JP2015209236A - Spout plug - Google Patents

Abstract

PROBLEM TO BE SOLVED: To facilitate opening and closing operation and suppress the disturbance of fluid flow in a spout plug.SOLUTION: A spout plug 1 comprises: a plug body 2 having a first cylindrical part 22 into which a fluid flows, a second cylindrical part 23 provided with an opening 23a, and a tubular part 24 in which spiral grooves 25A, 25B are formed; and a cock 3 having a rotation operation part 31C screwed to the spiral grooves 25A, 25B, and a cylindrical plunger part 31A which is slidably adhered to the entire circumference of a tapered inner peripheral surface 24a of the tubular part 24, and opens and closes the opening 23a in response to a rotation amount. In a second duct, a cylindrical upstream side duct P2 having a first inner diameter B larger than an inner diameter A of the opening 23a and a cylindrical downstream side duct P1 of a length C, whose diameter is reduced from the first inner diameter B to the inner diameter A of the opening 23a, are formed. When an inner diameter of a cylindrical surface 22b is defined as D, following relationship is satisfied: 0.3<A/B<0.7, 0.3≤C/B≤1, D>B.

Description

  The present invention relates to a spout stopper. For example, in order to pour out the liquid contained in a liquid packaging container such as a bag-in-box, it is attached to the spout part made of a spout of the liquid packaging container and pours liquid or stops its dispensing. It relates to spout stoppers.

2. Description of the Related Art Conventionally, for example, liquid packaging containers called bag-in-box are known as containers for storing liquid seasonings, liquids such as water and alcohol, and various chemical solutions. This bag-in-box has a structure in which an easily deformable inner bag made of a synthetic resin flexible sheet is put in a cardboard outer box, and the inner bag for storing liquid is made of a synthetic resin and an annular spout. Is provided as a spout part.
In such a liquid packaging container, the spout part is arranged on the side of the outer box, and a cock-type spout stopper is provided so that liquid can be poured out through the spout part while the outer box is left stationary. It has been known.
For example, Patent Document 1 discloses a cylindrical body portion, a cap-shaped rotating portion that is screwed to the outer peripheral surface of the cylindrical body portion, and a fitting portion that is fitted into the cylinder of the cylindrical body portion, and is below the top plate portion of the cap-shaped rotating portion. A cock-type spout stopper is described which comprises a plunger portion fitted on an inner surface so as to be freely rotatable.

JP 2009-214911 A

However, the prior art as described above has the following problems.
In the cock-type spout stopper described in Patent Document 1, the tip of the plunger portion is fitted into the opening at the tip of the cylindrical portion so that the liquid does not leak when closed. However, if the frictional force in the fitting portion is large, the torque required for opening and closing the plug increases, so that the length of the fitting portion is made as short as possible.
Further, when the spout stopper is reduced in size, the outer diameter of the cap-shaped rotating part is also reduced, and the torque required for opening and closing is further increased. For this reason, it is necessary to further shorten the length of the fitting portion, and there is a problem that liquid leakage may occur or the liquid flow may be disturbed at the time of pouring.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a spout plug that can be easily opened and closed and that can suppress disturbance of the liquid flow.

In order to solve the above-described problems, the spout stopper according to the aspect of the present invention is provided so as to be able to be fitted to the spout part of the liquid packaging container, and is accommodated in the liquid packaging container when fitted with the spout part. A first tubular body portion formed with a first pipe for allowing fluid to flow from the spout port, and extending in a direction intersecting the first duct of the first tubular body, A second tubular portion that is in communication with the first conduit and has a second conduit having an opening at the first end; and a second tubular portion opposite to the first end of the second tubular portion. A stopper body having a tubular portion connected to the second end coaxially with the second pipe line and having a spiral groove formed on the outer periphery thereof, and a rotation operation portion screwed into the spiral groove of the tubular portion; , And is inserted from the inside of the rotation operation part into the tubular part and the second cylindrical part, and is slidably adhered over the entire inner peripheral surface of the tubular part. And a plug member having a cylindrical plunger portion that opens and closes the opening of the second conduit according to the amount of rotation of the rotation operation portion, and the second conduit includes the first member A cylindrical upstream pipe line having a first inner diameter that is larger than the inner diameter of the opening, and extending from an end of the upstream pipe line. A downstream pipe formed in a cylindrical shape that is reduced in diameter from an inner diameter of 1 to the inner diameter of the opening, the inner diameter of the opening is A, the first inner diameter is B, and the length of the downstream pipe A spout stopper that satisfies the following formulas (1), (2), and (3), where C is the length and D is the inner diameter of the first pipe at the portion communicating with the second pipe.
D <B (1)
0.3 <A / B <0.7 (2)
0.3 ≦ C / B ≦ 1 (3)

  In the spout stopper, the downstream pipe line of the second pipe line has the same inner diameter as the inner diameter of the opening, and is smaller than the first cylindrical part connected to the opening and the first inner diameter. A second cylindrical portion having a second inner diameter larger than the inner diameter of the opening, and the plunger portion has a smaller diameter than the inner diameter of the second cylindrical portion, and is longer than the length of the second cylindrical portion. A first outer cylinder part that is detachably fitted to the first cylindrical part and is larger than an outer diameter of the first outer cylinder part, and is detachably fitted to the second cylindrical part. An outer cylinder part and a third outer cylinder part slidably in close contact with the inner peripheral surface of the tubular part, and when the rotary operation part is rotated to open and close, the third outer cylinder part is The first outer cylinder part is fitted to the first cylindrical part and the second outer cylinder part is the first outer cylinder part in a state of maintaining a close contact state with the inner peripheral surface of the tubular part. A double closed state fits into the cylindrical portion, it is preferable that the second outer cylinder portion may take a single closed only fitted to the second cylindrical portion.

  In the spout stopper, the inner peripheral surface of the tubular part is separated from the second cylindrical part in order to change the frictional force with the third outer cylindrical part in a range in close contact with the third outer cylindrical part. It is preferable that a taper shape that gradually increases in diameter is formed.

