JP7490305B2 - Pump dispenser and discharge container - Google Patents

Description

The present invention relates to a pump dispenser and a dispensing container.

For example, as described in Patent Document 1, a pump dispenser is known that includes a fixed member having a cylinder and fixed to the mouth of the container body, an actuating member that cooperates with the cylinder to form a pump chamber and has a discharge valve for the pump chamber and an internal flow path that communicates with the pump chamber via the discharge valve, and that reduces the volume of the pump chamber by being pushed down in the axial direction of the cylinder against a reaction force, and a rod-shaped valve body that is rod-shaped and extends vertically and constitutes a suction valve for the pump chamber, and the actuating member includes an annular piston that slides vertically on the inner peripheral surface of the cylinder, a cylindrical stem having a lower end that presses down the piston, and a piston guide that has a valve seat for the discharge valve that seats and presses up the piston, is fixed to the stem, and slides vertically on the outer peripheral surface of the rod-shaped valve body.

With a discharge container that includes such a pump dispenser and a container body to which the pump dispenser is attached and that contains liquid, the volume of the pump chamber can be increased or decreased by repeatedly pressing down and releasing the actuating member, thereby discharging the liquid in the container body through the internal flow path of the actuating member. In addition, the piston guide slides on the outer circumferential surface of the rod-shaped valve body to guide it in the vertical direction, allowing for smooth pressing and returning of the actuating member.

JP 2016-83616 A

However, in conventional pump dispensers having the above-mentioned structure, the piston guide has a cylindrical piston guide body that forms part of the internal flow path of the actuating member on the radially inward side, and the piston guide body is configured to slide up and down in tight contact on the outer circumferential surface of the rod-shaped valve body. For this reason, depending on the materials of the piston guide and the rod-shaped valve body, the piston guide may swell and expand in diameter upon contact with liquid, compromising the tightness between the piston guide and the rod-shaped valve body, i.e., airtightness, and adversely affecting the pump function, resulting in a problem of limiting the types of liquid that can be stored in the container body.

The present invention aims to solve these problems, and its objective is to provide a pump dispenser and a dispensing container in which the type of liquid that can be contained in the container body is not likely to be limited by the materials of the piston guide and the rod-shaped valve body.

The pump dispenser of the present invention includes a fixed member having a cylinder and fixed to an opening portion of a container body, an actuating member which cooperates with the cylinder to form a pump chamber, has a discharge valve for the pump chamber, and an internal flow path which communicates with the pump chamber via the discharge valve, and which reduces the volume of the pump chamber by being pushed down in the axial direction of the cylinder against a reaction force, and a rod-shaped valve body which is rod-shaped and extends in a vertical direction and constitutes a suction valve for the pump chamber, and the actuating member is an annular piston which slides in the vertical direction on the inner peripheral surface of the cylinder, and a rod-shaped valve body which slides in the vertical direction on the piston. and a piston guide having a valve seat for the discharge valve on which the piston seats and is fixed to the stem, the piston guide comprising a topped cylindrical piston guide body which slides in the up-down direction on the outer circumferential surface of the rod-shaped valve body and which is open only downward , and when the operating member is pressed down and the inside of the pump chamber is pressurized, the rod-shaped valve body is pressed down by the sliding resistance between the outer circumferential surface of the rod-shaped valve body and the piston guide body, thereby maintaining the suction valve in a closed state .

In addition, in the pump dispenser of the present invention, in the above configuration, it is preferable that one of the inner peripheral surface of the piston guide body and the outer peripheral surface of the rod-shaped valve body is provided with a plurality of sliding protrusions arranged in the circumferential direction, which slide in the up-down direction on the other of the inner peripheral surface of the piston guide body and the outer peripheral surface of the rod-shaped valve body.

The discharge container of the present invention is characterized by comprising the pump dispenser and a container body to which the pump dispenser is attached and which contains liquid.

The present invention provides a pump dispenser and a dispensing container in which the type of liquid that can be accommodated in the container body is not likely to be limited by the materials of the piston guide and the rod-shaped valve body.

1 is a vertical cross-sectional view showing a dispensing container according to an embodiment of the present invention in a state before an actuation member is pressed down. 2 is a cross-sectional view taken along line AA in FIG. 1. 2 is a vertical cross-sectional view showing the discharge container shown in FIG. 1 in a state where an actuating member is pressed down. FIG.

