JP2015127220A - Foamer dispenser - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a foamer dispenser capable of suppressing the solidification of a fluid on a foam member.SOLUTION: A stem 16 comprises: an upper stem 41 in which a push-down head 20 is attached to the upper end part; and a lower stem 42 extending downward from the upper stem 41. The upper stem 41 is supported so as to move downward in an upward biased state with respect to the lower stem 42. A connection passage 85 having an upward/downward flow passage 85a extending in a vertical direction is disposed between a nozzle hole 33 and a foam member 18. The lower stem 42 is provided with a block body 87 for blocking an upper end opening of the upward/downward flow passage 85a, which is erected upward. The block body 87 opens the upper end opening according to the fall of the upper stem 41 with respect to the lower stem 42.

Description

  The present invention relates to a former dispenser.

Conventionally, for example, a former dispenser as shown in Patent Document 1 below is known. The former dispenser has a stem erected so as to be movable downward in an upward biased state at a mouth portion of a container body in which a liquid is stored, a pressing head disposed at an upper end portion of the stem and having a nozzle hole formed therein, An urging member for urging the stem upward; a liquid piston linked to the stem; a liquid cylinder in which the liquid piston is housed slidably up and down; an air piston linked to the stem; An air cylinder in which an air piston is slidably moved vertically, a gas-liquid mixing chamber for mixing the liquid from the liquid cylinder and the air from the air cylinder, and the gas-liquid mixing chamber and the nozzle hole. And a foaming member that foams the gas-liquid mixture from the gas-liquid mixing chamber.
The former dispenser pushes down the pressing head to move the stem downward, thereby transferring the liquid in the container and mixing it with air, and discharging a foam formed by foaming these gas-liquid mixture.

Japanese Patent Laid-Open No. 2005-13945

  However, in the conventional former dispenser described above, the liquid may dry and solidify on the foam member in the process of repeated use. In addition, when a liquid solidifies on a foaming member, there exists a problem of becoming difficult to foam a foam to appropriate foam quality, etc., for example.

  This invention is made | formed in view of such a situation, Comprising: It aims at providing the former dispenser which can suppress that a liquid solidifies on a foaming member.

In order to solve the above problems, the present invention proposes the following means.
A former dispenser according to the present invention includes a pump having a stem erected in an upwardly biased state at a mouth portion of a container body in which a liquid is accommodated, and a nozzle hole disposed at an upper end portion of the stem. A presser head, and a liquid piston and an air piston linked to the stem, and the liquid piston is accommodated in the pump so as to be slidable vertically. A liquid cylinder, an air cylinder in which the air piston is housed slidably up and down, and a gas-liquid mixing chamber for mixing the liquid from the liquid cylinder and the air from the air cylinder And a foam member for foaming the gas-liquid mixture from the gas-liquid mixing chamber, and the stem has an upper stem with the pressing head attached to an upper end portion thereof, and directed downward from the upper stem. An extended lower stem, and the upper stem is supported so as to be movable downward in an upwardly biased state with respect to the lower stem, and vertically between the nozzle hole and the foam member. A connection path having an up and down flow path is disposed, and the lower stem is provided with a closing body that stands upward and closes an upper end opening of the up and down flow path. The closing body opens the upper end opening as the lower stem descends.

According to this configuration, when the foam head is discharged, when the pressing head is pressed, the upper stem descends relative to the lower stem, thereby opening the upper end opening of the upper and lower flow paths. When the stem is lowered together with the upper stem and the pressing head, the liquid piston and the air piston are also lowered. Thus, the liquid in the liquid cylinder and the air in the air cylinder are supplied into the gas-liquid mixing chamber, and the liquid and air are mixed to form a gas-liquid mixture. Further, when the gas-liquid mixture passes through the foaming member, the gas-liquid mixture is foamed to form a foam, and the foam is discharged from the nozzle hole through the connection path.
On the other hand, when the pressing of the pressing head is released, the pressing head, the stem, the liquid piston, and the air piston are restored and displaced upward. At this time, the upper stem is restored and displaced upward with respect to the lower stem, so that the closing body closes the upper end opening of the upper and lower flow paths. Thereby, the communication between the nozzle hole through the connection path and the gas-liquid mixing chamber is blocked.
In the former dispenser of the present invention, since the lower stem is provided with a closing body that closes the upper end opening of the upper and lower flow paths, the foaming member passes through the nozzle hole and the upper end opening in the standby state before the pressing head is pressed. Can be prevented from being exposed to the open air. Thereby, it becomes possible to suppress that a liquid dries and solidifies on a foaming member, for example, foam of a suitable foam quality can be made to foam stably.