  According to the spout plug of the present invention, the inner diameter of the opening of the second pipe of the plug main body is A, the first inner diameter is B, the length of the downstream pipe is C, and the portion communicating with the second pipe is used. When the inner diameter of the first pipe is D, 0.3 <A/B<0.7, 0.3≦C/B≦1, and D> B are satisfied. There is an effect that the disturbance of the flow can be suppressed.

It is a typical perspective view which shows the external appearance of the spout stopper of embodiment of this invention. It is a typical longitudinal section of the spout stopper of an embodiment of the present invention in the fully closed state. It is a typical longitudinal section of the spout stopper of an embodiment of the present invention of a full open state. It is a typical front view which shows the external appearance of L view in FIG. 2, and a partial cross section of the plug main body of the spout stopper of embodiment of this invention. It is a typical longitudinal cross-sectional view of the stopper main body of the spout stopper of embodiment of this invention. FIG. 6 is an M view in FIG. 5. It is operation | movement explanatory drawing in the 2nd flow path of the spout stopper of embodiment of this invention. It is operation | movement explanatory drawing in the tubular part of the spout stopper of embodiment of this invention.

Below, the spout stopper of embodiment of this invention is demonstrated with reference to an accompanying drawing.
FIG. 1 is a schematic perspective view showing an appearance of a spout stopper according to an embodiment of the present invention. FIG. 2 is a schematic longitudinal sectional view of the spout stopper according to the embodiment of the present invention in a fully closed state. FIG. 3 is a schematic longitudinal sectional view of the spout stopper according to the embodiment of the present invention in a fully opened state. FIG. 4 is a schematic front view showing an appearance and a partial cross-section of the spout body of the spout stopper according to the embodiment of the present invention as viewed in FIG. FIG. 5 is a schematic longitudinal cross-sectional view of the stopper body of the spout stopper according to the embodiment of the present invention. FIG. 6 is an M view in FIG.
In addition, since each figure is a schematic diagram, the shape and dimension are exaggerated or simplified (the following drawings are also the same).

As shown in FIG. 1, the spout stopper 1 of this embodiment is comprised combining the stopper main body 2 and the cock 3 (plug member).
As shown in FIG. 2, the spout stopper 1 is suitable for, for example, pouring a fluid in a liquid packaging container 11 called a back-in-box that contains an appropriate fluid.
As the attachment shape of the spout stopper 1 to the liquid packaging container 11, an appropriate shape can be adopted according to the shape of the spout 10 that is the spout part of the liquid packaging container 11.
Below, as an example, the spout 10 provided in the inner bag (not shown) arranged in the outer box of the liquid packaging container 11 is fixed to the side surface of the outer box arranged on the horizontal plane, and the fluid F is spouted 10. An example in the case of flowing into the plug main body 2 along the axis X extending in the horizontal direction through will be described.
Unless otherwise specified, the position and orientation of each member of the spout stopper 1 will also be described based on the position and orientation when the outer box and the spout 10 are arranged in this way.
The type of the fluid F is not particularly limited. That is, it may be a food fluid or a non-food fluid. For example, examples of the fluid F include liquid seasonings, water, alcohol, or medical or industrial chemicals.

  In this specification, when describing the relative position with respect to a member such as a shaft or a cylinder that can specify an axis such as the central axis, the direction along the axis is the axial direction, the direction around the axis is the circumferential direction, and the axis is the axis. A direction along a line intersecting the axis line on the orthogonal plane is referred to as a radial direction. In the radial direction, the direction away from the axis may be referred to as a radially outward (outside), and the direction approaching the axis may be referred to as a radially inward (inside).

  The plug body 2 includes an attachment portion 21 provided so as to be fitted to the spout 10, a first cylindrical portion 22 for allowing the fluid F flowing out from the spout 10 to flow along the axis X, and a first cylindrical portion. The second cylinder part 23 that allows the fluid F that has flowed into the pipe 22 to be guided in the direction intersecting the axis X and to be discharged to the outside, and is coaxial with the second cylinder part 23 from one end of the second cylinder part 23. And a tubular portion 24 that is extended.

The attachment portion 21 can adopt an appropriate shape according to the shape of the spout 10.
In the present embodiment, the attachment portion 21 adopts a shape corresponding to the spout 10 being made of an annular member extending in the direction along the axis X.
Specifically, the attachment portion 21 includes an insertion tube portion 21 a that fits inside the inner peripheral surface 10 a of the spout 10, and an annular engagement portion 21 b that fits externally on an engagement protrusion 10 b provided on the outer peripheral surface of the spout 10. And a substrate portion 21c extended in a direction perpendicular to the axis X in order to hold the insertion tube portion 21a and the engaging portion 21b integrally.

The first cylindrical portion 22 extends from the inner side of the insertion tube portion 21a in the substrate portion 21c in the direction along the axis X, and extends from the proximal end (the substrate portion 21c) to the distal end side (first A taper tube portion 22A and a cylindrical tube portion 22B are provided in this order toward the two cylinder portions 23).
Further, as shown in FIG. 1, a rib-like reinforcing structure is formed on the outer peripheral portion of the first cylindrical body portion 22 between the first cylindrical body portion 22 and the substrate portion 21c.

Inside the tapered tube portion 22A, a tapered surface 22a is formed which gradually decreases in diameter from the proximal end side toward the distal end side and has an inner diameter D at the connection portion with the cylindrical tube portion 22B.
A cylindrical surface 22b having an inner diameter D is formed in the cylindrical tube portion 22B from the proximal end side toward the distal end side.
The tapered surface 22a and the cylindrical surface 22b are formed coaxially, and the respective central axes are aligned with the axis X.
Thus, the 1st pipe line extended along the axis line X is formed in the inside of the 1st cylinder part 22 by the taper surface 22a and the cylindrical surface 22b. Hereinafter, the inner diameter D of the cylindrical surface 22b may be referred to as the outlet diameter of the first pipeline.

As shown in FIGS. 3 and 4, the inside of the second cylindrical portion 23 extends in a direction intersecting the first pipeline of the first cylindrical portion 22, and the cylinder in the first pipeline at the side portion. A second conduit is formed which communicates with the tip of the surface 22b and has an opening 23a at the first end e1.
As long as the second pipe extends in the direction intersecting with the axis X, the crossing angle and the direction of the opening 23a are not limited, but in this embodiment, as an example, the central axis Z of the second pipe is in the vertical direction. It is extended, orthogonal to the axis X, and the opening 23a is directed vertically downward.
The inner diameter A of the opening 23a is smaller than the inner diameter D of the cylindrical surface 22b.