The following describes an example of a pump dispenser 1 and a dispenser container 2 according to one embodiment of the present invention with reference to the drawings.

In this specification, the up-down direction means the direction along the central axis O of the cylinder 18, i.e., the axial direction of the cylinder 18, the down direction means the direction in which the actuating member 5 is pushed down, the up direction means the opposite direction, the circumferential direction means the direction going around the central axis O, the radial direction means the direction along a straight line perpendicular to the central axis O, the longitudinal section means a section including the central axis O, and the transverse section means a section perpendicular to the central axis O.

As shown in FIG. 1, the pump dispenser 1, which is an embodiment of the present invention, constitutes a dispensing container 2, which is an embodiment of the present invention, together with a container body 3 to which the pump dispenser 1 is attached and which contains liquid L.

The container body 3 has a cylindrical mouth 3a, a body 3b connected to the lower end of the mouth 3a, and a bottom (not shown) connected to the lower end of the body 3b, forming a storage space S inside which liquid L is stored. Note that the mouth 3a may be in a tubular shape other than a cylindrical shape.

The liquid L contained in the container body 3 is a cleaning agent or cosmetic product, but is not limited to this and may be, for example, food, medicine, etc.

The pump dispenser 1 comprises a fixed member 4, an actuating member 5, a rod-shaped valve body 6, a spring 7, and a cover 8. The fixed member 4 is composed of a cylinder member 9, a suction pipe 10, a cap 11, a retaining member 12, and a packing 13. The actuating member 5 is composed of a piston 14, a stem 15, a piston guide 16, and a nozzle head 17.

The cylinder member 9, suction pipe 10, cap 11, retaining member 12, piston 14, stem 15, piston guide 16, nozzle head 17, rod-shaped valve body 6, and cover 8 are each integrally molded by injection molding of a synthetic resin material. The spring 7 is made of metal, but may also be made of synthetic resin, etc.

The cylinder member 9, rod-shaped valve body 6 and stem 15 are made of polybutylene terephthalate resin, the piston 14 is made of linear low-density polyethylene (LLDPE) resin, and the piston guide 16 is made of high-density polyethylene (HDPE) resin.

The fixing member 4 has a cylinder 18 and is fixed to the mouth portion 3a of the container body 3.

The cylinder 18 is provided in the cylinder member 9 and is composed of a cylindrical peripheral wall 18a centered on the central axis O, and a bottom wall 18b connected to the lower end of the peripheral wall 18a.

The peripheral wall 18a is fixed to the upper end surface of the mouth portion 3a by the cap 11 via the extension portion 9a. The extension portion 9a is composed of an upper peripheral wall 9b that extends upward from the upper end of the peripheral wall 18a and has a cylindrical shape coaxial with the central axis O, and a flange 9c that protrudes from the outer peripheral surface of the upper peripheral wall 9b. A gasket 13 is arranged on the lower surface of the flange 9c. The cap 11 has a cylindrical wall 11a that is attached to the outer peripheral surface of the mouth portion 3a via a threaded portion, an annular top wall 11b that protrudes radially inward from the upper end of the cylindrical wall 11a, and an upper cylinder 11c that extends upward from the inner peripheral edge of the top wall 11b and has a cylindrical shape coaxial with the central axis O. By attaching the cylindrical wall 11a to the mouth portion 3a, the flange 9c is sandwiched between the top wall 11b and the upper end surface of the mouth portion 3a, and thus the cylinder 18 is fixed to the mouth portion 3a. The cylinder 18 is arranged coaxially with the mouth portion 3a.

A retaining member 12 is fixed to the inner peripheral surface of the extension 9a by fitting to prevent the stem 15 from slipping out upward. The stem 15 is arranged coaxially with the central axis O and has a main body peripheral wall 15b that is a two-stage cylinder with an expanded diameter at the lower end 15a. The retaining member 12 has a lower tube wall 12a with an inner diameter equal to or larger than the outer diameter of the lower end 15a of the stem 15, and an upper tube wall 12b with an inner diameter smaller than the outer diameter of the lower end 15a of the stem 15.

