KR102267399B1 - Dried milk production system with capable of mixing lactic acid bacteria containing powder and dried milk uniformly - Google Patents

Abstract

Disclosed is a milk powder manufacturing system capable of uniformly mixing lactic acid bacteria powder. The milk powder manufacturing system capable of uniformly mixing the lactic acid bacteria powder according to the present invention comprises: a fluidized bed dryer for drying and cooling the powdered formula; and a lactic acid bacteria powder supply device for supplying the lactic acid bacteria powder to the fluidized bed dryer so that the formula powder and the lactic acid bacteria powder are uniformly mixed, the lactic acid bacteria powder supply device comprising: a storage tank in which the lactic acid bacteria powder is stored; a refill hopper that receives lactic acid bacteria powder from a storage tank; a receiving unit which is provided in communication with the refill hopper and receives and receives a quantity of lactic acid bacteria powder from the refill hopper; And the receiving unit is connected to one side in communication and the air supply device for supplying air to the other side is connected in communication with the main body and the main body is connected in communication to spray air, but the lactic acid bacteria powder accommodated in the receiving unit is sprayed by the venturi effect and a lactic acid bacteria powder supply unit for supplying air containing lactic acid bacteria powder to the fluidized bed dryer by having a first injection nozzle to be mixed with the air.

Description

DRIED MILK PRODUCTION SYSTEM WITH CAPABLE OF MIXING LACTIC ACID BACTERIA CONTAINING POWDER AND DRIED MILK UNIFORMLY

The present invention relates to a milk powder manufacturing system capable of uniformly mixing lactic acid bacteria powder, and more particularly, to a milk powder manufacturing system capable of uniformly mixing lactic acid bacteria powder with manufactured milk powder.

In general, when babies are unable to breastfeed after they are born, they are fed milk powder (milk powder and formula containing various nutrients such as whey protein and vitamins), and after about 3 to 6 months after birth, baby food is fed step by step for several years. will be fed

However, these formulas and baby food contain various ingredients such as vitamins and minerals in consideration of the nutritional supply aspect of the child, but the aspect of supplying bacteria such as lactic acid bacteria that aid digestion when the child ingests it is not sufficiently considered.

As children who were originally supposed to be breastfed drink formula, their ability to digest and absorb and their resistance to diseases are weakened, making it easy to suffer from various diseases such as frequent stomach upset, diarrhea, and allergies.

In addition, natural lactic acid bacteria such as reuteri are also present in breast milk, so babies can take lactic acid bacteria continuously. If you use this antibiotic, the bacteria in your intestines (both beneficial and pathogenic bacteria such as lactic acid bacteria) are almost killed by this antibiotic, so it is necessary to supplement lactic acid bacteria with food, but in most cases, you need to supplement lactic acid bacteria drinks or medicines separately. In many cases, the lack of lactic acid bacteria in the intestines of babies was not given. Accordingly, powdered milk containing lactic acid bacteria in the manufactured milk powder is commercially available.

On the other hand, in the conventional input of lactic acid bacteria to the manufactured milk powder, for example, after sterilizing the manufactured powdered milk and adding the liquid lactic acid bacteria before spray drying, there was a problem in that the lactic acid bacteria were killed during the spray drying process. The powder containing lactic acid bacteria was put on the line transferred to the storage hopper, but there was a problem that the manufactured milk powder and the powder containing lactic acid bacteria were not uniformly mixed.

Therefore, there is a need for research on a manufacturing system that can uniformly mix powder containing lactic acid bacteria with milk powder during mass production.

Republic of Korea Patent Publication No. 10-2005-0012212 (published on Jan. 31, 2005)

Therefore, the technical problem to be solved by the present invention is to provide a milk powder manufacturing system capable of uniformly mixing the lactic acid bacteria powder that can uniformly mix the powder containing lactic acid bacteria with the manufactured milk powder in mass production of the manufactured powdered milk.

According to an aspect of the present invention, there is provided a fluidized bed dryer for drying and cooling the powdered formula; and a lactic acid bacteria powder supply device for supplying the lactic acid bacteria powder to the fluidized bed dryer so that the formula powder and the lactic acid bacteria powder are uniformly mixed, wherein the lactic acid bacteria powder supply device includes: a storage tank in which the lactic acid bacteria powder is stored; a refill hopper receiving the lactic acid bacteria powder from the storage tank; a receiving unit provided in communication with the refill hopper and receiving and accommodating a quantity of the lactic acid bacteria powder from the refill hopper; And the accommodating unit is connected to one side and the air supply device for supplying air to the other side is connected in communication with the main body part and the body part is connected in communication to spray air, but the lactic acid bacteria powder accommodated in the accommodating unit is venturi A milk powder manufacturing system capable of uniformly mixing lactic acid bacteria powder including a lactic acid bacteria powder supply unit for supplying the air containing the lactic acid bacteria powder to the fluidized bed dryer by having a first injection nozzle that is mixed with the air sprayed by the effect can be provided.