The second pipe line includes a third cylindrical portion 23g that extends to a position facing the first cylindrical portion 22 and has a first inner diameter B that is larger than the inner diameter A of the opening 23a and the inner diameter D of the cylindrical surface 22b. It is comprised by the upstream pipe line P2 and the downstream pipe line P1 extended from the edge part of the upstream pipe line P2, and was formed in the cylinder shape diameter-reduced from the internal diameter B to the internal diameter A.
The length G (see FIG. 4) of the third cylindrical portion 23g is larger than the inner diameter D of the cylindrical surface 22b, and the cylindrical surface 22b includes the approximate center in the length direction of the third cylindrical portion 23g (including the case where it is the center). ).

As shown in FIG. 4, the downstream pipe line P1 has a third taper portion 23f and a second taper in a region having a length C between the end portion of the upstream third cylindrical portion 23g and the downstream opening 23a. The tapered portion 23e, the second cylindrical portion 23d, the first tapered portion 23c, and the first cylindrical portion 23b are arranged in this order.
The third tapered portion 23f is a tapered surface that gradually decreases in diameter as it goes from the third cylindrical portion 23g to the second tapered portion 23e.
The second taper portion 23e is a tapered surface that gradually decreases in diameter gradually from the end of the third taper portion 23f toward the second cylindrical portion 23d.
The second cylindrical portion 23d is a cylindrical surface having a constant second inner diameter E (A <E <B) between the end portion of the second tapered portion 23e and the first tapered portion 23c.
The first tapered portion 23c is a tapered surface that gradually decreases in diameter to the same extent as the second tapered portion 23e as it goes from the end of the second cylindrical portion 23d toward the first cylindrical portion 23b.
The first cylindrical portion 23b is a cylindrical surface having a constant inner diameter A between the end of the first tapered portion 23c and the opening 23a.

  In the present embodiment, the following formulas (1) to (3) are satisfied with respect to the inner diameters and lengths of the first pipeline and the second pipeline. The technical significance of these relationships will be described later together with the action of the spout stopper 1.

D <B (1)
0.3 <A / B <0.7 (2)
0.3 ≦ C / B ≦ 1 (3)

The tubular portion 24 extends coaxially with the second cylindrical portion 23 from the second end portion e2 of the second cylindrical portion 23, and the third end portion e3 located on the opposite side of the second end portion e2 opens. It is a tubular part.
A pair of spiral grooves which are guide grooves for supporting a cock 3 to be described later to be screwed into the outer peripheral surface 24c of the tubular portion 24 so as to be rotatable about the central axis Z and to be able to advance and retreat along the central axis Z. 25A and 25B are provided.
Each of the spiral grooves 25A and 25B is formed in a shape in which a rectangular groove is turned by a half circumference of the outer peripheral surface 24c, and is provided 180 ° rotationally symmetrical with respect to the central axis Z.
The swirling directions of the spiral grooves 25A and 25B rotate in the clockwise direction along the central axis Z as they proceed from the second end e2 toward the third end e3.

A tapered inner peripheral surface 24a (inner peripheral surface of the tubular portion) is formed on the inner peripheral portion of the tubular portion 24 from the second end e2 of the second cylindrical portion 23 toward the third end e3 of the tubular portion 24. And the inner peripheral surface 24b is formed in this order.
The tapered inner peripheral surface 24a is provided with a gradient θ that increases in diameter from the second cylindrical portion 23 toward the inner peripheral surface 24b in order to provide a distribution in sliding load when the plunger portion 31A described later moves forward and backward. It is a sliding surface.
When the tubular portion 24 is formed by resin molding, the gradient θ is set to be larger than the draft of the molded product.
The gradient θ on the tapered inner peripheral surface 24a can be set as appropriate in consideration of the operability when the cock 3 is opened and closed.
The inner diameter of the tapered inner peripheral surface 24 a at the connection portion with the second cylindrical portion 23 is set to an inner diameter H that is slightly larger than the inner diameter B of the second cylindrical portion 23.
The inner peripheral surface 24b is formed of a cylindrical surface having an inner diameter larger than the inner diameter of the tapered inner peripheral surface 24a at the adjacent portion.

  Although the material and manufacturing method of such a plug main body 2 are not specifically limited, in this embodiment, as an example, it manufactures by injecting synthetic resin.

As shown in FIGS. 2 and 3, the cock 3 includes a plug member 31 and a cap 32.
The plug member 31 includes a rotation operation part 31C, a plate-like part 31B, and a plunger part 31A.

The rotation operation portion 31C is a substantially cylindrical portion for performing an operation of opening / closing the opening 23a or adjusting the flow rate of the fluid F poured out when the opening 23a is opened by the cock 3.
As shown in FIGS. 5 and 6, the rotation operation portion 31 </ b> C has a substantially cylindrical shape in which an inner peripheral surface 31 q having an inner diameter slightly larger than the outer diameter of the tubular portion 24 is formed.
A pair of plate-like portions 31B described later are extended in a direction orthogonal to the central axis O on the inner peripheral portion of the first end f1 in the axial direction of the rotation operation portion 31C. A plunger portion 31A, which will be described later, is connected to the central portion of each plate-like portion 31B so as to be coaxial with the central axis O.
The plunger portion 31A passes through the inside of the rotation operation portion 31C and extends outward from the second end portion f2 opposite to the first end portion f1.

The axial length of the rotation operation portion 31C is set to a length that can cover at least the entire spiral grooves 25A and 25B (see FIG. 2).
A pair of locking claw portions 31nA and 31nB protrude radially inward from the inner peripheral surface 31q of the second end portion f2 of the rotation operation portion 31C at positions facing each other with the central axis O therebetween.
The cross-sectional shape and size of the locking claw portion 31nA (31nB) are cross-sectional shapes and sizes that can be slidably engaged in the spiral groove 25A (25B), respectively.

