JP2018140792A - Discharge container - Google Patents

Abstract

PROBLEM TO BE SOLVED: To propose a discharge container which is applicable to contents of low viscosity and which has good usability.SOLUTION: A discharge container includes: a cylindrical container body 2; a discharge member 40 attached to one end of the container body 2; a partition member 20 fitted in an inner peripheral surface of the container body 2 being separated from the discharge member 40; and a porous body 30 stored in a storage chamber R formed between the discharge member 40 and the partition member 20 out of the inside of the container body 2, and capable of including fluid contents. The contents included in the porous body 30 is discharged via the discharge member 40. The porous body 30 can be compressed in a cylinder axial direction of the container body 2, and a pressing mechanism D for compressing the porous body 30 via the partition member 20 is provided closer to the other end of the container body 2.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a discharge container, and more particularly to a container having a mechanism for feeding out contents by rotating a part of the container.

  As this type of container, a container body in which the mouth and neck stand up from the trunk portion of the lower surface opening, a partition member that hangs a cylinder from a partition plate that is slidably fitted inside the trunk portion, An operation member in which a rod portion raised from a bottomed fitting cylinder that is movably fitted is screwed into the cylindrical body, and the cylindrical body is fastened to the container body. In addition, there is known one in which one of the gripping portions is rotated with respect to the other to raise the partition member and send the contents to the discharge port on the upper part of the container body (Patent Document 1).

JP2010-6450

The delivery mechanism as described above is generally designed so that solid contents (such as lip balm) are fed out and applied to the target surface.
As an example of applying the delivery mechanism to a container that discharges the low-viscosity contents from the mouth and neck part having a smaller diameter than the trunk part, there is a container of Patent Document 1, but for example, if the container body is laid down accidentally during use, There is an inconvenience that many contents flow out.
When it is desired to store soft contents, a tube container can be used instead of the feeding container, but the usability is greatly changed. For example, the tube container cannot be used in an inverted state.

  An object of the present invention is to propose a discharge container that can be applied to low-viscosity contents and is easy to use.

The first means includes a cylindrical container body 2,
A discharge member 40 attached to one end of the container body 2;
A partition member 20 fitted to the inner peripheral surface of the container body 2 apart from the discharge member 40;
A porous body 30 that is contained in a storage chamber R formed between the discharge member 40 and the partition member 20 in the interior of the container body 2 and can contain a fluid content.
A discharge container configured to discharge the content contained in the porous body 30 through the discharge member 40,
The porous body 30 is compressible in the cylinder axis direction of the container body 2;
A pressing mechanism D for compressing the porous body 30 via the partition member 20 is provided near the other end of the container body 2.

  In this means, the discharge member 40 shown in FIG. 1 is attached to one end of the cylindrical container body 2, and the inside of the container body 2 is placed in a storage chamber R formed between the discharge member 40 and the partition member 20. A porous body 30 that can be impregnated with the contents and compressible in the cylinder axis direction is housed. And the pressing mechanism D which can compress the porous body 30 via the partition member 20 is arrange | positioned. Accordingly, the content can be easily discharged from the discharge member 40 by operating the pressing mechanism D. Since the contents are contained in the porous body 30, the contents do not immediately flow out even if the container body 2 is laid down accidentally or in an inverted state.

The “ejection member” may be of any structure as long as it can eject the contents. In the illustrated example, a so-called roll-on type discharge tool in which a rolling ball is rotatably incorporated in the discharge port is described, but a simple discharge port may be used.
The “porous body” may be any material that can keep the fluid content inside and can supply the content to the outside by compression. The sponge described below is a suitable example, but is not necessarily limited thereto.
The “pressing mechanism” does not need to be a mechanism that sends out contents by a rotating operation, and may be configured to manually perform a pushing operation using a pushing rod or the like, for example.
The “content” is not limited to a liquid as long as it has low viscosity and fluidity.

