KR102271397B1 - Container cap and mold for manufacturing the container cap - Google Patents

Abstract

The present invention relates to a container cap and a mold for manufacturing the same container cap, wherein the container cap (200) comprises: an external cap part (210) holding a fermented food therein, having a cap screw screw-coupled to a cap screw formed on the outer circumferential surface of a container body (100) and shielding the upper part of the container body (100); an internal cap part (220) protruding to the lower part on an edge of the ceiling surface of the external cap part (210) to be spaced from the external cap part (210); and gas shielding parts (230, 240, 250) formed in the internal cap part (220) and the external cap part (210) and coming in close contact with the inner circumferential surface of the container body (100) and the outer circumferential surface of the container body (100) when the external cap part (210) is screw-coupled to the container body (100) to block gas discharge step by step. The present invention allows the first gas shielding part (230) to the third gas shielding part (250) to block and concurrently release the pressure of fermented gas step by step, thereby gaining time for enabling a gas absorbent to absorb the fermented gas such that the container cap is prevented from exploding.

Description

Container cap and mold for manufacturing the container cap

The present invention relates to a container cap and a mold for manufacturing the container cap, and more particularly, to a separate collection container cap that blocks carbon dioxide emission and facilitates separation and discharge of a gas absorbent, and a mold for manufacturing the container cap.

As the number of single-person households increases, the demand for simple eating of fermented foods such as kimchi and doenjang that helps immunity is increasing.

Since fermented foods such as kimchi and soybean paste lose their freshness from the moment they are put in a container and distributed, they are packaged and distributed in sealed containers to maintain the freshness of the announced foods.

However, since fermented foods generate fermented gases such as carbon dioxide and ethylene, there is a problem in that the sealing or the cap is exploded due to the fermented gas in the distribution process.

As a solution to this, a gas absorbent is included in the sealed container, but since the gas absorbent is integrally attached to the cap of the sealed container, it is difficult for consumers to separate and discharge the container when discharging it. When fermentation gas is generated, there is still a problem that the sealed container cannot withstand it, so that the cap expands and explodes in severe cases.

In addition, a container product is being developed that allows only fermentation gas to be released by drilling a hole and attaching a breath sticker to prevent explosion of the cap. However, in this case, the smell of fermentation gas is leaked to the outside, so odor problems and generation of fermentation gas are reduced in the distribution process. It may cause a problem of deterioration of freshness by accelerating it.

Registered Patent Publication No. 0736199 (registered on June 29, 2007)

The present invention has been devised to solve the above problems, and an object of the present invention is to facilitate the separation of the gas absorbent, and to prevent the discharge of the fermentation gas step by step during the expansion of the container cap due to the fermentation gas, thereby causing the container cap to burst. It is to provide a container cap and a mold for manufacturing the container cap having a structure that helps the gas absorbent to efficiently absorb fermentation gas.

In a container cap according to an embodiment of the present invention for solving the above problems, the fermented food is accommodated therein, the cap screw is screwed to the cap screw of the container body formed on the outer circumferential surface, and an outer cap part for shielding the upper part of the container body and an inner cap portion protruding downward to be spaced apart from the outer cap portion around the edge of the ceiling surface of the outer cap portion, and formed in the inner cap portion and the outer cap portion, wherein the outer cap portion is screwed into the container body when the container body is It is in close contact with the inner circumferential surface and the outer circumferential surface of the container body and includes a gas shielding unit to prevent gas discharge step by step.

The inner cap portion includes at least one support protrusion protruding toward the center from the inner circumferential surface of the outer cap portion spaced apart from the ceiling surface by a predetermined distance and a fitting slit formed concave along the inner circumferential surface at a location spaced apart from the bottom surface of the support protrusion by a predetermined distance. , A gas absorbent is disposed between the ceiling surface of the outer cap and the support protrusion, and the edge of the sealing paper is fitted and fixed to the fitting slit.

The gas shielding portion, the first gas shielding portion protruding around the outer circumferential surface of the inner cap portion so as to be in close contact with the inner circumferential surface of the container body, and the inner cap portion and the outer cap portion so as to be in close contact with the upper end of the inner circumferential surface of the container body to protrude downward It includes a second gas shielding portion formed and a third gas shielding portion formed to protrude from the upper inner peripheral surface of the outer cap portion so as to be in close contact with the upper end of the outer peripheral surface of the container body.

