JP2019014509A - Tube container and production method of tube container - Google Patents

Abstract

To provide a tube container in which cracks never occurs to an inside face of a cylindrical drum portion at the time of embossing in an emboss tube and at the time that contents of the tube container are pushed out.SOLUTION: This invention relates to a push-out tube container subjected to embossing, which is characterized in that a concave groove is provided to a peripheral face on a shoulder portion side of a cylindrical drum portion, and a portion that is an innermost layer in the cylindrical drum portion and in which at least the concave groove is provided is formed using thermosetting resin as a main component that is a high molecular weight epoxy phenol. The push-out tube container is also characterized in that the epoxy phenol which forms the innermost layer of the cylindrical drum portion is a high molecular compound of 40,000-50,000.SELECTED DRAWING: Figure 3

Description

  The present invention is a tube container having a special body structure for the purpose of improving the usability of the contents (bulk) and reducing the remaining amount of the bulk, and further a tube container mainly composed of metal, The present invention relates to an embossed tube that hardly causes cracks on its inner surface and a method for manufacturing the same.

2. Description of the Related Art Conventionally, tube containers having various forms such as paste-like and gel-like drugs, quasi drugs, seasonings, cosmetics, and chemical materials are known. This type of tube container is composed of a cap, a conical shoulder having an extraction port into which the cap is screwed, and a cylindrical body.
Examples of the material of the cylindrical body include those made of metal such as aluminum, lead and tin, those made of plastic using materials such as polyethylene, and those obtained by laminating materials such as aluminum, paper and polyethylene. .

  In order to take out the contents in these tube containers, it is necessary to push the torso with fingers. The bulk pressed by the finger is pressed inside the conical shoulder that is shaped to close the axial end of the torso, and is pushed out through the extraction port that has a smaller diameter than the torso. The Due to the structure of the tube container, even if the tube body is crushed, the bulk of the lattice portion including the peripheral portion inside the shoulder portion cannot be completely used up. Further, since the shoulder itself is generally highly rigid, it is difficult to crush it.

  When extruding the contents, the shoulder is pressed from the outside, and the central portion with the extraction port is pressed from the inside. Therefore, the shoulder portion is in a state of being easily deformed. Further, it is not easy to return the shoulder part once deformed to the original form, and in the state of being deformed, the cap cannot be smoothly attached, and there arises a problem that the airtightness is deteriorated. In particular, expensive pharmaceuticals or the like whose contents are often pushed out at a time is relatively small. For example, in the case of an insect bite medicine with a body diameter of 19.05 mm and an internal volume of 20 g, the average amount used per time is 0.04 to 0.05 g, and the diameter of the body is 12.7 mm. In the case of an amount of 5 g ointment, the amount used once is about 0.03 to 0.04 g on average. In the case of a tube container filled with such contents, it is common to use up the contents while repeating the attachment and extrusion of the cap several times.

As a technique for reducing the residual amount of the bulk, a device in which the shoulder portion of the tube body is bent obliquely (for example, refer to Patent Document 1), or a container having a structure for crushing the shoulder portion (for example, Patent Document 2). See.) Was known.
However, in these tube containers, there is a certain limit in reducing the remaining bulk amount remaining inside the shoulder. The contents of the tube container are pushed out from the extraction port by pressing the body part with fingers, but usually the contents are pushed out from the bottom sealing edge in parallel to the sealing edge sequentially toward the extraction port. In this case, as the remaining amount of the bulk decreases, shrinkage stress and tensile stress are generated in the shoulder portion and the trunk portion.
As shown in FIG. 8, that is, if the diameter of the tube is D, the width W of the sealing edge is π * D / 2, and the distance from the lower end surface of the shoulder portion to the lower end of the remaining bulk remaining amount is x. The distance L ₁ from the shoulder periphery to the ends of the tube that has been extruded is given by the three-square theorem:
L ₁ = {X ² + [(π / 4−1 / 2) * D] ² } ^(1/2)
Also, the distance L _{2 to} the midpoint of the width is
L ₂ = [X ² + (D / 2) ² ] ^(1/2) .

