JP2019044649A - Discharger - Google Patents

Abstract

To provide a discharger which suppresses the entering of a piton into the inside of a step portion of a cylinder, even if the piston is strongly pressed into the cylinder.SOLUTION: A discharger 1 is equipped with a stem 12; an energizing member; a discharge head 13; a piston 41; and a cylinder 42. The cylinder is equipped with an upper cylinder portion 62 which surrounds the piston; a lower cylinder portion 63 which is disposed below the upper cylinder portion, and has an inner diameter smaller than that of the upper cylinder portion; and an annular step portion 65 which connects a lower end portion of the upper cylinder portion and an upper end portion of the lower cylinder portion. An upper surface of the step portion extends gradually downward toward the outside in a diametrical direction.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a dispenser.

Conventionally, for example, as shown in Patent Document 1 below, a stem disposed movably downward in an upwardly biased state, and a discharge head mounted on the upper end of the stem and having a discharge hole for the content liquid And a cylindrical piston linked to the vertical movement of the stem, and a cylinder in which the piston is housed slidably in the vertical direction, and when the stem and the piston are moved downward with respect to the cylinder, the content fluid in the cylinder A dispenser is known which is discharged from a discharge hole through the inside of a stem.
In this dispenser, the stem first moves downward with the piston to raise the internal pressure of the cylinder, and then the stem moves downward with respect to the piston, and the liquid in the cylinder reaches the discharge head through the stem and into the discharge head It is discharged from.

JP 2008-30798 A

  In this type of dispenser, when the piston is strongly pushed into the step of the cylinder, the lower end of the piston enters the inside of the step of the cylinder so that the piston is deformed and the space between the piston and the cylinder Of the sealability of the

  The present invention has been made in consideration of such circumstances, and it is an object of the present invention to prevent the piston from entering the inside of the step portion of the cylinder even when the piston is strongly pushed into the cylinder. Do.

  In order to solve the above problems, the dispenser according to the present invention is provided with a stem disposed movably downward, a biasing member for biasing the stem upward, and an upper end portion of the stem. A discharge head having a discharge hole formed therein, a piston linked to the vertical movement of the stem, and a cylinder in which the piston is slidably housed in the vertical direction, and the stem is moved downward with respect to the cylinder The discharge device discharges the liquid content in the cylinder from the discharge hole through the stem, and the cylinder is disposed below the upper cylinder portion and the upper cylinder portion surrounding the piston. Connects the lower end of the upper cylindrical portion and the upper end of the lower cylindrical portion, and abuts when the piston is at the lowered end position. And an annular step portion, The upper surface of the parts are characterized by extending gradually downward toward the radially outer side.

  According to the dispenser of the present invention, of the cylinder, the upper surface of the step portion with which the piston abuts gradually extends downward as it goes radially outward. With this configuration, when the piston is strongly pressed against the step during priming or when the content liquid is discharged, this pressed portion is displaced radially outward along the upper surface of the step Force to work. Therefore, even when the piston is strongly pushed into the cylinder, it is possible to prevent the piston from entering radially inward of the step. In addition, since deformation of the piston directed radially inward of the stepped portion is suppressed, it is possible to suppress deterioration in sealability between the piston and the cylinder. Furthermore, the sealing performance can be further enhanced by pressing the piston against the inner peripheral surface of the cylinder by the radially outward force acting on the piston.

  Here, at least a portion of the inner circumferential surface of the stepped portion connected to the upper surface of the stepped portion, a tapered surface may be formed which gradually reduces its diameter toward the lower side.

  In this case, since the tapered surface guides the movement of the biasing member when the biasing member is assembled on the radially inner side of the stepped portion, manufacturing efficiency can be improved. In addition, even if such a tapered surface is provided, the piston can be prevented from entering along the tapered surface in the radial direction of the stepped portion by the upper surface of the stepped portion being inclined as described above. .

  Further, in the portion of the piston that contacts the upper surface of the step when the piston is positioned at the lowered end position, an inclined surface extending downward gradually as it goes radially outward is formed. Good.

  In this case, when the piston descends, the inclined surface of the piston and the upper surface of the step abut in the vertical direction, and the piston is more reliably displaced radially outward with respect to the portion of the piston that abuts the step of the cylinder Force can be applied. Therefore, the piston can be more reliably restrained from entering the inside of the step. Furthermore, when the inclined surface is pressed against the upper surface of the step, the force for pressing the piston toward the inner circumferential surface of the cylinder is further increased, so the sealability between the piston and the cylinder can be further improved. .

  According to the present invention, even when the piston is strongly pushed into the cylinder, the piston can be prevented from entering inside the step of the cylinder.

It is a longitudinal cross-sectional view which shows the state in which the adapter for right-fronted both sides was mounted to the dispenser which concerns on 1st Embodiment. It is an enlarged view of the dispenser shown in FIG. It is an enlarged view of a piston periphery of the dispenser shown in FIG. FIG. 3 is a longitudinal cross-sectional view of the dispenser shown in FIG. 2, showing a state in which a stem is pushed down with respect to a cylinder. FIG. 5 is an enlarged view around a piston of the dispenser shown in FIG. 4; It is an enlarged view of the adapter for right-backed shown in FIG. It is an enlarged view of the A section of Drawing 5, (a) shows the state where the piston and the step of a cylinder separated, and (b) shows the state where the step of a piston and a cylinder contacted. It is a figure corresponding to FIG. 7 (a), (b) about the dispenser which concerns on 2nd Embodiment.

First Embodiment
Hereinafter, the configuration of the dispenser according to the first embodiment will be described with reference to FIGS. 1 to 7. In addition, in each drawing used for the following description, in order to make each member into a recognizable size, the scale is appropriately changed.