The first gas shielding part is an inclined mountain formed by a meeting of an upwardly inclined surface inclined upwardly from the lower end of the outer peripheral surface of the inner cap part to an outer upper direction and a downward inclined surface inclined downwardly from the upper end of the outer peripheral surface of the inner cap part to an outer lower direction. The inclination angle of the inclined surface is greater than the inclination angle of the downward inclined surface.

The second gas shielding part includes a straight protruding surface protruding downward while forming a first space spaced apart from the upper end of the inner cap part, and the upper inner edge of the container body by being inclined from the lower end of the straight protruding surface to the upper end and A close-close inclined surface of the corner is bent upward from the close-contact inclined surface to form an upper-contact inclined surface that is in close contact with the upper edge of the container body, and the end of the corner-close inclined surface forms a gap between the inner circumferential surface of the container body do.

The third gas shielding unit includes an inclined protrusion surface that protrudes from the inner circumferential surface of the outer cap part of the container cap toward the upper end of the outer circumferential surface of the container body to form a second space spaced apart from the upper surface close contact inclined surface, and the inclined protrusion A curved contact surface that is bent roundly at the end of the surface and is in close contact with the outer circumferential surface of the container body, and a support protrusion surface that is bent at the end of the curved contact surface and extends to the inner circumferential surface of the outer cap part are formed.

The fermented gas generated in the fermented food accommodated in the container body is absorbed by the gas absorbent, but the excess capacity moves to the space between the inner peripheral surface of the container body and the upwardly inclined surface of the first gas shielding part, and when it exceeds a certain pressure, the When the inner circumferential surface of the container body and the inclined mountain of the first gas shield are widened, the fermentation gas moves to the first space to lower the internal pressure, and when the first gas shield exceeds a certain pressure in an open state, the fermentation gas moves to a gap between the inner peripheral surface of the container body and the edge close inclined surface of the second gas shield, and the connection portion between the edge close inclined surface and the upper surface contact inclined surface of the second gas shield is separated from the inner peripheral surface of the container body As the fermentation gas moves to the second space, the internal pressure is lowered.

The container cap is manufactured in a mold.

The mold includes a fixed side plate installed on the fixed side, a fixed plate installed on the fixed side plate and provided with a die, a first main core provided on the die and constituting a part of the shape of the outer cap of the container cap, and the fixed side plate; The first main core is provided in an eject plate that is movably installed between the fixed plates and has an eject pin for taking out the molded container cap, and a movable side plate installed on the movable side and a movable plate installed on the lower side of the movable side plate. A second main core forming a first cavity corresponding to the shape of the outer cap portion of the container cap in cooperation with and one end are installed on the ejection plate to move together with the ejection plate, and the other end to cooperate with the first main core and a deformable core pin having a deformable core forming a second cavity corresponding to the shape of the inner cap portion of the container cap.

A pin hole through which the eject pin passes and a core hole through which the deformable core pin passes are formed on the upper surface of the first main core, and when injection molding is injected into the first cavity and the second cavity, the pin hole is formed through the eject pin. The upper surface of the core is shielded and the upper surface of the deformable core pin is shielded from the core hole.

A position in which one end of the deformable core pin is rotatably installed on the ejection plate and a core hole formed in the first main core are shifted, so that the deformable core pin is installed to be inclined.

In a state in which the upper surface of the deformable core pin blocks the core hole, the deformable core at the other end of the deformable core pin cooperates with the first main core to form the second cavity, and the deformable core pin passes through the core hole to form the second cavity. When rising, the deformable core pin moves in a direction away from the inner circumferential surface of the inner cap portion of the container cap, thereby enabling the container cap to be taken out.

The container cap of the present invention facilitates the separation of the gas absorbent upon discharge, and when the container cap is expanded due to the fermentation gas, the first gas shielding unit to the third gas shielding unit prevent the discharge of the fermentation gas step by step, so that the gas absorbent prevents the fermentation gas from being discharged. It is a structure that aids in efficient absorption Therefore, the present invention provides the gas absorbent with time to absorb the fermented gas, thereby preventing the container cap from bursting, preventing the odor leakage of the fermented gas, and providing the effect of keeping and distributing fermented food fresh. can be expected

In addition, in the mold for manufacturing the container cap of the present invention, the shape of the inner cap part and the support protrusion can be formed and taken out by the deformable core pin moving in the diagonal direction, so that the container cap having a complicated shape can be manufactured.