As shown in FIG. 6, the inner peripheral surface 31q at the first end f1 of the rotation operation portion 31C sandwiches the central axis O and the locking claws 31nA and 31nB in a plan view viewed along the central axis O. A pair of fan-shaped plate-like portions 31B are respectively extended radially inward.
As shown in FIG. 5, the surface of each plate-like portion 31B opposite to the second end portion f2 is a plane perpendicular to the central axis O, and constitutes a cap attachment surface 31j for attaching a cap 32 described later. .
At the outer peripheral portion of the cap attachment surface 31j, the rotation operation portion 31C slightly protrudes, and a cap insertion hole 31k having a circular diameter in plan view is formed.
An opening end of a plunger portion 31A, which will be described later, is connected to the center portion of the plate-like portion 31B at a position coaxial with the central axis O, and a plunger hole portion 31p formed inside the plunger portion 31A opens. ing.

  On the outer peripheral surface 31m of the rotation operation portion 31C, a protrusion 31r having a mountain-shaped cross section extending in the axial direction is provided with a gap in the circumferential direction so as to prevent slipping when the user performs a rotation operation. Many are formed.

  With such a configuration, when the rotation operation portion 31C is rotated around the central axis Z in a state where the locking claws 31nA and 31nB of the rotation operation portion 31C are engaged with the spiral grooves 25A and 25B, respectively, the spiral groove 25A , Move forward and backward in the axial direction along 25B.

The plunger portion 31A is a substantially bottomed cylindrical portion that is disposed coaxially with the central axis O and has an end having an opening connected to the inner peripheral portion of the plate-like portion 31B.
When the rotation operation part 31C is rotated around the central axis Z of the tubular part 24 and the second cylindrical part 23, the plunger part 31A fixed via the plate-like part 31B also performs the same movement. That is, the plunger portion 31 </ b> A rotates around the central axis Z and moves forward and backward along the central axis Z in the tubular portion 24 and the second cylindrical portion 23.
The shape of the plunger portion 31 </ b> A can open and close the spout stopper 1 with such an operation. Below, arrangement | positioning of each part of 31 A of plunger parts may be demonstrated in the relative positional relationship of the movement position of 31 A of plunger parts, and the plug main body 2. FIG.
FIG. 2 shows a state in which the plunger portion 31A comes closest to the opening 23a by the rotation of the rotation operation portion 31C. This state is a fully open state of the spout stopper 1. Such a position of the plunger portion 31A is referred to as a fully closed position.
FIG. 3 shows a state where the plunger portion 31A is farthest from the opening 23a. This state is a fully closed state of the spout stopper 1. Such a position of the plunger portion 31A is referred to as a fully opened position.

The plunger portion 31A has a third outer cylinder portion 31h, a large diameter portion 31g that forms a part of the third outer cylinder portion 31h, and an intermediate outer portion from the connecting portion with the plate-like portion 31B toward the distal end side in the extending direction. The cylinder part 31f, the taper part 31e, the 2nd outer cylinder part 31d, the step part 31c, the 1st outer cylinder part 31b, and the front end surface 31a are provided in this order.
The inside of the plunger portion 31A is stealed in order to make the plunger portion 31A have a substantially uniform thickness, thereby forming a plunger hole portion 31p.

The third outer cylindrical portion 31h is a substantially cylindrical cylindrical portion that is inserted into the inner peripheral surface 24b and the tapered inner peripheral surface 24a of the tubular portion 24.
The outer diameter of the third outer cylinder portion 31h is a distal end portion that has an outer diameter smaller than the inner diameter of the inner peripheral surface 24b at the base end portion on the plate-like portion 31B side and slides on the tapered inner peripheral surface 24a. Then, it has the internal diameter which fits inside the taper inner peripheral surface 24a so that sliding is possible.
The side surface on the base end side of the third outer cylinder portion 31h is cut out in a rectangular shape from the plate-shaped portion 31B to the position facing the locking claw portions 31nA and 31nB in the opposing direction of the locking claw portions 31nA and 31nB. A pair of openings 31i are provided.

The opening 31i is a shape provided to eliminate the undercut caused by the locking claws 31nA and 31nB when the plug member 31 is integrally formed. Therefore, the opening 31i can be deleted when undercut processing is performed or when the plug member 31 is not formed by integral molding.
However, if such an opening 31i is provided, the mold configuration of the mold can be simplified and the weight of the plug member 31 can be reduced as compared with the case where the opening 31i is not provided.

The large-diameter portion 31g partially improves the sealing performance with respect to the tapered inner peripheral surface 24a at the distal end portion of the third outer cylinder portion 31h adjacent to the intermediate outer cylinder portion 31f. It is the cyclic | annular site | part provided in the slightly larger diameter from the outer diameter of this part.
The axial position of the large-diameter portion 31g is provided at a position that moves within the range of the tapered inner peripheral surface 24a when the plunger portion 31A moves by the operation of the rotation operation portion 31C.

The intermediate outer cylinder part 31f is a part that moves forward and backward within the third cylindrical part 23g when the plunger part 31A moves by the operation of the rotation operation part 31C.
For this reason, the entire outer diameter of the intermediate outer cylinder portion 31f is a cylindrical surface or a tapered surface that is smaller than the inner diameter B of the third cylindrical portion 23g.
However, in the intermediate outer cylinder portion 31f, the outer diameter b of the tip portion adjacent to the later-described tapered portion 31e is larger than the inner diameter of the third tapered portion 23f.

The taper portion 31e can be brought into contact with the third taper portion 23f and the second taper portion 23e in the downstream side pipe P1 when the plunger portion 31A is moved by the operation of the rotation operation portion 31C. This is the part that forms the upstream seal.
The tapered portion 31e is a tapered surface that gradually decreases in diameter from the distal end portion of the intermediate outer cylindrical portion 31f toward the second outer cylindrical portion 31d.
The taper is preferably an intermediate taper between the third taper portion 23f and the second taper portion 23e, or a taper equivalent to the second taper portion 23e.

The second outer cylinder portion 31d has a cylindrical surface extending from the end of the taper portion 31e. When the plunger portion 31A is moved by the operation of the rotation operation portion 31C, the second outer cylinder portion 31d is a second pipe in the downstream side pipe P1. This is a portion that is slidably fitted into the cylindrical portion 23d.
For this reason, the outer diameter of the second outer cylinder portion 31d is an outer diameter e larger than the inner diameter E of the second cylindrical portion 23d.
The axial length of the second outer cylinder portion 31d is substantially the same (including the same case) as the axial length of the second cylindrical portion 23d.

