JPH0958732A - Pump unit for container - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simplify the structure of a pump unit for a container and to reduce cost therefor. SOLUTION: A suction valve 20, a piston main body 30, a stem 40, a piston valve 50, a spring 90, and a delivery valve 91 are assembled into a cylinder 10, and a flange 13 of the cylinder 10 is mounted on a cap 70 and a pump head 80 is mounted on the upper part of the stem 40. A first passage 35 is formed between the outer circumferential face of a partition wall 31 of the piston main body 30 and the inner circumferential face of the cylinder 10, a second passage 37 is formed between the outer circumferential face of a shaft sleeve part 33 of the piston main body 30 and the piston valve 50, a third passage 46 is formed between the outer circumferential face of the shaft sleeve part 33 and the inner circumferential face of the stem 40, and a pump chamber 19 and a delivery passage 44 in the stem 40 are made to communicate with each other through the first passage 35, the second passage 37 and the third passage 46 while the second passage 37 is made available for being shut by movement of the piston main body 30 and relative vertical movement of the piston valve 50 against the stem 40.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pump device which is attached to a mouth tube of a container and pours out the contents in the container.

[0002]

2. Description of the Related Art Japanese Utility Model Publication No. 7-13816 discloses one of such container pump devices. This pump device is provided with a cylinder having a hollow cylindrical shape, the inside of which is a pump chamber and having a suction port at a lower portion thereof, and the cylinder is attached to the mouth cylinder portion of the container by a cap. Inside the cylinder, a suction valve, a piston body, and a piston valve are incorporated, a stem is connected to an upper portion of the piston body, and a pump head having a pouring nozzle is fixed to a tip of the stem.

A hollow cylindrical piston main body having an opening at the top and bottom and a hollow cylindrical stem connected to the piston main body and used as a pouring passage for the piston can move up and down in the cylinder. On the outer side, a piston packing that slides in a sealed state on the inner peripheral surface of the cylinder and the outer peripheral surface of the piston body is attached so as to be vertically movable relative to the piston body. This piston packing has a function of opening and closing a through hole provided in a peripheral wall portion of the piston body in a direction orthogonal to the axis.

The suction valve is arranged below the piston body, and a guide rod extends upward from a valve body that opens and closes the suction port of the cylinder. The guide rod is sealed from the lower opening of the piston body. It is slidably inserted.

A space surrounded by the cylinder, the suction valve, the piston body and the piston valve forms a pump chamber, and the pump chamber communicates with a pouring passage in the stem when the through hole of the piston body is opened. When the through hole is closed by the piston valve, it is cut off from the pouring passage.

In the conventional pump device having such a structure, when the pump head is pushed down, the suction valve closes the suction port, the piston body descends together with the stem, the piston valve opens the through hole, and the pump chamber is closed. Contents are pushed out into the spouting passage in the stem through the through hole and are spouted out from the spout of the pump head.

When the pushed piston body and stem are pushed back by the elasticity of the spring provided between the piston body and the cylinder and pushed up, the piston valve rises together with the piston body while closing the through hole. Therefore, the pump chamber becomes negative pressure,
The suction valve is lifted upward to open the suction port, and the contents in the container are pumped up from the suction port into the pump chamber.

[0008]

In the container pump device, it is general that almost all members are made of plastic, but in the conventional container pump device having the above-mentioned structure,
A through hole as a flow path must be provided in the peripheral wall portion of the piston main body in a direction orthogonal to the axis, and when the piston main body is injection-molded using a mold, a hole-shaped This requires horizontal punching, which complicates the mold structure and contributes to an increase in manufacturing cost.

The present invention has been made in view of the above problems of the prior art, and an object of the present invention is to provide a container pump device having a simple structure and capable of reducing the manufacturing cost.