Since L ₁ <L ₂ from the above equation, when a pressing force is applied, the difference between L ₁ and L ₂ is absorbed, so that a contraction stress occurs in the portion corresponding to L ₁ , Tensile stress will be generated in the part corresponding to ₂ . Then, as X becomes smaller, that is, as the remaining amount of bulk decreases, the ratio of the difference between L ₁ and L ₂ gradually increases, so that these stresses further increase.
This shrinkage stress causes irregular deformations such as irregular wrinkles and dents in the body, and these wrinkles and dents impede pushing into the shoulder of the body and require excessive force for extrusion. In addition, the tensile stress works to resist the pressing force, so a large force is required for extrusion, and the shoulder part is deformed by pulling the shoulder part downward, causing the problem of screwing of the cap and the decrease in airtightness. It was to become.
By studying such problems, a tube container called an embossed tube has been developed (see Patent Document 3).
Such an embossed tube prevents irregular deformation of the tube as much as possible by providing a concave groove around the cylindrical body, and allows the contents to be pushed out without requiring excessive force. As a result, an excellent effect of reducing the bulk remaining amount is exhibited.

In general, the tubular cylindrical body has a metal layer that protects the contents and a protective layer formed of polyethylene or the like in order to protect the metal from the contents.
However, such an embossed tube has a problem that a crack is generated in the protective layer when a concave groove is formed. For this reason, although depending on the type of contents, there is a concern that the function of protecting the metal layer from the contents may be deteriorated due to such problems.
In particular, the body of the tube container has an intermediate layer formed of metal to protect the contents. Further, in order to protect the metal layer and suppress the alteration of the contents, the inner surface is generally covered with a protective layer formed of polyethylene resin or the like. However, when a crack occurs on the inner surface as described above, there is a concern that the contents may exude, erode the metal layer, and cause alteration of the contents.

Japanese Utility Model Publication No. 62-19945 Japanese Utility Model Publication No. 7-37949 Japanese Patent No. 3596875

The present invention has been made to solve the above-described drawbacks of the prior art, and the object of the present invention is to provide irregular recesses in the tube by providing a concave groove around the cylindrical body. In addition to preventing as much as possible, it is possible to extrude contents without requiring excessive force, and as a result, to reduce the remaining amount of bulk. And this invention suppresses generation | occurrence | production of the crack at the time of embossing in the inner surface of the part in which the concave groove formed in the circumference | surroundings of a cylindrical trunk | drum is provided, protects a metal layer, and prevents the deterioration of the content. For the purpose.
Another object of the present invention is to provide a tube container in which no crack is generated on the inner surface of the cylindrical body even when the concave groove is folded when the contents of the tube container are pushed out.

  Another object of the present invention is to make it possible to manufacture a tube container having a small bulk remaining amount and a crack that does not crack on the inner surface of the cylindrical body part by a simple process while suppressing the manufacturing cost of the embossed tube.

The present invention has the following configuration in order to solve the above problems.
(1) An extruded tube container having a tubular body and a shoulder, wherein the tubular body of the extruded tube container is formed by laminating two or more layers of different materials, and the tubular body A concave groove is provided on the peripheral surface on the shoulder side of the portion, and the innermost layer in the cylindrical body portion, at least the portion where the concave groove is provided is thermoset mainly composed of a high molecular weight epoxy resin. It is a tube container characterized by being formed with a conductive resin.

(2) The above-mentioned (1), wherein the epoxy resin, which is the main component of the thermosetting resin forming the innermost layer of the cylindrical body, is a polymer compound having a molecular weight of 40,000 to 50,000. ) Described in the tube container.
The epoxy resin according to the present invention is a polymer compound having a molecular weight of 40,000 to 50,000. This is because if an epoxy resin having a molecular weight of less than 40,000 is used, the problem of cracks on the inner surface of the cylindrical body portion that occurs during embossing or extrusion cannot be solved.
In addition, secondary workability (embossability) and curability are in a trade-off relationship, and secondary workability is improved. However, if the molecular weight exceeds 50,000, curability is reduced. Is concerned. If the curability is lowered, it tends to be very weak against an impact such as dropping, and as a result, the metal layer and the contents come into contact with each other, and there is a risk that a serious problem such as leakage occurs.