Further, the lower stem may be formed with an annular groove that communicates with the upper stem and in which the lower end of the upper stem slides in an airtight manner as the upper stem descends with respect to the lower stem.
According to this configuration, when the pressing of the pressing head is released, the upper stem rises so as to be retracted from the annular groove in the process in which the upper stem rises with respect to the lower stem. Thereby, the inside volume of the sealed part in the annular groove is expanded, and the inside of the annular groove is in a negative pressure state. After that, when the upper stem retreats from the annular groove and the inside of the annular groove communicates with the inside of the upper stem, the negative pressure in the annular groove passes through the inside of the upper stem and the upper end opening of the upper and lower flow passages, and enters the connection path. Acts on the nozzle hole side. Thereby, the foam remaining on the nozzle hole side in the connection path is pulled back toward the gas-liquid mixing chamber side (in the upper and lower flow paths) (so-called back suction function). Thereby, the liquid dripping from the nozzle hole after discharge of a foam and the solidification of the foam on the nozzle hole side in a connection path can be suppressed.

The pump includes an air passage that communicates the inside of the air cylinder and the gas-liquid mixing chamber, and the air piston includes a cylindrical portion through which the lower stem is inserted, The stem is formed with a flange-like contact portion that protrudes outward in the radial direction of the lower stem and contacts the lower end of the cylindrical portion from below the cylindrical portion, and a part of the air passage is The pump is formed between the cylindrical portion and the lower stem, and opens to the pump when the air piston is lowered by the pressing of the pressing head, and the liquid flows from the gas-liquid mixing chamber side through the air passage. There may be provided a backflow prevention valve that prevents the air from flowing into the cylinder.
According to this configuration, when the air piston rises with respect to the lower stem, for example, when the internal pressure of the air cylinder rises, the cylinder portion of the air piston is separated from the contact portion, and the inside of the air passage is Even if the air cylinder communicates with the air cylinder, the communication between the gas-liquid mixing chamber through the air passage and the air cylinder is kept blocked by the backflow prevention valve. Thus, the backflow prevention valve can prevent the liquid from flowing into the air cylinder through the air passage from the gas-liquid mixing chamber side.

  According to the former dispenser concerning the present invention, it can control that a liquid solidifies on a foaming member.

It is a longitudinal cross-sectional view of the discharge container in embodiment. It is a principal part enlarged view of FIG. It is explanatory drawing for demonstrating the effect | action of a former dispenser, Comprising: It is a longitudinal cross-sectional view corresponded in FIG. It is explanatory drawing for demonstrating the effect | action of a former dispenser, Comprising: It is a longitudinal cross-sectional view corresponded in FIG. It is explanatory drawing for demonstrating the effect | action of a former dispenser, Comprising: It is a longitudinal cross-sectional view corresponded in FIG. It is explanatory drawing for demonstrating the effect | action of a former dispenser, Comprising: It is a longitudinal cross-sectional view corresponded in FIG.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
A discharge container 1 shown in FIG. 1 includes a container body 2 in which liquid is stored, a pump 3 having a stem 16 erected on the mouth portion 2a of the container body 2 so as to be movable downward in an upward biased state, and the stem. And a former dispenser 10 having a pressing head 20 disposed at the upper end of 16 and having nozzle holes 33 formed therein, and discharges the liquid in the container body 2 in the form of bubbles.

  The pump 3 includes a mounting cap 11, an air cylinder 12, a liquid cylinder 13, a liquid piston 14, a first urging member 15 a and a second urging member 15 b, a stem 16, and an air piston 17. And a foam member 18 and a gas-liquid mixing chamber 19.

Here, the air cylinder 12, the liquid cylinder 13, the liquid piston 14, and the air piston 17 are formed in a cylindrical shape. The central axes of the air cylinder 12, the liquid cylinder 13, the liquid piston 14, and the air piston 17 are located on a common axis and are arranged coaxially with the axis of the container body 2.
Hereinafter, this common axis is referred to as the axis O, the direction along the axis O is referred to as the vertical direction, the bottom side of the container body 2 along the vertical direction is referred to as the lower side, and the opposite side of the lower side is referred to as the upper side. Further, in a plan view viewed from the up and down direction, a direction orthogonal to the axis O is referred to as a radial direction, and a direction around the axis O is referred to as a circumferential direction.

