KR102665963B1 - Manufacturing system of cider vinegar with kelp ingredient having air discharging cap - Google Patents

Abstract

The present invention relates to a vinegar production system made of kelp and equipped with an air discharge cap. The present invention not only improves sensory quality, but also has an excellent DPPH radical scavenging function, and reduces the secretion of NO and TNF-α, which are inflammatory mediators, and has antioxidant activity. Apple cider vinegar containing kelp ingredients, which exhibits excellent efficacy in promoting and anti-inflammatory, can be manufactured quickly and in large quantities.
Apple cider vinegar produced by the present invention can be used for various purposes, such as for beverages, as an additive for functional foods, and for pharmaceutical purposes.

Description

Vinegar manufacturing system of kelp ingredient having an air discharge cap {MANUFACTURING SYSTEM OF CIDER VINEGAR WITH KELP INGREDIENT HAVING AIR DISCHARGING CAP}

The present invention relates to a vinegar production system, which includes kelp components to improve sensory quality as well as improve antioxidant activity and exhibit excellent anti-inflammatory effects, and to produce vinegar suitable for food or health functional foods, etc. It relates to a vinegar production system made of kelp and equipped with a cap.

In general, vinegar is produced from raw materials containing starch using microorganisms through alcohol fermentation and acetic acid fermentation processes.

Vinegar is a complex acid seasoning that contains various nutrients such as acetic acid, which gives a sour taste, as well as various organic acids, amino acids, and esters, and has recently been used as a health food or beverage.

Vinegar is largely divided into synthetic vinegar and fermented vinegar. Fermented vinegar is divided into alcoholic vinegar and natural vinegar. Synthetic vinegar is produced by making synthetic acetic acid using ethylene and acetylene extracted from petroleum, then diluting it and adding seasonings and sweeteners. do.

Fermented vinegar uses the traditional parallel fermentation method and is divided into a brewing method by diluting alcohol and a two-stage fermentation method of alcohol and acetic acid fermentation.

When producing vinegar on a factory scale, a method of acetic acid fermentation under aerobic conditions using alcohol is used, but it does not have a similar level of umami as the traditional fermentation method of brewed vinegar, and the usefulness of amino acids, organic acids, etc. Substance content is insufficient.

Traditional vinegar not only acts as an acidulant, but also has a rich taste and is nutritionally excellent, and its acidity, soluble solids content, and alcohol content are generally higher than those of synthetic vinegar.

Meanwhile, more than 15 million tons of seaweed is produced annually worldwide, of which kelp, seaweed, and seaweed account for the largest proportion. Among these seaweeds, kelp, which is rich in nutrients and is called the vegetable of the sea, is one of the representative foods that helps with constipation by increasing the amount of bowel movements. Alginic acid, which is abundant in kelp, helps with diet by interfering with the absorption of fat. It is known to give .

Kelp produced domestically is mainly used for the extraction of polysaccharide alginic acid, and although it has various physiological activities, it has very low processability and has the property of easily absorbing toxic substances, making it difficult to use as a raw material for seasonings such as vinegar. There was a side.

In particular, there are almost no products or manufacturing devices that combine kelp with vinegar, a type of seasoning that is currently widely consumed, and most of the recent kelp-related research is on aquaculture, and products and manufacturing methods using kelp processing and functionality. and device development research are insufficient.

Accordingly, as part of the development of a product combining apple cider vinegar with kelp, the present inventor studied kelp-fermented apple cider vinegar and found through experiments that it does not impart toxicity to cells and exhibits functionality such as anti-inflammatory effects as well as a strong antioxidant effect. By confirming this, the present invention was completed.

Korean Patent No. 10-0884059 (2009.02.10) Korean Patent No. 10-1016751 (2011.02.15)

The present invention includes kelp components to improve sensory quality as well as improve antioxidant activity and exhibit excellent anti-inflammatory effects. It is possible to manufacture vinegar suitable for food or health functional foods, and it is possible to produce vinegar through stirring, maturation, and sterilization during the vinegar production process. The purpose is to provide a kelp-based vinegar production system equipped with an air discharge cap that can produce high-quality vinegar by proceeding with the process.

In order to achieve the above object, the vinegar production system of kelp ingredients equipped with an air discharge cap of the present invention forms a mixture by mixing 5 parts by weight of dried kelp powder and 300 parts by weight of purified water with respect to 100 parts by weight of apple concentrate, A mixing module (1000) that inoculates the mixture with sourdough starter and performs alcohol fermentation to produce an alcoholic fermentation product; An acetic acid fermentation module (2000) that produces an acetic acid fermentation broth with an acidity of 4.0-5.5% by inoculating 10 parts by weight of an acetic acid bacteria strain with respect to 100 parts by weight of the alcoholic fermentation product and then performing acetic acid fermentation; A stirring module (3000) for stirring and maturing the acetic acid fermentation broth; A filtration module 4000 for filtering the acetic acid fermentation broth (filtering by-products); a maturation module (5000) that stirs the acetic acid fermentation broth filtered from the filtration module (4000) and ripens it again; A sterilization module (6000) for sterilizing the aged acetic acid fermentation broth; and a packaging module (7000) for packaging and shipping the vinegar sterilized through the sterilization module (6000) in small portions; Including,

First, the mixing module 1000 is formed with a space 1001a capable of containing the mixture, an inlet 1002 for introducing the mixture is formed on the upper side, and an inlet 1002 is formed on the lower side to discharge the alcoholic fermentation product. a mixing tank (1001) in which an outlet (1003) is formed; A rotating shaft 1008 installed vertically and rotatably in the space 1001a and having a rotating blade 1010 for mixing the mixture to the outside; A drive motor 1004 installed on the mixing tank 1001 to rotate the rotation shaft 1008; Power transmission units (1005, 1006, 1007) installed on the upper part of the space (1001a) to rotate the rotation shaft (1008) using the rotational force of the drive motor (1004); A support frame 1012 installed at the lower part of the mixing tank 1001 to support the mixing tank 1001; A horizontal fixing bar 1013 installed horizontally on the support frame 1012; A vertical bar (1014) installed to be movable in the vertical direction on the horizontal fixed bar (1013); A fixing bracket 1015 installed on the lower side of the vertical bar 1014; A base plate (1016) rotatably installed below the fixing bracket (1015); and an elastic member 1017 that elastically supports the base plate 1016; It consists of