(3) The thermosetting resin forming the innermost layer of the cylindrical body is formed of an amino-modified epoxy phenol composed of an amino resin and a phenol resin in addition to a high molecular weight epoxy resin as a main component. The tube container according to (1) or (2) above, which is characterized.
(4) The metal tube container described in any one of (1) to (3) above, wherein the extruded tube container is made of a material mainly composed of metal.
Examples of the material for the metal container in the present invention include aluminum, lead, tin, and the like, and aluminum is particularly preferable from the viewpoints of workability and economy.
Since such a metal material has a weaker restoring force than plastic or the like, when the shape of the tube is deformed by extrusion, the bulk in the tube is held in the same shape until the next extrusion. Since the bulk can be further extruded from such a held state, the effect of the present invention appears more remarkably compared to a tube made of plastic or the like.

In addition, for a drug that easily denatures due to external influences, a metal tube container having a high barrier property is preferable.
The shape and dimensions of the groove of the present invention are determined by design depending on the material used for the tube, etc., but the action of absorbing deformation due to stress is increased as the groove dimension increases with respect to the tube diameter. It appears prominently. Even after extending according to the tensile stress, it is preferable that the recess is formed. This is to ensure that the concave groove is folded and pressed against the inner surface of the shoulder portion in the final extrusion that uses up the remaining bulk amount.
In addition, in a tube container in which a protective layer is formed on the innermost layer of a metal material such as aluminum, the effect of using an amino-modified epoxy resin as an inner surface liquid becomes higher. That is, the amino-modified epoxy resin has a characteristic of good adhesion to a metal material such as aluminum because it has been subjected to an amino-modified treatment.

(5) A method for producing an extruded tube container comprising a cylindrical body, a shoulder with an extraction port, and a cap, wherein the cylindrical body in the extruded tube container is formed, annealed, and After applying a thermosetting resin whose main component is a high molecular weight epoxy resin having a molecular weight of 40,000 to 50,000 to the inner surface of the innermost layer, embossing is performed, so that the peripheral surface on the shoulder side of the cylindrical body portion A tube container manufacturing method is characterized in that a concave groove is provided in the tube container.
(6) The method for producing a metal tube container according to the above (5), wherein the extruded tube container is formed of a material mainly composed of metal.

As the embossing in the present invention, various processing methods such as a roll transfer method, a punching method, a match metal method, vacuum / pressure forming, and high frequency forming can be employed. Examples of the method for forming the tube container include press working and blow molding. In general, pressing involves many steps before a product is finished.
The present invention can manufacture a container that achieves a reduction in the remaining amount of bulk easily, quickly and inexpensively by adding an embossing process to the tube container manufacturing process. In addition, the reason why the embossing process sequence is applied after applying a thermosetting resin mainly composed of a high molecular weight epoxy resin having a molecular weight of 40,000 to 50,000 is that the inner coating is performed after the embossing process. It is considered that the occurrence of cracks can be suppressed, but the coating after embossing can be considered to cause uneven coating on the protective layer.

  A tube container is manufactured through many processes. In general, the capping step of screwing the cap onto the threaded portion is performed after the tube container is coated. When embossing is performed at the beginning of the manufacturing process, for example, when the cylindrical body portion of the container is press-molded, the thickness of the protective layer can be made uniform in the subsequent process of coating the inside and outside of the tube. Inconveniences such as inability to occur.

  Therefore, the present invention is characterized in that embossing is performed simultaneously in the capping step which is relatively close to the final step, or embossing is performed before and after the capping step. As the embossing in the present invention, various processing methods such as a roll transfer method, a punching method, a match metal method, vacuum / pressure forming, and high frequency forming can be employed in the same manner as described above. A roll transfer method or a punching method is particularly preferable from the viewpoint of compatibility with press working.

With the tube container of the present invention, it is possible to suppress the occurrence of cracks on the inner surface during embossing, protect the metal layer, and prevent the contents from being altered or leaked.
In addition, the tube container of the present invention can provide a tube container in which no crack is generated on the inner surface of the cylindrical body portion even when the concave groove is folded when the contents of the tube container are pushed out.
In addition, the tube container manufacturing method according to the present invention provides a tube container with a small remaining amount of bulk by a simple process while suppressing the manufacturing cost of the embossed tube, and the tube in which the inner surface of the cylindrical body does not crack There is an excellent effect that enables the production of the container.