[0010]

The present invention adopts the following means in order to solve the above problems. The present invention is (a)
A cylinder having a hollow tubular shape, the inside of which is a pump chamber, a suction port which is connected to the pump chamber is provided in the lower portion, and which is inserted into the container from the mouth tube portion of the container and fixed to the mouth tube portion,
(B) A suction valve that allows the inflow into the pump chamber from the suction port of the cylinder and prevents the outflow from the pump chamber into the container, and (c) is mounted in the cylinder so as to be able to move up and down,
A partition wall portion that partitions the pump chamber is provided at a lower portion, a shaft portion stands up from the partition wall portion, and a first flow path that connects to the pump chamber is provided between an outer peripheral surface of the partition wall portion and an inner peripheral surface of the cylinder. (D) It has a hollow cylindrical shape with the piston body, the inside is a pouring passage, the lower part is vertically inserted into the cylinder, the upper part is projected from the cylinder, and the shaft of the piston main body is opened from the lower opening. The upper part of the shaft portion is inserted, and the stem connected to and fixed to the shaft part by forming a third flow path connecting to the outer peripheral surface of the shaft part and forming a (3) annular shape. It is arranged between the inner peripheral surface and the outer peripheral surface of the shaft portion of the piston body, and is movably attached between the partition wall portion of the piston body and the lower end of the stem along the axial direction. The first flow path and the third flow path between the first flow path and the third outer surface.
A second flow passage that communicates with the flow passage is formed, and a first seal portion that slides in pressure contact with the inner peripheral surface of the cylinder, a second seal portion that slides in pressure contact with the lower inner peripheral surface of the stem, and the partition wall portion of the piston body A piston valve having a third seal portion that abuts and blocks the first flow path and the second flow path; and (f) a spring that is installed between the cylinder and the piston body and biases the piston body upward. And (g) a pump head that is fixed to the upper end of the stem and has a spout for pouring out the contents in the spout passage of the stem, and a piston valve when the pump head, the stem, and the piston body descend The third seal portion is separated from the partition wall portion of the piston body, the pouring passage of the pump chamber communicates with the pouring passage of the stem through the first flow passage, the second flow passage, and the third flow passage, and the pouring outlet of the pump head The contents can be poured out from the When the valve, stem and piston body rise, the third seal part of the piston valve abuts the partition wall of the piston body to block the first and second flow paths, the suction valve opens and the contents in the container A container pump device characterized by being pumped up from a suction port of a cylinder into a pump chamber (corresponding to claim 1).

When the piston body and stem descend,
The third seal portion of the piston valve separates from the partition wall portion of the piston body to open the second flow passage, and the pouring into the pump chamber and the stem through the first flow passage, the second flow passage, and the third flow passage. The passage connects. Therefore, when the piston body descends, the contents in the pump chamber pass through the first flow path, the second flow path, and the third flow path,
It is poured from the pouring outlet of the pump head through the pouring passage. Since the pouring path of the contents passes through the outside of the piston main body, it is not necessary to use the inside of the piston main body as a flow path, and it is not necessary to provide a through hole as a flow path in the piston main body.

When the piston body and the stem rise, the third seal portion of the piston valve abuts on the partition wall portion of the piston body to close the second flow passage and shut off the pump chamber from the pouring passage. Therefore, as the piston body rises, the suction valve opens the suction port, and the contents in the container are pumped up from the suction port to the pump chamber.

The container pump device of the present invention can also be configured as follows. That is, the suction valve includes a valve body that opens and closes the suction port of the cylinder, and a guide rod that extends upward from the valve body. The shaft portion of the piston body has a hollow cylindrical shape and the partition wall portion has a shaft portion. Is formed so that the guide rod of the suction valve is inserted into the hollow portion of the shaft portion in a sealed state so as to be capable of relative up and down movement (corresponding to claim 2).

With this construction, the inside of the shaft portion of the piston body communicates with the pouring passage of the stem, but the lower end of the shaft portion of the piston body is closed by the guide rod of the suction valve. The interior of the piston does not function as a flow path for the contents, but merely guides the guide rod of the suction valve.