The bottom wall 18b of the cylinder 18 has a suction port 18c arranged coaxially with the central axis O. A suction pipe 10 is attached to the suction port 18c. The suction pipe 10 extends from the suction port 18c toward the bottom of the container body 3. The suction port 18c is also provided with a suction valve seat 18d on which the rod-shaped valve body 6 is seated from above. The rod-shaped valve body 6 is movable in the vertical direction relative to the suction valve seat 18d, and its lower end has a seating portion 6a that seats on the valve seat 18d. In other words, the rod-shaped valve body 6, together with the suction valve seat 18d, constitutes a suction valve 20 of the pump chamber 19 described later. The suction valve 20 allows the flow of liquid L from the storage space S toward the pump chamber 19, while functioning as a check valve that blocks the flow of liquid L from the pump chamber 19 toward the storage space S.

The actuating member 5 cooperates with the cylinder 18 to form the pump chamber 19, and has a discharge valve 21 for the pump chamber 19 and an internal flow passage 22 that communicates with the pump chamber 19 via the discharge valve 21. The actuating member 5 is a member that reduces the volume of the pump chamber 19 by being pushed down in the axial direction of the cylinder 18 against the reaction force.

The piston 14 of the actuating member 5 is an annular member that slides vertically on the inner circumferential surface of the cylinder 18. The piston 14 has a cylindrical outer sliding part 14a that slides vertically on the inner circumferential surface of the cylinder 18 while in close contact with the inner circumferential surface, a cylindrical inner sliding part 14b that slides vertically on the inner circumferential surface of the lower end part 15a of the stem 15 while in close contact with the inner circumferential surface, and a partition wall 14c that closes the gap between the outer sliding part 14a and the inner sliding part 14b.

The lower end of the inner sliding portion 14b of the piston 14 has a seating portion 14d that seats on the valve seat 16a of the piston guide 16. The piston 14 can move upward relative to the piston guide 16 by pressing down on the actuating member 5, and can move downward relative to the piston guide 16 by releasing the pressing. Thus, the piston 14, together with the valve seat 16a of the piston guide 16, constitutes the discharge valve 21 of the pump chamber 19. The discharge valve 21 functions as a check valve that allows the flow of liquid L from the pump chamber 19 toward the internal flow path 22, while preventing the flow of liquid L from the internal flow path 22 toward the pump chamber 19.

The stem 15 of the actuating member 5 is a cylindrical member having a lower end 15a that pushes down the piston 14. The stem 15 has the aforementioned main body peripheral wall 15b and a number of vertical ribs 15c arranged in a circumferential direction on the inner peripheral surface of the main body peripheral wall 15b.

The nozzle head 17 of the actuating member 5 is a member attached to the upper end of the main body wall 15b of the stem 15 and has an outlet 17a for the liquid L. The nozzle head 17 has a cylindrical inner wall 17b arranged coaxially with the central axis O, an outer wall 17c arranged coaxially on the radially outer side of the inner wall 17b, a top wall 17d that connects the upper ends of the inner wall 17b and the outer wall 17c and is pressed down, and a cylindrical tip nozzle 17e that extends laterally from the side of the inner wall 17b and has an outlet 17a at its tip. The inner wall 17b is attached to the upper end of the main body wall 15b of the stem 15 by fitting, and the internal space of the inner wall 17b is connected to the outlet 17a through the inside of the tip nozzle 17e. The outer peripheral wall 17c has an inner diameter equal to or greater than the outer diameter of the upper tube 11c of the cap 11, and the lower end of the outer peripheral wall 17c is located directly above the top wall 11b of the cap 11.

The piston guide 16 of the actuating member 5 has a valve seat 16a of the discharge valve 21 on which the piston 14 is seated and pushed up, and is a member fixed to the stem 15. The piston guide 16 has a topped cylindrical piston guide body 16b that slides vertically on the outer circumferential surface of the rod-shaped valve body 6 and is open only downward.

The piston guide 16 also has an enlarged diameter portion 16c that extends radially outward from the lower end of the piston guide body 16b. A valve seat 16a of the discharge valve 21 is provided on the upper surface of the enlarged diameter portion 16c. The outer peripheral edge of the enlarged diameter portion 16c has a guided portion 16d that is guided in the vertical direction by the inner peripheral surface of the cylinder 18. The enlarged diameter portion 16c also has a passage port 16e for liquid L that connects the space on its lower surface side to the space on its upper surface side radially outward of the valve seat 16a.