The second means includes the first means, and the porous body 30 is formed of an impregnated body that can be elastically stretched and impregnated with contents,
The pressing mechanism D is formed so that the pressing to the porous body 30 is released and the porous body 30 can be elastically restored from the compressed state.

  In this means, it is proposed that the porous body 30 is formed of an impregnated body that can elastically expand and contract, and that the pressing mechanism D is formed so that the pressing of the porous body 30 can be released. Specifically, when a part of the container is rotated and the partition member 20 is fed out to the discharge member 40 side, the part may be rotated in the reverse direction and the partition member 20 may be fed back. According to this means, when the porous body 30 is compressed too much and excessive contents flow into the discharge member 40 side, the excess content is a porous body that is impregnated by releasing the pressure of the porous body 30. Can be sucked back into the body 30.

The third means includes the first means or the second means, and has a gripping cylinder portion 10a located on the other end side of the container body 2 and is rotatably supported inside the container body 2. Shaft cylinder member 10 is provided,
The pressing mechanism D converts the rotational force into a push-up force of the partition member 20 by rotating one of the shaft tube member 10 and the container body 2 around the tube axis of the container body 2. This is a feeding mechanism configured as follows.

  In this means, as the pressing mechanism D, a feed-out mechanism that presses by the action of a screw by rotating one of the shaft tube member 10 and the container body 2 with respect to the other is employed. In the configuration of the present invention in which the porous body 30 is impregnated with the contents, the method of pushing in using the above-mentioned push rod does not know the amount of force when the user compresses the porous body 30 at the first use, There is a possibility that excessively strong compression may cause a larger amount of contents to be discharged than expected. In this means, since the structure which converts rotational force into pushing force is employ | adopted, such inconvenience does not occur easily.

The fourth means includes a third means, and a plurality of elastic pieces 12 protruding from one of the outer surface of the shaft tube member 10 and the inner surface of the container body 2 are provided at equal intervals on the other side. The sound emitting means C is configured by engaging with the engagement rib 9 so as to be able to get over.

  In this means, sound producing means C comprising elastic pieces 12 protruding from one of the outer surface of the shaft tube member 10 and the inner surface of the container body 2 shown in FIG. 2, and a plurality of engaging ribs 9 attached to the other at equal intervals. Has proposed. Thereby, the rotation amount can be accurately grasped by counting the generated sound.

The fifth means includes any one of the first means to the fourth means, and the discharge member 40 fits one half 42a of the plug cylinder 42 to one end side of the container body 2, A stopper rib 44 is attached to the distal end of the stopper tube 42, and the inner stopper 41 is formed by projecting a receiving seat 48 from the inner surface of the stopper tube 42 away from the stopper rib 44;
A rolling ball 50 is rotatably provided between the locking rib 44 and the receiving seat 48.

  As shown in FIG. 1, this means proposes a so-called roll-on type discharge member in which a rolling ball 50 is rotatably incorporated in an inner plug 41. As a result, the low-viscosity contents can be taken out via the rolling balls and applied to the target surface. As a matter of course, in the inverted state as shown in FIG. 3, even in the upright state shown in FIG. 1, the rolling ball 50 rolls along the target surface T, so that the liquid accumulated on the porous body 30 side Since it adheres to the surface of 50 and carries to the target surface T, it can apply | coat without any trouble and is convenient.

The sixth means has fifth means and is configured such that the rolling ball 50 sandwiched between the locking rib 44 and the receiving seat 48 contacts the porous body 30.

  In this means, as shown in FIG. 4, since the rolling ball 50 sandwiched between the locking rib 44 and the seat 48 is in contact with the porous body 30, the content contained in the porous body 30 is small. However, the contents directly attached from the porous body 30 are moved to the target surface while the rolling ball 50 rolls on the target surface, so that the content can be reliably applied.