1 is a perspective view showing a container cap according to an embodiment of the present invention.
Figure 2 is a view showing a longitudinal section of the container cap according to an embodiment of the present invention.
3 is a view showing a state in which the contents, the gas absorbent, and the sealing paper are arranged in the container body and the container cap according to an embodiment of the present invention.
Figure 4 is a view for explaining the first gas shield of the container cap according to an embodiment of the present invention.
5 is a view for explaining the second gas shield of the container cap according to an embodiment of the present invention.
6 is a view for explaining the third gas shielding portion of the container cap according to an embodiment of the present invention.
7 is a view for explaining the gas absorbent of the container cap according to an embodiment of the present invention.
8 is a cross-sectional view showing a mold for manufacturing a container cap according to an embodiment of the present invention.
9 is a partially enlarged cross-sectional view showing a mold for manufacturing a container cap according to an embodiment of the present invention.
10 is an exploded cross-sectional view showing a mold for manufacturing a container cap according to an embodiment of the present invention.
11 is a perspective view illustrating a first main core and a deformable core pin according to an embodiment of the present invention.
12 is a plan view showing a first main core according to an embodiment of the present invention.
13 is a view showing a state in which the container cap is molded according to an embodiment of the present invention.
14 is a view for explaining a state that the container cap is taken out.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 is a perspective view showing a container cap according to an embodiment of the present invention, Figure 2 is a view showing a longitudinal section of the container cap according to an embodiment of the present invention, Figure 3 is a container body and container according to an embodiment of the present invention It is a diagram showing the state in which the contents, gas absorbent, and sealing paper are arranged in the cap.

As shown in FIG. 1 , the container cap 200 of the present invention is coupled to the container body 100 for manufacturing fermented foods such as kimchi and soybean paste. The state in which the container cap 200 is coupled to the container body 100 is called a container 10, and the container 10 accommodates internal expansion due to the fermentation gas to prevent bursting (explosion), and the fermentation gas counts. is also prevented.

Fermentation gas is generated at a maximum during the first few days after production of fermented food, and when that period is cured, the amount of generation becomes constant. Therefore, the portion connecting the container body 100 and the container cap 200 may burst because fermented gas is generated in excess of the capacity that the gas absorbent can absorb at the initial stage of fermentation after manufacturing the fermented food. In order to prevent this, the container cap 200 prevents the discharge of the fermentation gas step by step when the container cap is expanded due to the fermentation gas and at the same time releases it, thereby preventing the container cap from bursting until the generation amount of the fermentation gas becomes constant.

When the fermentation gas is released step by step during the expansion of the container cap, the gas absorbent gives time to absorb the fermentation gas, and in particular, it can prevent the container cap from bursting at the beginning of fermentation when the amount of fermentation gas is maximum. have.

2 and 3, looking at the state in which the container cap 200 is coupled to the container body 100, the container body 100 is provided with a receiving space containing fermented food (contents), the container The cap 200 is provided with a gas absorbent and a sealing paper. Silica gel can be used as the gas absorbent, and the sealing paper serves to prevent contact between the gas absorbent and the contents. When the gas absorbent is mounted on the container cap 200 and the sealing paper is disposed, the gas absorbent can be stably fixed, the function of the gas absorbent to absorb the fermentation gas becomes smooth, and the separation and discharge of the gas absorbent is easy.

Specifically, the container cap 200 includes an outer cap portion 210 , an inner cap portion 220 , and gas shielding portions 230 , 240 , and 250 . The outer cap part 210 accommodates fermented food therein, and the cap screw 211 is screwed to the cap screw 211 of the container body 100 formed on the outer circumferential surface, and the appearance shields the upper part of the container body 100 . is formed with

The inner cap part 220 is formed in a shape protruding downward to be spaced apart from the outer cap part 210 around the edge of the ceiling surface of the outer cap part 210 . The inner cap part 220 is provided to form gas shielding parts 230, 240 and 250 for simultaneously releasing and preventing the discharge of fermentation gas in stages. In addition, the inner cap 220 is provided for mounting the gas absorbent and sealing paper.