The outer peripheral surface of the piston guide body 16b is provided with a number of vertically extending guide ribs 16f arranged in the circumferential direction to guide the inner sliding portion 14b of the piston 14 in the vertical direction. In addition, the upper end of the piston guide body 16b is provided with an upper end cylindrical wall 16g that is cylindrical and coaxial with the piston guide body 16b. The upper end of the piston guide body 16b and the upper end cylindrical wall 16g are attached to the multiple vertical ribs 15c of the stem 15 by fitting.

The internal flow passage 22 of the actuating member 5 is therefore composed of the space between the inner sliding portion 14b of the piston 14 and the piston guide body 16b, the space between the stem 15 and the piston guide body 16b and the upper end cylindrical wall 16g (the space between the multiple vertical ribs 15c), the space inside the stem 15 above the upper end cylindrical wall 16g, the space inside the inner peripheral wall 17b of the nozzle head 17, and the space inside the tip nozzle 17e.

The spring 7 is a member that applies a reaction force to the operating member 5 when it is pressed down. The spring 7 is a coil-shaped compression spring that is arranged coaxially with the central axis O. A number of vertical ribs 18e extending in the vertical direction are arranged in a circumferential direction at the lower end of the peripheral wall 18a of the cylinder 18, and the lower end of the spring 7 abuts against the upper surfaces of these vertical ribs 18e. In addition, the upper end of the spring 7 abuts against the lower surface of the enlarged diameter portion 16c of the piston guide 16.

The rod-shaped valve body 6 is a rod-shaped member extending vertically and constituting the suction valve 20 of the pump chamber 19. The rod-shaped valve body 6 has a hollow columnar valve body 6b whose lower end is arranged coaxially with the central axis O, and a columnar body 6c which extends coaxially upward from the upper end of the valve body 6b and has a smaller diameter than the valve body 6b. The lower end of the valve body 6b has the seat portion 6a described above. In addition, a number of locking projections 6d are arranged in the circumferential direction on the outer peripheral surface of the valve body 6b, which abut against the lower end of the spring 7 to stop the upward movement of the rod-shaped valve body 6.

The piston guide body 16b is configured to slide vertically on the outer circumferential surface of the columnar body 6c of the rod-shaped valve body 6 with the radially inner space of the piston guide body 16b communicating with the pump chamber 19. More specifically, as shown in FIG. 2, a plurality of (four) sliding protrusions 16h are arranged in the circumferential direction on the inner circumferential surface at the lower end of the piston guide body 16b, and each of the sliding protrusions 16h can slide vertically on the outer circumferential surface of the columnar body 6c. In addition, the radially inner space of the piston guide body 16b communicates with the pump chamber 19 through the circumferential gaps between the plurality of sliding protrusions 16h. The number, shape and arrangement of the sliding protrusions 16h can be changed as appropriate. In addition, the sliding protrusions 16h may be provided on the outer circumferential surface of the columnar body 6c instead of on the inner circumferential surface of the piston guide body 16b. By configuring the piston guide body 16b to slide vertically on the outer circumferential surface of the columnar body 6c of the rod-shaped valve body 6 via the multiple sliding protrusions 16h, when the actuating member 5 is pushed down to pressurize the pump chamber 19, the rod-shaped valve body 6 is pushed down by the sliding resistance of the multiple sliding protrusions 16h, and the suction valve 20 can be maintained in a closed state. In addition, at that time, the piston guide body 16b and the rod-shaped valve body 6 slide locally via the multiple sliding protrusions 16h, which suppresses the generation of excessive sliding resistance, and the radially inner space of the piston guide body 16b is connected to the pump chamber 19, allowing the actuating member 5 to be pushed down smoothly.