According to the first aspect of the invention, since the contents are stored in the porous body 30, even when the container body 2 is inverted or laid down, a low-viscosity liquid immediately leaks out. Since the liquid is pushed out by compressing the porous body 30 with the pressing mechanism, the liquid content can be quickly taken out by operating the pressing mechanism D.
According to the invention relating to the second means, the porous body 30 is formed of an impregnated body that can elastically expand and contract and can impregnate the contents, and the pressing mechanism can release the compression of the porous body 30. Since it comprised, when the porous body 30 is compressed too much, the excess content can be sucked back to the porous body 30 from the discharge member 40 side by releasing the said compression.
According to the invention relating to the third means, the pressing mechanism D rotates the other of the shaft cylinder member 10 and the container body 2 around the cylinder axis of the container body 2, thereby applying this rotational force to the above-described rotational force. Since the feeding mechanism is configured to convert the partition member 20 into a push-up force, it is easy to accurately take out an appropriate amount of liquid according to the number of rotations.
According to the fourth aspect of the invention, a plurality of engaging ribs in which the tips of the elastic pieces 12 protruding from one of the outer surface of the shaft tube member 10 and the inner surface of the container body 2 are provided at equal intervals on the other side. Since the sound output means C is configured by engaging with 9 so as to be able to get over, it becomes easier to sensuously grasp the amount of feed by the number of generated sounds, and the liquid supply amount can be set more appropriately.
According to the fifth aspect of the invention, the discharge member 40 is formed by the inner stopper 41 attached to one end of the container body 2 and the rolling balls 50 built in the inner stopper 41. The contents can be applied to the target surface in either the standing state or the inverted state.
According to the sixth aspect of the invention, since the rolling ball 50 sandwiched between the locking rib 44 and the receiving seat 48 is configured to contact the porous body 30, the liquid contained in the porous body 30. Can be reliably taken out via the rolling ball 50 that rotates in a contact state, and there is no need to operate the pressing mechanism D for every take-out operation.

It is a longitudinal cross-sectional view of the discharge container which concerns on 1st Embodiment of this invention. It is a cross-sectional view of the container of FIG. It is explanatory drawing of the use condition of the container of FIG. It is a longitudinal cross-sectional view of the principal part of the discharge container which concerns on 2nd Embodiment of this invention. It is explanatory drawing of the use condition of the container of FIG.

  1 to 3 show a discharge container according to a first embodiment of the present invention. The discharge container includes a container body 2, a shaft tube member 10, a rotating body 16, a partition member 20, a porous body 30, a discharge member 40, and a cap 52. Each of these members can be formed of, for example, a synthetic resin.

As shown in FIG. 1, the container body 2 is formed of a cylindrical body 4 and a bottom member 8.
The cylindrical body 4 is a cylindrical wall having both upper and lower openings. In the illustrated example, the cylindrical body 4b has a straight cylindrical shape that is long in the vertical direction, a mouth and neck portion 4a having a smaller diameter than the intermediate cylindrical portion 4b, and a larger inner diameter than the intermediate cylindrical portion. Leg cylinder portion 4c. At least one engagement protrusion 6 is provided vertically in the lower half of the intermediate cylinder 4b.
The bottom member 8 stands up from the outer peripheral portion of the ring-shaped bottom plate portion 8b with the fitting tube portion 8a fitted to the inner surface of the leg tube portion 4c.
In the illustrated example, a retaining means f formed by a lateral rib and a lateral groove is provided on the opposing surfaces of the leg cylinder part 4c and the fitting cylinder part 8a. Although not shown in the drawings, the leg tube portion 4c and the fitting tube portion 8a are provided with rotation retaining means formed by vertical ribs and vertical concave stripes.
Further, a tapered plate portion 8c having a small upper end is projected from the inner peripheral end of the bottom plate portion 8b, and a hanging cylinder portion 8d is suspended from the outer peripheral end of the bottom plate portion 8b. The hanging cylinder part 8d in the illustrated example is formed to have the same outer diameter as the leg cylinder part 4c.
A plurality of hooking ribs 9 are vertically arranged at equal intervals on the inner surface of the hanging cylinder portion 8d.
A sliding contact rib 8f is provided around the inner end of the bottom surface of the bottom plate portion 8b.
An insertion port (not shown) for inserting a locking projection 14 described later is formed at an appropriate position of the tapered plate portion 8c.

