated from the upper surface of the holding cylinder portion 73, whereby the second check valve V2 is opened.

  A connecting cylinder part 76 is erected from the top plate portion around the holding cylinder part 73.

  The nozzle cylinder 80 has a top cylinder shape, and has an application port 82 opened at the center of the upper end. Further, the lower part of the tube wall of the nozzle tube is formed in the enlarged diameter tube part 80 a and is fitted to the outer surface of the connecting tube part 76. Further, a seal cylinder portion 80b fitted to the inner surface of the connecting cylinder portion 76 is suspended from the vicinity of the upper end of the large diameter cylinder portion. A measuring chamber R is formed inside the nozzle cylinder 80. The nozzle cylinder is preferably formed to be transparent or translucent and provided with a display portion such as a scale.

  The operation cylinder 84 is rotatably attached to the upper part of the container part 2. In this embodiment, although attached to the auxiliary | assistant cylinder part 22 of the cap-shaped member 10, this structure can be changed suitably, for example, an auxiliary wall part is abbreviate | omitted and attached to the trunk | drum of a container body. it can.

As shown in FIG. 2, a guide groove G including an inclined groove GI is formed on the inner surface of the operation cylinder 84, and the engaging convex part 70 of the coating head 60 is inserted into the guide groove G, so that the operation cylinder The rotational force to 84 is converted to a force that lowers the operating member 50.
Unlike the illustrated example, an engagement convex portion may be provided on the inner surface of the operation cylinder, and a guide groove may be provided on the outer surface of the head peripheral wall.

  In the present embodiment, the guide groove G is formed by repeating the vertical groove portion GV, the lateral groove portion GL, and the inclined groove portion GI as one cycle, and is formed in a sawtooth shape as a whole. The vertical groove portion is disposed equiangularly (180 ° in the illustrated example), and when the engaging convex portion 70 enters the lateral groove portion GL, it remains in that state against the upward biasing force of the operating member (in the vertical direction). Locked). However, this shape can be changed as appropriate. It is important that all the vertical grooves GV have the same vertical width, so that a certain amount of liquid can be measured.

  Although the operation cylinder 84 can be in the form of a single cylinder, in the case of mold forming, there is a problem that the guide groove becomes shallow due to the problem of die cutting. In the present embodiment, the operation cylinder 84 is composed of two bodies: an enclosing cylinder 85 that surrounds the upper portion of the container portion 2 and a double cylinder 88 that is assembled to the enclosing cylinder 85. The double cylinder 88 has an outer cylinder part 88a fitted to the outer surface of the surrounding cylinder 85, and the inner cylinder part 88b that contacts the upper inner surface of the surrounding cylinder 85 from the upper end of the outer cylinder part is folded back and hung down. Become. The hanging length of the inner cylindrical portion 88b varies depending on the position in the circumferential direction. A partition rib 86 is continuously provided on the inner surface of the surrounding cylinder 85 at a predetermined interval from the lower end 90 of the inner cylinder portion 88b. The hanging length of the inner cylinder portion 88b is adjusted so that the guide groove G is formed between the lower end 90 of the inner cylinder portion 88b and the partition rib 86.

  The lower end of the surrounding cylinder 85 slides on the step between the upper cylinder part 22a and the intermediate cylinder part 22b, and the lower end of the outer cylinder part 88a slides on the step between the intermediate cylinder part 22b and the lower cylinder part 22c. Abuts in a movable manner. Further, a horizontal groove that can be slidably fitted to the retaining rib 23 provided on the outer surface of the intermediate cylinder portion 22b is provided on the lower inner surface of the outer cylinder portion 88a.

  The overcap 100 has a top tube shape, and a lower end portion is detachably fitted to the first reduced diameter portion 6a. From the center of the top wall of the overcap 100, a plug portion 102 that closes the application port 82 is suspended, and from the periphery of the plug portion 102, a nozzle holding tube that fits on the outer surface of the nozzle tube 80. 104 is suspended.

According to the above configuration, first, when the overcap 100 is removed from the state of FIG. 1, the operation tube 84 is rotated by pressing the body portion of the container body 4 by hand, the engaging convex portion 70 moves in the guide groove G. To do. When the engaging convex part 70 moves the inclined groove part GI in a guide groove, the action | operation member 50 is pushed down below. Thereby, a fixed amount of liquid enters the measuring chamber R from the cylinder 32 through the second check valve V2. Next, when the engaging convex part 70 enters the vertical groove part GV, the push-down is released and the operating member 50 is raised.
In addition, when the engagement convex part 70 exists in the horizontal groove part GL of the guide groove G, the engagement convex part 70 will remain in a horizontal groove and will be in the state locked with respect to the upward biasing force. From this state, if necessary, the operation cylinder can be further rotated, which is convenient.