As shown in FIG. 1, the cover 8 is a member that covers the nozzle head 17 by being detachably attached to the fixing member 4. The cover 8 has a stopper portion 8a with a generally C-shaped cross section that is detachably attached to the upper tube 11c of the cap 11. When attached to the upper tube 11c, the stopper portion 8a is interposed between the upper surface of the top wall 11b of the cap 11 and the lower end of the outer peripheral wall 17c of the nozzle head 17, thereby preventing the nozzle head 17 from being unintentionally pressed down. The upper end of the stopper portion 8a is connected to a cover main body 8b that covers the tip nozzle 17e and top wall 17d of the nozzle head 17 when the stopper portion 8a is attached to the upper tube 11c.

Therefore, by removing the cover 8 from the state shown in FIG. 1 and pressing down the top wall 17d of the nozzle head 17, the actuating member 5 is pressed down against the reaction force of the spring 7 as shown in FIG. 3, thereby decreasing the volume of the pump chamber 19, closing the suction valve 20, opening the discharge valve 21, and discharging the liquid L in the pump chamber 19 from the discharge port 17a through the internal flow path 22 of the actuating member 5. In addition, by releasing the pressing operation, the actuating member 5 is returned upward by the reaction force of the spring 7, thereby increasing the volume of the pump chamber 19, opening the suction valve 20, closing the discharge valve 21, and sucking up the liquid L in the storage space S into the pump chamber 19. In addition, at that time, the piston guide 16 slides on the outer circumferential surface of the rod-shaped valve body 6 to be guided in the vertical direction, allowing the actuating member 5 to be smoothly pressed down and returned.

As described above, in this embodiment, the piston guide 16 is provided with a cylindrical piston guide body 16b with a top that slides vertically on the outer circumferential surface of the rod-shaped valve body 6 and opens only downward. Therefore, the internal flow path 22 of the actuating member 5 is formed only on the outside of the piston guide body 16b, not on the inside, so there is no need to seal the sliding contact between the inner circumferential surface of the piston guide body 16b and the outer circumferential surface of the rod-shaped valve body 6 by tightly contacting them. Therefore, even if the piston guide 16 and the rod-shaped valve body 6 swell due to contact with the liquid L and their contact state changes, the pump function can be maintained well.

This makes it possible to prevent the type of liquid L that can be contained in the container body 3 from being limited to those that do not swell the piston guide 16 and the rod-shaped valve body 6. Although polyester resins such as polybutylene terephthalate resin are less likely to cause such swelling, it is not preferable to use polybutylene terephthalate resin for two members that slide against each other in a tight contact state, since the sliding resistance is relatively large. In addition, although it is preferable for the liquid L as a cleansing agent or cosmetic to contain these components for functional reasons, examples of components that tend to swell or soften polyolefin resins such as high density polyethylene (HDPE) resin and linear low density polyethylene (LLDPE) resin include hydrocarbon oils, ester oils, polyols, etc.

The present invention is not limited to the above-described embodiment, and various modifications are possible without departing from the spirit of the invention.

Therefore, the pump dispenser 1 and the dispensing container 2 of the above embodiment can be modified in various ways, for example as described below.

As long as the pump dispenser 1 includes the fixed member 4, the actuating member 5, and the rod-shaped valve body 6, various modifications are possible. As long as the fixed member 4 has a cylinder 18 and is fixed to the mouth portion 3a of the container body 3, various modifications are possible. The actuating member 5 cooperates with the cylinder 18 to form the pump chamber 19, has a discharge valve 21 of the pump chamber 19, and an internal flow path 22 that communicates with the pump chamber 19 via the discharge valve 21, and reduces the volume of the pump chamber 19 by being pushed down in the axial direction of the cylinder 18 against the reaction force, and as long as it includes the piston 14, the stem 15, and the piston guide 16, various modifications are possible. As long as the piston 14 is annular and slides up and down on the inner surface of the cylinder 18, various modifications are possible. As long as the stem 15 is cylindrical and has a lower end 15a that pushes down the piston 14, various modifications are possible. The piston guide 16 has a valve seat 16a of the discharge valve 21 that seats and pushes up the piston 14, is fixed to the stem 15, and can be modified in various ways as long as it has a piston guide body 16b. The piston guide body 16b can be modified in various ways as long as it is a topped cylindrical body that slides vertically on the outer circumferential surface of the rod-shaped valve body 6 and opens only downward. The rod-shaped valve body 6 can be modified in various ways as long as it is a rod-shaped body that extends vertically and constitutes the suction valve 20 of the pump chamber 19.