The shaft tube member 10 is attached to the bottom member 8 of the container body 2. The shaft cylinder member 10 shown in the figure has a gripping cylinder part 10a having the same outer diameter as the hanging cylinder part 8d, and the lower annular plate part 10b from the upper end of the gripping cylinder part 10a and the lower annular plate part 10b. The upper annular plate portion 10d protrudes inward in a flange shape from the upper end of the stepped cylindrical portion 10c rising from the inner peripheral end. In the illustrated example, an engaging recess 11 is provided around the outer edge of the upper end surface of the gripping cylinder portion 10a, and the lower end portion of the hanging cylinder portion 8d is brought close to the engaging recess 11. The sliding rib 8f of the bottom member 8 is brought into contact with the upper annular plate portion 10d to reduce the frictional resistance between the bottom member 8 and the shaft tube member 10. Further, a shaft rod portion 10e is erected from the inner periphery of the upper annular plate portion 10d.
The shaft rod portion 10e is fitted to the upper inner end of the tapered plate portion 8c and protrudes upward from the bottom member 8. A locking projection 14 is attached to the outer surface of the shaft rod portion 10e, and the locking projection 14 is locked to the upper end of the tapered plate portion 8c. A screw groove s is formed on the outer surface of the shaft rod portion 10e so as to be positioned above the locking projection 14.
The elastic piece 12 protrudes outward in the horizontal direction from the outer surface of the stepped cylinder portion 10c. The elastic piece 12 in the illustrated example has a vertical plate shape that is long horizontally.
The elastic piece 12 and the hooking rib 9 form a sound emitting means C. The sound output means C rotates the container body 2 with respect to the shaft member 10 so that the elastic piece 12 abuts on the engaging rib 9 and then bends as shown by an imaginary line in FIG. A click sound is generated when getting over the section. In addition, the said structure can be changed suitably, for example, while protruding an elastic protrusion piece from the appropriate position of the bottom member 8, you may provide the rib for hooking in the outer surface of the axial cylinder member 10. FIG.

The rotating body 16 is a member that rotates with respect to the shaft tube member 10 together with the container body 2. In the rotating body 16 of the present embodiment, a sliding cylindrical portion 16b that can slide in the vertical direction with respect to the intermediate cylindrical portion 4b is provided on an outer peripheral portion of a horizontal annular substrate 16a, and an inner peripheral portion of the annular substrate 16a. Each has a lifting cylinder portion 16d screwed to the outer surface of the shaft rod portion 10e.
In the illustrated example, the sliding cylinder portion 16b is erected from the outer peripheral portion of the annular substrate 16a, and the engagement protrusion 6 is fitted into the engagement groove 17 provided on the outer surface of the sliding cylinder portion 16b. Thus, the rotation of the rotating body 16 with respect to the container body 2 is realized. These configurations can be changed as appropriate. For example, an engaging groove may be formed at an appropriate position of the container body 2, and an engaging protrusion may be formed on the rotating body 16.
The elevating tube portion 16d may have any structure as long as it can be raised and lowered by being rotated around the shaft rod portion 10e. Although a thread may be provided in a certain range in the tube length direction, a protrusion that engages with the screw groove s of the shaft rod portion 10e may be provided at an appropriate position of the elevating tube portion 16d.
The lifting cylinder portion 16d in the illustrated example extends in the vertical direction from the inner peripheral portion of the annular substrate 16a. The lower half portion of the elevating cylinder portion 16d is thicker than the upper half portion, and the stopper 18 projects downward from the lower half portion. The stopper 18 is provided so as to contact the locking projection 14 when the rotating body 16 is at the lower limit position with respect to the shaft rod portion 10e.
A connecting tube portion 16c concentric with both the tube portions is erected from the upper surface of the annular substrate 16a and is positioned between the sliding tube portion 16b and the elevating tube portion 16d.
Further, from the lower surface of the annular substrate 16a, a cylindrical pedestal portion 16e surrounding the elevating cylinder portion 16d is suspended from the vicinity of the bottom plate portion 8b.

