KR101374244B1 - Fabrication method and pressure maintenance nozzle is formed bottle cap - Google Patents

Abstract

In the present invention, the existing gas discharging technology has a relatively complicated internal configuration, difficult to completely block the outside air flowing into the gas outlet, and when the contents are discharged, the contents are buried in the discharge port, which is not sanitary. The nozzle support case, the silicon nozzle, the guide ring, and the nozzle protection cap are composed of various sizes depending on the size of the lid of each container, such as a plastic bottle or a beverage bottle, which can be easily obtained. It can be used as a container to store fermented food by changing only the lid, and prevents deterioration or decay of contents by blocking external air, and it is easy to use hygienically because the contents do not get on the inlet when removing contents. Bottle with pressure holding nozzle to reduce production costs due to its simplicity There is provided a lid.

Description

Bottle cap with pressure holding nozzle and manufacturing method {FABRICATION METHOD AND PRESSURE MAINTENANCE NOZZLE IS FORMED BOTTLE CAP}

The present invention can be used as a container for storing the fermented food by replacing only the lid because it is manufactured according to the size of the lid of the container such as PET bottles, beverage bottles, fermentation drums, etc., the contents at the inlet when removing the contents It is hygienic and does not matter, and the structure is simple, and relates to a bottle cap cap and a manufacturing method formed with a pressure holding nozzle that can reduce the production cost.

In modern society, the majority of people are chased by time, lead to irregular lifestyles, and westernized eating habits such as fast foods increase the incidence of various adult diseases and cancers. Interest is also growing.

In particular, fermented foods produce various kinds of bioactive substances in the fermentation process of microorganisms such as lactic acid bacteria and yeast to promote metabolism of the body, lower cholesterol, and abundant essential amino acids and vitamins to prevent adult disease and anticancer The effect of this is widely known and is included in many of our own food, which has been spotlighted as a food familiar to us.

It has a variety of forms such as jangjang, salted fish, fermented liquor, etc. Here, fermented liquor is produced through anaerobic fermentation that decomposes organic matter in the absence of oxygen as a raw material of grains or fruits. If you keep it, it can be manufactured easily by anyone, so it is also manufactured in many homes.

At this time, the fermented liquor produces carbon dioxide gas due to microbial respiration in the process of fermentation, and if the gas is not discharged in a timely manner, the gas inside the storage container becomes saturated and expands. Bursting to withstand it has to be confirmed from time to time, the storage container had a problem that the shape is deformed due to expansion.

In addition, if the container is not sealed, such as an eco-friendly fermentation detergent that can be deteriorated by external air, there is a problem that must be confirmed from time to time due to the gas generated even when creating an environment suitable for useful microorganisms in the process of fermentation through storage. Various techniques have been developed for venting gases.

However, the existing gas discharge technology has a relatively complicated internal configuration, which is expensive to produce, it is difficult to completely block the outside air flowing into the gas outlet, and when the contents are removed through the nozzle, the contents are buried in the inlet and sanitarily. There was also a bad problem.

In order to solve the above problems, the present invention is manufactured in various sizes according to the size of the caps of containers, such as PET bottles, beverage bottles, fermentation drums, etc., which are easily obtained with the existing constant size, and have excellent compatibility so that only the lids are fermented. It can be used as a container to store food, and it prevents the deterioration or decay of the contents by blocking external air, and it is easy to use hygienically because the contents are not buried in the inlet when removing the contents, and the structure is simple to reduce the production cost. It is an object of the present invention to provide a bottle cap with a pressure maintaining nozzle which can be saved.

In order to achieve the above object, the cap of the cap is formed with a pressure retention nozzle according to the present invention,

A nozzle support case which is made of a cylindrical shape and has a hollow lid, and has an insertion hole through which a silicon nozzle can be inserted in the center of the top, and is compatible with a standardized lid.