  The mounting cap 11 is screwed into the mouth portion 2 a of the container body 2, and the upper cylinder portion is formed with a smaller diameter than the lower cylinder portion 21 and extends upward from the lower cylinder portion 21. 22 and a connecting step portion 23 for connecting the lower cylinder portion 21 and the upper cylinder portion 22 to each other. In the illustrated example, a restriction member 24 for restricting the downward movement of the pressing head 20 relative to the attachment cap 11 is detachably attached to the upper cylindrical portion 22.

  The pressing head 20 includes an outer cylinder 31 into which the upper cylinder portion 22 of the mounting cap 11 enters inward along with the downward movement thereof, an inner cylinder 32 disposed on the inner side of the outer cylinder 31 and mounted on the stem 16, A nozzle cylinder 34 extending radially outward from the cylinder 32 and having a nozzle hole 33 formed at the tip thereof, covering the upper end opening of the outer cylinder 31, and the outer cylinder 31, the inner cylinder 32 and the nozzle cylinder 34 And a top plate 35 for connecting the two.

The stem 16 is erected on the mouth portion 2a of the container body 2 so as to be movable downward in an upward biased state. The stem 16 includes an upper stem 41 in which the inner cylinder 32 of the pressing head 20 is externally fitted to the upper end portion, and a lower stem 42 extending downward from the upper stem 41.
The upper stem 41 is formed with a mounting cylinder 43 fitted in the inner cylinder 32 of the pressing head 20 and a diameter larger than that of the mounting cylinder 43, and extends downward from the mounting cylinder 43 to be mounted on the mounting cap. 11 and an insertion cylinder 44 inserted into the upper cylinder part 22. A plurality of locking projections 45 projecting inward in the radial direction are formed in the insertion tube 44 at intervals in the circumferential direction. A sliding cylinder portion 46 that protrudes outward in the radial direction is formed in a lower portion of the insertion cylinder 44 that is located in the upper cylinder portion 22 of the mounting cap 11.

The lower stem 42 includes a first lower stem 51 linked to the liquid piston 14, and a second lower stem 52 linked to the air piston 17 and connecting the first lower stem 51 and the upper stem 41. ing.
The lower part of the first lower stem 51 is externally fitted to a small cylinder part 72 (described later) of the liquid piston 14, and an annular pedestal part 53 that protrudes radially inward is disposed on the upper part. In addition, a flange-shaped contact portion 54 that protrudes outward in the radial direction is disposed at an intermediate portion between the upper portion and the lower portion of the first lower stem 51.

The second lower stem 52 has an upper portion that surrounds the lower portion of the upper stem 41 from the outside in the radial direction, and a lower portion that is externally fitted to the first lower stem 51, and an inner tube 55 that is disposed inside the outer tube 55. , And an inner cylinder 56 disposed immediately above the first lower stem 51.
At the upper end of the inner cylinder 56, a flange-shaped step portion that protrudes inward in the radial direction is formed. A crested cylindrical support portion 57 is erected upward at the stepped portion. A communication hole 58 extending over the entire length in the vertical direction is formed in the support portion 57, and through the communication hole 58, the inside of the inner cylinder 56 of the second lower stem 52 and the inside of the insertion cylinder 44 of the upper stem 41 are formed. , Is in communication.

  Further, the sliding cylinder portion 46 of the upper stem 41 is disposed in an annular groove 61 formed between the outer cylinder 55 and the inner cylinder 56 of the second lower stem 52 so as to be airtightly slidable up and down. Yes. When the upper head 41 is in the standby state before the pressing head 20 is pressed, that is, when the upper stem 41 is in the raised end position, the sliding cylinder portion 46 of the upper stem 41 is positioned above the annular groove 61, The inside of the insertion cylinder 44 of the upper stem 41 communicates. In the annular groove 61, a first urging member 15a that urges the upper stem 41 and the second lower stem 52 in the vertical direction away from each other is disposed. The first urging member 15 a is interposed between the bottom portion of the annular groove 61 and the lower end edge of the upper stem 41 in the second lower stem 52, and the upper urging member 41 is disposed with respect to the second lower stem 52. It is supported so that it can move downward in an upward biased state.