<Raw Material of the Present Invention> Each component of the container pump device of the present invention can be formed of plastic.

[0016]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to FIG.
3 will be described with reference to FIG. 1 and 2 show a container pump device of the present invention (hereinafter, simply referred to as a pump device).
FIG.

The pump device is attached to the mouth tube portion 2 of the container 1, and its main components are a cylinder 10, a suction valve 20, a piston body 30, a stem 40, a piston valve 50, and a cap 70. , Pump head 80,
The spring 90, the discharge valve 91, the packing 92, and the suction pipe 93 are provided.

The cylinder 10 is in the shape of a hollow cylinder having an opening at the top and bottom, and has a large-diameter tubular portion 11 at the upper portion and a small-diameter tubular portion 12 at the lower portion. The upper end of the large-diameter tubular portion 11 is radially outward. A projecting annular flange portion 13 is provided. An annular valve seat 14 projecting inward is formed on the inner surface of the boundary between the large-diameter cylindrical portion 11 and the small-diameter cylindrical portion 12, and the inside of the valve seat 14 serves as a suction port 15. A plurality of plate-shaped guide ribs 16 projecting inward and extending in the axial direction are provided in the circumferential direction on the inner surface of the lower end of the large-diameter cylindrical portion 11, and a stepped spring receiving portion 16 a is provided in the middle of each vertical rib 16. Are formed.

An annular packing 92 is joined to the lower surface of the flange portion 13, and an upper end portion of a suction pipe 93 is fitted inside the small diameter cylindrical portion 12. The lower end of the suction pipe 93 extends near the bottom of the container.

A suction valve 20, a piston body 30, a stem 40, a piston valve 50 and a spring 90 are mounted inside the large-diameter cylindrical portion 11 of the cylinder 10. The suction valve 20 has a rod-like shape, and can be seated on and separated from the valve seat 14, a guide rod 22 extending upward from an upper portion of the valve body 21, and an outer peripheral surface of the valve body portion 21 at predetermined circumferential intervals. And a plurality of fins 23 provided.

The valve body 21 is a guide rib 16 of the cylinder 10.
It is slidably inserted inside. The outer peripheral portion of the tip of the valve body 21 is formed in a convex curved shape, and the outer peripheral portion of the tip is seated on the upper surface of the valve seat 14 to close the suction port 15, and the outer peripheral portion of the tip separates from the valve seat 14 and sucks. Open mouth 15.

The radial tips of the fins 23 of the suction valve 20 extend to positions beyond the spring receiving portions 16a of the cylinder 10, and the fins 23 are inserted between the guide ribs 16 of the cylinder 10.

The piston body 30 is arranged above the suction valve 20 and is attached to the cylinder 10 so as to be able to move up and down. The piston body 30 includes a substantially cylindrical partition wall portion 31 formed in the lower portion, and a hollow cylindrical shaft cylinder portion (shaft portion) 33 that penetrates a top plate portion 32 of the partition wall portion 31.
A space surrounded by the partition wall portion 31 of the piston body 30 and the large-diameter cylinder portion 11 of the cylinder 10 is a pump chamber 19.

A plurality of vertical ribs 34 are provided on the outer peripheral surface of the lower portion of the partition wall 31 at equal intervals in the circumferential direction. This vertical rib 34
The outer peripheral surface of is slidable on the inner peripheral surface of the large-diameter cylindrical portion 11 of the cylinder 10, and between the vertical ribs 34 between the outer peripheral surface of the partition wall portion 31 and the inner peripheral surface of the large-diameter cylindrical portion 11. A first flow path 35 is formed in the. The guide rod 22 of the suction valve 20 is slidably and slidably inserted from the lower opening into the shaft cylindrical portion 33, and the guide rod 22 closes the lower opening of the shaft cylindrical portion 33. Has been.