As shown in FIG. 1, the dispenser 1 urges the top 12 of the mounting cap 11 attached to the opening 3 of the container body 2, the stem 12 disposed movably downward, and the stem 12 upward. A coil spring 95 (biasing member), a discharge head 13 mounted on the upper end of the stem 12 and having a discharge hole 13A for the content liquid, a cylindrical piston 41 linked to the vertical movement of the stem 12, and a piston The cylinder 41 includes a cylinder 42 slidably accommodated therein, and a piston guide 43 extending downward from the stem 12 and vertically penetrating the inside of the piston 41.
In the illustrated example, the dispenser 1 is mounted with an adapter 200 for vertical and reverse rotation, which will be described later.

(Direction definition)
Here, the mounting cap 11, the stem 12, the piston 41, the cylinder 42, and the piston guide 43 are disposed with their central axes positioned on a common axis.
Hereinafter, this common axis is referred to as the central axis O, and the direction along the central axis O is referred to as the vertical direction. Further, in a plan view seen from the up and down direction, a direction intersecting the central axis O is referred to as a radial direction, and a direction circling around the central axis O is referred to as a circumferential direction. Further, in a plan view, in the radial direction, the direction in which the discharge hole 13A of the discharge head 13 opens is referred to as the front, the opposite direction is referred to as the rear, and the direction orthogonal to both the vertical direction and the front and rear direction .

  As shown in FIG. 2, the mounting cap 11 has an annular top wall 11a having an opening 11c at its center, and a cylindrical peripheral wall 11b extending downward from the outer peripheral edge of the top wall 11a. And. On the inner peripheral surface of the peripheral wall portion 11 b, a female screw is formed which is screwed to a male screw formed on the outer peripheral surface of the mouth 3 of the container body 2.

The stem 12 is provided at the mouth 3 of the container body 2 so as to be movable downward in an upward biasing state.
The inner diameter and outer diameter of the lower portion of the stem 12 are larger than the inner diameter and outer diameter of the upper portion of the stem 12. A tapered stepped cylindrical portion 12A is formed between the upper and lower portions of the stem 12.
As shown in FIGS. 2 and 3, as the stem 12 and the piston guide 43 move downward with respect to the piston 41, a vertical compressive force is applied between the stem 12 and the piston 41 by the piston 41 and the stem 12. An elastic piece 25 is disposed.

  The elastic pieces 25 are formed in a plate shape in which the front and back surfaces face in the radial direction and extend in the vertical direction. The elastic pieces 25 are formed at the lower end opening edge of the stem 12 and are arranged in plurality (six in this embodiment) at equal intervals in the circumferential direction. The elastic piece 25 is integrally formed with the stem 12. The plurality of elastic pieces 25 are formed to have the same shape and the same size. The radial size (thickness) of the elastic piece 25 is thinner than the thickness of the stem 12. The stem 12 and the elastic piece 25 are formed of a material having a certain degree of rigidity, such as polypropylene, which deforms when the elastic piece 25 is applied with a constant force.

The discharge head 13 has a cylindrical mounting cylindrical portion 31 mounted on the upper end portion of the stem 12 and a cylindrical nozzle cylindrical portion 32 protruding forward from the mounting cylindrical portion 31. ing.
The mounting tube portion 31 is fitted in the stem 12. At the upper end portion of the mounting cylindrical portion 31, a shaft portion 10A that protrudes in the left-right direction is formed. The shaft portion 10A has a circular shape when viewed from the left and right direction. At the upper end portion of the mounting cylindrical portion 31, a locked portion 120 that protrudes rearward is formed.

The locked portion 120 is formed in a block shape having a pair of lightening holes 121 opened in the left-right direction. An engagement protrusion 122 is formed on the engaged portion 120 for restraining movement of the stopper 130 described later from the restricted position to the restricted release position.
The engagement protrusion 122 is provided so as to protrude downward from the rear end portion of the engaged portion 120. The lower end of the engagement protrusion 122 is located above the upper end of the stem 12. At the rear of the engagement protrusion 122, an inclined surface 122a is formed which extends upward gradually toward the rear.

A core rod body 35 extending in the front-rear direction and a tipped cylindrical tip 36 attached to the front end of the core rod body 35 are disposed in the nozzle cylinder portion 32.
On the outer peripheral surface of the core rod body 35, a plurality of flow channel grooves 35A are formed, which extend in the front-rear direction and allow the flow of the content liquid with the inner peripheral surface of the nozzle cylinder 32. The tip 36 is disposed coaxially with the core rod body 35, and has a cylindrical tip cylindrical portion 37 in which the core rod body 35 is fitted inside, and an end provided on the front end portion of the tip cylindrical portion 37. And a wall portion 38.

The tip cylinder 37 is fitted in the nozzle cylinder 32. The end wall portion 38 is in contact with the front end surface of the core rod body 35. A spin flow passage 38A communicating with the flow passage groove portion 35A of the core rod body 35 is formed on the rear surface of the end wall portion 38 that contacts the front end surface of the core rod body 35. At a central portion of the end wall portion 38, a discharge hole 13A communicating with the spin flow passage 38A is opened forward.
The tip 36 can discharge the content liquid in the form of mist. Further, by changing the shape of the tip 36 and the nozzle tip and the like, it is possible to discharge the content liquid in the form of a bubble or in a straight line. For example, foam-like discharge can be performed by providing a foam member such as mesh at the nozzle tip of the present embodiment.

  The piston 41 is disposed radially inside the outer cylinder piston 51 fitted in the cylinder 42 so as to be vertically slidable, and is an inner cylinder piston that surrounds the piston guide 43 from the outside in the radial direction. 52 and an annular connecting portion 53 connecting the outer cylinder piston 51 and the inner cylinder piston 52. The outer cylinder piston 51, the inner cylinder piston 52, and the annular connection portion 53 are disposed coaxially with the central axis O, respectively. In the illustrated example, the outer cylinder piston 51, the inner cylinder piston 52, and the annular connecting portion 53 are integrally formed.