The stirring module 3000 is mounted on the support 3002 of the base 3001, has a space portion 3003a capable of containing the acetic acid fermentation broth, and has an inlet 3005 on the upper side for injecting the acetic acid fermentation broth. ) is formed, and an outlet 3007 for discharging the stirred and aged acetic acid fermentation broth is formed at the bottom (3003); A rotary shaft 3011 installed vertically and rotatably within the space 3003a; A rotating frame 3012 formed integrally with the rotating shaft 3011 and having a plurality of stirring blades 3013 formed on the outer circumference; A rotation drive motor 3010 installed on the top of the stirring tank 3003 to rotate the rotation shaft 3011; A plurality of auxiliary stirring wings (3020, 3034) installed on the side of the stirring tank (3003) to stir the acetic acid fermentation broth in the stirring tank (3003); A driving motor for auxiliary stirring (3015) that transmits power through a driving gear (3017) and a driven gear (3019) to rotate the axes (3018, 3016) of the auxiliary stirring blades (3020, 3034); An up-down movable plate 3009 installed on the upper side of the space 3003a to be movable up and down; An up-down cylinder (3008) installed on the upper part of the stirring tank (3003) to drive the up-down movable plate (3009); A detection tank (3004) formed in communication with the stirring tank (3003) to detect the concentration of acetic acid fermentation broth in the stirring tank (3003); In order to selectively connect the stirring tank 3003 and the detection tank 3004 through a communication hole 3023, it is installed to be openable and closed on the side of the detection tank 3004, and is elastically supported by a spring 3033. Open/close valve (3025); A detection head (3031) for detecting the concentration of acetic acid fermentation broth in the detection tank (3004); and a concentration detector 3030 connected to the detection head 3031; Equipped with

The maturation module 5000 has an inner case 5002 formed inside the outer case 5001, a maturation space 5002a for maturing the acetic acid fermentation broth is formed in the inner case 5002, and is formed on the upper side. A main body (5010) in which an acetic acid fermentation liquid inlet (5111) is formed for injecting the acetic acid fermentation liquid; A stirring rotation shaft (5004) rotatably installed in the ripening space (5002a) in a vertical direction and including a stirring blade (5041); A stirring motor 5003 installed on the upper part of the inner case 5002 to rotate the stirring rotation shaft 5004; A discharge plate 5005 that blocks the lower end of the inner case 5002 and has a plurality of discharge holes 5051 for discharging the acetic acid fermentation broth; An up-down discharge block (5007) having a plurality of blocking rods (5007a) and discharge holes (5007b) to adjust the discharge of acetic acid fermentation broth by selectively opening and closing the discharge hole (5051) while moving up and down (moving) up and down; A hopper for water extraction (5110) installed at the lower part of the up-down discharge block (5007); An up-down adjustment screw rod (5009) screwed to the up-down discharge block (5007) and rotatably installed on the discharge plate (5005) to move the up-down discharge block (5007) up and down; In order to wash the inner wall of the aging space 5002a, it is installed to be movable up and down within the aging space 5002a, and a space 5192 having a washing water flow path 5192a is formed therein, and a nozzle is formed on the bottom. a washing pipe (5190) in which an exposure hole (5191) is formed; a stretchable wash water supply pipe (CH) connected to the wash pipe (5190) and supplying wash water through a wash water pump (5200); an up-down cylinder 5101 installed at the top of the inner case 5002 to move the cleaning pipe 5190 up and down; It is installed in the washing pipe 5190, and is elastically supported by a spring 5170 to block the washing water passage 5192a before spraying the washing water. After spraying the washing water, it moves elastically downward by water pressure to form the washing water passage 5192a. ) an up-down pressure plate (5130) having a stopper (5181) for opening the washing water, and a washing water spray hole (5131) for spraying the washing water; A washing water spray nozzle 5140 is installed at the lower part of the up-down pressure plate 5130 and connected to the washing water spray hole 5131, and sprays washing water through the nozzle exposure hole 5191 when the up-down pressure plate 5130 is lowered. ; a nozzle exposure hole opening/closing gate (5162) rotatably installed on the bottom of the cleaning pipe (5190) with a hinge (H) to flexibly open and close the nozzle exposure hole (5191); And a pusher ( 5161): Equipped with,

The sterilization module 6000 includes a main body 6001 in which a space 6001a is formed; a coolant storage tank 6006 installed on the side of the main body 6001 and storing coolant therein; It is installed in the space 6001a, and has an acetic acid fermentation liquid storage space 6002a therein, and an acetic acid fermentation liquid inlet 6002b is formed on one side of the upper part, and an acetic acid fermentation liquid outlet 6002c is formed on the other side of the upper part. Fermentation broth storage tank (6002); A heating block (6004) fixed to the bottom of the space (6001a) and equipped with a sterilizing heating wire (6005) at the top to heat and sterilize the acetic acid fermentation broth in the acetic acid fermentation broth storage tank (6002); A cooling water circulation pipe 6013 that is configured to surround the outer circumference of the acetic acid fermentation broth storage tank 6002, with one end connected to the upper side of the cooling water storage tank 6006 and the other end connected to the lower side of the cooling water storage tank 6006. ; A circulation pump 6010 installed inside the coolant storage tank 6006 to circulate the coolant of the coolant storage tank 6006 through the coolant circulation pipe 6013; A hollow cold air supply pipe ( 6007); a cold air supply pipe rotation motor (6014) for rotating the cold air supply pipe (6007); A cold air supply housing (6018) installed to surround the cold air supply pipe rotation motor (6014); A blowing fan 6017 installed on the cold air supply pipe rotation motor 6014 to supply cold air from the cold air supply housing 6018 into the cold air supply pipe 6014; and an acetic acid fermentation broth discharge pump (6021) for discharging the sterilized and cooled acetic acid fermentation broth through the acetic acid fermentation broth discharge port (6002c); The technical feature is that it has a .

