JP6096600B2 - Dispenser for aerosol containers - Google Patents

Description

  The present invention relates to an aerosol container in which a nozzle is formed by mounting a nozzle-side nozzle member that forms an injection port at a front end to a stem-side nozzle member that is connected to a cover member that is mounted on the aerosol container via a hinge portion. In particular, the present invention is intended to facilitate cleaning of the nozzle.

  Conventionally, as this type of aerosol container discharge tool, a single-type aerosol container discharge tool in which a nozzle is connected to one stem rising from a mounting cup of one container, and one each from a mounting cup of two containers There are known a two-stage aerosol container discharge tool in which nozzles are connected to a total of two stems rising, and an aerosol container discharge tool in which nozzles are connected to two stems rising from a mounting cup of one container.

  In such a conventional aerosol container ejection tool, when the contents remaining in the nozzle flow path after the contents are ejected, the nozzle side nozzle member is removed from the stem side nozzle member, and the nozzle side nozzle member I am trying to wash it.

  For example, in an aerosol container discharge tool described in Patent Document 1, an injection port side nozzle member is mounted on a stem side nozzle member, and an L-shaped pour-out that rises from the mounting portion and bends forward. It is comprised from the cylinder part and the operation lever part provided in a row by the mounting part.

Japanese Patent No. 4707276

  However, in the nozzle member on the injection port side described in Patent Document 1, the contents remaining in the dispensing cylinder portion cannot be easily washed away.

  The present invention has been developed to solve the above-described conventional problems, and an object thereof is to provide an aerosol container discharger capable of facilitating cleaning of a nozzle.

That is, the gist configuration of the present invention is as follows.
1. A cover member attached to the mounting cup of the aerosol container, a stem-side nozzle member connected to the cover member via a hinge portion and capable of pushing down the stem rising from the mounting cup, and attached to the stem-side nozzle member In an aerosol container discharge tool comprising an injection port side nozzle member that forms an injection port for contents at the front end,
The stem-side nozzle member includes a connection portion that forms a flow path that is connected to the stem and extends upward from the stem, and a fitting cylinder portion that forms a flow path that is connected to the flow path of the connection portion and extends forward.
The injection port side nozzle member includes an injection cylinder portion that forms a flow path that connects and fits the fitting cylinder portion from the rear end to the front end injection port from the flow passage of the fitting cylinder portion, and the injection A mounting portion that is connected to the rear of the tube portion and is attached to the connection portion;
The ejection nozzle for an aerosol container, wherein the ejection port side nozzle member is made of an elastic material that allows the contents remaining in the ejection cylinder part to be discharged by crushing the injection cylinder part .

2. The ejection device for an aerosol container according to claim 1, wherein the nozzle member on the injection port side further includes an operation lever portion provided continuously behind the mounting portion.

3. The mounting portion of the nozzle member on the injection port side is enlarged by elastically deforming the mounting portion and raising the operation lever portion with respect to the injection tube portion, and inserting the fitting tube portion and the connection portion. Said 2 aerosol container discharge tool which equips the lower part with the opening which enables.

4). The ejection port side nozzle member, said the jet pipe portion and the attachment portion and the elastic material, is insert molded article or two-color molded product of the operation lever portion is large rigid material more rigid than the elastic material, the Discharge tool for 2 or 3 aerosol containers.

  According to the present invention, the connecting portion of the stem side nozzle member is connected to the stem, the mounting portion of the injection port side nozzle member is attached to the connection portion, and the fitting cylinder portion of the stem side nozzle member is connected to the injection port side nozzle. By inserting and fitting into the injection cylinder part of the member, the contents from the stem are caused to flow down in the connection part, the flow path in the fitting cylinder part, and the flow in the injection cylinder part by pushing down the injection port side nozzle member. It can inject from the injection port of an injection cylinder part front end through a path | route. According to the present invention, since the nozzle member on the injection port side is formed of an elastic material, when cleaning, the injection cylinder part is crushed with a finger, and the contents remaining in the injection cylinder part can be easily discharged. Can do.

  Therefore, according to this invention, the discharge tool for aerosol containers which can facilitate the washing | cleaning of a nozzle can be provided.