As shown in FIG. 3, the outer cylinder piston 51 includes a cylindrical upper portion 51 a protruding upward from the annular connection portion 53 and a cylindrical sliding contact portion 51 b protruding downward from the annular connection portion 53. ing. The lower end portion of the sliding contact portion 51b is a portion that comes in contact with the upper surface 65b of a step portion 65 described later of the cylinder 42 when the piston 41 is positioned at the lowered end position (see FIG. 5).
The outer peripheral surface of the upper side portion 51 a is in contact with or close to the inner peripheral surface of the cylinder 42. The upper portion 51 a is disposed with a gap in the radial direction between it and the elastic piece 25, and surrounds the elastic piece 25 from the outer side in the radial direction. The upper end of the upper portion 51 a is located above the upper end of the elastic piece 25. The lower end portion of the sliding contact portion 51 b is in contact with the inner peripheral surface of the cylinder 42.

  The inner cylinder piston 52 projects upward from the annular connection portion 53, and the upper end projects downward from the inner cylinder portion 52 a fitted in the stem 12 so as to be vertically slidable, and the annular connection portion 53. A cylindrical closing portion 52b is provided so as to be vertically movable, and block communication between the inside of the stem 12 and the inside of the cylinder 42.

An upper portion of the inner cylindrical portion 52a located in the stem 12 extends radially outward gradually from the lower side toward the upper side. The inner cylindrical portion 52 a is disposed with a clearance in the radial direction from the outer peripheral surface of the peripheral cylindrical portion 43 D of the piston guide 43 and the elastic piece 25. The inner cylindrical portion 52 a may be in contact with the elastic piece 25.
The closed portion 52b extends radially inward gradually from the upper side to the lower side. The lower end portion of the closed portion 52 b is in contact with the outer peripheral surface of the circumferential cylindrical portion 43 D of the piston guide 43. The lower end portion of the closing portion 52b is located above the lower end portion of the sliding contact portion 51b.

The annular connection portion 53 is disposed at an intermediate portion in the vertical direction of each of the outer cylinder piston 51 and the inner cylinder piston 52, and has an annular shape disposed coaxially with the central axis O. On the upper surface of the annular connection portion 53, a sliding contact surface 54 on which the elastic piece 25 is in sliding contact with the downward movement of the stem 12 and the piston guide 43 with respect to the piston 41 is formed. The sliding contact surface 54 extends continuously over the entire circumference. The sliding surface 54 may extend intermittently over the entire circumference.
The lower end portion of the elastic piece 25 is separated upward from the sliding contact surface 54. The radially inner portion of the elastic piece 25 and the radially outer portion of the sliding surface 54 face each other in the vertical direction.

  As shown in FIG. 2, the cylinder 42 is formed in a multistage cylindrical shape. The cylinder 42 includes an upper cylindrical portion 62 extending in the vertical direction, a lower cylindrical portion 63 extending downward from the lower end portion of the upper cylindrical portion 62, and having a smaller inner diameter and outer diameter than the upper cylindrical portion 62; A small diameter portion 64 extending downward from the lower end portion of the lower cylindrical portion 63 and having an inner diameter and an outer diameter smaller than that of the lower cylindrical portion 63, and a lower end portion of the upper cylindrical portion 62 and an upper end portion of the lower cylindrical portion 63 It has an annular step portion 65 to be connected, and a connection cylindrical portion 69 extending downward from the small diameter portion 64.

The stepped portion 65 is opposed to the outer cylinder piston 51 of the piston 41 in the vertical direction. When the piston 41 is located at the lowered end position (see FIG. 5), the sliding contact portion 51 b of the outer cylinder piston 51 abuts on the upper surface 65 b of the step portion 65. A tapered surface 65a whose diameter is gradually reduced toward the lower side is formed on at least a portion of the inner circumferential surface of the stepped portion 65 connected to the upper surface 65b of the stepped portion 65. The tapered surface 65 a has a role of facilitating the operation of inserting the coil spring 95 into the lower cylindrical portion 63 when manufacturing the discharger 1. In the present embodiment, although the tapered surface 65a extends from the upper end opening edge of the step portion 65 to the upper end portion of the lower cylindrical portion 63, the tapered surface 65a is formed only on a part of the inner circumferential surface of the step portion 65. It may be done.
In the present embodiment, the upper surface 65b of the step portion 65 gradually extends downward as it goes radially outward.

  At the upper portion of the upper cylindrical portion 62, an air hole 62B communicating the inside and the outside of the upper cylindrical portion 62 is formed. At the upper end portion of the upper cylindrical portion 62, an annular support plate portion 61 which protrudes outward in the radial direction is formed. The lower surface of the top wall 11 a of the mounting cap 11 is in contact with the outer peripheral portion of the upper surface of the support plate 61. A first packing 66 is disposed between the support plate portion 61 and the upper end opening edge 3 a of the mouth 3 of the container body 2. The support plate 61 and the first packing 66 are fixed between the top wall 11 a of the mounting cap 11 and the opening 3 by screwing the peripheral wall 11 b of the mounting cap 11 to the opening 3. Be done. The support plate portion 61, the upper cylindrical portion 62, the lower cylindrical portion 63, and the small diameter portion 64 are disposed coaxially with the central axis O.

On the upper surface of the support plate portion 61, there is formed a standing cylindrical portion 60 which extends upward and is inserted into the opening 11c of the mounting cap 11. The outer diameter and the inner diameter of the upright cylindrical portion 60 are larger than the outer diameter and the inner diameter of the upper cylindrical portion 62. The upper end opening edge 60A of the upright cylindrical portion 60 is positioned at the same position as the stepped cylindrical portion 12A of the stem 12 in the vertical direction.
The upper surface of the support plate portion 61 is located at the same position in the vertical direction as the upper end opening edge of the upper portion 51 a of the piston 41. An annular second packing 56 is disposed integrally with the upper surface of the inner peripheral portion of the support plate portion 61 located radially inward of the erected cylindrical portion 60 and the upper end opening edge of the upper portion 51 a of the piston 41. (See Figure 3).