It is a figure which shows the tube container which concerns on Embodiment 1 of this invention. (A) is a top view of the tube container which concerns on Embodiment 1. FIG. FIG. 3B is a side view of the tube container according to the first embodiment. It is the II-II arrow cross section of the tube container shown in FIG. 1 which concerns on Embodiment 1 of this invention. (A) is the II-II arrow directional cross-sectional view in Fig.1 (a). (B) is the II-II arrow sectional drawing in FIG.1 (b). (C) And (d) is sectional drawing in the conventional tube container. It is a conceptual diagram which shows the laminated structure in the cylindrical trunk | drum in the tube container which concerns on Embodiment 1 of this invention. It is a conceptual diagram explaining one function of the embossing part in the tube container which concerns on Embodiment 1 of this invention. It is a figure which shows the process of embossing. It is an enlarged view of the groove | channel of the recessed part in an embossing part. It is a conceptual diagram for demonstrating the inner surface coating process in the manufacturing method of the tube container which concerns on this embodiment. It is a figure for demonstrating the irregular deformation accompanying extrusion of the contents in a tube container. (A) is a front view, (b) is a side view.

Hereinafter, an example of an embodiment according to a tube container and a method for manufacturing the tube container will be described. In addition, since embodiment shown below is an illustration of this invention, even if it is embodiment which is not described below, it may belong to the scope of the present invention.
Embodiment 1
The present invention is an extruded tube container having a cylindrical body and a shoulder, wherein the cylindrical body of the extruded tube container is formed by laminating two or more layers of different materials, and the cylindrical A concave groove is provided on the peripheral surface on the shoulder side of the trunk, and the innermost layer in the cylindrical trunk and at least the portion where the concave groove is provided is mainly composed of a high molecular weight epoxy resin. It is formed of a thermosetting resin.
For example, as shown in FIG. 1, an extruded tube container having a cylindrical body portion 7 and a shoulder portion 6, wherein a large round concave groove 4 is provided on the peripheral surface of the cylindrical body portion 7 on the shoulder portion 6 side. It is a tube container.

A concave groove 4 is provided on the peripheral surface on the shoulder side of the cylindrical body of the tube container according to the present invention, as shown in FIG. The concave groove 4 is a cylindrical body portion 7 of the tube container, and is provided in the vicinity of the extraction port 8 and the shoulder portion 6 in the tube container. For shrinkage stress, the groove is deformed so as to be folded, and for tensile stress, the groove is deformed so as to extend, and functions to absorb these stresses.
The inner peripheral diameter of the tube at the bottom of the concave groove 4 may be smaller than the outer peripheral diameter of the tube at the shoulder and the trunk. Therefore, the cross-sectional shape in the axial direction of the concave groove 4 may be not only U-shaped but also V-shaped as shown in FIG. 1, or may be a bellows-shaped W shape having a plurality of concave portions.
The groove may be continuous or discontinuous along the peripheral surface. Any shape may be used as long as it can absorb at least deformation caused by shrinkage stress and tensile stress. Further, a plurality of concave grooves 1 may be provided adjacent to each other in the axial direction.

  FIG. 2A is a cross-sectional view taken along the line II-II in FIG. 1, showing a case where the body portion 7 of the tube container in FIG. Moreover, FIG.2 (b) is II-II arrow sectional drawing of the tube container in FIG.1 (b). FIG. 2C is a cross-sectional view corresponding to FIG. 2A, showing a case where the body of a general-purpose tube container having no concave groove 4 is bent at a substantially right angle with respect to the extraction port. . Further, FIG. 2 (d) is a cross-sectional view corresponding to FIG. 2 (b) showing a case where the body of a general-purpose tube container having no concave groove 4 is bent at a substantially right angle with respect to the extraction port. .

FIG. 2 is a cross-sectional view showing a comparison of how the bulk remaining at the boundary between the inner side of the shoulder portions 6 and 32 and the trunk portions 7 and 34 is used up. 2 (a) and 2 (b) are illustrations of a tube container having a concave groove 4 according to the present invention, and FIGS. 2 (c) and 2 (d) show the structure of a conventional product.
2C and 2D, when the bent portion of the body portion 34 is pushed out toward the extraction port, the shoulder portion 32 is held by fingers while the body portion 34 is pressed toward the extraction port. Therefore, pressing is applied in the direction of the trunk. As a result, a tensile force is applied to the boundary between the shoulder portion 32 and the body portion 34 by pressing the body portion 34 against the extraction port, and a bending stress is applied to the shoulder portion 32 accordingly.