The partition member 20 includes a partition plate 20a that vertically partitions the intermediate tube portion 4b of the cylinder body 4, and a piston portion 20b is formed on the outer periphery of the partition plate 20a. The piston portion 20b is in sliding contact with the inner peripheral surface of the intermediate cylinder portion 4b. An engagement hole 22 is provided at the center of the lower surface of the partition plate 20a, and the mounting cylinder portion 20c is suspended from the periphery of the engagement hole. The mounting cylinder portion 20c is fitted to the connecting cylinder portion 16c. An engagement convex portion e for preventing the partition member 20 from coming off is attached to the fitting portion of both the cylindrical portions. Further, on the inner side of the mounting cylinder portion 20c, there is provided a detent rib 21 for engaging with the lifting cylinder portion 16d.
As described above, the raising and lowering cylinder portion 16d of the rotating body 16 secured to the container body 2 is screwed to the outer peripheral surface of the shaft rod portion 10e of the shaft cylinder member 10, and the connecting cylinder portion 16c of the rotating body 16 is connected. And a mounting cylinder portion 20c of the partition member 20 are fitted to form a pressing mechanism D for sending out the contents.
The upper end portion of the shaft rod portion 10e is fitted in the engagement hole 22.

The porous body 30 has a role of storing the content liquid therein, and is provided so as to be oozed out by compression operation. Furthermore, the porous body 30 of the present embodiment is formed of an elastic material (for example, sponge) that can be impregnated with the content liquid.
The porous body 30 is accommodated in a storage chamber R between the partition member 20 and a discharge member 40 described later in the container body 2 such as a sponge.
The porous body 30 of the present embodiment is formed in a columnar shape corresponding to the cylindrical hole of the cylindrical body 4 of the container body 2 and occupies almost the entire internal volume of the storage chamber R.
In the illustrated example, the lower surface 30a of the porous body 30 is in contact with the upper surface of the partition plate 20a, and the outer peripheral surface 30c of the porous body 30 is in contact with the inner surfaces of the intermediate cylinder portion 4b and the mouth neck portion 4a. Specifically, a lower notch n <b> 1 that is notched according to the shape of the upper portion of the piston portion 20 b of the partition member 20 is formed on the entire circumference of the lower outer surface of the cylindrical porous body 30. Further, an upper notch n2 that is notched in accordance with the shape of the mouth / neck portion 4a of the container body 2 and the discharge member 40 described later is formed on the entire circumference of the upper outer surface of the porous body 30. The upper notch n <b> 2 has a first upward stepped portion 32 that is close to the lower end of the mouth / neck portion 4 a and a second upward stepped portion 34 that is close to the lower end of the ejection member 40.

The discharge member 40 includes an inner plug 41 and rolling balls 50.
The inner plug 41 is formed of a plug cylinder 42 and a seat 48 formed on the inner surface of the plug cylinder.
The lower half part 42a of the plug cylinder 42 is fitted to the inner surface of the mouth / neck part 4a, and the upper half part 42b stands up above the mouth / neck part 4a. A stopper rib 44 is provided at the upper end of the inner surface of the stopper tube 42 to prevent the rolling ball from coming off, and a hook portion 46 is attached to the outer surface of the stopper tube 42 to engage with the upper end surface of the mouth neck 4a. Has been.
The receiving seat 48 has an annular projecting piece 48a that protrudes from the inner surface of the plug cylinder 42 and has an upper surface that is a concave surface having an arcuate cross section. A sliding contact ridge 48b is provided on the inner end of the upper surface of the annular protrusion 48a, and a plate-like contact ring 48c is extended inward from the annular protrusion 48a. The contact ring 48c is in contact with the upper surface 30b of the porous body 30.