The small diameter portion 64 includes a straight cylindrical portion 67 extending straight downward from the lower end portion of the lower cylindrical portion 63, and a tapered cylindrical portion 68 whose inner diameter and outer diameter gradually decrease as going downward from the lower end portion of the straight cylindrical portion 67; have. The valve body 44 is disposed on the inside of the tapered cylindrical portion 68 so as to be freely attached to and detached from the tapered surface of the tapered cylindrical portion 68.
The valve body 44 is a so-called ball valve made of a synthetic resin formed in a spherical shape. The valve body 44 is preferably made of synthetic resin from the viewpoint of suppressing the time and effort of sorting at the time of disposal. Further, the valve body 44 may be made of metal or the like. Furthermore, it may be a check valve using various valve bodies instead of the ball valve.

  On the inner peripheral surface of the tapered cylindrical portion 68, a control protrusion 68A extending upward as it goes inward from the outer side in the radial direction is provided in a protruding manner. The inner diameter of the upper end of the restriction protrusion 68A is smaller than the outer diameter of the valve body 44. Thus, the valve body 44 is restricted from being separated upward from the restriction projection 68A. In addition, the gap | interval which interrupts extension of the circumferential direction is formed in 68A of control protrusion.

The piston guide 43 is formed in a bottomed cylindrical shape including a peripheral cylindrical portion 43D extending downward from the stem 12 and a bottom wall portion. The bottom wall of the piston guide 43 is located below the closed portion 52b of the piston 41, as shown in FIG. The bottom wall portion is formed with an annular flange portion 43A that protrudes outward in the radial direction.
The lower end portion of the peripheral cylindrical portion 43D of the piston guide 43 is formed with an abutting portion 43E whose outer diameter gradually decreases as it goes upward from the upper surface of the flange portion 43A. The lower end portion of the closed portion 52b of the piston 41 is in contact with the contact portion 43E.

  A communication hole 43B for communicating the inside of the piston guide 43 with the inside of the cylinder 42 is formed in the peripheral cylindrical portion 43D of the piston guide 43. The communication holes 43B are disposed, for example, on both sides sandwiching the central axis O in the radial direction. The communication hole 43B is located above the contact portion 43E with which the closed portion 52b abuts. Thus, the communication between the communication hole 43B and the inside of the upper cylindrical portion 62 of the cylinder 42 is blocked.

As shown in FIG. 2, a through hole 43 </ b> C communicating the inside of the piston guide 43 and the inside of the stem 12 is formed in the circumferential cylindrical portion 43 </ b> D of the piston guide 43. The through holes 43 </ b> C are, for example, disposed on both sides of the central axis O in the radial direction, similarly to the communication holes 43 </ b> B. The through hole 43 </ b> C is disposed above the communication hole 43 </ b> B and opens toward the inner circumferential surface of the stepped cylindrical portion 12 </ b> A of the stem 12. By forming the communication hole 43B and the through hole 43C in the piston guide 43, the air between the piston guide 43 and the piston 41, and between the piston guide 43 and the stem 12 can be prevented from staying. .
A portion of the piston guide 43 located above the through hole 43 </ b> C is fitted in the stem 12. Thus, the piston guide 43 moves up and down together with the stem 12.

At a lower end portion of the piston guide 43, a guide projection 43F which protrudes downward and in which the coil spring 95 is mounted is formed. The guide protrusion 43F is configured by arranging a plurality of plates whose front and back surfaces face in the circumferential direction around the central axis O. The guide protrusion 43 </ b> F is disposed from the lower portion of the upper cylindrical portion 62 in the cylinder 42 to the upper portion of the lower cylindrical portion 63.
The upper end portion of the coil spring 95 abuts on the lower surface of the flange portion 43A, and the lower end portion abuts on the upper end opening edge of the straight cylindrical portion 67 in the cylinder 42. Thus, the piston guide 43 receives an upward biasing force from the coil spring 95.

  Furthermore, in the present embodiment, the discharger 1 is rotatably disposed around the rotation axis L on the support member 15 erected at the rear of the mounting cap 11 and the support member 15, and a pressing member that depresses the discharge head 13. 16 and a stopper 130 for restricting the downward movement of the ejection head 13. The dispenser 1 may not have the support member 15, the pressing member 16, and the stopper 130.

  The support member 15 has a top cylindrical surrounding cylinder portion 15a which is externally mounted on the standing cylinder portion 60 of the cylinder 42, a guide cylinder 15c extending upward from the top wall of the surrounding cylinder portion 15a, and the surrounding cylinder portion 15a It has a pair of side wall portions 77 protruding rearward from the rear and spaced apart in the left-right direction, and a rear wall portion 78 connecting the rear end edges of the side wall portions 77 in the left-right direction. ing.

  The top wall of the surrounding cylinder portion 15a is formed in an annular shape, and a guide cylinder 15c is disposed at the inner peripheral edge portion of the top wall. The stem 12 is inserted into the guide cylinder 15c so as to be movable downward. In the lower surface of the top wall of the surrounding cylindrical portion 15a, there is provided an inner depending cylindrical portion 15d into which the stem 12 is inserted, and an outer depending cylindrical portion disposed between the inner depending cylindrical portion 15d and the peripheral wall of the surrounding cylindrical portion 15a. 15e are formed. The guide cylinder 15c, the inner depending cylindrical portion 15d, and the outer depending cylindrical portion 15e are disposed coaxially with the central axis O.

The lower end portion of the peripheral wall of the surrounding cylindrical portion 15a is vertically opposed to the top wall portion 11a of the mounting cap 11 with a gap.
The outer hanging cylindrical portion 15 e is fitted in the standing cylindrical portion 60. The lower end opening edge of the outer depending cylindrical portion 15 e is pressed against the upper surface of the inner peripheral portion of the support plate portion 61 in the cylinder 42 via the second packing 56.
The inner depending cylindrical portion 15 d is encased at the lower portion of the stem 12. The lower end opening edge of the inner depending cylindrical portion 15 d is pressed against the upper end opening edge of the upper portion 51 a of the piston 41 via the second packing 56.
The second packing 56 is externally fitted to the lower end portion of the stem 12. The second packing 56 communicates between the outside air introduction passage R defined between the stem 12 and the guide cylinder 15 c and the upper space of the cylinder 42 located above the sliding contact portion 51 b of the piston 41. Can be cut off.