  The shoulder portion 32 is generally made of a highly rigid material, but is deformed by a certain bending stress or more. In particular, a metal tube has a property of holding a plastic force as compared with a resin tube, and therefore, plastic strain tends to occur from the shoulder to the extraction port. And it is difficult to return the shoulder part 32 once deformed to the original state, so that a problem occurs in the screwing of the cap or the airtightness deteriorates. However, in the products of the present invention shown in FIGS. 2A and 2B, the tensile stress caused by pressing the body portion 7 against the extraction port is absorbed by the folded concave portion 4. As a result, no tensile stress is generated at the boundary between the shoulder portion 6 and the trunk portion 7, and the bending stress of the shoulder portion 6 is less than that of the conventional product. As a result, in the product of the present invention, the shoulder 6 is hardly deformed.

However, it has been known that such a concave groove 4 may be cracked during embossing on the inner surface of the portion where the concave groove 4 is provided. Such a crack causes a problem since the protection of the metal layer is insufficient and the contents cannot be prevented from being deteriorated. Further, when the contents of the tube container are pushed out, there is a risk that a crack is generated on the inner surface of the cylindrical body portion by folding the concave groove 4.
FIG. 3 is a cross-sectional view showing a laminated structure of a cylindrical trunk in the tube container according to the embodiment of the present invention.
As shown in FIG. 3, the cylindrical body portion of the tube container according to the first embodiment includes a print layer 11, a metal layer 12, and a heat mainly composed of a high molecular weight epoxy resin in the innermost layer of the cylindrical body portion. It is comprised from the layer 14 formed with the curable resin.
In the tube container of the present invention, a thermosetting resin mainly composed of a high molecular weight epoxy resin is formed in the innermost layer of the cylindrical body portion where at least the concave groove 4 is provided. Therefore, the crack problem can be solved.

  In the extruded tube container of the present invention, a click feeling is generated when the recess 4 is pressed against the shoulder 6. As shown in FIG. 4, the inner diameter of the tube at the bottom of the recess 4 before the contents 5 are extruded has a distance C1. Next, the bottom part of the recessed part 4 moves to the extraction port 8 side by pressing the body part 7 toward the shoulder part 6, and the inner diameter of the bottom part of the recessed part 4 becomes narrow to C2. At this time, the inner surface on the shoulder side of the recess 4 is substantially perpendicular to the axial direction. A compressive force is applied to the opening C2 formed by the bottom of the recess 4 in the circumferential direction. Such compression force is greatest when the interval between the inner diameters C2 is minimized, and the strongest force is required for the extrusion of the contents 5. Therefore, when the body part 7 is pushed to push the contents 5 further than the state of the inner diameter C2, the compressive force generated in the opening C2 in the bottom part of the recessed part 4 is released, and the recessed part 4 is pressed against the back side of the shoulder part 6. . The release of this compressive force becomes a click feeling and is transmitted to the person pushing out the contents 5 from the tube container.

Next, an example of a method for producing the product of the present invention will be described with reference to FIGS. The product of the present invention is a metal tube container.
First, slag is press-molded by cold forging combined extrusion. Next, the upper end of the extraction port and the bottom end surface of the cylindrical body on the side opposite to the extraction port serving as the filling port are cut. At that time, thread rolling for screwing the cap onto the extraction port is performed. Next, it heats with an annealing furnace and the work hardening by plastic working is removed.
In the next step, in order to protect the contents, the inside of the tube container is painted to form a protective film.
Here, as a method of forming the protective film inside the tube container, spray coating or the like can be mentioned. For example, spray coating is efficiently performed by the method shown in FIG.
The spray gun is a long-axis nozzle type. As a basic operation, the spray gun is applied by inserting the spray gun from the rear end opening of the metal tube container toward the tip of the tube and retreating it while spraying the paint. After the impact pressing process, the created metal tube container is subjected to a lace process and an annealing process, and then conveyed to the inner surface coating table by a roving star 48 shown in FIG.