  The air cylinder 12 extends downward from the mounting portion 63 and an annular mounting portion 63 sandwiched in the vertical direction between the connecting step portion 23 of the mounting cap 11 and the mouth portion 2 a of the container body 2. A peripheral wall portion 64 and an annular bottom wall portion 65 projecting radially inward from the peripheral wall portion 64.

  The liquid cylinder 13 is formed integrally with the air cylinder 12. The liquid cylinder 13 is connected to the base tube portion 66 extending downward from the inner peripheral edge of the bottom wall portion 65 of the air cylinder 12 and the lower end of the base tube portion 66 downward. The taper part 67 which is gradually reduced in diameter as it goes is provided with a hanging cylinder part 68 provided continuously from the lower end of the taper part 67 downward. A plurality of vertical ribs extending in the vertical direction are provided on the inner peripheral surface of the portion of the liquid cylinder 13 where the base tube portion 66 and the taper portion 67 are connected to each other at intervals in the circumferential direction.

  A liquid piston 14 is accommodated in the liquid cylinder 13 so as to be slidable in the vertical direction. The liquid piston 14 is linked to the stem 16. The liquid piston 14 is connected to the liquid cylinder 13 in a liquid-tight state so as to be slidable in the vertical direction, the lower end is connected to the large cylinder 71, and the upper part is fitted into the first lower stem 51. And a combined small cylinder portion 72.

  The second urging member 15 b urges the first lower stem 51 upward through the liquid piston 14. The second urging member 15 b is interposed between the portion of the liquid piston 14 where the large cylinder portion 71 and the small cylinder portion 72 are connected and the above-described vertical rib of the liquid cylinder 13. In addition, as the 2nd biasing member 15b and the 1st biasing member 15a mentioned above, a coil spring, a resin spring, etc. are employable, for example. Further, it is preferable that the second urging member 15b has a larger spring constant than that of the first urging member 15a.

  A rod-shaped valve member 73 is inserted into the liquid cylinder 13, the liquid piston 14, and the second urging member 15b. A hollow inverted conical upper valve body 73 a is formed at the upper end portion of the valve member 73, and a lower valve body 73 b is formed at the lower end portion of the valve member 73. The upper valve body 73a is seated on a valve seat formed at the upper end of the liquid piston 14 so as to be separated from above the valve seat. The lower valve body 73 b is spaced upward from the tapered portion 67 of the liquid cylinder 13 and is formed so as to be seated on the tapered portion 67. On the outer peripheral surface of the lower valve body 73b, a guide convex portion (not shown) disposed between the vertical ribs of the liquid cylinder 13 is projected.

  The air piston 17 is accommodated in the air cylinder 12 so as to be slidable up and down. The air piston 17 is linked to the stem 16 (lower stem 42). The air piston 17 includes an inner sliding cylinder part (cylinder part) 75 sheathed on the first lower stem 51, an outer sliding cylinder part 76 fitted in the air cylinder 12, and inner sliding thereof. And a connecting portion 77 that connects the cylindrical portion 75 and the outer sliding cylindrical portion 76.

  The inner sliding cylinder part 75 is externally fitted to the sliding part located above the contact part 54 in the first lower stem 51 so as to be slidable in the vertical direction. And the lower end edge of the inner sliding cylinder part 75 is seated on the contact part 54 so as to be separated from above.

  The connecting portion 77 is formed in an annular shape that connects the central portions in the vertical direction of each of the inner sliding cylinder portion 75 and the outer sliding cylinder portion 76 over the entire circumference. The connecting portion 77 includes an upper chamber 78 a defined above the connecting portion 77 and a lower chamber 78 b defined below the connecting portion 77 in the air cylinder 12. , Through holes are formed.

  A valve cylinder portion 81 is fitted to a portion of the inner sliding cylinder portion 75 located below the portion connected to the connection portion 77. On the outer peripheral surface of the valve cylinder portion 81, an elastically deformable annular outside air introduction valve 81a that opens and closes the above-described through-hole is protruded. The outer peripheral edge portion of the outside air introduction valve 81a is in close contact with the lower surface of the connecting portion 77 so as to be separated.