A silicon nozzle inserted into the upper end of the nozzle protection cap and formed at a predetermined angle in the center formed convex in the lower direction, and an outer portion formed convexly curved in the upper direction;

A circular ring-shaped rubber ring is formed between the silicon nozzle and the nozzle protection cap to remove the separation space, and a guide ring for preventing the up and down shaking of the silicon nozzle,

It is achieved by being inserted into a coupling hole formed in the center of the nozzle support case in a hollow cylindrical shape, the nozzle protection cap for supporting and fixing the silicon nozzle and the guide ring.

In addition, the bottle cap cap manufacturing method is formed pressure holding nozzle according to the present invention

Forming a nozzle support case having the same diameter as a bottle cap to be used as a storage container and having a hole in which a nozzle protection cap can be inserted into the center by plastic injection molding;

Forming the silicon nozzle inserted into the upper end of the nozzle protective cap by injection molding the silicon, and selectively cutting the center of the circular cut elastic part at regular intervals according to the viscosity and the gas generation amount of the stored contents;

After inserting the guide ring and the silicon nozzle to the top of the nozzle protective cap in sequence to produce a pressure reducing vessel lid by engaging the circumference of the nozzle protective cap to the engaging jaw formed in the inner bottom of the nozzle support case,

It is achieved by the step of mounting the pressure reducing vessel lid to the bottle containing the fermented food.

As described above, in the present invention is a fermented food by changing the lid only because it is manufactured in a variety of sizes according to the size of the lid of the container, such as PET bottles, beverage bottles, fermentation drums, etc. can easily obtain the existing constant size It can be used as a container that can be used for storage, and prevents deterioration or decay due to the inflow of external air, and it is easy to use hygienically without having to wipe the area around the inlet when removing the contents with the gas outlet. And the simple structure has a good effect of reducing the production cost.

1 is a perspective view showing the overall shape of the component is inserted into the cap of the cap cap is formed pressure maintaining nozzle according to the present invention,
Figure 2 is an exploded perspective view showing the components of the cap cap bottle formed with a pressure retention nozzle according to the present invention,
Figure 3 is an exploded perspective view showing the cut and easy to understand the components of the cap of the cap is formed pressure maintaining nozzle according to the present invention,
4 is a perspective view showing a cut surface of the nozzle support case of the present invention;
Figure 5 is an exploded perspective view showing an enlarged cut surface of the silicon nozzle, guide ring, nozzle protection cap of the present invention,
Figure 6 is an embodiment sequentially showing that the gas is discharged by the circular incision elastic portion of the silicon nozzle bent to the top due to the pressure increase due to the expansion of the gas,
7 is a perspective view showing a form in which the circular incision elastic portion of the silicon nozzle of the present invention is opened to the top,
8 is a front view showing a cut surface of the nozzle protection cap of the present invention,
Figure 9 is a perspective view showing the shape of the nozzle protection cap of the present invention,
10 is an embodiment showing a storage container coupled to the cap cap bottle formed with a pressure retention nozzle according to the present invention,
11 is a view showing the bottle cap coupling portion and the silicon nozzle coupled according to the size of the storage container according to the present invention, an embodiment showing an enlarged incision of the silicon nozzle.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

Figure 1 relates to a perspective view showing the overall shape of the bottle cap cap formed with a pressure holding nozzle according to the present invention, Figure 2 relates to an exploded perspective view showing the components of the bottle cap cap formed with a pressure holding nozzle according to the present invention. , It is composed of the nozzle support case 100, the silicon nozzle 200, the guide ring 300, the nozzle protective cap 400.

First, the nozzle support case 100 according to the present invention will be described.

The nozzle support case 100 is formed in a cylindrical shape as a whole and has a hollow lid shape, and an insertion hole 111 into which a silicon nozzle can be inserted at the top center is formed, and can be used with a standardized lid. It is manufactured by size to be combined in place of the existing cap cap, which is composed of a protective cap fixing part 110, the cap cap 120.