Gas shielding portions 230, 240, 250 are formed on the inner cap portion 220 and the outer cap portion 210, and when the outer cap portion 210 is screwed to the container body 100, the inner circumferential surface of the container body 100 and the container body 100 and It is closely attached to the outer circumferential surface and plays a role in preventing the release of fermentation gas in stages

The gas shielding parts 230 , 240 , and 250 include a first gas shielding part 230 , a second gas shielding part 250 , and a third gas shielding part 250 . The primary gas shielding part (230,240,250) prevents the fermented gas from being discharged when the container cap 200 is expanded, and at the same time prevents the container cap from bursting by releasing it when the pressure is higher than a certain pressure, and the second gas shielding part 250 is the container cap During the expansion of 200, the second prevents the discharge of fermentation gas and at the same time prevents the container cap from bursting by releasing it when the pressure is higher than a certain pressure, and the third gas shielding unit 250 is a thirdly fermented gas when the container cap 200 is expanded. prevents the release of The third gas shielding unit 250 prevents the discharge of the fermentation gas in a third manner and at the same time prevents the container from bursting by releasing it when the pressure is higher than a certain pressure, but does not occur until the third gas shielding unit 250 is released. Usually, when the third gas shielding unit 250 blocks the discharge of the fermentation gas, the generation amount of the fermentation gas becomes constant, so that the gas absorbent can absorb all the amount of the generated gas.

The first gas shielding part 230 is formed to protrude around the outer peripheral surface of the inner cap part 220 so as to be in close contact with the inner peripheral surface of the container body 100 . The second gas shielding part 250 is formed to protrude downward from the connection part of the inner cap part 220 and the outer cap part 210 so as to be in close contact with the upper end of the inner circumferential surface of the container body 100 . The third gas shielding part 250 is formed to protrude from the upper inner peripheral surface of the outer cap part 210 so as to be in close contact with the upper end of the outer peripheral surface of the container body 100 .

The inner cap 220 includes a support protrusion 221 and a fitting slit 222 on the inner circumferential surface.

The support protrusion 221 is formed of one or more protruding toward the center from the inner circumferential surface of the outer cap portion 210 spaced apart from the ceiling surface by a predetermined distance. For example, the support protrusion 221 may be formed of three pieces formed at intervals of 60 degrees on the inner circumferential surface of the inner cap part 220 . The support protrusion 221 is for mounting the gas absorbent. The gas absorbent is mounted between the ceiling surface of the outer cap part 210 and the support protrusion 221 to be stably positioned.

The fitting slit 222 is recessed along the inner circumferential surface at a position spaced apart from the bottom surface of the support protrusion 221 by a predetermined distance. The fitting slit 222 is a configuration for fixing the sealing paper. The edge of the sealing paper is fitted and fixed to the fitting slit 222 .

By the above configuration, the container 10 has a gas layer in which the fermentation gas is located between the contents and the sealing paper, and the sealing paper is spaced apart from the gas absorbent by a predetermined interval so that the fermentation gas passing through the sealing paper can be smoothly absorbed by the gas absorbent. have

Figure 4 is a view for explaining the first gas shield of the container cap according to an embodiment of the present invention.

As shown in FIG. 4 , the first gas shielding part 230 has an upwardly inclined surface 231 that is inclined upwardly from the lower end of the outer peripheral surface of the inner cap part 220 toward the outer upper side and the outer peripheral surface of the inner cap part 220 from the upper end to the outer lower direction. It is an inclined mountain 233 formed by meeting the downwardly inclined downwardly sloping surfaces 232 .

The first gas shielding unit 230 has the inclined mountain 233 in close contact with the inner circumferential surface of the container body 100 to prevent the discharge of fermentation gas primarily, and at the same time to prevent the container cap from bursting by opening when the pressure is higher than a predetermined pressure.

The inclination angle of the upwardly inclined surface 231 is greater than the inclination angle of the downwardly inclined surface 232 . The angle of inclination of the upward inclined surface 231 is such that the gap between the inclined mountain 233 and the container body 100 is easily opened when the fermentation gas is introduced and a predetermined pressure or more is exceeded. The fermentation gas widens the inner circumferential surface of the container body 100 and the inclined mountain 233 in a manner that pushes the inner cap part 220 in the inward direction.

5 is a view for explaining the second gas shield of the container cap according to an embodiment of the present invention.

As shown in FIG. 5 , the second gas shielding part 250 has a straight protruding surface 242 protruding downward while forming a first space 241 spaced apart from the upper end of the inner cap part 220 , and a straight protruding surface. It is bent obliquely from the lower end to the upper side of the container body 100 and is inclined upward from the corner close inclined surface 243 and the corner close inclined surface 243 that are in close contact with the upper inner corner of the container body 100. A close contact inclined surface 244 to the upper surface is formed.