FIG. 3 is a half cross-sectional view showing a state in which an aerosol container discharge tool according to an embodiment of the present invention is mounted on an aerosol container, with the left half from the front and the right half along A-A in FIG. 2. It is a partial cross section figure which follows BB of FIG. FIG. 3 is a partial cross-sectional view taken along the line CC in FIG. 2. It is a partial cross section figure which shows the state which rotated the stem side nozzle member of the discharge tool for aerosol containers of FIG. 1 via the hinge part according to FIG. FIG. 5 is a partial cross-sectional view showing a state in which the injection port side nozzle member is further removed from the state of FIG. 4 according to FIG. 4. FIG. 1 shows an ejection port side nozzle member of the aerosol container ejection tool of FIG. 1, (a) is a right side view, (b) is a front view, and (c) is a front view showing a state in which the ejection cylinder portion is crushed with a finger. It is. FIG. 9 is a half cross-sectional view showing a state in which an aerosol container discharge device according to another embodiment of the present invention is mounted on an aerosol container, with the left half from the front and the right half along DD in FIG. 8. FIG. 9 is a partial cross-sectional view taken along line EE in FIG. 7. FIG. 9 is a partial cross-sectional view taken along line FF in FIG. 8. It is a partial cross section figure which shows the state which rotated the stem side nozzle member of the discharge tool for aerosol containers of FIG. 7 via the hinge part according to FIG. It is a partial cross section figure which shows the state which removed the injection nozzle side nozzle member from the state of FIG. 10 according to FIG. FIG. 7 shows a nozzle member on the ejection port side of the aerosol container discharge tool of FIG. 7, (a) is a right side view, (b) is a front view, and (c) is a front view showing a state in which the spray cylinder portion is crushed with a finger. It is. It is a partial cross section figure which shows the modification of the discharge tool for aerosol containers of FIG. 7 according to FIG.

Hereinafter, with reference to FIGS. 1-6, the aerosol container discharge tool which concerns on one Embodiment of this invention is illustrated and demonstrated in detail.
In the present specification, “front” refers to the nozzle outlet side, and “rear” refers to the opposite side of the nozzle along the axis of the nozzle. Moreover, a side is the left-right direction at the time of seeing a container toward back from the front.

  As shown in FIGS. 1 to 3, the aerosol container discharge device 1 of this example includes a cover member 20, a stem side nozzle member 30, and an injection port side nozzle member 40, and mounting of two aerosol containers 50. This is a dual aerosol container discharge tool in which nozzles are connected to a total of two stems 52 that rise one by one from a cup 51.

  Each of the two aerosol containers 50 is, for example, a metal bottomed cylindrical container body 53 that is secured by, for example, tightening the outer edge of a metal mounting cup 51 and is different from each other inside. Contains various types of contents.

  The two aerosol containers 50 are connected to each other by a fixed platen 54 fitted and fixed to both the mounting cups 51. The stationary platen 54 includes a track-shaped outer peripheral wall 54 a that is undercut engaged with both outer peripheral surfaces of the mounting cup 51. Abutting pieces 54b that abut on the upper surface of the mounting cup 51 are connected to both sides of the upper end edge of the outer peripheral wall 54a.

  The cover member 20 is attached to the mounting cups 51 of the two aerosol containers 50 via the fixed plate 54. The cover member 20 includes a track-shaped peripheral wall portion 21 that surrounds the outer peripheral wall 54a of the stationary platen 54 and comes into contact with the outer peripheral surface. Locking holes 21 a that are locked to locking protrusions 54 c that protrude from both sides of the outer peripheral wall 54 a of the stationary platen 54 are formed on both sides of the inner peripheral surface of the peripheral wall portion 21.

  The upper portion of the peripheral wall portion 21 forms a dome shape having a notch in the front-rear direction, and a stem-side nozzle member 30 is connected to the notch portion via a hinge portion 22.

  The stem-side nozzle member 30 includes a connection portion 31 connected to the two stems 52. The connecting portion 31 is provided with two fitting cylinders 31a fitted to the stems 52, and a top-like cylindrical shape connected to the upper side of each fitting cylinder 31a and having a diameter smaller than that of the fitting cylinder 31a. The two connection cylinders 31b and the connection plate 31c that connects these connection cylinders 31b. Each of the two fitting cylinders 31 a is connected to a connecting plate part 32 extending rearward from the hinge part 22, and is rotatable via the hinge part 22. Reinforcing ribs 32 a extending in the front-rear direction are formed on the lower surface of the connecting plate portion 32.