As shown in FIG. 2, the foaming member 18 is disposed between the gas-liquid mixing chamber 19 and the nozzle hole 33 and foams the gas-liquid mixture transferred from the gas-liquid mixing chamber 19. The foam member 18 includes a casing 82 and a foam element 83.
The casing 82 is formed in a two-stage cylindrical shape having an upper side as a large diameter portion 82a and a lower side as a small diameter portion 82b. The large diameter portion 82 a is fitted in the inner cylinder 56 of the second lower stem 52 described above, and the small diameter portion 82 b is fitted in the upper end portion of the first lower stem 51.

  In the illustrated example, two foaming elements 83 are provided, and both the foaming elements 83 are mounted in the casing 82 (large diameter portion 82a). Of the foam elements 83, the lower foam element 83 has a mesh body 83b stretched on the lower opening surface of the cylinder 83a, and the upper foam element 83 has a mesh on the upper opening face of the cylinder 83a. A body 83b is stretched.

  The gas-liquid mixing chamber 19 mixes the liquid transferred from the liquid cylinder 13 and the air transferred from the air cylinder 12. In the illustrated example, the gas-liquid mixing chamber 19 is provided in the upper end portion of the first lower stem 51. In the first lower stem 51, the gas-liquid mixing chamber 19 is a space between the above-described small diameter portion 82 b of the casing 82 and the upper surface of the pedestal portion 53. A spherical liquid discharge valve 19 a seated on the pedestal 53 is provided in the gas-liquid mixing chamber 19. The liquid discharge valve 19a is seated on the pedestal 53 so as to be separable.

Here, a connection path 85 is defined between the pressing head 20 and the stem 16 to connect the nozzle hole 33 of the pressing head 20 and the foam member 18. Specifically, the connection path 85 includes an upper and lower flow path 85a extending along the vertical direction, and a horizontal flow path 85b extending along the radial direction from the upper end of the vertical flow path 85a.
The vertical channel 85 a is defined by the upper stem 41 and the second lower stem 52, extends upward from the foam member 18, and is disposed coaxially with the axis O. That is, in the upper and lower flow paths 85a, the lower end opening is connected to the foam member 18, and the upper end opening is connected to the nozzle hole 33 via the horizontal flow path 85b.
The lateral flow path 85 b is configured by a portion located inside the nozzle cylinder 34 in the radial direction from the nozzle hole 33.

  The second lower stem 52 is provided with a closing body 87 that closes the upper end opening of the upper and lower flow path 85a so as to be openable and closable. The closing body 87 includes a rod body 88 extending coaxially with the axis O, and a valve body 89 disposed on the upper end portion of the rod body 88.

The rod body 88 is loosely inserted into the upper stem 41, and a lower end portion thereof is fitted into a through hole formed in the top wall portion of the support portion 57 described above, and an upper end portion thereof is the inner cylinder 32 in the pressing head 20. And the nozzle cylinder 34. In addition, projecting portions 90 projecting outward in the radial direction are disposed on the rod body 88 at intervals in the circumferential direction. These protruding portions 90 are formed over the entire portion of the bar body 88 that avoids the lower end portion in the vertical direction, and the lower end edge thereof is close to or in contact with the upper end edge of the support portion 57.
The valve body 89 has a disk shape in a plan view as viewed from the up and down direction, and divides the inside of the connection path 85 into an upper and lower flow path 85a and a horizontal flow path 85b. The lower surface of the valve body 89 is in close contact with the upper end edge of the upper stem 41 (mounting cylinder 43) and closes the vertical flow path 85a.

  In the former dispenser 10 configured as described above, the gas-liquid mixing chamber 19 and the lower chamber 78b of the air cylinder 12 can communicate with each other through the air passage R. That is, the air passage R includes a first communication groove R1 formed on the outer peripheral surface of the casing 82 (small diameter portion 82b) and a second communication groove R2 formed on the outer peripheral surface of the first lower stem 51. I have.