The side wall 77 extends upward gradually from the front side toward the rear side. At the upper end of the side wall portion 77, a projecting piece 80 formed in a semicircular shape protruding upward in a front view as viewed from the left and right direction is formed. A cylindrical shaft 77A is provided on the protruding piece 80 so as to protrude outward in the left-right direction. The shaft 77A is disposed rearward of the stem 12. An imaginary axis line passing through the center of the shaft 77A and extending in the left-right direction is the swing axis L of the pressing member 16. Thus, the swinging axis L is disposed rearward of the stem 12 and extends in the left-right direction.
On the inner surface of the rear wall portion 78, there is formed a reinforcing wall 78a which protrudes upward and which integrally connects the inner surfaces of the pair of side wall portions 77 and the projecting pieces 80 in the left-right direction.

The pressing member 16 is attached to the support member 15 via the shaft 77A. Thus, the pressing member 16 is connected to the support member 15 so as to be swingable around the swing axis L.
The pressing member 16 has a top plate 90 covering the discharge head 13 from above, a front plate 91 extending gradually downward from the front end edge of the top 90, and left and right sides of the top 90 And a pair of side plate portions 92 which extend downward from the side edge of the and which face each other in the left-right direction.
The discharge head 13 is disposed in an internal space surrounded by the top plate portion 90 and the pair of side plate portions 92. Therefore, the pair of side plate portions 92 is disposed so as to sandwich the discharge head 13 in the left-right direction.

The top plate portion 90 has a smoothly curved shape so as to expand upward, and its rear end portion abuts on the upper end portion of the rear wall portion 78 in the support member 15 from above. Thereby, the upward swing of the pressing member 16 around the swinging axis L is restricted.
A first through hole 93 penetrating the top plate portion 90 is formed in the front side portion of the top plate portion 90.
The first through hole 93 is formed in the center portion in the left-right direction of the top plate portion 90, and is opened forward. Thus, the front portion of the top plate 90 is bifurcated in the left-right direction. The front plate portion 91 extends gradually downward from the front end edge of the bifurcated top plate portion 90 toward the front.

  The nozzle cylindrical portion 32 of the discharge head 13 is inserted into the first through hole 93. Thus, the nozzle cylindrical portion 32 protrudes forward from the front plate portion 91 through the first through hole 93, and relative rotation around the central axis O of the pressing member 16 and the ejection head 13 is restricted. There is. The lower portion of the front plate portion 91 is a finger hook portion for putting a finger on.

  The pair of side plate portions 92 of the pressing member 16 sandwiches the upper portion of the pair of side wall portions 77 of the support member 15 in the left-right direction. Thereby, relative rotation around the central axis O of the support member 15 and the pressing member 16 is restricted. On the inner surface on the rear side of the pair of side plate portions 92, a shaft hole portion 92A into which a shaft body 77A is inserted is formed. Thus, the pressing member 16 is swingably supported around the shaft 77A, that is, around the swing axis L.

In the pressing member 16, an engagement groove 31 </ b> A engaged with the shaft portion 10 </ b> A of the discharge head 13 is formed. The engagement groove 31A is formed in a semicircular shape that opens downward at a lower end portion of a plate portion that protrudes inward in the left-right direction from the pair of side plate portions 92 of the pressing member 16. The shaft portion 10A is inserted into the engagement groove 31A.
In the above configuration, when the pressing member 16 is swung downward about the swing axis L, the inner circumferential surface of the engagement groove 31A pushes the outer circumferential surface of the shaft portion 10A downward, thereby the stem 12 and the piston guide 43 descends against the upward biasing force of the coil spring 95.

  The stopper 130 is provided swingably around a shaft 131 parallel to the swing axis L of the pressing member 16 and restricts the downward movement of the discharge head 13. The stopper 130 swings backward around the shaft 131 with respect to the regulated position, which restricts the downward movement of the ejection head 13, and the regulated release position which permits the downward movement of the ejection head 13 (shown in FIG. Movably disposed between the position) and The stopper 130 restricts the downward movement of the discharge head 13 in the restriction position, and permits the downward movement of the discharge head 13 in the restriction release position.

The stopper 130 is disposed above the shaft body 131 and the shaft body 131 installed between the pair of side wall portions 77, and when the stopper 130 is positioned at the restricting position, the stopper 130 of the lower surface of the locked portion 120 and the guide cylinder 15c. A pinched portion 132 sandwiched between the upper end opening edge and a pair of knobs 134 connected to both end portions in the left-right direction of the shaft 131 and positioned on the outer side in the left-right direction of the side plate portion 92 .
The shaft body 131 is formed in a rod shape extending in the left and right direction, and both end portions in the left and right direction of the shaft body 131 are rotatably fitted around the central axis in support concave portions 82 formed in the pair of side wall portions 77 There is. The support recess 82 is disposed rearward of the stem 12 and forward of the swing axis L.

As shown in FIG. 6, the vertically inverted adapter 200 includes a cylindrical main body cylindrical portion 210.
The main body cylindrical portion 210 is disposed coaxially with the central axis O. The main body cylindrical portion 210 has a cylindrical outer cylindrical member 211 fitted outside the cylinder 42 and an inner cylindrical member 212 fitted inside the outer cylindrical member 211. In the lower end portion of the inner cylindrical member 212, the upper end portion of a cylindrical pipe 213 for circulating the content liquid in the container body 2 is fitted. The outer cylindrical member 211, the inner cylindrical member 212, and the pipe 213 are disposed coaxially with the central axis O.