A plurality of vertical ribs 36 are provided on the outer peripheral surface of the lower portion of the shaft tube portion 33 at equal intervals in the circumferential direction, and the upper portion of the shaft tube portion 33 is connected to the stem 40. The stem 40 is arranged above the piston body 30 and is attached to the cylinder 10 so as to be able to move up and down. The stem 40 is in the shape of a hollow cylinder whose upper and lower sides are open, the upper part is a small diameter cylinder part 41, the lower part is a large diameter cylinder part 42, and the inside of the upper part of the small diameter cylinder part 41 is a pouring passage 44.

An annular valve seat 43 projecting inward is provided on the inner peripheral surface of the upper portion of the small-diameter cylindrical portion 41, and a spherical discharge valve 91 is inserted above the valve seat 43, and the discharge valve 91 is The discharge passage 44 is seated on the valve seat 43 to close the discharge passage 44, and the discharge valve 91 separates from the valve seat 43 to open the discharge passage 44.

A plurality of vertical ribs 45 are provided on the inner peripheral surface of the small-diameter cylindrical portion 41 below the valve seat 43 at equal intervals in the circumferential direction, and inside the vertical ribs 45, the piston main body 30 is provided. The upper portion of the shaft tube portion 33 is fitted and fixed, and the stem 40 and the piston body 30 are integrated. In this assembled state, as shown in FIG. 3, the spout passage 44 is provided between the vertical ribs 45 between the inner peripheral surface of the small diameter cylindrical portion 41 and the outer peripheral surface of the shaft cylindrical portion 33.
A third flow path 46 communicating with the above is formed.

The large-diameter tubular portion 42 is located outside the vertical rib 36 of the piston body 30, and the lower end of the large-diameter tubular portion 42 is located above the partition wall portion 31 of the piston body 30 and spaced upward.

Integral piston body 30 and stem 4
0 is a spring 9 provided between the partition wall 31 of the piston body 30 and the spring receiving portion 16a of the cylinder 10.
Always urged upward by 0.

The fin 23 of the suction valve 20 can be hooked on the lower end of the spring 90, and the valve body 21 of the suction valve 20 is separated from the valve seat 14 as shown in FIG. The upper limit position of the suction valve 20 is when it hits the lower end of the spring 90.

A piston valve 50 is inserted outside the vertical rib 36 of the piston body 30 and between the partition wall portion 31 of the piston body 30 and the large-diameter cylinder portion 42 of the stem 40. The piston valve 50 has an annular shape, and the piston body 30 and the stem 4 are provided between the partition wall portion 31 and the large-diameter cylindrical portion 42.
It is attached so that it can move up and down with respect to zero.

The upper and lower outer peripheral surfaces of the outer annular portion 51 of the piston valve 50 serve as first seal portions 52, 52, which slide in pressure contact with the inner peripheral surface of the large-diameter cylindrical portion 11 of the cylinder 10 to form an inner annular portion. The upper end of the outer peripheral surface of 53 is the second seal portion 54.
As a result, the inner peripheral surface of the large-diameter cylindrical portion 42 of the stem 40 is pressed and slid in a sealed state, and the lower end portion of the inner annular portion 53 can be brought into contact with and separated from the top plate portion 32 of the piston body 30 as a third seal portion 55. Has become.

Further, the inner peripheral surface of the inner annular portion 53 slides on the outer peripheral surface of the vertical rib 36 of the piston main body 30 to form the piston main body 3
The first flow path 35 and the third flow path 4 are provided between the vertical ribs 36 between the outer peripheral surface of the shaft cylindrical portion 33 of 0 and the inner peripheral surface of the inner annular portion 53.
A second flow path 37 is formed to connect 6 with. The second flow path 37 is connected to the third seal portion 55 of the piston valve 50.
Is blocked by hitting the top plate portion 32 of the piston body 30, and is opened when the third seal portion 55 is separated from the top plate portion 32 to open the first flow path 35 and the third flow path 4
6 is connected. The piston valve 50 and the piston body 30 form a piston.