Between the first lower stem 51 and the second lower stem 52, a backflow prevention valve 93 that partitions the air passage R into the gas-liquid mixing chamber 19 side and the air cylinder 12 side is disposed. The backflow prevention valve 93 opens when the air piston 17 descends due to the pressing of the pressing head 20, and prevents the liquid from flowing into the air cylinder 12 through the air passage R from the gas-liquid mixing chamber 19 side (details). Will be described later).
Specifically, the backflow prevention valve 93 is fitted in the outer cylinder 55 of the second lower stem 52, and protrudes radially inward from the valve cylinder part 94, so that the second lower stem 52 And an elastically deformable annular valve body 95 that opens and closes the above-described second communication groove R2 of the stem 52. The inner peripheral edge of the valve body 95 is in close contact with the upper surface of the first lower stem 51 so as to be able to be separated, and closes the above-described second communication groove R2 from above.

  The former dispenser 10 moves the stem 16 downward by depressing the pressing head 20, thereby transferring the liquid in the container body 2 and mixing it with air, and foaming these gas-liquid mixtures. A liquid (hereinafter referred to as a foam) is discharged from the nozzle hole 33.

Next, the operation of the above-described former dispenser 10 will be described. In the former dispenser 10, the valve body 89 of the closing body 87 closes the upper end opening of the upper and lower flow path 85a in a standby state before the pressing head 20 is pressed.
When the former dispenser 10 is used, first, the restricting member 24 (see FIG. 1) is removed from the upper cylindrical portion 22, and then the pressing head 20 is pressed as shown in FIG. In the former dispenser 10, since the spring constant of the first urging member 15a is set smaller than the spring constant of the second urging member 15b as described above, the pressing head 20 and the upper stem 41 are provided with the first attachment. The second lower stem 52 descends against the urging force of the urging member 15a. Thereafter, the pressing projection 20 of the upper stem 41 abuts against the top wall portion of the support portion 57 by continuing to press the pressing head 20. As a result, lowering of the pressing head 20 and the upper stem 41 with respect to the second lower stem 52 is restricted (restricted state).

In the process in which the pressing head 20 and the upper stem 41 are lowered with respect to the second lower stem 52, the upper stem 41 is spaced downward with respect to the valve body 89, thereby opening the upper end opening of the upper and lower flow path 85a. The vertical flow path 85a and the horizontal flow path 85b communicate with each other.
Further, when the pressing head 20 and the upper stem 41 are lowered with respect to the second lower stem 52, the sliding cylinder portion 46 of the upper stem 41 enters the annular groove 61, and the inside of the annular groove 61 is airtightly slid. Move.

Next, as shown in FIG. 4, when the pressing head 20 is further pressed from the restricted state, the pressing head 20, the stem 16, and the liquid piston 14 are integrally pressed down.
At this time, the inner sliding cylinder portion 75 of the air piston 17 slides on the outer peripheral surface of the above-described sliding portion of the first lower stem 51, and the upper end portion of the inner sliding cylinder portion 75 is the second lower stem. By sliding on the inner peripheral surface of 52 (outer cylinder 55), the vertical position of the air piston 17 is maintained. As a result, a communication gap Ra that communicates the air passage R and the lower chamber 78b is formed between the contact portion 54 of the first lower stem 51 and the lower end edge of the inner sliding cylinder portion 75 of the air piston 17. It is formed. At this time, the valve member 73 is also lowered, so that the lower valve body 73b is seated on the taper portion 67 of the liquid cylinder 13 and the lower end opening of the liquid cylinder 13 is closed. Note that the upper valve body 73a of the valve member 73 may be separated from the valve seat portion of the liquid piston 14 when the communication gap Ra is formed.

  Thereafter, as shown in FIGS. 4 and 5, when the pressing head 20 is further pressed, the air piston 17 moves downward together with the pressing head 20, the stem 16 and the liquid piston 14, and the air piston 17 slides outward. The cylindrical portion 76 slides downward on the inner peripheral surface of the peripheral wall portion 64 of the air cylinder 12.

  At this time, the outside air introduction valve 81a remains in close contact with the lower surface of the connecting portion 77, and the through hole of the air piston 17 is closed. Thereby, the air in the lower chamber 78b is compressed, and this air is transferred toward the gas-liquid mixing chamber 19 through the communication gap Ra and the air passage R. Specifically, as shown in FIG. 6, the air that has flowed into the air passage R from the communication gap Ra flows upward in the second communication groove R2 of the air passage R. As a result, the valve body 95 of the check valve 93 is pushed up to open the second communication groove R2. As a result, the air flows from the second communication groove R2 into the first communication groove R1, and is then transferred into the gas-liquid mixing chamber 19.

