JPH0612354U - Pouring container - Google Patents

Abstract

(57) [Summary] [Purpose] A fine sphere containing a solvent is dispersed in a solution to contain the contents, and the fine sphere is broken in a container and poured out while mixing the solution and the solvent. Provided is a pouring container that can be used. [Structure] A squeeze container body 2 is provided with a mouth tube portion 3, a tubular flow passage body 4 is provided in the mouth pipe portion 3, and a flow passage 5 penetrating in the flow passage body 4 is formed. 5 is formed so that the inner diameter gradually increases toward the outlet side, and a rod-shaped body 6 is provided inside the flow path 5. The rod-shaped body 6 is formed at an acute angle on one end side facing the inside of the container. In addition, a plurality of annular protrusions 8 are provided around the middle of the rod-shaped body 6, and a threaded portion 9 is provided around the other end of the rod-shaped body 6.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pouring container, and more particularly, to a container for containing contents in which microspheres that are destructible and contain a solvent therein are dispersed in a solution.

[0002]

[Prior art]

 Conventionally, when a solution-like substance, regardless of whether it is a natural substance or a chemical substance, is stored in a container, it may change over time due to a chemical change such as polymerization.

[0003] In addition to changes due to changes in substances, ultraviolet rays from the outside may cause alteration or discoloration, and oxygen in the air may oxidize the contents.

Further, in natural flavors and prepared flavors that are a mixture of substances having different volatility, some volatile substances may be altered in content due to volatilization of the volatile substances. In particular, it is usual to add a fragrance to a lotion or emulsion, but various changes as described above are likely to occur in such a mixture, and various measures need to be taken.

In many cases, it is possible to suppress the chemical change of the contents by chemical treatment, but in the process of developing a more effective product, the chemical change over time is liable to occur. You may not get it.

In order to put such a product into practical use, for example, in the case where there is a first solution and a second solution which should be used at the same time but are not suitable for mixing, in the first solution, It is conceivable to disperse fine spheres (microcapsules) that are destructible and contain the second solution inside.

According to such a method, since the two do not come into direct contact with each other at the time of storage, the reaction is avoided, and at the time of use, the desired effect can be exerted by destroying and mixing the fine spheres. Become.

[0008]

[Problems to be solved by the device]

 However, when such a method is adopted, it is necessary to destroy the fine spheres by using the solution in which the fine sphere solution is dispersed in the palm of the hand and crushing it when using it, which is insufficient in terms of usability. There are various aspects.

The present invention has been made in view of the above-mentioned matters, and contains a content in which a fine sphere that is destructible and contains a solvent is dispersed in a solution, and the fine sphere is broken in a container. Therefore, it is a technical subject to provide a pouring container capable of pouring after mixing a solvent and a solution.

[0010]

[Means for Solving the Problems]

 In order to solve the above-mentioned technical problems, the present invention is a container for containing contents in which a fine sphere 1 which is destructible and contains a solvent inside is dispersed in a solution. It was configured.

That is, the mouth tube portion 3 is provided in the squeeze container body 2, the tubular flow passage body 4 is provided in the mouth pipe portion 3, and the flow passage 5 penetrating into the flow passage body 4 is formed. The flow path 5 is formed so that the inner diameter gradually increases toward the outlet side, and a rod-shaped body 6 is provided inside the flow path 5, and the rod-shaped body 6 has an acute angle on one end side facing the inside of the container. A plurality of annular protrusions 8 are provided around the middle of the rod-shaped body 6, and a threaded portion 9 is provided around the other end of the rod-shaped body 6. When the spheres 1 are pumped into the flow path 5, the fine spheres 1 are broken at the leading portion 7 and sequentially passed through the protrusions 8 and the screw portions 9 to be crushed.

The head portion 7 can be formed in a conical shape or a pyramidal shape.

[0013]

[Action]

 When the squeeze container body 2 is strongly pressed to increase the internal pressure, the fine spheres 1 are pumped into the flow path 5. At this time, the fine spheres 1 are first pressed against the leading portion 7 and broken, and the solvent inside flows out.

The solvent inside and the fragments and solutions of the fine spheres 1 are further pulverized and mixed while passing through the gap between the flow path 5 and the annular projection 8 provided in the middle of the rod-shaped body 6. Then, the mixture is further promoted while passing through the threaded portion 9 formed on the other end side of the rod-shaped body 6.

Since the solvent and the solution can be sufficiently mixed and poured out after breaking the microspheres in the container as described above, the trouble of crushing the microspheres after pouring is unnecessary.

[0016]

【Example】

 Next, an embodiment of the present invention will be described with reference to FIGS. The squeeze container body 2 is made of a flexible synthetic resin, and the inside thereof contains the contents formed by dispersing the fine spheres 1 which are destructible and contain the solvent therein in a solution.

The squeeze container body 2 is provided with a mouth tube portion 3. A screw thread 3a is provided on the outer periphery of the mouth tube portion 3, and the cap 20 is adapted to be fitted onto the screw thread 3a.

A spacer 40 is fitted in the mouth tube portion 3. The spacer 40 has a substantially cylindrical body having a hole 41 in the center, and the surface facing the inside of the container has a flat shape so that the contents can be introduced into the hole 41 when the internal pressure of the container increases. You can do it.

The hole 41 has a large diameter on the outlet side and forms a fitting portion 42. One end of the flow path body 4 formed in a tubular shape is fitted in the fitting portion 42. A flow passage 5 is formed in the flow passage body 4 so as to penetrate therethrough, and the flow passage 5 is formed such that the inner diameter thereof gradually increases toward the outlet side.