  The outer cylindrical member 211 is disposed at an intermediate portion in the vertical direction of the outer cylindrical portion 214 and the cylindrical outer cylindrical portion 214 in which the straight cylindrical portion 67 of the cylinder 42 is fitted in the upper end portion. And a cylindrical connection cylinder part 217 which extends downward from the partition wall part 215 and is connected to the upper end of the inner cylinder member 212.

  In the partition wall portion 215, a liquid passage hole 219 penetrating in the vertical direction is formed. The outer peripheral surface of a portion of the upper end portion of the connection cylindrical portion 217 is connected to the inner peripheral surface of the outer cylindrical portion 214, and the outer peripheral surface of the other portion is the inner side in the radial direction from the inner peripheral surface of the outer cylindrical portion 214 Spaced apart. Then, the upside introduction hole 221 is formed in the outer cylindrical member 211 integrally penetrating the part of the connecting cylindrical portion 217 and the outer cylindrical portion 214 in the radial direction. At the time of inversion, the introduction hole 221 is provided so as to be able to introduce the liquid content in the container body 2 into the connecting cylindrical portion 217 when the discharger 1 is inverted.

  The inner cylindrical member 212 is disposed lower than the cylindrical upper cylindrical portion 222 whose upper end is connected to the connecting cylindrical portion 217 and the upper cylindrical portion 222, and the lower end is from the lower end of the outer cylindrical member 211. The lower cylindrical portion 223 is positioned at the lower side, and the cylindrical coupling cylindrical portion 224 is configured to connect the upper cylindrical portion 222 and the lower cylindrical portion 223.

  The upper end portion of the upper cylindrical portion 222 is externally fitted to the connecting cylindrical portion 217. Then, between the outer peripheral surface of the upper cylindrical portion 222 and the inner peripheral surface of the outer cylindrical portion 214, a first flow path r1 for circulating the content liquid is formed. The first flow passage r1 communicates with the liquid passage hole 219. The lower end portion of the upper cylindrical portion 222 has a tapered shape in which the inner diameter and the outer diameter gradually decrease toward the lower side, and a spherical switching valve 225 is disposed inside the upper cylindrical portion 222.

Between the outer peripheral surface of the coupling cylinder portion 224 and the inner peripheral surface of the outer cylinder portion 214, a second flow passage r2 for circulating the content liquid is formed. The second flow passage r2 communicates with the first flow passage r1. The connecting cylinder portion 224 is formed with a communication hole 226 for communicating the inside thereof with the second flow passage r2. A plurality of communication holes 226 are formed in the coupling cylindrical portion 224 at intervals in the circumferential direction.
Here, the communication hole 226, the second flow passage r2, the first flow passage r1 and the liquid passage hole 219 are the upright introduction hole 229 and the inverted introduction hole 221 of the lower end of the inner cylindrical member 212, and the connecting cylinder portion of the cylinder 42. A communication passage r3 communicating with the lower end opening portion 69 is formed. The upright introduction hole 229 is disposed below the inverted introduction hole 221.

  The lower cylindrical portion 223 is fitted in the lower end portion of the outer cylindrical member 211. The upper end portion of the pipe 213 is fitted in the lower end portion of the lower cylindrical portion 223, and the lower end opening of the pipe 213 opens toward the bottom portion in the container body 2. The lower end opening of the pipe 213 and the upright introduction hole 229 are provided such that the liquid content in the container body 2 can be introduced into the inner cylindrical member 212 when the dispenser 1 is erected. At the time of erecting, the content liquid is introduced into the introduction hole 229 through the pipe 213.

  Next, the operation of the dispenser 1 configured as described above will be described.

  When using the discharger 1, first, the stopper 130 is swung from the control position to the control release position so that the pressing member 16 and the discharge head 13 can move downward. Next, the pressing member 16 is rotated downward around the rotation axis L. At this time, for example, while holding a fingertip on the finger hook portion of the front plate portion 91 of the pressing member 16, the pressing member 16 is rotated downward against the biasing force of the coil spring 95. When the pressing member 16 is rotated downward, the discharge head 13 moves downward, and the stem 12 and the piston guide 43 with respect to the cylinder 42 are closed with the valve body 44 closing the inside of the tapered cylindrical portion 68 of the cylinder 42. Be pushed down.

  When the stem 12 is depressed together with the piston guide 43, the depressing force applied to the stem 12 is transmitted to the piston 41 via the elastic piece 25, and the piston 41 becomes integral with the stem 12 and the piston guide 43. Move downward to As a result, with the closed portion 52 b of the piston 41 blocking the communication between the inside of the stem 12 and the inside of the cylinder 42, the inside of the cylinder 42 is pressurized.

  Here, air may be present in the cylinder 42, for example, when the discharger 1 is not in use. When air is present in the cylinder 42, when the pressing member 16 is operated as described above, priming for discharging the air in the cylinder 42 out of the cylinder 42 is performed. More specifically, when the piston 41 descends as shown in FIG. 4, the pressure in the cylinder 42 increases and the lower end portion of the sliding contact portion 51 b of the piston 41 abuts on the step portion 65 of the cylinder 42. In this state, when the pressing member 16 is further depressed and the stem 12 and the piston guide 43 are lowered, the elastic piece 25 of the stem 12 is elastically deformed radially outward along the sliding contact surface 54 as shown in FIG. . At this time, as the piston guide 43 descends with respect to the piston 41, the closed portion 52b of the piston 41 is separated upward from the contact portion 43E of the piston guide 43. Therefore, a gap in the radial direction is formed between the lower end portion of the closed portion 52b and the peripheral cylindrical portion 43D of the piston guide 43, and the communication hole 43B communicates with the inside of the cylinder 42 by this gap. Air flows into the circumferential cylindrical portion 43D through the communication hole 43B. Thus, the air in the cylinder 42 is exhausted. The internal pressure of the cylinder 42 further rises as the piston guide 43 descends until the communication hole 43B communicates with the inside of the cylinder 42.