However, it is preferable that one of the inner peripheral surface of the piston guide body 16b and the outer peripheral surface of the rod-shaped valve body 6 is provided with a plurality of sliding protrusions 16h arranged in the circumferential direction, which slide vertically on the other of the inner peripheral surface of the piston guide body 16b and the outer peripheral surface of the rod-shaped valve body 6.

The discharge container 2 can be modified in various ways as long as it comprises a pump dispenser 1 and a container body 3 to which the pump dispenser 1 is attached and which contains the liquid L.

In the above embodiment, the fixed member 4 is composed of a cylinder member 9, a suction pipe 10, a cap 11, a retaining member 12, and a packing 13, but is not limited to this. Also, in the above embodiment, the operating member 5 is composed of a piston 14, a stem 15, a piston guide 16, and a nozzle head 17, but is not limited to this.

In the above embodiment, the cylinder member 9, rod-shaped valve body 6, and stem 15 are made of polybutylene terephthalate resin, the piston 14 is made of linear low-density polyethylene (LLDPE) resin, and the piston guide 16 is made of high-density polyethylene (HDPE) resin, but this is not limited to the above. However, it is preferable that the cylinder member 9, rod-shaped valve body 6, and stem 15 are made of polyester resin, and the piston 14 and piston guide 16 are made of polyolefin resin.

REFERENCE SIGNS LIST 1 Pump dispenser 2 Discharge container 3 Container body 3a Mouth portion 3b Body portion 4 Fixing member 5 Actuating member 6 Rod-shaped valve body 6a Seat portion 6b Valve body 6c Column-shaped body 6d Locking projection 7 Spring 8 Cover 8a Stopper portion 8b Cover body 9 Cylinder member 9a Extension portion 9b Upper peripheral wall 9c Flange 10 Suction pipe 11 Cap 11a Cylinder wall 11b Top wall 11c Upper cylinder 12 Stop member 12a Lower cylinder wall 12b Upper cylinder wall 13 Gasket 14 Piston 14a Outer sliding portion 14b Inner sliding portion 14c Partition wall 14d Seat portion 15 Stem 15a Lower end portion 15b Body peripheral wall 15c Vertical rib 16 Piston guide 16a Valve seat 16b Piston guide body 16c Expanded diameter portion 16d, guided portion 16e, passage port 16f, guide rib 16g, upper end cylindrical wall 16h, sliding protrusion 17, nozzle head 17a, discharge port 17b, inner circumferential wall 17c, outer circumferential wall 17d, top wall 17e, tip nozzle 18, cylinder 18a, peripheral wall 18b, bottom wall 18c, suction port 18d, suction valve seat 18e, vertical rib 19, pump chamber 20, suction valve 21, discharge valve 22, internal flow path L, liquid O, central axis S, storage space

Claims (3)

A fixing member having a cylinder and fixed to a mouth portion of the container body;
an actuating member which cooperates with the cylinder to form a pump chamber, which has a discharge valve for the pump chamber and an internal flow passage which communicates with the pump chamber via the discharge valve, and which reduces a volume of the pump chamber by being pushed down in the axial direction of the cylinder against a reaction force;
a rod-shaped valve body extending in a vertical direction and constituting a suction valve of the pump chamber;
The actuating member is
an annular piston that slides in the up-down direction on an inner circumferential surface of the cylinder;
a cylindrical stem having a lower end for pushing down the piston;
a piston guide having a valve seat for the discharge valve on which the piston is seated and pushed up, the piston guide being fixed to the stem;
The piston guide includes a piston guide body having a cylindrical shape with a top that slides in the up-down direction on an outer circumferential surface of the rod-shaped valve body and is open only downward ,
a piston guide body that is provided with a piston guide member and ... The pump dispenser according to claim 1, wherein one of the inner peripheral surface of the piston guide body and the outer peripheral surface of the rod-shaped valve body has a plurality of sliding protrusions arranged in the circumferential direction and sliding in the up-down direction on the other of the inner peripheral surface of the piston guide body and the outer peripheral surface of the rod-shaped valve body. A dispensing container comprising the pump dispenser according to claim 1 or 2, and a container body to which the pump dispenser is attached and which contains a liquid.

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