The flange portion 13 of the cylinder 10 is attached to the cap 70, and the pump head 80 is fixed to the upper portion of the stem 40, whereby the pump device is unitized.

The cap 70 includes a screw cylinder portion 71 that is screwed into the mouth cylinder portion 2 of the container 1, a neck cylinder portion 73 that stands upward from a top plate portion 72 of the screw cylinder portion 71, and a large diameter cylinder of the cylinder 10. And a plurality of vertical ribs 76 are formed on the inner peripheral surface of the upper portion of the braking cylinder portion 75. They are provided at equal intervals in the direction.

The cap 70 is a small-diameter cylindrical portion 4 of the stem 40.
1 through the neck cylinder portion 73 and the braking cylinder portion 75 through the cylinder 10
While being fitted inside, the flange portion 13 of the cylinder 10 is inserted into the screw cylinder portion 71 and abutted against the top plate portion 72, and the flange portion 1
The outer peripheral edge of the lower end of 3 can be attached to the cylinder 10 by being hooked on the hooking protrusion 74.

By mounting the cap 70 on the cylinder 10, each member incorporated in the cylinder 10 is prevented from protruding from the cylinder 10, and the upper limits of the piston valve 50 and the stem 40 are regulated.

That is, the piston body 30 and the stem 40 are urged upward by the spring 90, but the upper end of the outer annular portion 51 of the piston valve 50 is cap 70.
Of the piston valve 5
The upper limit of 0 is regulated. At this time, a slight gap is formed between the upper end of the outer peripheral surface of the large-diameter cylindrical portion 42 of the stem 40 and the lower end of the vertical rib 76. Then, as a result of the upper limits of the stem 40 and the piston valve 50 being regulated, the pump head 80 in which each member incorporated in the cylinder 10 does not jump out of the cylinder 10 is a small-diameter tubular portion 41 of the stem 40.
An inner cylinder portion 81 to which the upper part of the inner cylinder portion 81 is fitted, an outer cylinder portion 82 surrounding the outer side of the inner cylinder portion 81, and a spout that is connected to the inside of the inner cylinder portion 81 and penetrates the outer cylinder portion 82 to project outward. Nozzle 83
And the tip of the spout nozzle 83 is opened as a spout 84.

The outer cylinder portion 82 is the neck cylinder portion 7 of the cap 70.
The pump head 80 is arranged so that it can enter inside 3.
Is dimensioned so that the lower end of the outer tubular portion 82 is located slightly below the upper end of the neck tubular portion 73 when is at the upper limit position.

The pump device assembled in this way is
By inserting the cylinder 10 into the container 1 from the mouth tube portion 2 and screwing the cap 70 into the mouth tube portion 2, the flange portion 13 and the packing 92 attached to the lower surface thereof are attached to the cap 7.
It is sandwiched and fixed between the top plate portion 72 of 0 and the upper end of the mouth tube portion 2 and fixed to the container 1.

FIG. 1 shows a state before the pump head 80 is pushed down. At this time, the stem 40 and the piston body 30 are located at the upper limit, and the third seal portion 55 of the piston valve 50 is the top plate portion of the piston body 30. The second flow path 37 is closed by being in contact with 32.

When the stem 40 and the piston main body 30 are lowered against the elasticity of the spring 90 by pushing down the pump head 80 from this state, the piston valve 50 causes the first seal portion 52 and the cylinder 10 at the beginning of the downward movement. It is stationary due to friction with the inner peripheral surface of the stem 4
Only 0 and the piston body 30 descend. As a result, the third seal portion 55 of the piston valve 50 separates from the top plate portion 32 to open the second flow passage 37, and the first flow passage 35 and the third flow passage 35 are opened.
The flow path 46 communicates with the second flow path 37.