As described above, the present invention has the following effects.

First, the present invention not only improves sensory quality, but also has excellent DPPH radical scavenging ability (scavenging effect), and has a kelp component that improves antioxidant activity and exhibits excellent anti-inflammatory effects by reducing the secretion of NO and TNF-α, which are inflammatory mediators. Apple cider vinegar can be manufactured quickly and in large quantities.

Second, the apple cider vinegar produced by the present invention can be used for various purposes, such as for beverages, as an additive for functional foods, and for pharmaceutical purposes.

Figure 1 is a block diagram illustrating the procedure for producing vinegar from kelp ingredients with an air discharge cap according to a preferred embodiment of the present invention.
Figure 2 is a front view showing a mixing module in a kelp vinegar production system equipped with an air discharge cap according to a preferred embodiment of the present invention.
Figure 3 is a plan view showing the power transmission part in the mixing module of the vinegar production system of kelp ingredients equipped with an air discharge cap according to a preferred embodiment of the present invention.
Figure 4 is an enlarged view of part A of Figure 2
Figure 5 is a front view showing the stirring module in the vinegar production system of kelp ingredients equipped with an air discharge cap according to a preferred embodiment of the present invention.
Figure 6 is a longitudinal cross-sectional view showing the stirring module in the vinegar production system of kelp ingredients equipped with an air discharge cap according to a preferred embodiment of the present invention.
Figure 7 is a rear view showing the stirring module in the vinegar production system of kelp ingredients equipped with an air discharge cap according to a preferred embodiment of the present invention.
Figure 8 is a view showing a drive motor for auxiliary stirring and a bracket supporting the drive motor for auxiliary stirring in the stirring module of the vinegar production system of kelp ingredients equipped with an air discharge cap according to a preferred embodiment of the present invention.
Figure 9 is a plan view showing the stirring module in the vinegar production system of kelp ingredients equipped with an air discharge cap according to a preferred embodiment of the present invention.
Figure 10 is an enlarged view of part B of Figure 6
Figure 11 is a perspective view showing the maturation module in the vinegar production system of kelp ingredients equipped with an air discharge cap according to a preferred embodiment of the present invention.
Figure 12 is a longitudinal cross-sectional view showing the maturation module in the vinegar production system of kelp components equipped with an air discharge cap according to a preferred embodiment of the present invention.
Figures 13 and 14 are enlarged views of part C of Figure 12
Figure 15 is a perspective view showing the discharge plate and discharge hole in the maturation module of the vinegar production system of kelp component equipped with an air discharge cap according to a preferred embodiment of the present invention.
Figure 16 is a perspective view showing the blocking rod and discharge hole of the up-down discharge block in the maturation module of the vinegar production system of kelp component equipped with an air discharge cap according to a preferred embodiment of the present invention.
Figures 17 and 18 are enlarged views of portion D of Figure 12
Figure 19 is a longitudinal cross-sectional view showing a sterilization module in a kelp vinegar production system equipped with an air discharge cap according to a preferred embodiment of the present invention.
Figure 20 is an enlarged view of part E of Figure 19
And Figure 21 is a plan view showing the air discharge cap in the vinegar production system of kelp component having an air discharge cap according to a preferred embodiment of the present invention.

Hereinafter, the vinegar manufacturing system of kelp ingredients equipped with an air discharge cap according to a preferred embodiment of the present invention forms a mixture by mixing 5 parts by weight of dried kelp powder and 300 parts by weight of purified water with respect to 100 parts by weight of apple concentrate, A mixing module (1000) that inoculates the mixture with sourdough starter and performs alcohol fermentation to produce an alcoholic fermentation product; An acetic acid fermentation module (2000) that produces an acetic acid fermentation broth with an acidity of 4.0-5.5% by inoculating 10 parts by weight of an acetic acid bacteria strain with respect to 100 parts by weight of the alcoholic fermentation product and then performing acetic acid fermentation; A stirring module (3000) for stirring and maturing the acetic acid fermentation broth; A filtration module (4000) for filtering the acetic acid fermentation broth; a maturation module (5000) that stirs the acetic acid fermentation broth filtered from the filtration module (4000) and ripens it again; A sterilization module (6000) for sterilizing and cooling the acetic acid fermentation broth; and a packaging module (7000) for packaging and shipping the vinegar sterilized through the sterilization module (6000) in small portions; There are technical features including:

The dried kelp pulverized product can be formed by removing foreign substances on the surface of the selected dried kelp and then pulverizing the dried kelp to a particle size of 0.1-5.0㎛. If the particle size of the dried kelp powder exceeds 5.0㎛, it is not easy to stir in the subsequent step, and if the particle size is less than 0.1㎛, the desired biological function is weak.

As an embodiment, the mixing process to form the mixture may be preferably performed at a temperature of 45 to 55°C, more preferably 50 to 53°C for 20 to 40 minutes, more preferably 30 to 35 minutes.

The mixture is inoculated with sourdough starter and subjected to alcohol fermentation to produce an alcoholic fermentation product. Alcohol fermentation induces saccharification of the mixture and at the same time produces various organic acids during fermentation, changing the pungent sour taste to a more mellow one, This is to stabilize pH. At this time, the fermentation starter is preferably inoculated at 10 parts by weight in dry weight per 100 parts by weight of the mixture, and the growth temperature range of the fermentation starter is preferably 25 to 35 ℃, more preferably 30 ℃, and the fermentation period is in the range. It is reasonable to ferment for 3 to 7 days, more preferably 5 days.