Inside each connection cylinder 31b, the flow path P ₁ extending from the stem 52 upward is formed. In addition, a locking projection 31d for locking an operation lever portion 43 of a jet port side nozzle member 40, which will be described later, protrudes behind the outer peripheral surface of the connection cylinder 31b. 31 d of latching protrusions are the taper surfaces in which the rear-end side part of an upper surface inclines below toward back.

From the outer peripheral surface of each connection cylinder 31b, the fitting cylinder part 33 is extended toward the front. Inside of each fitting tube 33, the flow path P ₂ extending forward connected to the flow path P ₁ of the connecting portion 31 is formed. The thickness in the vertical direction of the portion R ₁ above the fitting cylinder portion 33 of each connection cylinder 31 b is equal to the thickness of the peripheral wall 41 a of the injection cylinder portion 41 of the injection port side nozzle member 40. Further, the thickness in the vertical direction of the portion R ₂ below the fitting cylinder portion 33 of each connection cylinder 31 b is also equal to the thickness of the peripheral wall 41 a of the injection cylinder portion 41 of the injection port side nozzle member 40.

  The fitting cylinder part 33 is inserted and fitted from the rear end 41 b of the injection cylinder part 41 of the injection port side nozzle member 40. On the outer peripheral surface in the vicinity of the tip of the fitting cylinder portion 33, a seal projection 33 a that is in liquid-tight contact with the inner peripheral surface of the injection cylinder portion 41 of the injection port side nozzle member 40 is provided.

  The injection port side nozzle member 40 is provided continuously with the injection cylinder portion 41, a mounting portion 42 that is connected to the rear of the injection cylinder portion 41 and is attached to the connection portion 31 of the stem side nozzle member 30, and a rear of the mounting portion 42. The operation lever portion 43 is made of an elastic material.

Inside each injection cylinder part 41, a flow path P ₃ is formed that connects the flow path P ₂ of the fitting cylinder part 33 to the injection port H at the front end. The two injection cylinder parts 41 are mutually connected by the connection plate 41c between the surrounding walls 41a.

  As shown in FIGS. 2, 5, and 6A, the mounting portion 42 includes a front wall 42a, an upper wall 42b, a rear wall 42c, and left and right side walls 42d. The mounting portion 42 has a lower opening 42e (opening) formed below. The lower opening 42e has a shape in which the entire lower surface of the mounting portion 42 and the lower end to the vicinity of the upper end of each side wall 42d are cut out. The cutout of each side wall 42d has an arch shape at the upper edge. The lower opening 42e is enlarged by elastically deforming the mounting portion 42 and raising the operation lever portion 43 with respect to the injection cylinder portion 41, so that the fitting cylinder portion 33 and the connection portion 31 (connection of the stem side nozzle member 30) are connected. The cylinder 31b) can be inserted into the lower opening 42e.

The upper wall 42b of the mounting portion 42, upper portion R ₁ and matable engagement hole 42f is formed from the fitting tube 33 of the connecting cylindrical body 31b.

  The operation lever portion 43 includes a plate-like operation piece 43 a extending rearward from the upper end edge of the rear wall 42 c of the mounting portion 42. A reinforcing plate 43b is provided below the front end edge of the operation piece 43a. The upper portion of the reinforcing plate 43b is connected to the rear wall 42c of the mounting portion 42. The reinforcing plate 43b and the rear wall 42c are formed with a locking hole 44 that penetrates in the front-rear direction and engages with the locking protrusion 31d formed on the connecting cylinder 31b of the stem-side nozzle member 30 described above. ing. Between the operation piece 43a and the reinforcing plate 43b, a total of three reinforcing ribs 43c having a right triangle shape in side view are formed on both side edges and the center in the left-right direction of the operating piece 43a and the reinforcing plate 43b.

  The injection port side nozzle member 40 is formed as an insert molded product or a two-color molded product using the injection cylinder portion 41 and the mounting portion 42 as an elastic material and the operation lever portion 43 as a rigid material. From the viewpoint of securing

According to such a configuration, each stem 52 is pushed down by pushing down the operation lever portion 43 of the injection port side nozzle member 40 as indicated by an arrow in FIG. 3, and the contents from each stem 52 are transferred to the connecting portion. flow path P ₁ in _31, it can be injected from the injection port H of the jet pipe unit 41 front through the flow path P ₃ of the flow path P ₂ and the injection tube portion 41 of the fitting tubular portion 33.