  By the way, in the priming operation, when the elastic piece 25 is elastically deformed, a further downward force is applied to the piston 41 in a state where the lower end portion of the sliding contact portion 51b abuts on the step portion 65. At this time, the lower end portion of the sliding contact portion 51b enters the inside in the radial direction of the step portion 65 along the tapered surface 65a, and the sliding contact portion 51b bends radially inward, whereby the outer peripheral surface of the sliding contact portion 51b. The sealability between the upper cylinder portion 62 and the upper cylinder portion 62 may be reduced. Moreover, such a phenomenon may occur, for example, when the pressing member 16 is operated with a strong force other than priming.

  Therefore, in the present embodiment, as described above, the upper surface 65b of the step portion 65, which abuts when the piston 41 is positioned at the lowering end position, gradually extends downward as it goes radially outward. With this configuration, when the piston 41 is lowered with respect to the cylinder 42, the lower end of the sliding contact portion 51b first contacts the upper surface 65b of the step portion 65. When a downward force is applied to the piston 41 in this state, as shown in FIGS. 7 (a) and 7 (b), a force is applied to displace the sliding contact portion 51b radially outward. It becomes. Therefore, even if the stepped portion 65 is provided with the tapered surface 65a, the sliding contact portion 51b is prevented from entering the radially inner side of the stepped portion 65 along the tapered surface 65a, and the sliding contact portion 51b and the upper portion The sealing performance between the cylindrical portion 62 can be secured. Furthermore, the sealing performance can be further enhanced by pressing the outer circumferential surface of the sliding contact portion 51b against the inner circumferential surface of the upper cylindrical portion 62 by the radially outward force acting on the sliding contact portion 51b.

  When the operation of the pressing member 16 is repeated in a state where the air in the cylinder 42 is discharged by the above priming, the liquid content in the cylinder 42 is raised in the stem 12 and introduced into the nozzle cylinder 32 and the discharge head It is discharged from the 13 discharge holes 13A. Specifically, when the stem 12 is depressed together with the piston guide 43, the depressing force applied to the stem 12 is transmitted to the piston 41 via the elastic piece 25, and the piston 41 becomes integral with the stem 12 and the piston guide 43, It moves downward with respect to the cylinder 42. As a result, with the closed portion 52 b of the piston 41 blocking the communication between the inside of the stem 12 and the inside of the cylinder 42, the inside of the cylinder 42 is pressurized. When the stem 12 is further depressed in this state, the upward movement of the piston 41 is suppressed by the increased internal pressure of the cylinder 42, and the stem 12 and the piston guide 43 move downward with respect to the piston 41.

  For this reason, the stem 12 and the piston guide 43 apply a compressive force in the vertical direction to the elastic piece 25 disposed between the stem 12 and the piston 41 to elastically deform the elastic piece 25 with respect to the piston 41. Move down. Then, similarly to the above-described priming operation, while the internal pressure of the cylinder 42 is rising, the closed portion 52b of the piston 41 is separated upward from the contact portion 43E, and between the closed portion 52b and the outer peripheral surface of the piston guide 43 A radial gap is formed.

Thereby, the content fluid in the cylinder 42 flows into the piston guide 43 through the gap between the inner peripheral surface of the closed portion 52 b and the outer peripheral surface of the piston guide 43 and the communication hole 43 B.
Then, the content liquid flowing into the piston guide 43 flows in the upper portion of the stem 12 to reach the nozzle cylinder 32 and is discharged from the discharge hole 13 A of the nozzle cylinder 32. As a result, the content liquid contained in the container body 2 can be discharged to the outside through the discharge hole 13A.

  Thereafter, when the operation of the pressing member 16 is released, the stem 12 and the piston 41 restore and move relative to the cylinder 42 based on the biasing force from the coil spring 95. At this time, the inside of the cylinder 42 has a negative pressure, and this negative pressure acts on the valve body 44 to open the inside of the tapered cylindrical portion 68 and acts on the switching valve 225 through the communication passage r3. Then, when the discharger 1 is erected, the switching valve 225 maintains a state in which the communication between the introduction hole 221 at the time of inversion and the communication passage r3 is shut off. As a result, the liquid content in the container body 2 reaches the lower end opening of the cylinder 42 through the introduction hole 229, the main cylinder portion 210 and the communication passage r3 and flows into the cylinder 42 when erecting.

  On the other hand, when the dispenser 1 is inverted, the lower end opening of the pipe 213 opened to the bottom in the container body 2 protrudes from the liquid surface of the content liquid in the container body 2. Moreover, with the introduction hole 221 at the time of inversion being positioned in the content liquid in the container main body 2, the switching valve 225 is separated from the inside of the upper cylindrical portion 222 based on its own weight. The communication passage r3 communicates with the inside of the main body cylindrical portion 210. Therefore, when negative pressure is generated in the cylinder 42, the liquid content in the container main body 2 reaches the lower end opening of the cylinder 42 through the introduction hole 221, the main body cylindrical portion 210 and the communication passage r3 when inverted. It flows into 42.

  When the discharge head 13, the stem 12 and the piston 41 are integrally pressed with respect to the cylinder 42 at any of the erecting time and the inverted time of the discharger 1, the cylinder 42 is positioned below the piston 41 in the cylinder 42. The lower space is pressurized, and the liquid content in the lower space ascends in the stem 12 and is discharged from the discharge hole 13A. In this process, the second packing 56 opens the lower end opening of the outside air introduction passage R, the outside air introduction passage R communicates with the upper space in the cylinder 42, and the outside air is introduced into the upper space in the cylinder 42.

  When the discharge head 13, the stem 12 and the piston 41 are released from being pushed down and restored and displaced upward, the lower space in the cylinder 42 becomes negative pressure, and the content liquid in the container body 2 becomes the lower part in the cylinder 42 It is introduced into space. In this process, the air in the upper space is introduced into the container body 2 by communication between the upper space in the cylinder 42 and the inside of the container body 2 through the air holes 62B.