  When applying the liquid, the container may be turned upside down to bring the application port 82 into contact with the target surface.

  As for the usage of this container, the liquid for one cycle of the guide groove may be applied immediately after being stored in the measuring chamber R, or the liquid for several cycles may be applied after being stored in the measuring chamber R. May be.

  Hereinafter, other embodiments of the present invention will be described. In these descriptions, the description of the same configuration as that of the first embodiment is omitted.

  5-10 has shown the fixed quantity application | coating container which concerns on 2nd Embodiment of this invention. In this embodiment, the shape of the guide groove is changed, and a pressing piece for unlocking the operating cylinder is provided on the cap-shaped member.

  The guide groove G of the present embodiment is formed in a wave shape as shown in FIG. In this shape, inclined groove portions GI whose inclination directions are reversed across the lateral groove portions GL appear alternately. In this form of the guide groove G, the operation member 50 is smoothly switched between the descending process and the ascending process.

  Further, in the present embodiment, the cap-shaped member 10 has one pushing piece 26 as shown in FIG. 6, and the operation cylinder 84 is an appropriate number (a pair in the illustrated example) of through holes for operating the pushing piece. 92.

  The through hole 92 is formed so as to penetrate the surrounding cylinder 85 and the outer cylinder part 88 a of the operation cylinder 84. The pair of through holes 92 are preferably provided at 180 ° symmetrical positions. Similarly, when three or more through-holes are provided, they may be provided at the control position.

  The pushing piece 26 is formed by cutting three sides while leaving a part of one side (base end portion 27) of the upper cylindrical portion 22a. In the illustrated example, a horizontal U-shaped slit 24 is provided. Thereby, the cylindrical wall portion in the cut becomes a pushing piece that can swing around the base end portion 27 shown in FIG. As shown in the figure, the pushing margin of the pushing piece is sufficiently taken between the pushing piece forming portion (the upper cylinder portion 22a in the illustrated example) of the auxiliary cylinder portion and the mounting cylinder portion 12. A distal end portion (referring to a portion opposite to the base end portion) of the pushing piece 26 is formed thick so as to protrude into the through hole 92. Thus, the operation cylinder 84 is locked so that it cannot be rotated. By pushing the push button 28, the push button is released from the through hole 92, and the lock is released.

  When using the container of the present embodiment, the overcap is removed from the state shown in FIG. 5, and then the push button 28 is pressed, and then the operation cylinder 84 is rotated. Then, as shown in FIG. 9, the operating member 50 is lowered, and a certain amount of liquid enters the measuring chamber R. When the operation cylinder 84 is further rotated, the operating member rises again as shown in FIG. In this state, the application port 82 may be applied to the target surface.

DESCRIPTION OF SYMBOLS 2 ... Container part 4 ... Container body 6 ... Trunk part 6a ... 1st reduced diameter part 6b ... 2nd reduced diameter part 6c ... 3rd reduced diameter part 8 ... Mouth-and-neck part 10 ... Cap-shaped member 12 ... Mounted cylinder part 13 ... Extension cylinder part 14 ... 1st engagement protrusion 16 ... Inward flange 18 ... Guide cylinder part 20 ... Outward flange 22 ... Auxiliary cylinder part 22a ... Upper cylinder part 22b ... Intermediate cylinder part 22c ... Lower cylinder part 23 ... Extraction Stopping rib 24 ... Slot 26 ... Pushing piece 27 ... Base end 28 ... Push button 30 ... Pump device 32 ... Cylinder 34 ... Bridge 36 ... Tapered wall 38 ... Suction pipe 42 ... Retaining member 50 ... Operating member 52 ... Plunger 52a ... 1st pipe body 52b ... 2nd pipe body 60 ... Application | coating head 61 ... Head main body 62 ... Top plate 64 ... Mounting cylinder part 66 ... Drooping cylinder part 68 ... Head peripheral wall 69 ... 2nd latching protrusion 70 ... Engaging convex part 72 ... Communication port 73 ... Holding cylinder part 74 ... Valve member 74a ... Main body 74b ... Cap-like part 76 ... Connecting cylinder part 80 ... Nozzle cylinder 80a ... Expanded cylinder part 80b ... Sealing cylinder part 82 ... Application port 84 ... Operation cylinder 85 ... Enclosing cylinder 86 ... Dividing rib 88 ... 2 Heavy cylinder 88a ... Outer cylinder part 88b ... Inner cylinder part 90 ... Lower end part 92 ... Through hole
DESCRIPTION OF SYMBOLS 100 ... Overcap 102 ... Plug part 104 ... Nozzle holding cylinder G ... Guide groove GI ... Inclination groove part GL ... Lateral groove part GV ... Vertical groove part P ... Packing R ... Metering chamber V1 ... 1st check valve V2 ... 2nd check valve