  The rolling ball 50 is a member for applying the content liquid while rolling on the target surface T, and is rotatably held between the locking rib 44 of the plug cylinder 42 and the seat 48. The lower surface of the rolling ball 50 is in contact with only the sliding contact protrusion 48b, so that the rolling ball 50 can be easily rotated by reducing the frictional resistance.

  The cap 52 has a cap cylinder 56 suspended from the outer periphery of the top plate 54, and a lower portion of the cap cylinder 56 is fitted (screwed in the illustrated example) to the outer surface of the mouth neck portion 4a. A cylindrical abutment rib 58 projects downward from the center of the lower surface of the top plate 54 and abuts against the upper surface of the rolling ball 50.

In the above configuration, when the cap 52 is removed from the state of FIG. 1 and then the gripping cylinder portion 10a is supported by hand and the cylinder body 4 of the container body 2 is gripped and rotated, the bottom member 8 rotates together with the cylinder body 4, Every time the elastic piece 12 of the shaft tube member 10 gets over the engaging rib 9, a sound is generated. The user can accurately grasp the amount of rotation of the container body 2 by the number of times of this sound.
When the container body 2 is rotated with respect to the shaft tube member 10 in this manner, the rotating body 16 is also rotated together with the container body 2 by the engagement of the engaging ridge 6 and the engaging groove 17. The rotating body 16 rises with respect to the shaft tube member 10 by the screw structure between the elevating tube portion 16d and 10e.
The rotating body 16 pushes up the partition member 20 and compresses the porous body 30. As a result, the content liquid contained in the porous body 30 oozes out to the discharge member 40 side and stays between the receiving seat 48 of the discharge member 40 and the rolling ball 50.
Here, as shown in FIG. 3, when the container body 2 is inverted and the rolling ball 50 is pressed against the target surface T and moved in the in-plane direction, the rolling ball 50 rolls, and the rolling ball causes the stagnant liquid. Can be applied to the target surface T with a rolling ball.
In the illustrated example, the rolling ball is used in an inverted state. However, even in the upright state, the rolling ball is pressed against the target surface T and rolled, so that the liquid accumulated between the receiving seats 48 is rolled into the rolling ball 50. It will adhere to the surface of this and will be carried to the target surface T, and can apply | coat without trouble.
If the container body 2 is excessively rotated with respect to the shaft tube member 10, an excessive content liquid is discharged to the discharge member 40 side. In this case, the container body 2 can be rotated in the reverse direction. That's fine. If it does so, the partition member 20 will leave | separate from the discharge member 40 side in the reverse order to the above-mentioned process, and the excessive content liquid will be sucked back by the porous body 30 by the elastic recovery of the porous body 30.

  Hereinafter, a discharge container according to another embodiment of the present invention will be described. In these descriptions, the description of the same configuration as that of the first embodiment is omitted.

4 and 5 show a discharge container according to the second embodiment of the present invention. In the present embodiment, in the configuration of the discharge container of the first embodiment, the contact ring 48 c of the discharge member 40 is omitted, and the rolling balls 50 are brought into contact with the upper surface 30 b of the porous body 30. is there.
In this configuration, since the porous body 30 containing a liquid is always in contact with the rolling ball 50, the liquid that has directly contacted the rolling ball 50 from the porous body 30 adheres to the surface of the rolling ball 50 and reaches the target surface T. When the rolling ball 50 rotates along, the target surface T is reached. Therefore, it is not necessary to perform the feeding operation every time the coating operation is performed, and it is convenient to perform the feeding operation when the amount of liquid to be applied is reduced.