  Further, when removing the ejection port side nozzle member 40 for cleaning, as shown in FIG. 4, the operation lever portion 43 of the ejection port side nozzle member 40 is pulled upward so that each fitting of the stem side nozzle member 30 is performed. The combined cylinder 31a can be removed from each stem 52. Then, the mounting portion 42 of the injection port side nozzle member 40 is elastically deformed and the operation lever portion 43 is lifted up with respect to the injection tube portion 41 to enlarge the lower opening 42e, and the fitting tube of the stem side nozzle member 30 is expanded. By extracting the part 33 and the connection part 31 (connection cylinder 31b) from the lower side opening 42e, the injection port side nozzle member 40 can be removed as shown in FIG.

Thus, since the injection port side nozzle member 40 is removable, cleaning of the injection port side nozzle member 40 becomes easy. Furthermore, when washed off the jet pipe 41 contents remaining in (FIGS. 6 (a) and 6 (b) refer) in the flow path P ₃ of the injection port side nozzle member 40, the injection port side nozzle member 40 Is formed of an elastic material, the injection cylinder portion 41 can be crushed with a finger as shown in FIG. Therefore, the contents remaining in the injection cylinder part can be easily discharged.

Next, with reference to FIGS. 7-12, the aerosol container discharge tool which concerns on other embodiment of this invention is illustrated and demonstrated in detail.
As shown in FIGS. 7 to 9, the aerosol container discharge device 1 ′ of this example includes a cover member 200, a stem-side nozzle member 300, and an injection-portion-side nozzle member 400, and includes one aerosol container 500. It is an aerosol container discharge tool in which a nozzle is connected to two stems 502 that rise from a mounting cup 501.

  The aerosol container 500 is, for example, a metal body having a bottomed cylindrical container body 503, which is fixed by, for example, tightening the outer edge of a metal mounting cup 501 (the wound portion becomes an annular edge 501a). There are two types of contents inside. In addition, the aerosol container 500 has a total of two stems 502 connected to the storage spaces for the respective contents, and a projection 501b having a track shape in plan view is mounted at the center of the mounting cup 501. The two stems 502 protrude in a lump from the middle step 501c of the cup 501. Note that the shape of the protrusion 501b in plan view may be rectangular or elliptical.

  The cover member 200 is attached to the mounting cup 501 of the aerosol container 500. In this example, the cover member 200 is directly attached to the annular edge 501a of the mounting cup 501, but the cover member 200 may be attached via a fixed plate attached to the annular edge 501a. .

  The cover member 200 includes a peripheral wall 201 having an outer shape substantially the same diameter as the outer peripheral surface of the aerosol container 500. The upper part of the peripheral wall 201 forms a dome shape having a notch in the front-rear direction, and a lower wall 202 covering the middle step part 501c of the mounting cup 501 is provided in the rear region of the notch part through the inner side wall 201a. It is suspended from 201. A vertical rib 201b is projected from the upper front portion of the inner peripheral side surface of the inner side wall 201a.

  Positioning walls 202 a that abut on both side surfaces in the longitudinal direction of the protrusions 501 b of the mounting cup 501 are erected on the inner peripheral side edge of the lower wall 202. On the outer peripheral side of the positioning wall 202 a, an inner wall 202 b that abuts on the upper surface of the annular edge 501 a of the mounting cup 501 is suspended from the lower wall 202. A vertical wall 202c having a circular arc shape in a plan view extending up from the upper surface of the protrusion 501b of the mounting cup 501 is erected from the lower wall 202 at the outer peripheral side edge of the lower wall 202, which is the outer peripheral side of the inner wall 202b. . Further, an outer wall 203 that is detachably locked to the lower edge of the peripheral surface of the annular edge 501 a of the mounting cup 501 is suspended from the peripheral wall 201 and the lower wall 202 on the outer peripheral side of the inner wall 202 b.

  A stem-side nozzle member 300 is connected to a front region of the above-described cutout portion of the peripheral wall 201 via a hinge portion 204.

  The stem-side nozzle member 300 includes a connection portion 301 including a fitting cylinder 301a, a connection cylinder 301b, and a connection plate 301c. In the stem-side nozzle member 300 of this example, a lateral rib 301e protruding toward the opposed inner side wall 201a is provided at the lower end of the outer peripheral surface of each fitting cylinder 301a, and the outer peripheral surface of the connecting cylinder 301b is left and right and rearward. 1 has the same configuration as the connecting portion of the example described above with reference to FIGS. 1 to 6 except that the locking projection 301d is formed at the center in the left-right direction.