Thereafter, when the stem 12 and the piston 41 return to the original state, the communication between the outside air introduction passage R and the upper space in the cylinder 42 is blocked by the second packing 56, and the inside and the outside of the container body 2 through the outside air introduction passage R Communication with is blocked.
In addition, since the second packing 56 for blocking the communication between the outside air introduction passage R and the upper space in the cylinder 42 is disposed even if the discharger 1 is inverted, etc., the content liquid in the container body 2 is a cylinder. Even if the upper space in 42 is reached, the contents liquid can be prevented from leaking out through the outside air introduction passage R.

  As described above, according to the discharge device 1 of the present embodiment, the upper surface 65b of the step portion 65 of the cylinder 42 gradually extends downward as it goes radially outward. With this configuration, even when the piston 41 is strongly pressed against the step 65 during priming or when the content liquid is discharged, the sliding contact portion 51b enters the inside in the radial direction of the step 65 and the piston 41 and the cylinder It can suppress that the sealing performance between 42 and the like is reduced. Further, by pressing the sliding contact portion 51b against the inner peripheral surface of the upper cylindrical portion 62 of the cylinder 42 by the radially outward force acting on the sliding contact portion 51b, the sealing performance can be further enhanced.

Second Embodiment
Next, a second embodiment according to the present invention will be described, but the basic configuration is the same as the first embodiment. For this reason, the same code | symbol is attached | subjected to the same structure, the description is abbreviate | omitted, and only a different point is demonstrated.
In the present embodiment, the shape of the piston 41 is different from that of the first embodiment.

  As shown in FIGS. 8A and 8B, of the piston 41 of the present embodiment, the lower end portion of the sliding contact portion 51b opposed to the upper surface 65b of the step portion 65 in the vertical direction is radially outward. The inclined surface 51c is formed to extend gradually downward toward the direction. The inclined surface 51c abuts on the upper surface 65b of the step portion 65 when the piston 41 is located at the lowered end position (see FIG. 8B).

  According to the present embodiment, when the piston 41 descends and abuts on the step portion 65 and the piston 41 is further pushed downward, the inclined surface 51 c of the piston 41 abuts on the upper surface 65 b of the step portion 65. Thus, the force to displace the sliding contact portion 51b radially outward can be generated more reliably. Therefore, the sliding contact portion 51 b can be more reliably restrained from falling inward in the radial direction of the step portion 65. Furthermore, when the inclined surface 51c is pressed against the upper surface 65b of the step portion 65, the force for pressing the sliding contact portion 51b against the upper cylindrical portion 62 of the cylinder 42 also becomes large, so the sealability between the piston 41 and the cylinder 42 is improved. It can be improved more.

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

For example, in the embodiment, the tapered surface 65a of the step portion 65 is formed in a linear shape in a longitudinal sectional view, but the tapered surface 65a may be curved in a longitudinal sectional view.
The tapered surface 65 a may not be formed on the cylinder 42. Even in this case, for example, it is assumed that the lower end portion of the sliding contact portion 51b of the piston 41 intrudes into a gap provided between the guide projection 43F and the step portion 65 in order to arrange the coil spring 95. Then, as the upper surface of the step portion 65 is inclined as described above, the sliding contact portion 51b can be prevented from entering the gap between the guide projection 43F and the step portion 65.
Moreover, in the said embodiment, although the discharger 1 which has the trigger type pressing member 16 was made into an example and demonstrated, this invention is also applicable with respect to the discharger 1 of another kind. For example, the present invention may be applied to a discharger of a type that discharges the content liquid by pressing a button. Similarly, the present invention may be applied to a discharger that discharges the content liquid using a liquid pump or the like.

In the above embodiment, the elastic piece 25 of the stem 12 and the sliding contact surface 54 of the piston 41 have a pressure accumulation structure for discharging the content liquid in a state in which the pressure in the cylinder 42 is further increased. The present invention may be applied to the dispenser 1 having no structure.
In the second embodiment, the inclined surface 51c is formed at the lower end portion of the sliding contact portion 51b. However, the present invention is not limited to this configuration, and the inclined surface may be a portion of the piston 41 that contacts the step portion 65. Should be formed.

  In addition, it is possible to replace components in the above-described embodiment with known components as appropriate without departing from the spirit of the present invention, and the above-described embodiments and modifications may be combined as appropriate.

  DESCRIPTION OF SYMBOLS 1 ... Dispenser 12 ... Stem 13 ... Discharge head 13 A ... Discharge hole 41 ... Piston 42 ... Cylinder 43 ... Piston guide 51c ... Sloped surface 62 ... Upper cylinder part 63 ... Lower cylinder part 65 ... Step part 65a ... Taper surface 65b ... Upper surface 95: Coil spring (biasing member)

Claims (3)

A stem disposed movably downward,
A biasing member for biasing the stem upward;
A discharge head attached to an upper end portion of the stem and having a discharge hole for the content liquid formed therein;
A piston associated with the vertical movement of the stem;
And a cylinder in which the piston is slidably accommodated.
A discharger for discharging the liquid content in the cylinder from the discharge hole through the stem when the stem is moved downward with respect to the cylinder,
The cylinder is
An upper cylinder portion surrounding the piston;
A lower cylindrical portion disposed below the upper cylindrical portion and having a smaller inner diameter than the upper cylindrical portion;
And an annular step which connects the lower end portion of the upper cylindrical portion and the upper end portion of the lower cylindrical portion and abuts when the piston is positioned at the lowered end position,
The upper surface of the said step part is characterized by extending toward the downward gradually as it goes to radial direction outward.   The discharge according to claim 1, wherein at least a portion of the inner peripheral surface of the stepped portion connected to the upper surface of the stepped portion is formed with a tapered surface whose diameter gradually decreases toward the lower side. vessel.   In the portion of the piston that abuts on the upper surface of the step when the piston is positioned at the lowering end position, an inclined surface that extends gradually downward toward the radially outer side is formed. The dispenser according to claim 1 or 2, wherein

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