After the lower end of the large-diameter cylindrical portion 42 of the stem 40 hits the piston valve 50, the piston valve 50 descends integrally with the piston body 30 and the stem 40, and the piston body 30 and the stem 40 are separated. The open state of the second flow path 37 is maintained until the lower limit is reached.

When the piston body 30 descends, the pump chamber 1
The inside of 9 is pressurized, and the suction valve 20 is pushed down by this pressure, the valve body 21 is seated on the valve seat 14, and the suction port 15 is closed.

When the suction port 15 is closed, the piston main body 30 is lowered so that the contents in the pump chamber 19 are removed from the first flow path 3.
5, it is pushed out to the pouring passage 44 of the stem 40 through the second flow path 37 and the third flow path 46, and the discharge valve 91 is pushed up,
It is poured out from the pouring outlet 84 through the pouring nozzle 83 of the pump head 80. FIG. 2 shows a state in which the pump head 80 is pushed down and the piston body 30 and the stem 40 are positioned at the lower limit.

Then, when the hand is released from the pump head 80,
The elasticity of the spring 90 causes the piston body 30 and the stem 40 to spring back and be pushed up. At the initial stage of the rise, the piston valve 50 is stationary due to the friction between the first seal portion 52 and the inner peripheral surface of the cylinder 10, and only the stem 40 and the piston body 30 rise. As a result, the top plate portion 32 of the piston body 30 becomes
The second flow path 37 is closed by hitting the third seal portion 55 of No. 0.

After the top plate portion 32 hits the third seal portion 55, the piston valve 50 rises together with the piston body 30 and the stem 40, and the piston body 30 and the stem 40 reach the upper limit position. Until
The closed state of the second flow path 37 is maintained.

When the piston body 30 rises, the pump chamber 1
The inside of 9 becomes a negative pressure state, the suction valve 20 is lifted by this negative pressure, the valve body 21 separates from the valve seat 14, and the suction port 15 opens. After the suction port 15 is opened, the piston body 3
With the increase of 0, the content in the container 1 is pumped up from the suction port 15 into the pump chamber 19.

In the present embodiment, the discharge valve 91 is seated on the valve seat 43 to shut off the outside air when the pump head 80 is raised, but when the discharge valve 91 is not installed, the pump head 80 is raised. Sometimes pump head 8 including spout 84
The contents in 0 are drawn into the pump.

As described above, in this pump device, the third flow path 4 is provided between the piston body 30 and the stem 40.
By providing 6, the flow path through which the content flows from the pump chamber 19 to the pouring path 44 in the stem 40 is a path that passes outside the piston body 30, and the inside of the piston body 30 must be the flow path. Disappears.

Therefore, it is not necessary to provide a through hole as a flow path in the small-diameter cylindrical portion 31 of the piston body 30 in the direction orthogonal to the axis, the structure of the piston body 30 is simplified, and the manufacturing cost of the piston body 30 is reduced. It is possible to reduce the manufacturing cost of the pump device.

[0052]

As described above, according to the present invention,
A first flow passage is provided between the outer peripheral surface of the partition wall of the piston body and the inner peripheral surface of the cylinder, and a second flow passage is provided between the outer peripheral surface of the shaft portion of the piston body and the piston valve. A third flow passage is provided between the outer peripheral surface of the shaft portion and the inner peripheral surface of the stem, and the pump chamber and the pouring passage in the stem are communicated with each other through the first flow passage, the second flow passage, and the third flow passage. Second, by moving the piston valve up and down relative to the piston body and stem.
By enabling the passage to be blocked, the passage through which the contents flow from the pump chamber to the pouring passage becomes a passage that passes through the outside of the piston body, and it is not necessary to use the inside of the piston body as the passage.