The protective cap fixing part 110 is protruded in a cylindrical shape in the center of the top of the nozzle support case 100, the gas discharge hole 111 for discharging the fermentation gas is formed in the center of the silicon nozzle 200 and It serves to stably support the nozzle protection cap 300, which is protruded along the bottom circumference of the gas discharge hole 111, as shown in Figure 4 in contact with the top of the silicon nozzle in the vertical direction of the nozzle Nozzle fixing protrusion 112 is formed to block the shaking, protruding at intervals of 90 ° along the inner circumference of the lower end to catch the cap catching portion 420 to secure the nozzle protective cap 400 to secure the projection cap ( 113 is formed.

The bottle cap coupling portion 120 is formed at the lower end of the protective cap fixing portion 110, the inner circumference is formed in the same size as the outer circumference of the lid coupling portion of the upper end of the storage container 2, the bottle cap formed along the inner circumference Thread 121 is inserted into the screw bone formed in the outer circumference of the lid coupling portion and is rotatably coupled.

This is the first bottle cap coupling portion (120a) coupled to the plastic bottle storage container (2a) containing the standardized 500ml ~ 1.5L bottled water or beverages, and the beverage bottle storage container (2b) containing vitamin water, coffee, milk beverage ) Is compatible with the lid coupling portion of the storage container (2) used as a second bottle cap coupling portion (120b) coupled to the third bottle cap coupling portion (120c) coupled to the bottled water bottle (2c) of more than 18.9ℓ Can be combined.

Next, the silicon nozzle 200 according to the present invention will be described.

The silicon nozzle 200 is inserted into the upper end of the nozzle protection cap 400 and is formed by making a cut at a predetermined angle in the center made convex in the lower direction, the outer portion is formed convexly curved in the upper direction to the internal pressure Opening and closing by the gas to be discharged, it is composed of a circular cut elastic portion 210, impact relief 220, fixed support 230.

The circular incision elastic portion 210 is protruded circularly convex in the lower direction, is formed by cutting at a predetermined interval based on the center of the circular, which is formed convexly to the lower end to the structure in which the incision is gathered in the center direction If the pressure inside the storage container is the same as the external pressure or the pressure difference is not large, there is no gap between the cutouts 211 to block the inflow of external air, and the fermentation gas is generated inside the storage container so that the elastic limit is not exceeded. As shown in Figure 6, it is bent in the upper direction sequentially from the center end to maintain the pressure by discharging the internal air, after the high pressure gas is discharged is restored by the elastic and sealed.

In addition, when the pressure is applied to the side of the storage container 2 to remove the contents to the incision 211, the contents are discharged as much as the pressure applied, the form is restored, the incisions are gathered and closed without gap, so that the contents do not adhere to the inlet. Sealed, hygienic and easy to use.

Circular cut elastic portion 210 of the present invention is selectively cut according to the viscosity and gas generation amount of the fermented food stored in the storage container, the viscosity of the fermented food is relatively low, such as the first bottle cap coupling portion (120a) In the case of a small storage container, an eight-blade incision 211a, which is cut into eight blades at intervals of 45 ° with respect to the center of the lower middle protrusion, is formed using a silicon nozzle 200a.

Here, the silicon nozzle (200a) formed of the eight-blade cutout (211a) is formed to withstand pressure of 0.15 ~ 0.2kgf / ㎠ to maintain the shape at a pressure of 0.15kgf / ㎠ or less to seal the inside, 0.2kgf At the pressure of / cm 2 or more, it is bent and opened in the upper direction starting from the center portion, and has a structure that is closed again when the pressure is lowered to 0.2kgf / cm 2 or less.

In this case, the reason for using the silicon nozzle 200a having the eight blade cutouts 211a is that the smaller the storage container capable of storing a small amount of fermented food therein, the lower the pressure, the lower the pressure, and the lower the cutting blade, the higher the pressure. If the shape of the storage container is not made, or if it is severe, there is a problem that explodes due to high pressure, so the silicon nozzle 200a having a small incision and relatively weak elastic force is suitable.