Claims (6)

A container body ( 4 ) that stands up the mouth-and-neck section (8), and a container section (2) having a cap-like member (10) fitted to the outer surface of the mouth-and-neck section;
A cylinder (32) suspended from the mouth and neck (8) into the container body ( 4 );
In the cylinder (32), the plunger (52), which is the lower half, is urged upward to be slidably raised and lowered, and the application head (60), which is the upper half, is attached to the plunger (52). An operating member (50) provided with a measuring chamber (R) continuous with the coating port (82) inside the head ;
An operation cylinder (84) rotatably fitted to the upper part of the container part (2),
A guide groove (G) including an inclined groove portion (GI) is inserted into one of the operation tube (84) and the coating head (60), and an engaging protrusion is slidably inserted into the guide groove (G). Forming the respective parts (70) and rotating the operation cylinder (84) relative to the container part (2) to move the operating member (50) up and down by a certain width;
The liquid in the container body ( 4 ) is sucked into the cylinder (32) through the first check valve (V 1) by the vertical movement of the operating member (50) with a certain width, and the second reverse from the cylinder (32). A fixed amount application characterized in that a fixed amount of liquid is taken into the measuring chamber (R) of the application head (60) through the stop valve (V2) and can be discharged from the application port (82). container. The coating head (60) includes a head main body (61) in which a connecting tube portion (76) is erected from the periphery of the communication port (72) on the upper surface, and a transparent or semi-finished fitting with the connecting tube portion (76). A transparent nozzle cylinder (80), the nozzle hole of the nozzle cylinder (80) is used as an application port (82), and the inside of the nozzle cylinder (80) is used as a measuring chamber ( R ) , The quantitative application container according to claim 1.   The operation tube (84) is formed from the upper end of the outer tube portion (88a) contacting the outer surface of the envelope tube (85) with respect to the envelope tube (85) surrounding the upper portion of the container portion (2). Assemble the double cylinder (88) with the inner cylinder part (88b) suspended from the upper part of the inner surface of the inner cylinder part. Rib (86) is provided, and the above-mentioned guide groove (G) is formed between the partition rib (86) and the lower end of the inner cylinder portion (88b). The quantitative application container according to claim 1, wherein the drooping length is configured to change in the circumferential direction. The cap-shaped member (10) projects an inward flange (16) inwardly from the upper end of the mounting cylinder (12) fitted to the outer surface of the mouth and neck (8), and the inward flange (16) and the mouth The collar (34) at the upper end of the cylinder (32) is provided so as to be sandwiched between the neck (8) and the outer surface of the mounting cylinder (12) is assisted through an outward flange (20). The cylinder part (22) is suspended, and a slit (24) is formed in the auxiliary cylinder part (22), and a pushing piece (26) having a distal end as a push button (28) is formed inside the slit. And
A through hole (92) is formed in the operation tube (84) so that the push button (28) can be pushed in through the through hole (92), and the push button (28) is not pushed in. The quantitative application container according to any one of claims 1 to 3, wherein 28) is provided so as to engage with the through hole (92) to prevent the operation cylinder (84) from rotating.   The guide groove (G) is formed in a saw blade shape in which the inclined groove portion (GI) and the vertical groove portion (GV) are alternately repeated, and the horizontal groove portion is provided between the inclined groove portion (GI) and the vertical groove portion (GV). The quantitative application container according to any one of claims 1 to 4, wherein (GL) is provided. The quantitative application container according to any one of claims 1 to 4, wherein the guide groove (G) is formed in a wave shape in which the inclined groove portion (GI) and the lateral groove portion (GL) are continuous.