DESCRIPTION OF SYMBOLS 2 ... Container body 4 ... Cylindrical body 4a ... Mouth neck part 4b ... Intermediate | middle cylinder part 4c ... Leg cylinder part 6 ... Engagement protrusion 8 ... Bottom member 8a ... Fitting cylinder part 8b ... Bottom plate part 8c ... Tapered plate part
8d ... Dripping cylinder part 8f ... Sliding contact rib 9 ... Hooking rib 10 ... Shaft cylinder member 10a ... Gripping cylinder part 10b ... Lower annular plate part 10c ... Stepped cylinder part 10d ... Upper annular plate part 10e ... Shaft bar part 11 ... engagement concave part 12 ... elastic piece 14 ... locking convex part 16 ... rotating body 16a ... annular substrate 16b ... sliding cylinder part 16c ... connecting cylinder part 16d ... lifting cylinder part 16e ... cylindrical pedestal part 17 ... engaging concave groove DESCRIPTION OF SYMBOLS 18 ... Stopper 20 ... Partition member 20a ... Partition plate 20b ... Piston part 20c ... Mounting cylinder part 21 ... Rotating retaining rib 22 ... Engagement hole 30 ... Porous body 30a ... Lower surface 30b ... Upper surface 30c ... Outer peripheral surface 32 ... 1st upward Step 34 ... Second upward step 40 ... Discharge member 41 ... Inner plug 42 ... Plug barrel 42a ... One half (lower half) 42b ... Other half (upper half)
44 ... Locking rib 46 ... Bridge 48 ... Receiving seat 48a ... Annular protrusion 48b ... Sliding protrusion 48c ... Abutting ring 50 ... Rolling ball 52 ... Cap 54 ... Top plate 56 ... Cap cylinder 58 ... Abutting Rib C ... Sound output means D ... Pressing mechanism e ... Engaging projection f ... Stopping means n1 ... Lower notch n2 ... Upper notch R ... Storage chamber s ... Screw groove T ... Target surface

Claims (6)

A cylindrical container (2);
A discharge member (40) attached to one end of the container body (2);
A partition member (20) fitted to the inner peripheral surface of the container body (2) apart from the discharge member (40);
A porous body containing a fluid content stored in a storage chamber (R) formed between the discharge member (40) and the partition member (20) in the container body (2). Body (30),
With
A discharge container configured such that the content contained in the porous body (30) is discharged through the discharge member (40),
The porous body (30) is compressible in the cylinder axis direction of the container body (2),
A discharge container, wherein a pressing mechanism (D) for compressing the porous body (30) via the partition member (20) is provided near the other end of the container body (2). The porous body (30) is formed of an impregnated body that can be elastically stretched and impregnated with contents,
2. The discharge according to claim 1, wherein the pressing mechanism (D) is formed so as to release the pressing to the porous body (30) so that the porous body (30) can be elastically restored from the compressed state. container. A shaft cylinder member (10) having a gripping cylinder part (10a) located on the other end side of the container body (2) and rotatably supported inside the container body (2) is provided.
The pressing mechanism (D) rotates the other of the shaft cylinder member (10) and the container body (2) around the cylinder axis of the container body (2) to thereby apply this rotational force to the partition member. The discharge container according to claim 1 or 2, wherein the discharge container is a feed mechanism configured to convert into a pushing force of (20).   The tip of the elastic piece (12) protruding from one of the outer surface of the shaft tube member (10) and the inner surface of the container body (2) is moved over a plurality of engaging ribs (9) provided at equal intervals on the other side. 4. The discharge container according to claim 3, wherein the sound output means (C) is configured by being engaged with each other. The discharge member (40) has one half (42a) of the plug cylinder (42) fitted to one end of the container body (2), and a locking rib (44) at the tip of the plug cylinder (42). An inner plug (41) in which a receiving seat (48) protrudes from the inner surface of the plug cylinder (42) apart from the locking rib (44);
5. A rolling ball (50) rotatably incorporated between the locking rib (44) and the seat (48). Discharge container. The rolling ball (50) sandwiched between the locking rib (44) and the seat (48) is configured to contact the porous body (30). The discharge container as described.