  The step part 31c is a boundary part produced by a difference in outer diameter with a first outer cylinder part 31b described later. The step portion 31c is preferably narrow in the axial direction, and for this reason, it is possible to employ a flat surface perpendicular to the central axis O or a tapered surface with a steep diameter reduction along the axial direction.

The first outer cylinder portion 31b is inserted without contacting the second cylindrical portion 23d in the downstream side pipe P1 when the plunger portion 31A moves by the operation of the rotation operation portion 31C, and the first cylindrical portion 23b. It consists of a cylindrical surface that fits slidably.
For this reason, the outer diameter of the first outer cylinder part 31b is smaller than the inner diameter E of the second cylindrical part 23d and is larger than the inner diameter B of the first outer cylinder part 31b.
The length in the axial direction of the first outer cylinder portion 31b may be equal to or longer than the length in the axial direction of the first cylindrical portion 23b. In the present embodiment, the length between the second cylindrical portion 23d and the first tapered portion 23c. A length slightly longer than the length from the boundary to the opening 23a is adopted.
The first outer cylinder portion 31b is a portion that closes the first cylindrical portion 23b at the fully closed position of the plunger portion 31A.

The distal end surface 31a is a portion that closes the distal end portion in the extending direction of the plunger portion 31A, and a plane intersecting the central axis O or an appropriate curved surface can be adopted.
In this embodiment, the shape of the front end surface 31a is a concave curved surface in which the central portion is depressed.

  Although the material and manufacturing method of such a plug member 31 are not particularly limited, in the present embodiment, as an example, the plug member 31 is manufactured by injection molding a synthetic resin.

As shown in FIG. 2, a cap 32 is attached to the end of the plug member 31 on the proximal end side.
The cap 32 is a member that covers the proximal end of the plug member 31 and closes the opening of the proximal end of the cock 3 by including a top plate portion 32a and a fitting protrusion 32b.
The top plate portion 32a is a plate-like member that is inserted into the cap insertion hole 31k so as to be able to contact the cap mounting surface 31j of the plug member 31 and cover substantially the entire cap insertion hole 31k (including the entire case). It is.
The fitting protrusion 32b is a member that is inserted into the plunger hole 31p that opens in the cap attachment surface 31j and engages with the plunger hole 31p, and is erected at the center of the top plate 32a. Yes.

  The cap 32 having such a configuration is mounted by inserting the fitting protrusion 32b into the plunger hole 31p until the top plate 32a contacts the cap attachment surface 31j.

  The material of the cap 32 is not particularly limited, and an appropriate synthetic resin, rubber, metal, or the like can be used. In this embodiment, as an example, it is formed of the same synthetic resin as the plug member 31.

Next, operation | movement of the spout stopper 1 is demonstrated centering on the opening / closing operation | movement.
FIGS. 7A and 7B are operation explanatory views in the second flow path of the spout stopper according to the embodiment of the present invention. FIG. 8 is an operation explanatory diagram of the tubular portion of the spout stopper according to the embodiment of the present invention.
However, in FIGS. 7A, 7 </ b> B, and 8, only a half section in the radial direction is shown in order to simplify the illustration.

In the fully closed state of the spout 1 shown in FIG. 2, the rotation operation portion 31C of the cock 3 is rotated clockwise as viewed from the cap 32, and the plunger portion 31A is moved to the distal end side in the protruding direction. Is formed.
At this time, as shown in FIG. 7A, the distal end portion of the plunger portion 31A has reached a position where the outer peripheral portion of the distal end surface 31a is substantially aligned (including when aligned) with the opening 23a. The opening 23a is closed when the one cylindrical portion 23b is fitted into the first outer cylinder portion 31b.

Since the outer diameter b of the first cylindrical portion 23b is larger than the inner diameter B of the first outer cylindrical portion 31b, the first cylindrical portion 23b and the first outer cylindrical portion 31b are elastically deformed from each other and closely contact each other in the radial direction. Thus, the first seal portion S1 is formed in the downstream pipe line P1.
Note that FIG. 7A is a schematic diagram, and is drawn so as to overlap each other in the first seal portion S1, because the elastic deformation of the member is ignored for simplicity. Actually, the surfaces of the overlapping portions are in close contact with each other and the vicinity thereof is elastically deformed. The greater the overlap, the greater the respective elastic deformation.
FIG. 7B and FIG. 8 are similarly simplified.

Further, since the outer diameter e of the second outer cylinder portion 31d is larger than the inner diameter E of the second cylindrical portion 23d, the second outer cylinder portion 31d and the second cylindrical portion 23d are elastically deformed to each other in the radial direction. They are in close contact with each other.
Further, the taper portion 31e adjacent to the second outer cylinder portion 31d abuts on a part of the second taper portion 23e and the third taper portion 23f, and elastically deforms from each other in accordance with the mutual dimensional relationship, so that the radial direction Are in close contact with each other.
Thus, the taper part 31e and the second outer cylinder part 31d are fitted into and closely adhered to a part of the third taper part 23f, the second taper part 23e, and a part of the second outer cylinder part 31d. Thus, the second seal portion S2 is formed in the downstream side pipe line P1.

In the present embodiment, the axial length of the first outer cylinder portion 31b is longer than the length from the boundary between the second cylindrical portion 23d and the first tapered portion 23c to the opening 23a. Therefore, in the vicinity of the boundary between the first tapered portion 23c and the second cylindrical portion 23d, a part of the first tapered portion 23c and the second cylindrical portion 23d, a part of the first outer cylindrical portion 31b and the stepped portion 31c, A gap T is formed between the two.
That is, the first seal portion S1 and the second seal portion S2 are spaced apart from each other in the axial direction with a gap T therebetween, and the first seal portion and the second seal portion are formed as double seal portions independent of each other. It has become.
As described above, in the fully closed state, the downstream side pipe P1 is doubly closed by forming the first seal part S1 and the second seal part S2 in the downstream side pipe P1, and from the opening 23a. Fluid does not flow out.