As shown in FIG. 7D, the inner surface of the metal tube container on the table A is applied by inserting a spray gun 53 and spraying paint onto the inner surface of the shoulder portion and the inner surface of the trunk portion. At this time, the metal tube container is preferably rotated. Here, since the round is formed on the circumferential inner surface of the switching portion between the body portion and the shoulder portion of the tube container, the paint can be applied to the circumferential inner surface of the switching portion with high accuracy and uniformity.
Here, as the coating material, for example, a thermosetting resin, a thermoplastic resin, a dispersion type coating material, a low temperature curing type coating material, or the like can be used. Specifically, epoxy phenol of an epoxy paint can be used.

The inner surface coating on the table B is performed by inserting the spray gun 53 of FIG. 7D and spraying the coating material on the inner surface of the shoulder portion and the inner surface of the trunk portion. At this time, the metal tube is rotating.
The inner surface coating on the table C is performed by inserting the spray gun 51 of FIG. 7B and spraying the coating material on the inner surface of the discharge portion and the inner surface of the shoulder portion. At this time, the metal tube is rotating.
The inner surface coating on the table D is applied by inserting the spray gun 52 shown in FIG. At this time, the metal tube is rotating.
The inner surface of the table E is applied by inserting the spray gun 52 shown in FIG. At this time, the metal tube is rotating.
The inner surface coating on the table F is performed by inserting the spray gun 51 of FIG. 7B and spraying the coating material on the inner surface of the discharge portion and the inner surface of the shoulder portion. At this time, the metal tube is rotating.
By such a process, a highly resistant coating film with high resistance to the contents of the metal tube can be uniformly and accurately applied. It is preferable that an intermediate drying step is interposed between step C and step D. Further, the combination of spray guns is not limited to the above steps.

Subsequently, the tube appearance is coated with a ground coating liquid. Further, a product name or the like is printed on the surface of the tube container.
In the next step, a cap is screwed onto the screw portion provided at the extraction port of the tube container by a capping machine. At that time, embossing was applied from the inside of the turntable.
Such embossing is performed by pressing the embossing die 24 against the shoulder 22 side of the cylindrical body by an air cylinder, as shown in FIG. Although the cross-sectional shape of the embossing die 24 in FIG. 5 is circular, it may be an embossing die having a cross-sectional shape such as a triangle according to a desired embossing shape.

Since the container itself rotates in the direction of the arrow, a groove is formed on the circumference of the cylindrical body 25 by the embossing die 24 pressed as shown in FIG.
Such embossing is not necessarily performed simultaneously with capping, and may be performed immediately before or after capping.

A tube container as shown in FIG. 1 is completed through these steps. A concave groove 4 is formed on the shoulder 6 side of the cylindrical body 7 by embossing.
After embossing is completed, a sealing agent for preventing leakage of the contents is applied to the inside of the tube container hem.
After filling the contents, sealing is performed to complete a product filled with the contents.
If the manufacturing method of the metal tube container which concerns on this embodiment is used, the metal tube container of outer diameter (PHI) 11.1 mm-57.0 mm can be manufactured widely. Further, the shape of the discharge portion of the metal tube container is not limited, and various metal tube containers such as an open type, a closed type, and a pointed open type can be manufactured.

Example 1
A metal extruded tube container shown in FIG. 1 was produced. The extruded tube container according to this example (described as “product of the present invention” in Table 1) is a metal extruded tube container having a cylindrical body part, a shoulder part, and a concave groove. The tube container used in Example 1 was φ28.5 × 180 mm.
FIG. 6 is an enlarged view of a concave groove portion of the tube container according to the present embodiment. The angle of the central bottom portion of the concave groove is approximately 90 °, the groove depth from the top surface to the central bottom portion is 0.75 mm, and the groove width in the axial direction is 3.0 mm. The curvature of the bottom of the groove is a radius R1.5 mm.

Such a tube container is manufactured by press molding, but the concave groove 1 was formed by embossing. The material forming the innermost layer of the cylindrical body 7 is amino-modified epoxy phenol having a molecular weight of 40,000 to 50,000. As an example, such a tube container was manufactured.
Further, as a comparative example, the tube container shown in FIG. 1 was manufactured, and a tube container of the same scale was manufactured for comparison, and the innermost layer was formed of amino-modified epoxy phenol having a molecular weight of 5,000. As a comparative example, such a tube container was manufactured (described as “conventional product” in Table 1).
And in order to confirm the crack state which generate | occur | produces in the inner surface of the tube container which gave said 2 types of embossing, the electricity supply test was done.
Here, the energization test is a test in which the tube is filled with a 5% aqueous solution of copper sulfate, then a voltage of 7 V is applied for 30 seconds, and the maximum current value flowing at that time is measured.
Table 1 summarizes the contents of the conventional products as the tube container and the comparative example in Example 1, and shows the average value obtained by measuring the energization values of 16 each.