  The injection port side nozzle member 400 includes an injection cylinder portion 401, a mounting portion 402, and an operation lever portion 403, and is made of an elastic material. As shown in FIGS. 8, 11, 12 (a), and 12 (b), the injection port side nozzle member 400 of this example has different shapes of the lower opening 402 e and the fitting hole 402 f of the mounting portion 402. Except that the locking hole 404 is formed at the center in the left-right direction, it has the same configuration as the nozzle member 400 of the injection port side in the example described above with reference to FIGS.

  The injection port side nozzle member 400 of this example can also be formed as an insert molded product or a two-color molded product using the injection cylinder portion 401 and the mounting portion 402 as an elastic material and the operation lever portion 403 as a rigid material. It is preferable from the viewpoint of securing the rigidity of 403.

According to such a configuration, each stem 502 is pushed down by pushing down the operation lever portion 403 of the ejection port side nozzle member 400 as indicated by an arrow in FIG. 9, and the contents from each stem 502 are transferred to the connecting portion. flow path _{P 1} in 301, it can be injected from the injection port H of the jet pipe 401 front end through the flow channel _{P 3} of the flow path _{P 2} and the injection tube portion 401 of the fitting tube 303.

  Further, when removing the ejection port side nozzle member 400 for cleaning, as shown in FIG. 10, the operation lever portion 403 of the ejection port side nozzle member 400 is pulled upward so that each fitting of the stem side nozzle member 300 is performed. The combined cylinder 301a can be detached from each stem 502.

  Then, the operation lever portion 403 is further lifted, the horizontal rib 301e provided on the stem side nozzle member 300 is brought into contact with the vertical rib 201b provided on the inner side wall 201a of the cover member 200, and the operation lever portion 403 is further moved forward. The mounting portion 402 of the ejection port side nozzle member 400 is elastically deformed simply by pulling it upward, and the lower opening 402a is expanded so as to lift the operation lever portion 403 with respect to the ejection cylinder portion 401, and the stem side nozzle member 300 is expanded. The fitting cylinder part 303 and the connection part 301 (connection cylinder body 301b) can be extracted from the lower opening 402a. As a result, as shown in FIG. 11, the ejection port side nozzle member 400 can be removed.

As described above, since the ejection port side nozzle member 400 is removable, the ejection port side nozzle member 400 can be easily cleaned. Further, the injection tube 401 of the injection port side nozzle member 400 (FIG. 12 (a) and 12 see FIG. 12 (b)) when the wash the contents remaining in the flow path _{P 3} in the injection port side nozzle member 400 Is formed of an elastic material, the spray cylinder 401 can be crushed with a finger. Therefore, the contents remaining in the injection cylinder part can be easily discharged.

  As a modification of this example, it is also possible to use an ejection port side nozzle member 400 ′ as shown in FIG. 13 instead of the ejection port side nozzle member 400. The ejection port side nozzle member 400 ′ has the same configuration as the ejection port side nozzle member 400 described above except that the structure of the mounting portion 402 is different.

  The mounting portion 402 of the injection port side nozzle member 400 'of this example includes a bottom wall 402g in addition to the front wall 402a, the upper wall 402b, the rear wall 402c, and the left and right side walls 402d. The front wall 402a is connected to the side wall 402d via an opening / closing hinge 402h so that a space surrounded by these walls can be opened / closed from the front. An opening / closing lever 406 having a locking claw 405 at the front end is swingably connected to the side wall 402d opposite to the side on which the opening / closing hinge 402h is provided, and the front wall 402a is locked to the locking claw 405. The nail | claw 407 to be projected is protrudingly provided.

The bottom wall 402 g, by opening the front wall 402a via an on-off hinge 402h, fitting tube 303 the lower portion _{R 2} of the insertable lower insertion hole 408 from each connection cylinder 301b is formed Has been. Moreover, also the upper wall 402b, closing hinge 402h by opening the front wall 402a through a fitting cylinder 303 from the upper portion _{R 1} of insertable upper insertion hole 409 of the connection cylindrical body 301b is formed Has been.

  With such a configuration, the ejection port side nozzle member 400 ′ is formed of an elastic material to facilitate cleaning, while the ejection port side nozzle member 400 ′ is connected to the stem side nozzle member 300 during use. It can be firmly fixed to the part 301. During cleaning, the locking lever 406 is pressed in the direction indicated by the linear arrow in FIG. 13 to release the locking claw 405 and the claw 407, and the front wall 402a is moved through the opening / closing hinge 402h. The nozzle member 400 ′ can be easily removed by rotating and opening in the direction indicated by the arc-shaped arrow in FIG.