The sourdough starter can use a variety of edible yeast, preferably Saccharomyces cerevisiae or Saccharomyces boyanus.

It is reasonable to adjust the alcohol concentration during alcohol fermentation to preferably 5 to 9%, more preferably 7 to 8%, and most preferably 7.4%.

In one embodiment of the present invention, the alcohol fermentation product is inoculated with acetic acid bacteria and then subjected to acetic acid fermentation to form an acetic acid fermentation product having an acidity of 4.0 to 5.5%. In one embodiment, the acetic acid fermentation is carried out by inoculating preferably 10 parts by weight of an acetic acid bacteria strain with respect to 100 parts by weight of the alcohol fermentation material, preferably at 25 to 35°C, more preferably at 30°C, and preferably at 30°C. It is reasonable to culture for 10 to 10 days, more preferably 7 days.

The acetic acid fermentation is preferably performed by adjusting the initial acidity to the range of 4.0 to 5.5%, more preferably 4.5 to 5.0%, but is not necessarily limited thereto.

Meanwhile, the acetic acid fermentation broth formed through the acetic acid fermentation contains abundant nutrients beneficial to the human body, such as dietary fiber, vitamin B, and digestive enzymes, and these nutrients require appropriate fermentation conditions and the production of yeast fermentation bacteria, acetic acid bacteria, etc. It is the result of this process.

In the present invention, the stirring module 3000 stirs the acetic acid fermentation broth to perform primary aging of the acetic acid fermentation broth. The ripening period may be, for example, 30 to 60 days, but is not limited thereto. The number of times of stirring can be 3 to 5 times over 30 to 60 days, but is not limited to this.

Through primary maturation, we can maximize the extraction of active ingredients contained in the acetic acid fermentation broth, and at the same time, we can expect improvement in the sensory quality of taste and aroma by completely going through the maturation process.

In the present invention, the filtration module 4000 filters the aged acetic acid fermentation product and separates the acetic acid fermentation broth. Although not shown in the drawing, filtration may be performed, for example, by sequentially passing an ultra-high-speed centrifugal filter and a diatomaceous earth filter.

In one embodiment, the filtration is performed by centrifuging through an ultra-high-speed centrifugal filter for 15 to 30 minutes at a rotation speed of 5,000 to 10,000 rpm to collect only the supernatant, and then filtering through a diatomaceous earth filter to remove various suspended substances or impurities contained in the supernatant. It can also be filtered.

In the present invention, the maturation module 5000 stirs the acetic acid fermentation broth filtered from the filtration module 4000 and performs secondary maturation. The ripening period may be, for example, 30 to 60 days, but is not limited thereto. The number of times of stirring can be 3 to 5 times over 30 to 60 days, but is not limited to this.

Through secondary maturation, we can maximize the extraction of the active ingredients contained in the acetic acid fermentation broth, and at the same time, further improvement in the sensory quality of taste and aroma can be expected by going through the maturation process completely.

In the present invention, the sterilization module 6000 sterilizes and cools the acetic acid fermentation broth.

Sterilization is carried out to destroy remaining enzymes, sterilize, or suppress bacteria. In one embodiment, the sterilization is a low temperature long time (LTLT) method of sterilizing at 63 to 65°C for about 30 minutes, High temperature short time (HTST), which sterilizes at 90 to 110℃ for 15 to 30 seconds, and ultra high temperature (UHT), which sterilizes at 120 to 150℃ for 1 to 3 seconds. In order to sterilize contaminating bacteria as much as possible while minimizing browning of the raw materials, it is most desirable to sterilize at a temperature of 98°C for approximately 30 seconds.

Cooling is performed to promote the activity of yeast, etc. In one embodiment, cooling can be performed by lowering the temperature of acetic acid fermentation sterilized at a relatively high temperature to 35 to 50°C, but is not necessarily limited thereto.

The components of the kelp-based vinegar production system equipped with an air discharge cap according to a preferred embodiment of the present invention will be described in detail as follows.

First, as shown in FIGS. 2 to 4, the mixing module 1000 is formed with a space portion 1001a capable of containing the mixture, and has an injection port 1002 for injecting the mixture on the upper side. A mixing tank (1001) formed with an outlet (1003) on the lower side for discharging the alcoholic fermentation product; A rotating shaft 1008 is installed vertically and rotatably in the space 1001a, and has a rotating blade 1010 for mixing the mixture on the outside of the space 1001a; A drive motor 1004 installed on the mixing tank 1001 to rotate the rotation shaft 1008; Power transmission units (1005, 1006, 1007) installed on the upper part of the space (1001a) to rotate the rotation shaft (1008) using the rotational force of the drive motor (1004); A support frame 1012 installed at the lower part of the mixing tank 1001 to support the mixing tank 1001; A horizontal fixing bar 1013 installed horizontally on the support frame 1012; A vertical bar (1014) installed to be movable in the vertical direction on the horizontal fixed bar (1013); A fixing bracket 1015 installed on the lower side of the vertical bar 1014; A base plate (1016) rotatably installed below the fixing bracket (1015); and an elastic member 1017 that elastically supports the base plate 1016; It can be configured by providing.

The power transmission unit includes a driven gear 1006 installed on the upper end of the rotating shaft 1008, a driving gear 1005 installed on the driving motor 1004, and between the driving gear 1005 and the driven gear 1006. It may be composed of a connecting gear 1007 installed on (see Figure 3).

The operator can adjust the height of the fixing bracket 1015 by rotating the vertical bar 1014 clockwise or counterclockwise, and the base plate 1016 is elastic by the elastic member (e.g., spring) 1017. By contacting the ground (bottom surface), the entire mixing tank 1001 can be stably supported.

The rotating blade 1010 may be fixed to the rotating shaft 1008 by a fixing pin 1090 (see FIG. 4).