The second gas shielding part 250 is in close contact with the upper surface edge of the container body 100, and prevents the discharge of the fermentation gas secondarily, and at the same time prevents the container cap 200 from bursting by opening when the pressure is higher than a certain pressure.

The first space 241 is to allow the fermentation gas to move to the first space 241 without applying pressure to the second gas shield 240 when the first gas shield 230 is opened to lower the internal pressure. .

In the second gas shielding unit 240, the end of the edge contact inclined surface 243 forms a gap between the inner circumferential surface of the container body 100 and the fermented gas is introduced into the gap to widen it. Therefore, the first space 241 is formed so as to be a blocked path through which the fermentation gas moves in order to prevent pressure from being momentarily applied to this gap when the first gas shielding part 230 is opened.

6 is a view for explaining the third gas shielding portion of the container cap according to an embodiment of the present invention.

As shown in FIG. 6 , the third gas shielding part is located on the inner circumferential surface of the outer cap part 210 of the container cap 200 so as to form a second space 251 spaced apart from the upper surface close contact inclined surface 244 . An inclined protruding surface 252 protruding toward the upper end of the outer peripheral surface of the container body 100, and a curved contact surface 253 that is bent roundly at the end of the inclined protruding surface 252 and is in close contact with the outer peripheral surface of the container body 100 and , a support protrusion surface 254 that is bent at the end of the curved contact surface 253 and extends to the inner circumferential surface of the outer cap part 210 is formed.

The third gas shielding part 250 is in close contact with the upper end of the outer circumferential surface of the container body 100 to prevent the discharge of fermentation gas in a third manner and at the same time to prevent the container cap 200 from bursting by opening when the pressure is higher than a predetermined pressure.

A cap screw 211 is provided under the third gas shielding part 250 . When the third gas shielding part 250 is released, the cap screw 211 screwing the container body 100 and the outer cap part 210 may prevent the discharge of the fermentation gas.

Specifically, as shown in FIG. 4 , the fermented gas generated in the fermented food accommodated in the container body 100 is absorbed by the gas absorbent, but the excess capacity is the inner peripheral surface of the container body 100 and the first gas shielding part 230 . moves into the space between the upward slopes of

In this state, when a certain pressure is exceeded, as shown in FIG. 5 , the fermented gas is spread out between the inner peripheral surface of the container body 100 and the inclined mountain 233 of the first gas shielding part 230, and the fermentation gas flows into the first space 241. to lower the internal pressure.

In addition, when the first gas shielding unit 230 exceeds a certain pressure in the open state, as shown in FIG. 6 , the fermentation gas between the inner circumferential surface of the container body 100 and the edge-close inclined surface of the second gas shielding unit 240 Moving to the gap between the second gas shielding portion 240, the edge of the close contact inclined surface 243 and the upper surface contact inclined surface 244 of the connecting portion of the inner peripheral surface and the inner peripheral surface of the container body 100 and the fermentation gas is the second space (251) to lower the internal pressure.

In addition, when the predetermined pressure is exceeded in the state in which the first gas shielding unit 230 is opened, the fermentation gas lowers the internal pressure by causing the third gas shielding unit 250 to be opened.

This process occurs at the beginning of fermentation when the amount of fermentation gas generated is maximum.

7 is a view for explaining the gas absorbent of the container cap according to an embodiment of the present invention.

As shown in FIG. 7, when the amount of fermentation gas is constant after the initial stage of fermentation, the gas absorbent absorbs all of the fermentation gas, so that the internal pressure of the container body 100 is lowered, and the first gas shielding unit 230, The opened state of the second gas shielding part 240 and the third gas shielding part 250 is restored. The container cap 200 is made of a plastic material and has a structure in which the first gas shielding part 230, the second gas shielding part 240 and the third gas shielding part 250 are elastically closely adhered and sealed, so that the pressure inside the container 10 is reduced. When it is lowered, the open state is released and it becomes a structure that is closely adhered again.

In the process, the fermentation gas in the first space 241 and the second space 251 may move into the container body 100 and pass through the sealing paper to be absorbed by the gas absorbent.

When the container cap 200 is discharged, it is easy to separate the gas absorbent, and when the container cap 200 is expanded due to the fermentation gas, the first gas shielding unit 230 to the third gas shielding part 250 is fermented gas step by step. It is a structure that prevents the container cap 200 from bursting by preventing the discharge of the gas and helps the gas absorbent to efficiently absorb the fermentation gas.