  The above description shows only one embodiment of the present invention, and various modifications can be made within the scope of the claims. For example, in the above-described example, the case of the dual-type aerosol container discharge tool and the case of the aerosol container discharge tool in which the nozzles are connected to the two stems rising from the mounting cup of one container have been described. It is also possible to use a single-type aerosol container discharge tool in which a nozzle is connected to one stem rising from a mounting cup of one container. In this case, for example, the stem-side nozzle member may be provided with one connection portion and one fitting cylinder, and the injection-portion-side nozzle member may be provided with one injection cylinder portion.

1,1 ′ Dispensing tool for aerosol container 20,200 Cover member 20
21 peripheral wall portion 21a locking hole 22 hinge portion 30, 300 stem side nozzle member 31, 301 connecting portion 31a, 301a fitting cylinder body 31b, 301b connecting cylinder body 31c, 301c connecting plate body 31d, 301d locking protrusion 32, 302 Connecting plate portion 32a, 302a Reinforcing rib 33, 303 Fitting tube portion 33a, 303a Seal projection 40, 400, 400 ′ Injection port side nozzle member 41, 401 Injection tube portion 41a, 401a Peripheral wall 41b, 401b Rear end 41c, 401c Connection plate 42, 402 Mounting portion 42a, 402a Front wall 42b, 402b Upper wall 42c, 402c Rear wall 42d, 402d Side wall 42e, 402e Lower side opening (opening)
42f, 402f Fitting hole 43, 403 Operation lever part 43a, 403a Operation piece 43b, 403b Reinforcement plate 43c, 403c Reinforcement rib 44, 404 Lock hole 50, 500 Aerosol container 51, 501 Mounting cup 52, 502 Stem 53, 503 Container body 54 Fixing plate 54a Outer peripheral wall 54b Contact piece 54c Locking protrusion 201 Peripheral wall 201a Inner side wall 201b Vertical rib 202 Lower wall 202a Positioning wall 202b Inner wall 202c Vertical wall 203 Outer wall 204 Hinge part 301e Horizontal rib 402g Bottom wall 402h Opening and closing hinge 405 engaging claw 406 closing lever 407 claw 408 lower insertion hole 409 upper insertion hole 501a annular edge 501b protrusions 501c middle portion P _{1, P} 2, _{P 3} the flow path R ₁ connected cylinder upper than the fitting tube portion moiety R ₂ connecting tube Lower portion H injection port than the fitting tube portion of

Claims (4)

A cover member attached to the mounting cup of the aerosol container, a stem-side nozzle member connected to the cover member via a hinge portion and capable of pushing down the stem rising from the mounting cup, and attached to the stem-side nozzle member In an aerosol container discharge tool comprising an injection port side nozzle member that forms an injection port for contents at the front end,
The stem-side nozzle member includes a connection portion that forms a flow path that is connected to the stem and extends upward from the stem, and a fitting cylinder portion that forms a flow path that is connected to the flow path of the connection portion and extends forward.
The injection port side nozzle member includes an injection cylinder portion that forms a flow path that connects and fits the fitting cylinder portion from the rear end to the front end injection port from the flow passage of the fitting cylinder portion, and the injection A mounting portion that is connected to the rear of the tube portion and is attached to the connection portion;
The ejection nozzle for an aerosol container, wherein the ejection port side nozzle member is made of an elastic material that allows the contents remaining in the ejection cylinder part to be discharged by crushing the injection cylinder part .   2. The aerosol container discharge tool according to claim 1, wherein the injection-port side nozzle member further includes an operation lever portion that is continuously provided behind the mounting portion.   The mounting portion of the nozzle member on the injection port side is enlarged by elastically deforming the mounting portion and raising the operation lever portion with respect to the injection tube portion, and inserting the fitting tube portion and the connection portion. The aerosol container discharge device according to claim 2, further comprising an opening to be provided below. The ejection port side nozzle member, said the jet pipe portion and the attachment portion and the elastic material, is insert molded article or two-color molded product of the operation lever portion is large rigid material more rigid than the resilient material, wherein Item 4. An aerosol container discharge tool according to Item 2 or 3.

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