A scraper 1011 is installed at the lower end of the rotating shaft 1008, and the scraper 1011 serves to scrape off sediment to prevent it from hardening on the bottom of the mixing tank 1001 during the mixing process.

The mixing module 1000 forms a mixture by mixing 5 parts by weight of dried kelp powder and 300 parts by weight of purified water with respect to 100 parts by weight of apple concentrate, inoculates the mixture with sourdough starter, and then performs alcohol fermentation to produce an alcohol fermentation product. Looking at the operation of the mixing module 1000, after injecting the mixture through the injection port 1002, the rotating shaft 1008 is rotated using the power of the driving motor 1004, so that the rotating blade 1010 is generated. The mixture is mixed with stirring and subjected to alcohol fermentation. Afterwards, the alcoholic fermentation product can be discharged through the outlet 1003.

In addition, the acetic acid fermentation module 2000 shown in FIG. 1 produces an acetic acid fermentation broth with an acidity of 4.0 - 5.5% by inoculating 10 parts by weight of acetic acid bacteria strain with respect to 100 parts by weight of alcoholic fermentation material and performing acetic acid fermentation. The acetic acid fermentation module 2000 may use a device for inoculating acetic acid bacteria into the alcoholic fermentation product, for example, a known dropper or measuring cup.

In addition, as shown in FIGS. 5 to 10, the stirring module 3000 is mounted on the support 3002 of the base 3001, and a space 3003a capable of containing the acetic acid fermentation broth is formed therein. , a stirring tank (3003) in which an inlet (3005) is formed on the upper side for injecting the acetic acid fermentation broth, and an outlet (3007) is formed in the lower part for discharging the acetic acid fermentation broth that has been primary aged through a stirring process; A rotary shaft 3011 installed vertically and rotatably within the space 3003a; A rotating frame 3012 formed integrally with the rotating shaft 3011 and having a plurality of stirring blades 3013 formed on the outer circumference; A rotation drive motor 3010 installed on the top of the stirring tank 3003 to rotate the rotation shaft 3011; A plurality of auxiliary stirring wings (3020, 3034) installed on the side of the stirring tank (3003) to stir and primary ripen the acetic acid fermentation broth in the stirring tank (3003); A driving motor for auxiliary stirring (3015) that transmits power through a driving gear (3017) and a driven gear (3019) to rotate the axes (3018, 3016) of the auxiliary stirring blades (3020, 3034); An up-down movable plate 3009 installed on the upper side of the space 3003a to be movable up and down; An up-down cylinder (3008) installed on the upper part of the stirring tank (3003) to drive the up-down movable plate (3009); A detection tank (3004) formed in communication with the stirring tank (3003) to detect the concentration of acetic acid fermentation broth in the stirring tank (3003); In order to selectively connect the stirring tank 3003 and the detection tank 3004 through a communication hole 3023, it is installed to be openable and closed on the side of the detection tank 3004, and is elastically supported by a spring 3033. Open/close valve (3025); A detection head (3031) for detecting the concentration of acetic acid fermentation broth in the detection tank (3004); and a concentration detector 3030 connected to the detection head 3031; It can be configured by providing.

The unexplained symbol 3006 is a protective case covering the rotation drive motor 3010, 3014 is a support bracket supporting the auxiliary stirring drive motor 3015, and 3026 is a knob of the opening and closing valve 3025. am.

Support brackets 3021 and 3022 are installed at the lower part of the rotary shaft 3011 to stably support the rotation of the rotary shaft 3011.

A mesh network 3024 may be installed in the communication hole 3023. A drain cap 3029 may be installed on the bottom of the detection tank 3004 to discharge the acetic acid fermentation liquid remaining in the detection tank 3004 to the outside.

The stirring module 3000 stirs and ages the acetic acid fermentation broth, and stirring is performed only when necessary.

Looking at the operation of the stirring module 3000, the acetic acid fermentation broth is injected through the injection port 3005 and then the rotation frame 3012 of the rotation shaft 3011 is rotated using the power of the rotation drive motor 3010. A plurality of stirring blades 3013 stir and age the acetic acid fermentation broth. In addition, by using the power of the auxiliary stirring drive motor 3015 to rotate the shafts 3016 and 3018, the auxiliary stirring blades 3020 and 3034 rotate, thereby further increasing stirring and maturation efficiency. During the stirring and maturation process, bubbles generated in the space 3003a of the stirring tank 3003 are broken by the needle 3009a formed on the lower surface of the up-down movable plate 3009, which moves up and down by the up-down cylinder 3008. .

When the handle 3026 of the on-off valve 3025 is pulled to detect the acetic acid fermentation broth concentration (acidity) in the stirring tank 3003, the elastic force of the spring 3033 is overcome and the on-off valve 3025 moves to the right. As the communication hole 3023 is opened, the acetic acid fermentation broth in the stirring tank 3003 flows into the detection tank 3004. At this time, the detection head 3031 is in contact with the acetic acid fermentation broth, and the acetic acid fermentation broth is detected in the concentration detector 3030. Make sure to detect the concentration. The stirred and aged acetic acid fermentation broth is discharged through the outlet (3007).