In addition, in the case of the storage container of the medium size, such as the second bottle cap coupling portion of the fermented food, using a silicon nozzle (200b) formed with a six blade incision cut into six blades at intervals of 60 degrees with respect to the center of the lower center projection To combine.

Here, the silicon nozzle 200b formed of the six-blade incision 211b is formed to withstand the pressure of 0.2 ~ 0.5kgf / ㎠ to maintain the shape at a pressure of 0.2kgf / ㎠ or less to seal the inside, 0.5kgf At the pressure of / cm 2 or more, it is bent and opened in the upper direction starting from the center portion, and has a structure that is closed again when the pressure is lowered to 0.5kgf / cm 2 or less.

At this time, the reason for using the silicon nozzle (200b) with a six-blade cut portion is that the silicon nozzle (200b) is suitable for the pressure of the storage container of the medium size that can store the fermented food in the 2 ~ 7L.

In addition, in the case of a relatively large storage container, such as a high viscosity of the fermented food or the third bottle cap coupling portion (120c), the four blade incision cut in four blades at intervals of 90 ° relative to the center of the lower center protrusion It combines using the silicon nozzle 200c in which the part 211c was formed.

Here, the silicon nozzle 200c formed of the four-blade incision 211c is formed to withstand the pressure of 0.5 ~ 2kgf / ㎠ to maintain the shape at a pressure of less than 0.5kgf / ㎠ and to seal the inside, 2kgf / ㎠ In the above pressure, it is bent in the upper direction starting from the center part, and is opened again when the pressure falls below 2 kgf / cm 2.

At this time, the reason for using the silicon nozzle (200c) formed with a four-blade incision (211c) is that the larger the volume of the storage container that can store a large amount of fermented food there is a relatively high pressure is easy to open even at low pressure Since there is a problem that the external air flows in, the silicon nozzle (200c) having a small incision portion and a strong elastic force is suitable.

As such, the bottle cap lid formed with a pressure holding nozzle according to the present invention has a silicon nozzle 200a formed of an eight-blade incision 211a having a pressure of 0.15 to 0.2kgf / cm 2, and a pressure of 0.2 to 0.5kgf / cm 2. By selecting one of the silicon nozzle 200b formed of the six blade cutout 211b and the silicon nozzle 200c formed of the four blade cutout 211c having a pressure of 0.5 to 2kgf / cm 2, PET bottle or It can be customized according to the lid size of each container such as beverage bottle, fermentation drum, etc. Above all, fermented food can be stored within the standard pressure value range of the pressure holding nozzle by replacing only the lid. This can prevent deterioration and corruption.

Here, the reference pressure value of the pressure holding nozzle is an 8-blade incision 211a pressure value having a pressure of 0.2kgf / ㎠, a six-blade incision 211b pressure value having a pressure of 0.2 ~ 0.5kgf / ㎠, It refers to the pressure value of the four-blade cutout (211c) having a pressure of 0.5 ~ 2kgf / ㎠.

The impact relief unit 220 serves to relieve the shock transmitted to the circular incision elastic portion 210 which is protruded in a round shape in the upper direction around the circular incision elastic portion is pushed to the top by the pressure, which is As shown in FIG. 6, the periphery of the circular incision elastic portion and the inner circumference following the incline are spread upward to distribute the pressure load acting on the circular incision elastic portion to extend the life of the silicon nozzle.

The fixed support portion 230 protrudes convexly in the upper direction along the circumference of the circular incision elastic portion, is formed to be the same as the diameter of the nozzle fixing portion 410 formed inside the upper end of the nozzle protection cap to the silicon nozzle 200 as a whole I support it.