  Further, as shown in FIG. 2, in this fully closed state, the intermediate outer cylinder portion 31f is located in the upstream pipeline P2 with a slight gap between the third outer cylinder portion 23g and the third cylindrical portion 23g. . Thereby, the intermediate outer cylinder part 31f covers the tip side of the cylindrical surface 22b of the first pipe line at a slightly spaced position.

On the other hand, the large-diameter portion 31g adjacent to the end of the intermediate outer cylinder portion 31f in the axial direction is fitted to the tapered inner peripheral surface 24a at a position close to the boundary with the third cylindrical portion 23g, as shown in FIG. Match. Therefore, the large diameter portion 31g having a diameter larger than the inner diameter H of the end portion of the tapered inner peripheral surface 24a abuts on the tapered inner peripheral surface 24a, and the tapered inner peripheral surface 24a and the large diameter portion 31g are mutually connected. It is elastically deformed and is in close contact with each other in the radial direction.
At this time, since the outer diameter of the third outer cylinder portion 31h is smaller than the inner diameter of the tapered inner peripheral surface 24a even if the outer diameter is smaller than that of the large diameter portion 31g, the third outer cylinder portion 31h is also tapered. It is in close contact with the inner peripheral surface 24a.
Thereby, the large diameter portion 31 g and the third outer cylinder portion 31 h constitute a third seal portion in the tubular portion 24. However, the main sealing effect by the third seal portion is obtained by the seal region s1 which is a fitting portion in which the large diameter portion 31g is deformed.

Thus, in the fully closed state, the second pipe line is closed by the first and second seal portions on the downstream side and closed by the third seal portion on the upstream side, and the cylindrical surface 22b of the first pipe line is closed. It communicates with the inside.
Therefore, when the fluid F flows from the spout 10 in the fully closed state, the fluid F is held inside the first pipeline and the second pipeline.

In order to pour out the fluid F from the spout 1 in the fully closed state, the rotation operation unit 31C is rotated counterclockwise as viewed from the cap 32. At this time, since the locking claws 31nA and 31nB of the rotation operation portion 31C are engaged with the spiral grooves 25A and 25B of the tubular portion 24, the rotation operation portion 31C is spirally formed along the spiral grooves 25A and 25B. Move to. Accordingly, the rotation operation unit 31C moves along the central axis Z in a direction away from the second cylindrical portion 23. Further, the plunger portion 31A fixed to the rotation operation portion 31C also moves in the same direction along the central axis Z while rotating in the same direction.
Thus, as shown in FIG.7 (b), the 1st outer cylinder part 31b is first extracted from the 1st cylindrical part 23b. Since the first outer cylinder part 31b has a smaller diameter than the second cylindrical part 23d, when the first outer cylinder part 31b moves to the region of the second cylindrical part 23d, the first outer cylinder part 31b becomes the second cylindrical part 23d. The first seal portion S1 is opened because it does not come into contact with.
However, even if the first outer cylinder part 31b is pulled out from the first cylindrical part 23b, the second outer cylinder part 31d maintains a fitted state with a part of the second cylindrical part 23d, so the second seal part. S2 remains as the second seal portion S2 ′ having a reduced fitting range.
For this reason, although a double seal part turns into a single seal part, the downstream pipe line P1 is still a closed state.

Further, if the rotation operation of the rotation operation portion 31C is continued, the rotation load is gradually reduced, and when the second outer cylinder portion 31d is pulled out from the second cylinder portion 23d, the second seal portion S2 ′ is also opened, and the plan The tip of the jar portion 31A is separated from all the inner peripheral surfaces of the downstream side pipe P1.
Thereby, a flow path communicating with the opening 23a is formed around the plunger portion 31A, and an open state is formed.
Further, when the rotation operation of the rotation operation portion 31C is continued, the tip end portion of the plunger portion 31A is also pulled out from the downstream side pipe P1, moves into the upstream side pipe P2, and communicates with the opening 23a. The road gradually expands.
As a result, as shown in FIG. 3, the fluid F kept in the first flow path and the second flow path moves to the opening 23a along the upstream pipe line P2 and the downstream pipe line P1, and the opening 23a Is poured vertically downward.

As shown in FIG. 8, when the plunger portion 31A is moved to fully open the spout stopper 1 as described above, the large-diameter portion 31g becomes the second cylindrical portion 23 on the tapered inner peripheral surface 24a. It moves from the end portion on the side to the end portion on the opposite side to the second cylindrical portion 23.
Since the large-diameter portion 31g is larger in diameter than the inner diameter of the tapered inner peripheral surface 24a at all moving positions, the seal region s2 that is a fitting portion in which the large-diameter portion 31g is deformed even in the fully opened state. Forming. Therefore, during the opening / closing operation, the end of the upstream side pipe P2 is closed by the third seal part, and the internal pressure of the first and second pipes is not reduced due to the inflow of outside air or the like. Absent.
However, since the tapered inner peripheral surface 24a has the gradient θ, the sliding load in the third seal portion gradually decreases during the period from the fully closed state to the fully opened state.

  As described above, in the present embodiment, when the rotation operation portion 31 </ b> C is rotated and the spout 1 is opened and closed, the third outer cylinder portion 31 h is a tapered inner peripheral surface 24 a which is the inner peripheral surface of the tubular portion 24. In a state in which the first outer cylinder part 31b is fitted to the first cylindrical part 23b and the second outer cylinder part 31d is fitted to the second cylindrical part 23d, It is possible to take a single closed state in which the two outer cylinder portions 31d are only fitted into the second cylindrical portion 23d.

  The flow rate of the fluid F increases as the retracted amount from the upstream pipe P2 in the plunger portion 31A increases, and as shown in FIG. 3, the locking claws 31nA and 31nB are end portions of the spiral grooves 25A and 25B. The maximum flow rate can be obtained in the fully opened state where the movement has been completed.

In the fully opened state in the present embodiment, the distal end surface 31a protrudes slightly toward the downstream pipe line P1 from the center of the cylindrical surface 22b, and the inner diameter is B, E, or more forward than the distal end surface 31a. As shown in A, a cylindrical channel having a length C that changes stepwise is formed.
Therefore, after the fluid F that has passed through the inside of the cylindrical surface 22b is decelerated after a part of the fluid F hits the tip of the plunger portion 31A in the upstream pipe P2, the second cylinder below the tip surface 31a. It passes through the upstream pipe line P2 in the body part 23, passes through the downstream pipe line P1, and is poured out from the opening 23a.