Explaining this state of expansion, assuming that the portion where the inner diameter does not change is the pipe portion and the portion where the inner diameter increases is the taper portion, the pipe portion, the taper portion, the pipe portion, and the diameter are The step 4a that expands, the tube portion, and the step that increases in diameter are formed in this order.

A rod-shaped body 6 is installed in the flow path 5. The rod-shaped body 6 is provided with a leading portion 7 formed at an acute angle on one end side facing the inside of the container, and further, in the middle of the rod-shaped body 6, annular projections 8 are provided at three places. A threaded portion 9 is provided around the other end of the rod-shaped body 6, and the outer circumference of the threaded portion 9 is formed so as to fit inside the step 4a whose diameter increases. A rectifying plate 6a is erected on the other end of the rod-shaped body 6. The flow path around the leading portion 7 is set to be narrower than the diameter of the fine sphere 1.

A nozzle body 30 is fitted onto the upper edge 4 a of the flow path body 4 in which the rod-shaped body 6 is housed and the mouth tube portion 3. The nozzle body 30 has a substantially conical shape, and a lower edge 31 of the nozzle body 30 is fitted on the mouth tube portion 3 and a back surface of the top portion is engaged with the upper edge 4a. The lower edge 31 is formed so as to be engaged with the convex portion 3b formed on the edge portion of the mouth tube portion 3 so as not to easily come off. A pouring hole 33 is provided at the top of the nozzle body 30, and the inlet of the pouring hole 33 is in contact with the upper edge of the straightening plate 6a. An annular packing presser 21 is formed on the back surface of the top plate of the cap 20, and a packing 22 is attached to a portion surrounded by the packing presser 21. The packing 22 is configured to close the pouring hole 33. Further, on the inner side of the lower edge of the cap 20, there is formed a thread portion 23 that is screwed into the above-described thread 3a.

Next, the operation of the above configuration will be described. When the squeeze container body 2 is strongly pressed to increase the internal pressure, the fine spheres 1 are pumped into the flow path 5 as shown by the arrow F. At this time, the fine sphere 1 is first pressed against the head portion 7 and destroyed. As a result, the solvent inside flows out and is dispersed in the solvent.

The fragments of the fine spheres 1 are further crushed while passing through the gap between the flow path 5 and the protrusions 8, and the solvent and the solution are mixed. Then, these mixtures rise while rotating the threaded portion 9 of the rod-shaped body 6, and further promote the mixing. In this way, when the fine spheres 1 are pumped into the flow path 5, the fine spheres 1 are broken at the leading portion 7 and also successively passed through the protrusions 8 and the screw portions 9 and crushed. Although the contents are rotated by passing through the threaded portion 9, they are rectified by the rectifying plate 6a and poured out.

As described above, since the fine spheres can be broken in the container and the solvent and the solution can be mixed and then poured out, there is no need to grind the fine spheres after the pouring.

[0026]

[Effect of device]

 As described above, according to the present invention, it is possible to store the content in which the fine spheres are dispersed, break the fine spheres in the container, and pour the mixture while mixing with the solution. At this time, since the fragments of the fine spheres are completely crushed in the process of passing through the head portion, the protrusion portion and the screw portion, the mixture of the solution and the solvent becomes more reliable.

[Submission date] October 18, 1993

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] 0022

[Correction method] Change

[Correction content]

A nozzle body 30 is fitted onto the upper edge 4 a of the flow path body 4 in which the rod-shaped body 6 is housed and the mouth tube portion 3. The nozzle body 30 has a substantially conical shape, and a lower edge 31 of the nozzle body 30 is fitted on the mouth tube portion 3 and a back surface of the top portion is engaged with the upper edge 4a. A recessed portion is formed on the lower edge 31, which is configured so as not come off easily engaged with the protrusion 3b formed on the rim of the mouth tube portion 3. A pouring hole 33 is provided on the top of the nozzle body 30, and the inlet of the pouring hole 33 is in contact with the upper edge of the straightening plate 6a. An annular packing presser 21 is formed on the back surface of the top plate of the cap 20, and a packing 22 is attached to a portion surrounded by the packing presser 21. Then, the packing 22 is configured to close the pouring hole 33. Further, on the inner side of the lower edge of the cap 20, there is formed a thread portion 23 that is screwed into the thread 3a.

[Brief description of drawings]

FIG. 1 is an exploded perspective view showing an embodiment of the present invention.

FIG. 2 is a sectional view showing an embodiment of the present invention.

[Explanation of symbols]

 1 ... Micro sphere, 2 ... Squeeze container body, 3 ... Mouth tube part, 4 ... Flow path body, 5 ... Flow path, 6 ... Rod body, 7 ... Leading part, 8 ... Projection part , 9 ... Screw part.

Claims (1)

[Scope of utility model registration request] 1. A container for accommodating the content of fine spheres, which are destructible and have a solvent contained therein, dispersed in a solution, wherein a squeeze container body is provided with a mouth cylinder part, A tubular flow passage body is provided in the portion to form a flow passage that penetrates the flow passage body,
The flow path was formed such that the inner diameter gradually increased toward the outlet side, and a rod-shaped body was provided inside the flow path, and the rod-shaped body was formed at an acute angle on one end side facing the inside of the container. A head portion is provided, a plurality of annular projections are provided in the middle of the rod-shaped body, and a threaded portion is provided around the other end of the rod-shaped body. The fine spheres are pumped into the flow path. Then, the fine sphere is broken at the leading end and is also crushed by successively passing through the protrusion and the screw.