The material of the silicon nozzle 200 according to the present invention is a polymer film that generates active oxygen on the surface of the addition polymerization type silicone rubber is coated,

As a room temperature curing type, based on 100 parts by weight of linear polydimethyl siloxane containing a vinyl group at the terminal,

1 to 10 parts by weight of polymethyl hydrosiloxane as a crosslinking agent,

0.1-5 parts by weight of platinum catalyst,

5-10 parts by weight of fumed silica (filler) is added, and a polymer film generating active oxygen is coated on the surface of the addition-polymerizable silicone rubber cured by stirring at 1,600-2,000 rpm.

The polymer film was mixed with a solution in which hematoporphyrin (HP) dissolved in photoethanol and polysiloxane (polysiloxane) in a 2: 1 weight ratio, followed by ultrasonication for 10 to 20 minutes in dark conditions. What was sprayed was made into a film.

The addition polymerization type silicone has the advantages of high precision, small volume change after curing, and excellent elastic recovery.

The addition-polymerization type silicone rubber is a room temperature curing type, based on 100 parts by weight of a linear polydimethyl siloxane containing a vinyl group at the terminal,

1 to 10 parts by weight of polymethyl hydrosiloxane as a crosslinking agent,

0.1-5 parts by weight of platinum catalyst,

Add 5 to 10 parts by weight of fumed silica, a filler, and stir at 1,600 to 2,000 rpm.

The crosslinking agent uses polymethyl hydrosiloxane having a Si—H group in the center of the chain.

The filler fumed silica is prepared by reacting silicon tetrachloride (Silicone Tetrachloride (SiCl ₄ )) at a high temperature of 1,000 to 1,200 ° C. under hydrogen and oxygen gas. At the beginning of the manufacturing process, spherical silica particles are formed and the primary particles thus formed form aggregation. In this process, silanol groups (Si-OH) are formed on the silica surface. Is formed.

When the amount of the fumed silica exceeds 10 parts by weight, the crosslinking time may be delayed. Therefore, the amount of the fumed silica is limited to 5 to 10 parts by weight (phr). desirable.

More specifically, the addition polymerization type silicone rubber is added to 100 g of polydimethyl siloxane (Polydimethyl Siloxane), 5 g of polymethyl hydrosiloxane (polymethyl hydrosiloxane), 2 g of platinum catalyst, 8 g of fumed silica (fumed silica), and then at 2,000 rpm Stirring and hardening are used.

In order to impart antimicrobial properties, the addition polymerization type silicone is coated with a polymer film that generates free radicals on the surface of the silicon.

The polymer film is prepared by adding polysiloxane to a solution dissolved by adding hematoporphyrin (HP), which is a photosensitive molecule, to ethanol, and then dispersing ultrasonically under dark conditions as a film.

At this time, the polymer film contains the photosensitive molecules, and activates by absorbing the external light energy to transfer the energy to other molecules whose own transition is prohibited, the photosensitive molecules in the ground state triplet in the excited triplet state The energy transfer to the anti-oxygen generates a single oxygen.

As a result, the polymer film generates active oxygen to impart antimicrobial activity to the addition polymerization type silicone.

The specific compounding ratio of the solution in which the photosensitive molecule hematoporphyrin (HP) is dissolved in ethanol and polysiloxane is 20g: 10g.

Next, the guide ring 300 according to the present invention will be described.

The guide ring 300 is formed between the silicon nozzle 200 and the nozzle protection cap 400 as a circular ring-shaped rubber ring is pressed under pressure to remove the separation space through the property to be restored, the silicon nozzle It prevents the shaking up and down.

This prevents the contents from leaking along the circumference of the silicon nozzle fixed inside the nozzle protection cap.

Next, the nozzle protection cap 400 according to the present invention will be described.

The nozzle protection cap 400 is inserted into the coupling hole formed in the center of the nozzle support case 100 in a hollow cylindrical shape as a whole, and serves to support and fix the silicon nozzle 200 and the guide ring 300. The nozzle fixing portion 410 is formed of a stepped portion capable of supporting the fixed support 230 of the silicon nozzle in the inner center, and rounds the outer circumference from the outer upper end to the central one side, and becomes thick at the end of the rounded portion. A stepped portion is formed so that the cap coupling portion 420 is coupled to the protective cap fixing protrusion 113 of the nozzle support case.