As a result, there is no need to provide a through hole as a flow path orthogonal to the axis in the shaft portion of the piston body, the structure of the piston body is simplified, and the manufacturing cost of the piston body can be reduced, which in turn An excellent effect that the manufacturing cost of the pump device can be reduced is exhibited.

[Brief description of drawings]

FIG. 1 is a longitudinal sectional view showing a state in which a pump head is located at an upper limit in a container pump device of the present invention.

FIG. 2 is a vertical cross-sectional view showing a state in which the pump head is located at the lower limit in the container pump device of the present invention.

FIG. 3 is a transverse cross-sectional view of a sliding portion between a piston body and a stem in the container pump device of the present invention.

[Explanation of symbols]

 1 Container 2 Port Cylinder 10 Cylinder 13 Flange Part 15 Suction Port 19 Pump Chamber 20 Suction Valve 21 Valve Body 22 Guide Rod 30 Piston Body 31 Partition Wall 33 Shaft Cylinder (Shaft) 35 First Channel 37 Second Channel 40 stem 44 pouring passage 46 third flow passage 50 piston valve 52 first seal portion 54 second seal portion 55 third seal portion 70 cap 80 pump head 84 spout 90 spring

Claims (2)

[Claims] (A) A hollow cylindrical shape, the inside of which is a pump chamber, and a suction port communicating with the pump chamber is provided in the lower part, and the suction tube part is inserted into the container from the mouth cylinder part of the container. (B) A suction valve that allows inflow into the pump chamber from the suction port of the cylinder and prevents outflow from the pump chamber to the inside of the container, and (c) a vertically movable mount in the cylinder. A first partition which has a partition wall partitioning the pump chamber in a lower portion, a shaft portion stands upward from the partition wall, and is connected to the pump chamber between an outer peripheral surface of the partition wall and an inner peripheral surface of the cylinder.
A piston body having a flow path, and (d) a hollow cylindrical shape,
The inside is a pouring passage, the lower part is vertically inserted into the cylinder, the upper part is projected from the cylinder, the upper part of the shaft part of the piston body is inserted from the lower opening, and the outer peripheral surface of this shaft part is inserted. And a stem fixedly connected to the shaft portion to form a third flow path connected to the pouring passage, and (e) has an annular shape, and has an inner peripheral surface of the cylinder and an outer peripheral surface of the shaft portion of the piston body. Is disposed between the partition wall of the piston body and the lower end of the stem so as to be movable in the axial direction, and the first flow path is provided between the piston body and the outer peripheral surface of the shaft portion. And a second seal part that forms a second flow path communicating with the third flow path and that slides in pressure contact with the inner peripheral surface of the cylinder and a second seal part that slides in pressure contact with the lower inner peripheral surface of the stem and the piston body. It has a third seal portion that abuts on the partition wall portion and blocks the first flow path and the second flow path. A piston valve, (f) a spring that is installed between the cylinder and the piston body to urge the piston body upward, and (g) a content fixed in the upper end of the stem, which is inside the stem passage passage. A pump head having a pouring port for pouring out the pump head, the stem, and the piston body when the piston body descends; The pump chamber and the pouring passage of the stem communicate with each other through the second flow passage and the third flow passage, so that the contents can be poured out from the pouring outlet of the pump head, and when the pump head, the stem and the piston body rise, The third seal portion comes into contact with the partition wall portion of the piston main body to contact the first flow passage and the second flow passage.
A pump device for a container, characterized in that a flow path is blocked, a suction valve is opened, and contents in the container are pumped up from a suction port of a cylinder into a pump chamber. 2. The suction valve includes a valve body that opens and closes a suction port of the cylinder, and a guide rod that extends upward from the valve body, and a shaft portion of the piston body has a hollow cylindrical shape and is a partition wall portion. Is formed with an opening connected to the hollow portion of the shaft portion, and the guide rod of the suction valve is inserted into the hollow portion of the shaft portion from this opening in a sealed state so that the guide rod can be moved up and down relatively. A pump device for a container according to.