  Although the opening operation has been described above, the closing operation can be performed by performing the above operation in reverse.

The effect | action of the spout stopper 1 of this embodiment demonstrated above is demonstrated.
First, in the initial stage of the opening operation, when the second seal portion S2 is not provided, the friction load due to the fitting is rapidly reduced when the first outer cylinder portion 31b is removed from the first cylindrical portion 23b. If the rotation operation unit 31C is continuously rotated with a small rotation torque, the opening of the valve suddenly progresses and the fluid may flow out at a stroke.
However, in the present embodiment, even if the first seal portion S1 is eliminated, the second seal portion S2 ′ remains, so even if the friction load is reduced, it is not immediately opened, and a low load operation is performed. By continuing to some extent, it is possible to shift from the closed state to the open state. Even in the case of performing the closing operation, it is possible to make the fully closed state after shifting from the open state to the closed state in a low load state.
For this reason, it is easy to adjust the timing of dispensing and the amount of dispensing. In other words, it is possible to gradually dispense a small amount of fluid F, and it is also possible to stop immediately when it is desired to stop the dispensing.

In particular, when the diameter of the spout stopper 1 is reduced, the rotation operation portion 31C is also reduced in diameter, so that the rotation operation force is increased. For this reason, in the configuration of only the single-closed state, if an attempt is made to prevent liquid leakage when switching between the fully-closed state and the fully-open state, the operating force becomes large and a light and easy operation cannot be performed.
In the present embodiment, since the double closed state is changed to the open state through the single closed state, it is possible to achieve both prevention of liquid leakage and light and easy operation.

  Furthermore, in the present embodiment, the inner diameter A of the opening 23a, the inner diameter B of the upstream pipeline P2, the length C of the downstream pipeline P1, and the outlet diameter D of the first pipeline are expressed by the above formulas (1) to (1). The relationship (3) is satisfied. For this reason, a favorable rectifying action is generated, and the fluid F is formed into a stable substantially cylindrical flow without splashing from the opening 23a or causing a liquid turbulence with an unstable shape.

When D <B, the plunger portion 31A inserted into the third cylindrical portion 23g can adjust the opening area of the cylindrical surface 22b from a substantially zero state according to the degree of insertion. Therefore, the flow of the fluid F can be easily controlled.
That is, even if the plunger portion 31A is pulled out from the downstream pipe line P1 and an open state is formed, the flow path continues to be narrow while the plunger portion 31A covers the entire cylindrical surface 22b. The flow rate is small, and the flow rate change according to the amount of movement of the plunger portion 31A is small.
However, when the plunger portion 31A covers a part of the cylindrical surface 22b, the amount of opening of the cylindrical surface 22b changes according to the position of the plunger portion 31A, so that the change in flow rate increases.

  On the other hand, in the case of D ≧ B, even when the plunger portion 31A is inserted, the fluid F flowing out to the side without flowing into the plunger portion 31A from the cylindrical surface 22b and flowing into the second flow path is always Arise. For this reason, when the opening 23a is opened, the fluid F suddenly flows out, and the flow tends to be disturbed in the initial stage of opening.

When A / B is 0.3 or less, since the amount of reduction in the inner diameter of the downstream pipe P1 becomes too large, the flow velocity of the fluid F becomes too large and the flow is likely to be disturbed. In addition, the outer diameter of the first cylindrical portion 23b is too small compared to the outer diameter of the intermediate outer cylinder portion 31f. For this reason, in particular, when the inner diameter B is made thin in order to reduce the size of the spout 1, the first cylindrical portion 23 b becomes too thin, making it difficult to manufacture and securing sufficient strength as a plug. Can not do.
When A / B is 0.7 or more, since the amount of reduction in the inner diameter of the downstream pipe P1 is too small, the rectifying effect by the restriction becomes insufficient, and liquid storm is likely to occur.

If C / B is less than 0.3, the length of the downstream pipe line P1 becomes too short compared to the inner diameter of the upstream pipe line P2, and a good rectifying effect cannot be obtained.
If C / B exceeds 1, the downstream pipe line P1 becomes too long, and it becomes difficult for the fluid F to be received below the opening 23a, making it difficult to use. Moreover, since the movement amount of the plunger part 31A for making it a full open state increases, it will take time to open and close.

  As described above, according to the spout plug 1 of the present embodiment, since the above formulas (1) to (3) are satisfied, the liquid flow is not easily disturbed even in a configuration that can be easily opened and closed. can do.

It should be noted that all the constituent elements described in the above embodiments can be implemented by appropriately changing or deleting combinations within the scope of the technical idea of the present invention.
For example, in the description of the above-described embodiment, an example in which the fully closed state of the spout plug 1 is a double closed state has been described. However, even in a single closed state, it can be opened and closed with a low load, and liquid leakage can be prevented. In some cases, a configuration in which the fully closed state is a single closed state is possible.
In the description of the above embodiment, the example has been described in which the inner peripheral surface of the tubular portion is configured by the tapered inner peripheral surface 24a having a tapered shape. However, when the operation force in the open state is not so large. The inner peripheral surface of the tubular portion may not have a taper shape or may have a draft angle.

Next, Examples 1 and 2 of the spout stopper 1 of the present embodiment described above will be described together with Comparative Examples 1 to 3.
In Examples 1 and 2 and Comparative Examples 1 to 3, in the spout stopper 1, the inner diameter A of the opening 23a, the inner diameter B of the upstream pipe P2, the length C of the downstream pipe P1, and the first pipe The outlet diameter D is changed.
About the conditions of each Example and each comparative example, it shows in following [Table 1] with the evaluation result.

In Example 1, D = 8.8 (mm), B = 10.3 (mm), A = 7.1 (mm), and C = 5.5 (mm), and the above formula (1) , (2) and (3) are all satisfied.
Example 2 differs from Example 1 only in that C = 8.0 (mm), and satisfies all of the above formulas (1), (2), and (3).