In addition, the maturation module 5000 has an inner case 5002 formed inside the outer case 5001, a maturation space 5002a for maturing the acetic acid fermentation broth is formed in the inner case 5002, and an upper upper part. A main body (5010) with an acetic acid fermentation liquid inlet (5111) formed on the side for injecting the acetic acid fermentation liquid; A stirring rotation shaft (5004) rotatably installed in the ripening space (5002a) in a vertical direction and including a stirring blade (5041); A stirring motor 5003 installed on the upper part of the inner case 5002 to rotate the stirring rotation shaft 5004; A discharge plate 5005 that blocks the lower end of the inner case 5002 and has a plurality of discharge holes 5051 for discharging the acetic acid fermentation broth; An up-down discharge block equipped with a plurality of blocking rods (5007a) and a plurality of discharge holes (5007b) at the bottom to adjust the discharge of acetic acid fermentation broth by selectively opening and closing the discharge hole (5051) while moving up and down (moving) up and down. (5007); A water discharge hopper (5110) installed integrally at the lower part of the up-down discharge block (5007); An up-down adjustment screw rod (5009) screwed to the up-down discharge block (5007) and rotatably installed on the discharge plate (5005) to move the up-down discharge block (5007) up and down; In order to wash the inner wall of the aging space 5002a, it is installed to be movable up and down within the aging space 5002a, and a space 5192 having a washing water flow path 5192a is formed therein, and a nozzle is formed on the bottom. a washing pipe (5190) in which an exposure hole (5191) is formed; a stretchable washing water supply pipe (CH) connected to the washing pipe 5190 and supplying washing water through a washing water pump 5200; an up-down cylinder 5101 installed at the top of the inner case 5002 to move the cleaning pipe 5190 up and down; It is installed in the washing pipe 5190, and is elastically supported by a spring 5170 to block the washing water passage 5192a before spraying the washing water. After spraying the washing water, it moves elastically downward by water pressure to form the washing water passage 5192a. ) an up-down pressure plate (5130) having a stopper (5181) for opening the washing water, and a washing water spray hole (5131) for spraying the washing water; A washing water spray nozzle 5140 is installed at the lower part of the up-down pressure plate 5130 and connected to the washing water spray hole 5131, and sprays washing water through the nozzle exposure hole 5191 when the up-down pressure plate 5130 is lowered. ; a nozzle exposure hole opening/closing gate (5162) rotatably installed on the bottom of the cleaning pipe (5190) with a hinge (H) to flexibly open and close the nozzle exposure hole (5191); And when the up-down pressure plate 5130 is lowered, the nozzle exposure hole opening/closing gate 5162 is pressed downward to open, penetrating the bottom of the cleaning pipe 5190 and protruding downward integrally with the bottom of the up-down pressure plate 5130. The formed pusher 5161: may be configured to include.

The unexplained symbol 5006 is a support ring that supports the discharge plate 5005, and 5009a is a bracket that rotatably holds the screw rod for up and down adjustment (5009).

The maturation module 5000 matures the acetic acid fermentation broth again, and stirring is performed only when necessary.

Looking at the operation of the maturation module 5000, the acetic acid fermentation broth is injected through the acetic acid fermentation broth inlet 5111, then flows into the maturation space 5002a and is aged over a certain period of time.

For ripening, the stirring motor 5003 drives to rotate the stirring rotation shaft 5004, causing the stirring blade 5041 to rotate and stir.

The aged acetic acid fermentation broth is blocked by the discharge plate 5005, and when the aged acetic acid fermentation broth is discharged, the up-down discharge block 5007 moves downward by the up-down adjustment screw rod 5009, and at this time, the blocking rod 5007a As the discharge hole 5051 is opened, the acetic acid fermentation liquid passes through the discharge hole 5051 (5007b) and is then discharged to the outside through the water hopper 5110.

After the aging process, the maturation space 5002a can be washed with washing water. The washing pipe 5190 has a washing water flow path 5192a inside, and before washing, the washing water flow path 5192a is connected to a stopper 5181. It is blocked to prevent washing water from leaking arbitrarily.

During washing, after the washing water is sprayed, the stopper 5181 of the up-down pressure plate 5130 moves downward elastically due to water pressure to open the washing water passage 5192a.

At this time, the spring 5170 is pressed downward, the pusher 5161 of the up-down pressure plate 5130 moves downward to press and open the nozzle exposure hole opening/closing gate 5162, and the washing water spray nozzle 5140 is connected to the up-down pressure plate 5130. When 5130 is lowered, it is exposed through the nozzle exposure hole 5191, and at the same time, the washing water flows in through the washing water spray hole 5131 and is then sprayed through the washing water spray nozzle 5140, so that the inner wall of the aging space 5002a can be washed.

In addition, the sterilization module 6000 includes a main body 6001 in which a space 6001a is formed; a coolant storage tank 6006 installed on the side of the main body 6001 and storing coolant therein; It is installed in the space 6001a, and has an acetic acid fermentation liquid storage space 6002a therein, and an acetic acid fermentation liquid inlet 6002b is formed on one side of the upper part, and an acetic acid fermentation liquid outlet 6002c is formed on the other side of the upper part. Fermentation broth storage tank (6002); A heating block (6004) fixed to the bottom of the space (6001a) and equipped with a sterilizing heating wire (6005) at the top to heat and sterilize the acetic acid fermentation broth in the acetic acid fermentation broth storage tank (6002); It is configured to rotate and surround the outer circumference of the acetic acid fermentation broth storage tank 6002, and has one end connected to the upper side of the cooling water storage tank 6006 and the other end connected to the lower side of the cooling water storage tank 6006. Condensation pipe) (6013); A circulation pump 6010 installed inside the coolant storage tank 6006 to circulate the coolant of the coolant storage tank 6006 through the coolant circulation pipe 6013; A hollow cold air supply pipe ( 6007); a cold air supply pipe rotation motor (6014) for rotating the cold air supply pipe (6007); A cold air supply housing (6018) installed to surround the cold air supply pipe rotation motor (6014); A blowing fan 6017 installed on the cold air supply pipe rotation motor 6014 to supply cold air from the cold air supply housing 6018 into the cold air supply pipe 6014; and an acetic acid fermentation broth discharge pump (6021) for discharging the sterilized and cooled acetic acid fermentation broth through the acetic acid fermentation broth discharge port (6002c); It can be configured by providing.

The unexplained symbol 6009 is a pulley, and 6016 is a connection belt, which is a power transmission unit for transmitting the rotational power of the cold air supply pipe rotation motor 6014 to the cold air supply pipe 6007.