  At this time, as shown in FIGS. 4 and 5, the liquid piston 14 is moved downward while compressing and deforming the second urging member 15 b with the lower end opening of the liquid cylinder 13 closed. Thus, the upper valve body 73a of the valve member 73 is separated from the valve seat portion of the liquid piston 14. As a result, the inside of the liquid cylinder 13 and the inside of the first lower stem 51 communicate with each other, and the liquid in the liquid cylinder 13 passes through the inside of the valve seat part and the outside of the upper valve body 73a and passes through the first lower part. It is transferred to the gas-liquid mixing chamber 19 in the stem 51.

  As described above, by pressing the pressing head 20, air and liquid are respectively transferred to the gas-liquid mixing chamber 19, and these are merged and mixed in the gas-liquid mixing chamber 19. This gas-liquid mixture is transferred to the foaming member 18 and is passed through the mesh body 83b of the lower foaming element 83 and the mesh body 83b of the upper foaming element 83 in order to be foamed into a foam and connected. It flows through the passage 85 and is discharged from the nozzle hole 33.

  Thereafter, when the pressing of the pressing head 20 is released, the pressing head 20 returns to the standby position by the reverse operation of the above-described ejection. Specifically, when the pressing of the pressing head 20 is released, the liquid piston 14 is raised by the restoring force of the second urging member 15b. As a result, the valve seat portion of the liquid piston 14 contacts the upper valve body 73a of the valve member 73, whereby the communication between the inside of the liquid cylinder 13 and the inside of the first lower stem 51 is cut off, and the gas-liquid mixing is performed. The liquid transfer to the chamber 19 is stopped. Note that it is preferable to release the pressing of the pressing head 20 while putting a hand or the like on the top plate 35 of the pressing head 20.

  The stem 16 and the pressing head 20 are integrally lifted together with the liquid piston 14 thus rising, and the contact portion 54 of the stem 16 is in contact with the lower end edge of the inner sliding cylinder portion 75 of the air piston 17. By contacting, the communication between the lower chamber 78b through the air passage R and the gas-liquid mixing chamber 19 is blocked, and the transfer of air to the gas-liquid mixing chamber 19 is stopped. Thereafter, the piston 17 for air is pushed up together with the stem 16 and the pressing head 20 by the restoring force of the second urging member 15b, so that the inside of the lower chamber 78b is in a negative pressure state. Thereby, the outside air introduction valve 81a is elastically deformed downward, and the through hole of the air piston 17 is opened. Thereby, outside air is supplied into the lower chamber 78b through the through hole and the upper chamber 78a.

  After the second urging member 15b is restored, the pressing head 20 and the upper stem 41 are raised relative to the lower stem 42 by the restoring force of the first urging member 15a. In the process in which the upper stem 41 rises toward the raised end position, the sliding cylinder portion 46 of the upper stem 41 rises so as to be retracted from the annular groove 61. Thereby, the internal volume of the sealing part in the annular groove 61 is expanded, and the inside of the annular groove 61 becomes a negative pressure state. Thereafter, when the sliding tube portion 46 is retracted from the annular groove 61 and the inside of the annular groove 61 and the inside of the insertion tube 44 of the upper stem 41 communicate with each other, the negative pressure in the annular groove 61 is increased inside the upper stem 41. And it acts in the horizontal flow path 85b through the upper end opening of the vertical flow path 85a. As a result, the foam remaining in the horizontal flow path 85b is pulled back from the side of the horizontal flow path 85b toward the vertical flow path 85a (so-called back suction function). Thereby, the dripping from the nozzle hole 33 after foam discharge and the solidification of the foam in the lateral flow path 85b can be suppressed.

  Thereafter, when the upper stem 41 reaches the ascending end position, the lower surface of the valve body 89 is brought into close contact with the upper end edge of the upper stem 41, thereby closing the vertical flow path 85 a. Thereby, the pressing head 20 returns to the standby state shown in FIG.

  As described above, according to the present embodiment, since the second lower stem 52 is provided with the closing body 87 that closes the upper end opening of the upper and lower flow path 85a, the nozzle in the standby state before the pressing head 20 is pressed. It is possible to suppress the foam member 18 from being exposed to the outside air through the hole 33 and the upper end opening. Thereby, it becomes possible to suppress that the liquid dries and solidifies on the foaming member 18, for example, foam of a suitable foam quality can be stably foamed.