Comparative Example 1 is an example in which the inner diameter of the second pipe line is made larger than that of Example 1, and the length of the downstream pipe line P1 is shortened, and D = 8.8 (mm), B = 13. 0 (mm), A = 10.7 (mm), and C = 3.5 (mm). Comparative Example 1 only satisfies the above formula (1), and does not satisfy the above formulas (2) and (3).
Comparative Example 2 differs from Example 1 only in that C = 3.0 (mm), and the above formulas (1) and (2) are satisfied, but the above formula (3) is not satisfied. .
Comparative Example 3 differs from Example 1 only in that A = 9.0 (mm), and the above formulas (1) and (3) are satisfied, but the above formula (2) is not satisfied. .

The evaluation was carried out by attaching the fluid to the liquid packaging container 11 and pouring out the fluid and observing how the fluid exits from the opening. The results are shown in the “Evaluation” column of [Table 1].
◯ (good) indicates that a fluid flow having a smooth and well-formed shape was formed without scattering and turbulence of the fluid. X (no good) indicates that fluid splattering or rampage was observed, and a smooth and well-formed liquid flow was not formed.

As shown in [Table 1], in Examples 1 and 2, no fluid splattering and turbulence were observed, a smooth and well-formed liquid flow was formed, and the evaluation was good.
On the other hand, the evaluations of Comparative Examples 1 to 3 were all x.
In Comparative Example 1, since A / B is larger than those in Examples 1 and 2, there is little throttling effect, and the liquid flow turbulence due to the change in the flow direction by the second flow path is large. Since the length C of the downstream pipe line is too short, it is considered that a sufficient rectifying effect is not obtained.
In Comparative Example 2, it is considered that a sufficient rectifying effect is not obtained because the length C of the downstream pipe line is too short as compared with Examples 1 and 2.
In Comparative Example 3, since A / B is larger than those in Examples 1 and 2, the throttling effect is small, and the length C of the downstream pipe line is relatively short, so that a sufficient rectifying effect is obtained. It is not considered.

1 Outlet plug 2 Plug body 3 Cock (plug member)
10 Spout (water inlet)
11 Liquid packaging container 22 1st cylinder part 22a Tapered surface (1st pipe line)
22b Cylindrical surface (first pipe)
23 2nd cylinder part 23a Opening 23b 1st cylindrical part (2nd pipe line, downstream pipe line)
23c 1st taper part (2nd pipe line, downstream pipe line)
23d 2nd cylindrical part (2nd pipe line, downstream pipe line)
23e 2nd taper part (2nd pipe line, downstream pipe line)
23f 3rd taper part (2nd pipe line, downstream pipe line)
23g Third cylindrical part (second pipe, upstream pipe)
24 Tubular part 24a Tapered inner peripheral surface (inner peripheral surface of tubular part)
25A, 25B Spiral groove 31 Plug member 31A Plunger part 31b First outer cylinder part 31C Rotation operation part 31d Second outer cylinder part 31f Intermediate outer cylinder part 31g Large diameter part 31h Third outer cylinder part 31nA, 31nB Locking claw part A Inner diameter (inner diameter of opening)
B Inner diameter (first inner diameter)
E Inner diameter (second inner diameter)
F Fluid O, Z Center axis P1 Downstream side pipe P2 Upstream side pipe S1 First seal part S2, S2 'Second seal part

Claims (3)

A first conduit is provided that is slidably fitted to the spout part of the liquid packaging container, and that allows a fluid contained in the liquid wrapping container to flow from the spout part when fitted to the spout part. A cylindrical body portion is extended in a direction intersecting the first pipeline of the first cylindrical body portion, and communicated with the first pipeline at a side portion, and an opening is provided at a first end portion. A second tubular portion having a second pipe formed therein, and a second end opposite to the first end of the second tubular portion are connected coaxially with the second pipe, A plug body having a tubular portion formed with a spiral groove; and
A rotation operation unit that is screwed into the spiral groove of the tubular part, and is inserted from the inside of the rotation operation part into the tubular part and the second cylindrical part, and extends over the entire circumference of the inner peripheral surface of the tubular part. A plug member having a cylindrical plunger portion that is slidably adhered and opens and closes the opening of the second conduit according to the amount of rotation of the rotation operation portion;
With
In the second pipeline,
A cylindrical upstream pipe line extending to a position facing the first cylindrical body part and having a first inner diameter larger than the inner diameter of the opening;
A downstream pipe formed in a cylindrical shape extending from an end of the upstream pipe and reducing in diameter from the first inner diameter to the inner diameter of the opening;
Formed,
When the inner diameter of the opening is A, the first inner diameter is B, the length of the downstream pipe is C, and the inner diameter of the first pipe in a portion communicating with the second pipe is D,
The following formulas (1), (2), and (3) are satisfied.
Spout plug.
D <B (1)
0.3 <A / B <0.7 (2)
0.3 ≦ C / B ≦ 1 (3) The downstream pipeline of the second pipeline is
A first cylindrical portion having the same inner diameter as the inner diameter of the opening and connected to the opening;
A second cylindrical portion having a second inner diameter that is smaller than the first inner diameter and larger than the inner diameter of the opening;
With
The plunger part is
A first outer cylinder portion having a smaller diameter than the inner diameter of the second cylindrical portion, shorter than the length of the second cylindrical portion, and detachably fitted to the first cylindrical portion;
A second outer cylinder portion that is larger than the outer diameter of the first outer cylinder portion and is detachably fitted to the second cylindrical portion;
A third outer cylinder portion slidably in close contact with the inner peripheral surface of the tubular portion;
With
When opening and closing by rotating the rotation operation unit,
In a state where the third outer cylinder part is kept in close contact with the inner peripheral surface of the tubular part, the first outer cylinder part is fitted to the first cylindrical part and the second outer cylinder part is the first The double closed state in which two cylindrical portions are fitted and the single closed state in which the second outer cylindrical portion is only fitted in the second cylindrical portion are possible. The spout stopper according to 1. The inner peripheral surface of the tubular part is
In order to change the frictional force with the third outer cylinder portion in a range in close contact with the third outer cylinder portion, a taper shape is formed that gradually increases in diameter as the distance from the second cylindrical portion increases. The spout stopper according to claim 2, characterized in that it is characterized in that

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