The unexplained code 6019 is a cold air connection hose for injecting cold air into the cold air supply pipe 6007, and the unexplained code 6003 is a support base structure that supports the heating block 6004.

The sterilization module 6000 sterilizes and cools the aged acetic acid fermentation broth. Looking at the operation of the sterilization module 6000, the acetic acid fermentation broth is injected into the acetic acid fermentation broth storage tank 6002 through the acetic acid fermentation broth injection port 6002b. In this state, the acetic acid fermentation broth is sterilized by heating the sterilizing heating wire 6005 of the heating block 6004, and the cooling water is circulated in the cooling water circulation pipe (condensation pipe) 6013 by driving the circulation pump 6010. While doing so, the acetic acid fermentation broth in the acetic acid fermentation broth storage tank 6002 is cooled again.

The coolant in the coolant storage tank 6006 is cooled by the cold air nozzle hole 6007a of the cold air supply pipe 6007 and the blade 6007b that agitates the coolant.

By driving the cold air supply pipe rotation motor 6014, the cold air supply pipe 6007 rotates and supplies cold air (bubbles) through the cold air nozzle hole 6007a, and the blade 6007b agitates the coolant, generating heat exchange by coolant. Prevent the temperature of the coolant from rising.

As shown in FIG. 21, cold air (air bubbles) remaining in the coolant storage tank 6006 is discharged to the outside through the check valve 6007d of the air discharge cap 6007c provided on the upper side of the coolant storage tank 6006. . The check valve 6007d discharges cold air bubbles and, conversely, prevents external air from entering, that is, allows gas to flow in only one direction.

The acetic acid fermentation broth that has been sterilized and cooled to a certain temperature is discharged to the outside through the acetic acid fermentation broth discharge port (6002c) by the acetic acid fermentation broth discharge pump (6021).

Lastly, the packaging module 7000 packages the sterilized vinegar through the sterilization module 6000 into small portions and ships them. The packaging module 7000 uses the configuration of a known packaging device for packaging liquid food.

As described above, the present invention has the following effects.

First, the present invention not only improves sensory quality, but also has excellent DPPH radical scavenging ability (scavenging effect), and has a kelp component that improves antioxidant activity and exhibits excellent anti-inflammatory effects by reducing the secretion of NO and TNF-α, which are inflammatory mediators. Apple cider vinegar can be manufactured quickly and in large quantities.

Second, the apple cider vinegar produced by the present invention can be used for various purposes, such as for beverages, as an additive for functional foods, and for pharmaceutical purposes.

1000: Mixed module
2000: Acetic acid fermentation module
3000: Stirring module
4000: Filtration module
500: Ripening module
600: Sterilization module
700: Packaging module

Claims (1)

A mixing module (1000) that forms a mixture by mixing 100 parts by weight of apple concentrate, 5 parts by weight of dried kelp powder, and 300 parts by weight of purified water, inoculates the mixture with sourdough starter, and then performs alcohol fermentation to produce an alcoholic fermentation product. ; An acetic acid fermentation module (2000) that produces an acetic acid fermentation broth with an acidity of 4.0-5.5% by inoculating 10 parts by weight of an acetic acid bacteria strain with respect to 100 parts by weight of the alcoholic fermentation product and then performing acetic acid fermentation; A stirring module (3000) for stirring and maturing the acetic acid fermentation broth; A filtration module (4000) for filtering the acetic acid fermentation broth; a maturation module (5000) that stirs the acetic acid fermentation broth filtered from the filtration module (4000) and ripens it again; A sterilization module (6000) for sterilizing the aged acetic acid fermentation broth; and a packaging module (7000) for packaging and shipping the vinegar sterilized through the sterilization module (6000) in small portions; Including,
The mixing module 1000 has a space 1001a capable of containing the mixture, an inlet 1002 for injecting the mixture is formed on the upper side, and an outlet for discharging the alcohol fermentation product is formed on the lower side. A mixing tank (1001) in which (1003) is formed; A rotating shaft 1008 installed vertically and rotatably in the space 1001a and having a rotating blade 1010 for mixing the mixture to the outside; A drive motor 1004 installed on the mixing tank 1001 to rotate the rotation shaft 1008; Power transmission units (1005, 1006, 1007) installed on the upper part of the space (1001a) to rotate the rotation shaft (1008) using the rotational force of the drive motor (1004); A support frame 1012 installed at the lower part of the mixing tank 1001 to support the mixing tank 1001; A horizontal fixing bar 1013 installed horizontally on the support frame 1012; A vertical bar (1014) installed to be movable in the vertical direction on the horizontal fixed bar (1013); A fixing bracket 1015 installed on the lower side of the vertical bar 1014; a base plate (1016) rotatably installed below the fixing bracket (1015); and an elastic member 1017 that elastically supports the base plate 1016; It consists of
The stirring module 3000 is mounted on the support 3002 of the base 3001, has a space portion 3003a capable of containing the acetic acid fermentation broth, and has an inlet 3005 on the upper side for injecting the acetic acid fermentation broth. ) is formed, and an outlet 3007 for discharging the stirred and aged acetic acid fermentation broth is formed at the bottom (3003); A rotary shaft 3011 installed vertically and rotatably within the space 3003a; A rotating frame 3012 formed integrally with the rotating shaft 3011 and having a plurality of stirring blades 3013 formed on the outer circumference; A rotation drive motor 3010 installed on the top of the stirring tank 3003 to rotate the rotation shaft 3011; A plurality of auxiliary stirring wings (3020, 3034) installed on the side of the stirring tank (3003) to stir the acetic acid fermentation broth in the stirring tank (3003); A driving motor for auxiliary stirring (3015) that transmits power through a driving gear (3017) and a driven gear (3019) to rotate the axes (3018, 3016) of the auxiliary stirring blades (3020, 3034); An up-down movable plate 3009 installed on the upper side of the space 3003a to be movable up and down; An up-down cylinder (3008) installed on the upper part of the stirring tank (3003) to drive the up-down movable plate (3009); A detection tank (3004) formed in communication with the stirring tank (3003) to detect the concentration of acetic acid fermentation broth in the stirring tank (3003); In order to selectively connect the stirring tank 3003 and the detection tank 3004 through a communication hole 3023, it is installed to be openable and closed on the side of the detection tank 3004, and is elastically supported by a spring 3033. Open/close valve (3025); A detection head (3031) for detecting the concentration of acetic acid fermentation broth in the detection tank (3004); and a concentration detector 3030 connected to the detection head 3031; Equipped with