Since the amount of gas absorbent that can absorb gas per unit time is determined, the first gas shielding unit 230 to the third gas shielding unit 250 uses the fermentation gas generated in excess of the capacity that the gas absorbent can absorb at the initial stage of fermentation. By blocking and releasing in stages at the same time, the gas absorbent gives time for the fermenting gas to be absorbed. If the fermentation gas is not released step by step, the container cap may burst.

Although the above-described container cap has been described as an example of application to a container for storing fermented foods such as kimchi and soybean paste, it is also applicable to packaging of other foods that generate carbon dioxide during storage and distribution in addition to kimchi.

On the other hand, the above-described container cap 200 is manufactured in an injection mold. The container cap 200 is characterized in that the inner cap portion 220 is additionally provided, and the inner cap portion 220 has a support protrusion 221 protruding in the central direction.

Hereinafter, a mold for manufacturing the container cap will be described.

8 is a cross-sectional view showing a mold for manufacturing a container cap according to an embodiment of the present invention, and FIG. 9 is a partially enlarged cross-sectional view showing a mold for manufacturing a container cap according to an embodiment of the present invention.

8 and 9, the mold for manufacturing the container cap is a fixed side plate 310, a fixed plate 320, a first main core 340, an eject plate 350, a movable side plate 370, It includes a second main core 390 and a deformable core pin 410 .

The fixed side plate 310 corresponds to the lower mold and is installed on the fixed side. The fixed plate 320 is installed on the fixed side plate 310 and the die 330 is provided. The first main core 340 is provided in the die 330 and constitutes a portion of the shape of the outer cap portion 210 of the container cap 200 . The ejection plate 350 is installed between the fixed side plate 310 and the fixed plate 320 to move up and down and includes an ejection pin 360 for taking out the molded container cap 200 .

As the ejection plate 350 moves upward, the eject pin 360 rises and the molded container cap 200 can be taken out.

The movable side plate 370 corresponds to the upper mold and is installed on the movable side. A movable plate 380 is installed under the movable side plate 370 . The second main core 390 is provided on the movable plate 380 and cooperates with the first main core 340 to form a first cavity m1 corresponding to the shape of the outer cap portion of the container cap. An injection hole 391 for injecting an injection product into the first cavity m1 is installed in the second main core 390 .

The deformable core pin 410 is a part for forming the support protrusion 221 in the inner cap 220 of the container cap 200 . The deformable core pin 410 has one end installed on the ejection plate 350 to move up and down together with the ejection plate 350 , and the other end of the inner cap portion 220 of the container cap 200 in cooperation with the first main core 340 . ) A deformable core 413 forming a second cavity m2 corresponding to the shape is formed.

10 is an exploded cross-sectional view showing a mold for manufacturing a container cap according to an embodiment of the present invention. 11 is a perspective view for explaining a first main core and a deformable core pin according to an embodiment of the present invention, and FIG. 12 is a plan view showing the first main core according to an embodiment of the present invention.

As shown in FIG. 10 , in the mold 300 , the movable side is movable up and down with respect to the fixed side. The movable side moves to the stationary side and the first main core 340 and the second main core 390 are combined to form a first cavity m1 and a second cavity m2, and the first cavity m1 and the second cavity m2 are formed. 2 The container cap 200 may be injection-molded by injecting an injection product (resin) into the cavity m2.

When the container cap 200 is injection molded, the movable side is moved upward to separate the second main core 390 from the first main core 340 . Thereafter, the eject pin 360 may be raised to separate the container cap 200 molded from the first main core 340 .

In this process, the deformable core 413 must also be separated from the container cap 200 .

To this end, as shown in FIGS. 11 and 12 , on the upper surface of the first main core 340 , the pin hole 341 through which the eject pin 360 passes and the core hole through which the deformable core pin 410 passes ( 342) is formed.

When injection molding is injected into the first cavity m1 and the second cavity m2, the pin hole 341 is shielded by the upper surface of the eject pin 360, and the upper surface of the deformable core pin 410 is shielded in the core hole 342. do.

The position where one end of the deformable core pin 410 is rotatably installed on the ejection plate 350 by the rotation pin 411 and the core hole 342 formed on the first main core 340 are positioned to be shifted, so that the deformable core pin ( The 410 is installed to be inclined, and accordingly, the deformable core pin 410 can move in an oblique direction.