Hereinafter, a method of manufacturing a bottle cap cap having a pressure holding nozzle according to the present invention will be described.

First, the nozzle support case having the same diameter as the bottle cap to be used as a storage container and having a hole in which a nozzle protection cap can be inserted is formed by plastic injection molding (S100).

Next, the silicon nozzle inserted into the upper end of the nozzle protection cap is formed by injection molding the silicon, and the center of the circular incision elastic portion is selectively formed at regular intervals according to the viscosity and the gas generation amount of the stored contents (S200).

Next, after inserting the guide ring and the silicon nozzle to the top of the nozzle protective cap in order to produce a pressure reducing container cap by engaging the circumference of the nozzle protective cap to the engaging jaw formed on the inner bottom of the nozzle support case (S300). ).

Next, the pressure reducing container is mounted on the bottle containing the fermented food (S400).

Although the form used in the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and those skilled in the art may understand that the modified embodiment may be modified and modified in various forms. will be. Therefore, the true scope of protection of the present invention should be defined only by the matter described in the claims.

100: nozzle support case 200: silicon nozzle
210: circular cut elastic portion 220: impact buffer
230: fixed support 300: guide ring
400: nozzle protection cap

Claims (6)

The nozzle support case 100, which is made of a cylindrical shape as a whole and has a hollow shape at the bottom thereof, has an insertion hole 111 into which a silicon nozzle can be inserted at the top center, and is compatible with a standardized lid.
Inserted into the upper end of the nozzle protection cap 400 and is formed by making a cut at a constant angle in the center made convex in the lower direction, the outer portion is formed convexly curved in the upper direction is opened and closed by the internal pressure to discharge the gas The silicon nozzle 200 made of a circular cut elastic portion 210, an impact mitigating portion 220, a fixed support portion 230,
A circular ring-shaped rubber ring formed between the silicon nozzle and the nozzle protection cap to remove the separation space, and a guide ring 300 to prevent the up and down shaking of the silicon nozzle;
Bottle cap cap formed with a pressure retention nozzle consisting of a nozzle protection cap 400 for supporting and fixing the silicon nozzle 200 and the guide ring 300 is inserted into the coupling hole formed in the center of the nozzle support case in a hollow cylindrical shape To
The circular incision elastic portion 210
An eight blade incision 211a which is cut into eight blades at an interval of 45 ° from the center of the lower center protrusion,
A six blade incision 211b which is cut into six blades at an interval of 60 ° from the center of the lower center protrusion,
It is characterized in that it is selectively cut according to the viscosity of the contents stored in the storage container and the size of the storage container among the four-blade incision (211c) is cut into four blades at intervals of 90 ° with respect to the center of the lower center projection. Bottle cap with a pressure retention nozzle made of.
delete delete The method of claim 1, wherein the silicon nozzle 200
A polymer film that generates free radicals is coated on the surface of an addition polymerization type silicone rubber,
As a room temperature curing type, based on 100 parts by weight of linear polydimethyl siloxane containing a vinyl group at the terminal,
1 to 10 parts by weight of polymethyl hydrosiloxane as a crosslinking agent,
0.1-5 parts by weight of platinum catalyst,
5-10 parts by weight of fumed silica (filler) is added, and a polymer film generating active oxygen is coated on the surface of the addition-polymerizable silicone rubber cured by stirring at 1,600-2,000 rpm.
The polymer film was mixed with a solution in which hematoporphyrin (HP) dissolved in photoethanol and polysiloxane (polysiloxane) in a 2: 1 weight ratio, followed by ultrasonication for 10 to 20 minutes in dark conditions. A cap cap with a pressure holding nozzle, characterized in that the injection was made of a film.
delete delete

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