The maturation module 5000 has an inner case 5002 formed inside the outer case 5001, a maturation space 5002a for maturing the acetic acid fermentation broth is formed in the inner case 5002, and is formed on the upper side. A main body (5010) in which an acetic acid fermentation liquid inlet (5111) is formed for injecting the acetic acid fermentation liquid; A stirring rotation shaft (5004) rotatably installed in the ripening space (5002a) in a vertical direction and including a stirring blade (5041); A stirring motor 5003 installed on the upper part of the inner case 5002 to rotate the stirring rotation shaft 5004; A discharge plate 5005 that blocks the lower end of the inner case 5002 and has a plurality of discharge holes 5051 for discharging the acetic acid fermentation broth; An up-down discharge block (5007) having a plurality of blocking rods (5007a) and discharge holes (5007b) to adjust the discharge of acetic acid fermentation broth by selectively opening and closing the discharge hole (5051) while moving up and down (moving) up and down; A hopper for water extraction (5110) installed at the lower part of the up-down discharge block (5007); An up-down adjustment screw rod (5009) screwed to the up-down discharge block (5007) and rotatably installed on the discharge plate (5005) to move the up-down discharge block (5007) up and down; In order to wash the inner wall of the aging space 5002a, it is installed to be movable up and down within the aging space 5002a, and a space 5192 having a washing water flow path 5192a is formed therein, and a nozzle is formed on the bottom. a washing pipe (5190) in which an exposure hole (5191) is formed; a stretchable wash water supply pipe (CH) connected to the wash pipe (5190) and supplying wash water through a wash water pump (5200); an up-down cylinder 5101 installed at the top of the inner case 5002 to move the cleaning pipe 5190 up and down; It is installed in the washing pipe 5190, and is elastically supported by a spring 5170 to block the washing water passage 5192a before spraying the washing water. After spraying the washing water, it moves elastically downward by water pressure to form the washing water passage 5192a. ) an up-down pressure plate (5130) having a stopper (5181) for opening the washing water, and a washing water spray hole (5131) for spraying the washing water; A washing water spray nozzle 5140 is installed at the lower part of the up-down pressure plate 5130 and connected to the washing water spray hole 5131, and sprays washing water through the nozzle exposure hole 5191 when the up-down pressure plate 5130 is lowered. ; a nozzle exposure hole opening/closing gate (5162) rotatably installed on the bottom of the cleaning pipe (5190) with a hinge (H) to flexibly open and close the nozzle exposure hole (5191); And a pusher ( 5161): Equipped with,

The sterilization module 6000 includes a main body 6001 in which a space 6001a is formed; a coolant storage tank 6006 installed on the side of the main body 6001 and storing coolant therein; It is installed in the space 6001a, and has an acetic acid fermentation liquid storage space 6002a therein, and an acetic acid fermentation liquid inlet 6002b is formed on one side of the upper part, and an acetic acid fermentation liquid discharge port 6002c is formed on the other side of the upper part. Fermentation broth storage tank (6002); A heating block (6004) fixed to the bottom of the space (6001a) and equipped with a sterilizing heating wire (6005) at the top to heat and sterilize the acetic acid fermentation broth in the acetic acid fermentation broth storage tank (6002); A cooling water circulation pipe 6013 that is configured to surround the outer periphery of the acetic acid fermentation broth storage tank 6002, with one end connected to the upper side of the cooling water storage tank 6006 and the other end connected to the lower side of the cooling water storage tank 6006. ; A circulation pump 6010 installed inside the coolant storage tank 6006 to circulate the coolant of the coolant storage tank 6006 through the coolant circulation pipe 6013; A hollow cold air supply pipe ( 6007); a cold air supply pipe rotation motor (6014) for rotating the cold air supply pipe (6007); A cold air supply housing (6018) installed to surround the cold air supply pipe rotation motor (6014); A blowing fan 6017 installed on the cold air supply pipe rotation motor 6014 to supply cold air from the cold air supply housing 6018 into the cold air supply pipe 6007; and an acetic acid fermentation broth discharge pump (6021) for discharging the sterilized and cooled acetic acid fermentation broth through the acetic acid fermentation broth discharge port (6002c); Provided with
With the acetic acid fermentation broth being injected into the acetic acid fermentation broth storage tank 6002 through the acetic acid fermentation broth inlet 6002b, the acetic acid fermentation broth is sterilized by heating the sterilizing heating wire 6005 of the heating block 6004. By driving the circulation pump 6010, the cooling water circulates in the cooling water circulation pipe 6013 to cool the acetic acid fermentation broth in the acetic acid fermentation broth storage tank 6002 again, and the cooling water in the cooling water storage tank 6006 is It is cooled by the cold air nozzle hole 6007a of the cold air supply pipe 6007 and the blade 6007b that agitates the cooling water, and the cold air supply pipe 6007 rotates by driving the cold air supply pipe rotation motor 6014, and the cold air nozzle hole Cold air bubbles (air) are supplied through (6007a), and the blade (6007b) agitates the coolant to prevent the temperature of the coolant from increasing due to heat exchange of the coolant, and the air bubbles are stored in the coolant storage tank (6006). A vinegar production system of kelp ingredients having an air discharge cap, characterized in that it is discharged to the outside through the check valve (6007d) of the air discharge cap (6007c) provided on the upper side.