When the deformable core pin 410 moves in an oblique direction, the deformable core 413 is separated from the support protrusion 221 of the container cap 200 in the process of taking out the molded container cap 200, so that the container cap 200 is taken out. This is possible.

11 and 12 , in the embodiment, three deformable core pins 410 are installed at intervals of 60 degrees, and eject pins 360 are installed between the deformable core pins 410 . Since the deformable core pin 410 is installed in an oblique line, when the ejection plate rises, the three are gathered toward the center and can be separated from the support protrusion 221 . The eject pin 360 is installed vertically and only serves to lift and take out the molded container cap 200 when ascending.

In a state where the upper surface of the deformable core pin 410 blocks the core hole 342 , the deformable core 413 at the other end of the deformable core pin 410 cooperates with the first main core 340 to form the second cavity m2 . formed, and when the deformable core pin 410 rises through the core hole 342 , the deformable core pin 410 moves in an oblique direction and thus moves away from the inner peripheral surface of the inner cap part 220 of the container cap 200 . will do Due to this, it is possible to take out the container cap 200 smoothly.

13 is a view showing a state in which the container cap is molded according to an embodiment of the present invention, and FIG. 14 is a view for explaining a state in which the container cap is taken out.

As shown in FIG. 13 , when the first cavity m1 and the second cavity m2 are filled with the injection material and the container cap 200 is molded, the movable side rises and the second main core 390 is molded. separated from the cap 200 . Accordingly, the container cap 200 is in a state in which it is possible to take it out.

In this state, as shown in FIG. 14 , the ejection plate 350 rises. When the eject plate 350 rises, the eject pin rises while lifting the container cap 200 to separate it from the first main core 340 . In this process, the eject pin 360 passes through the core hole 342 of the first main core 340 and moves in an oblique direction, so that the deformable core 413 is separated from the support protrusion 221 of the container cap 200 . and the container cap 200 can be taken out.

The above-described container cap and the mold for manufacturing the container cap are capable of forming and taking out the shape of the inner cap part and the support protrusion by the deformable core pin 410 moving in the diagonal direction. In addition, in the container cap, the first gas shielding part 230 to the third gas shielding part 250 block the pressure of the fermentation gas in stages and release it at the same time, thereby giving time for the gas absorbent to absorb the fermentation gas. It has the advantage of preventing bursting and preventing odor leakage of fermentation gas.

In the above, preferred embodiments of the present invention have been illustrated and described, but the present invention is not limited to the specific embodiments described above, and it is common in the technical field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Various modifications may be made by those having the knowledge of, of course, and these modifications should not be individually understood from the technical spirit or perspective of the present invention.

10: container 100: container body
200: container cap 210: outer cap part
211: cap screw 220: inner cap portion
221: support protrusion 222: fitting slit
230: first gas shielding unit 231: upward inclined surface
232: downward slope 233: slope mountain
240: second gas shielding unit 241: first space
242: straight protruding surface 243: edge contact inclined surface
244: upper surface close inclined surface 245: gap
250: third gas shielding unit 251: second space
252: inclined protruding surface 253: curved contact surface
254: support protrusion 300: mold
310: fixed side plate 320: fixed plate
330: die 340: first main core
341: pin hole 342: core hole
350: eject plate 360: eject pin
370: movable side plate 380: movable plate
390: second main core 391: injection hole
410: deformed core pin 411: rotation pin
413: deformable core m1: first cavity
m2: second cavity

Claims (2)