Here, in this embodiment, it was set as the structure provided with the backflow prevention valve 93 which partitions off the air path R into the gas-liquid mixing chamber 19 side and the air cylinder 12 side.
According to this configuration, for example, when the discharge container 1 is placed in a high-temperature environment or the like, the internal pressure of the air cylinder 12 rises, and the air piston 17 rises with respect to the first lower stem 51. Even if the inner sliding cylinder portion 75 of the piston 17 is separated from the contact portion 54 and the air passage R communicates with the air cylinder 12 through the communication gap Ra, the air-liquid mixing chamber 19 side of the air passage R The state where the communication with the air cylinder 12 side is blocked by the check valve 93 is maintained. Thereby, the backflow prevention valve 93 can prevent the liquid from flowing into the air cylinder 12 through the air passage R from the gas-liquid mixing chamber 19 side.

  As mentioned above, although embodiment of this invention was explained in full detail with reference to drawings, the concrete structure is not restricted to this embodiment, The design change etc. of the range which does not deviate from the summary of this invention are included.

For example, in the above-described embodiment, the configuration in which the connection path 85 includes the upper and lower flow paths 85a and the horizontal flow path 85b has been described. However, the connection path 85 may have at least the upper and lower flow paths 85a.
In the above-described embodiment, the configuration in which the lower stem 42 includes the first lower stem 51 and the second lower stem 52 has been described, but the configuration is not limited thereto.

  In addition, in the range which does not deviate from the meaning of this invention, it is possible to replace suitably the component in the embodiment mentioned above by the known component, and you may combine the modification mentioned above suitably.

DESCRIPTION OF SYMBOLS 2 ... Container body 2a ... Port part 3 ... Pump 10 ... Former dispenser 12 ... Air cylinder 13 ... Liquid cylinder 14 ... Liquid piston 16 ... Stem 17 ... Air piston 18 ... Foam member 19 ... Gas-liquid mixing chamber 20 ... Depressing head 33 ... Nozzle hole 41 ... Upper stem 42 ... Lower stem 75 ... Inner sliding cylinder part (cylinder part)
85 ... Connection path 85a ... Upper / lower flow path 87 ... Occlusion body 93 ... Backflow prevention valve R ... Air passage

Claims (3)

A pump having a stem erected at the mouth of the container body in which the liquid is accommodated in an upwardly biased state; and
A presser head disposed at the upper end of the stem and having a nozzle hole formed therein,
The pump includes
A liquid piston and an air piston linked to the stem;
A liquid cylinder in which the liquid piston is housed slidably up and down;
An air cylinder in which the air piston is housed slidably up and down;
A gas-liquid mixing chamber for mixing the liquid from the liquid cylinder and the air from the air cylinder;
A foam member for foaming the gas-liquid mixture from the gas-liquid mixing chamber,
The stem is
An upper stem to which the pressing head is mounted at the upper end;
A lower stem extending downward from the upper stem,
The upper stem is supported to be movable downward in an upward biased state with respect to the lower stem,
Between the nozzle hole and the foaming member, a connection path having a vertical channel extending in the vertical direction is disposed,
The lower stem is provided with a closing body that is erected upward and closes an upper end opening of the upper and lower flow path,
The former dispenser, wherein the closing body opens the upper end opening as the upper stem descends with respect to the lower stem.   The lower stem is formed with an annular groove that communicates with the upper stem and in which the lower end of the upper stem slides in an airtight manner as the upper stem descends relative to the lower stem. The former dispenser according to claim 1. The pump is formed with an air passage that communicates between the air cylinder and the gas-liquid mixing chamber,
The air piston includes a cylindrical portion through which the lower stem is inserted,
The lower stem is formed with a flange-like contact portion that protrudes outward in the radial direction of the lower stem and contacts the lower end of the cylindrical portion from below the cylindrical portion,
A part of the air passage is formed between the tube portion and the lower stem,
The pump has a backflow prevention valve that is opened when the air piston is lowered due to depression of the pressing head, and that prevents liquid from flowing from the gas-liquid mixing chamber side into the air cylinder through the air passage. The former dispenser according to claim 1, wherein the former dispenser is disposed.

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