Table 2 below is a graph showing the results of the energization test in Example 1 in a bar graph.

  As apparent from Table 2, the energization value in the tube container coated with the inner surface liquid corresponding to the molecular weight of 40,000 to 50,000 according to the present invention is the inner surface liquid corresponding to the molecular weight of 5,000. It was a low value compared with the energization value of the applied conventional tube container. From the above, it was proved that the tube container of the present invention can suppress the occurrence of cracks on the inner surface during embossing.

Example 2
In the same manner as in Example 1, a tube container subjected to embossing of φ28.5 × 180 mm was manufactured. As the inner surface liquid, two types (amino-modified epoxy phenol having a molecular weight of 40,000 to 50,000 and amino-modified epoxy phenol having a molecular weight of 5,000) were applied, and a hair color agent was filled as the contents.

In Tables 3 to 5 below, the medium brightness product is a hair color agent having a pH of about 8.0. On the other hand, the high brightness product is a hair color agent having a pH of about 10.0.
Moreover, two types of tube containers with different inner surface liquids were left in the sealed space. At this time, after storage for 30 days in an environment of 40 ° C. 75% RH (humidified condition) or 50 ° C. DRY (dry condition) as storage conditions, three hydrogen concentrations were measured under each condition. Table 3 shows the average values obtained as a result of measurement in Table 3 under the environment of 40 ° C. and 75% RH, and Table 4 shows the average value in the environment of 50 ° C. DRY.
In addition, dropping means that 12 individual packaging boxes (40 x 35 x 195 mm) are packed in one box, dropped from a height of about 1 m in that state, and then stored for 30 days under the respective storage conditions. It is a test that measures the hydrogen concentration.

As shown in Tables 5 and 6, in all tests under normal and falling conditions, the tube container according to this example was found to have a lower average hydrogen concentration (%) than the conventional tube container. It was. The fact that the value of the average hydrogen concentration is low indicates that the tube container according to the present invention is superior to the conventional tube container in secondary workability and has high impact resistance.
As a result, it was proved that the risk of contact between the contents of the tube container and the metal layer forming the tube container was reduced. That is, it can be seen that the tube container of the present invention can suppress the occurrence of cracks during embossing, and can protect the metal layer forming the tube container and prevent the contents from being altered. It was.

4 Concave groove 7, 34 Cylindrical body 6, 32 Shoulder 8 Extraction port

Claims (6)

An extruded tube container having a tubular body and a shoulder, wherein the tubular body of the extruded tube container is formed by laminating two or more different materials, and the shoulder of the tubular body A thermosetting resin in which a concave groove is provided on the peripheral surface of the portion side, and the innermost layer in the cylindrical body portion, at least the portion provided with the concave groove is a main component of a high molecular weight epoxy resin It is formed by the tube container characterized by the above-mentioned. 2. The tube according to claim 1, wherein the epoxy resin, which is a main component of the thermosetting resin forming the innermost layer of the cylindrical body, is a polymer compound having a molecular weight of 40,000 to 50,000. container. The thermosetting resin that forms the innermost layer of the cylindrical body is formed of amino-modified epoxyphenol composed of an amino resin and a phenol resin in addition to a high molecular weight epoxy resin as a main component. The tube container according to claim 1 or 2. The metal tube container according to any one of claims 1 to 3, wherein the extruded tube container is made of a material mainly composed of metal. A method for producing an extruded tube container comprising a cylindrical body, a shoulder with an extraction port and a cap, wherein the tubular body in the extruded tube container is formed, annealed, and the innermost layer in the tubular body After applying a thermosetting resin mainly composed of a high molecular weight epoxy resin having a molecular weight of 40,000 to 50,000 on the inner surface, embossing is performed to form a concave shape on the peripheral surface on the shoulder side of the cylindrical body. A method of manufacturing a tube container, comprising providing a groove. 6. The method for producing a metal tube container according to claim 5, wherein the extruded tube container is made of a material mainly composed of metal.

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