In the container cap,
The fermented food is accommodated therein, the cap screw is screwed to the cap screw of the container body formed on the outer peripheral surface, the outer cap portion for shielding the upper portion of the container body;
an inner cap portion protruding downward to be spaced apart from the outer cap portion around the edge of the ceiling surface of the outer cap portion; and
a gas shielding part formed on the inner cap part and the outer cap part, and in close contact with the inner circumferential surface of the container body and the outer circumferential surface of the container body when the outer cap part is screwed to the container body to prevent gas discharge step by step;
including,
The inner cap part
one or more support protrusions protruding toward the center from the inner circumferential surface at a position spaced apart from the ceiling surface of the outer cap part by a predetermined distance; and
a fitting slit concave formed along the inner circumferential surface at a position spaced apart from the bottom surface of the support protrusion by a predetermined distance;
includes,
A gas absorbent is disposed between the ceiling surface of the outer cap and the support protrusion,
The edge of the sealing paper is fitted and fixed to the fitting slit,
container cap. According to claim 1,
The gas shielding unit,
a first gas shielding portion protruding around the outer circumferential surface of the inner cap portion so as to be in close contact with the inner circumferential surface of the container body;
a second gas shielding portion protruding downward from the connection portion of the inner cap portion and the outer cap portion so as to be in close contact with the upper end of the inner circumferential surface of the container body; and
a third gas shielding part protruding from the inner peripheral surface of the outer cap part so as to be in close contact with the upper end of the outer peripheral surface of the container body;
includes,
The first gas shielding unit,
It is an inclined mountain formed by the meeting of an upwardly inclined surface inclined upwardly from the lower end of the outer peripheral surface of the inner cap part to an outer upper direction and a downward inclined surface inclined downward from the upper end of the outer peripheral surface of the inner cap part to an outer lower direction,
The inclination angle of the upward inclined surface is larger than the inclination angle of the downward inclined surface,
The second gas shielding unit,
A straight protruding surface that protrudes downward while forming a first space spaced apart from the upper end of the inner cap portion, and a corner close sloping surface that is inclined from the lower end of the straight protruding surface to the upper side and is in close contact with the upper inner corner of the container body and An upper surface close inclined surface is formed by being inclined upwardly from the corner close inclined surface and is in close contact with the upper surface edge of the container body,
The end of the edge-close inclined surface forms a gap between the inner peripheral surface of the container body,
The third gas shielding unit,
The inclined protruding surface protruding from the inner circumferential surface of the outer cap part of the container cap toward the upper end of the outer circumferential surface of the container body to form a second space spaced apart from the upper surface close-contact inclined surface, and the end of the inclined protruding surface. and a curved contact surface in close contact with the outer circumferential surface of the container body, and a support protrusion surface that is bent at the end of the curved contact surface and extends to the inner circumferential surface of the outer cap part,
Fermentation gas generated from the fermented food accommodated in the container body,
The gas absorbent absorbs, but the excess capacity moves to the space between the inner peripheral surface of the container body and the upwardly inclined surface of the first gas shield,
When the predetermined pressure is exceeded, the fermented gas moves to the first space as the inner circumferential surface of the container body and the inclined mountain of the first gas shielding part widen to lower the internal pressure,
When the first gas shielding unit exceeds a certain pressure in an open state, the fermentation gas moves to a gap between the inner circumferential surface of the container body and the edge tight inclined surface of the second gas shielding unit, and the corner close contact of the second gas shielding unit As the connecting portion of the inclined surface and the upper surface close-contact inclined surface spreads with the inner peripheral surface of the container body, the fermentation gas moves to the second space to lower the internal pressure,
The container cap is manufactured in a mold,
The mold is
a fixed side plate installed on the fixed side;
a fixed plate installed on the fixed side plate and provided with a die;
a first main core provided in the die and constituting a portion of the shape of the outer cap of the container cap;
an ejection plate movably installed between the fixed side plate and the fixed plate and having an ejection pin for taking out the molded container cap;
a movable side plate installed on the movable side; and
a second main core provided on a movable plate installed under the movable side plate and cooperating with the first main core to form a first cavity corresponding to the shape of the outer cap portion of the container cap;
a deformable core pin having a deformable core having one end installed in the ejection plate and moving together with the ejection plate, and having a deformable core formed at the other end in cooperation with the first main core to form a second cavity corresponding to the shape of the inner cap portion of the container cap;
including,
A pin hole through which the ejection pin passes and a core hole through which the deformable core pin passes are formed on the upper surface of the first main core,
When injection molding is injected into the first cavity and the second cavity, the pin hole is shielded by the upper surface of the eject pin, and the core hole is shielded by the upper surface of the deformable core pin;
A position in which one end of the deformable core pin is rotatably installed on the ejection plate and a core hole formed in the first main core are positioned to be shifted so that the deformable core pin is installed to be inclined,
In a state in which the upper surface of the deformable core pin blocks the core hole, the deformable core at the other end of the deformable core pin cooperates with the first main core to form the second cavity, and the deformable core pin passes through the core hole. When rising, the deformable core pin moves in a direction away from the inner circumferential surface of the inner cap portion of the container cap,
which made it possible to take out the container cap,
container cap.

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