A first air flow path connecting the air supply device and the other side of the main body in communication with the other side of the main body is provided to supply air to the other side of the main body, and the air containing the lactic acid bacteria powder is injected through the first injection nozzle. A second air flow path may be provided to connect the air supply device and the accommodation unit in communication with the air supply unit to supply air to the accommodation unit in order to prevent a vacuum from being applied in the accommodation unit.

A first relief valve for maintaining a constant pressure of the air supplied to the accommodation unit may be installed in the second air passage.

The first relief valve is connected to the second air flow path in communication with the air supplied along the second air flow path, and radially spaced apart from the center and formed continuously along the circumferential direction and a plurality of bulkheads in the radial direction. a valve body in which a groove portion having a plurality of through-holes passing through the partition wall is formed; a sealing plate seated on the upper surface of the valve body and supported by a plurality of the bulkheads and sealing the upper surface of the valve body; a pressure plate seated on the upper surface of the sealing plate; and a valve housing that is seated on the upper surface of the pressure plate and has a shape surrounding the valve body, the sealing plate, and the pressure plate and has an open lower surface.

The lactic acid bacteria powder supply device may further include an ionizer provided in the first air flow path to prevent static electricity generation.

The lactic acid bacterium powder supply device may further include a first load cell installed under the refill hopper to confirm the amount of the lactic acid bacterium powder stored in the refill hopper.

In the fluidized bed dryer, an infant formula supply port through which the powdered formula is supplied is formed at one end, and an infant formula outlet through which the dried and cooled infant formula powder is discharged is formed at the other end, and in front of the infant formula outlet. a dryer body having a damper protruding upward from the bottom surface; and the lactic acid bacteria powder installed on the upper portion of the dryer body in which the infant formula outlet is formed and connected to the first injection nozzle so that the powdered formula powder and the lactic acid bacteria powder are uniformly mixed, and supplied through the first injection nozzle It may include a second injection nozzle for spraying the air containing the downward.

The second injection nozzle receives the air containing the lactic acid bacteria powder from the first injection nozzle and sprays the nozzle body, but the cross-sectional area is increased in the longitudinal direction; and a nozzle housing disposed to surround the nozzle body and having an air supply port provided on the side to receive air from the air supply device so that the air containing the lactic acid bacteria powder sprayed from the nozzle body forms a swirling flow. have.

A third air flow path connecting the air supply device and the nozzle housing in communication with the nozzle housing is provided to supply air to the nozzle housing, and the first injection nozzle and the air containing the lactic acid bacteria powder are supplied to the nozzle body. A powder supply passage connecting the nozzle body in communication may be provided.

A spring may be wound around the outer surface of the powder supply passage and grounded.

At least one mesh network may be installed to be spaced apart from each other in the height direction at the infant formula outlet.

The storage tank includes: a tank body in which the lactic acid bacteria powder is stored, a thermal insulation material is embedded, and an opening is formed in the upper part; a first cover part rotatably installed on the upper part of the tank body to open and close the opening of the tank body; a second cover part which is rotatably installed on the first cover part and enables confirmation of the inside of the tank body; and a third cover part installed to surround the first cover part on the upper part of the tank body.

The storage tank may further include a second load cell installed in the lower portion of the tank body to enable checking the amount of the lactic acid bacteria powder stored in the tank body.

A nitrogen supply device for supplying nitrogen gas to the storage tank and the refill hopper to form a positive nitrogen pressure in the storage tank and the refill hopper may be further included.

A first nitrogen supply passage connecting the nitrogen supply device and the storage tank in communication with the storage tank is provided to supply nitrogen gas to the storage tank, and the nitrogen supply device communicates with the refill hopper to supply nitrogen gas to the refill hopper A second nitrogen supply passage is provided to be connected to each other, and a second relief valve for maintaining a constant pressure of nitrogen gas supplied to the storage tank may be installed in the first nitrogen supply passage.

In an embodiment of the present invention, the lactic acid bacteria powder can be uniformly mixed with the manufactured milk powder by spraying air containing the lactic acid bacteria powder on the dried and cooled powdered milk in a fluidized bed dryer.

1 is a structural diagram schematically showing a milk powder manufacturing system according to the present invention.
Figure 2 is a cross-sectional view showing the lactic acid bacteria powder supply unit according to the present invention.
3 is a cross-sectional view showing a first relief valve according to the present invention.
4 is an exploded perspective view showing the first relief valve according to the present invention.
5 is an operation state diagram showing the mixing operation of the lactic acid bacteria powder and the powdered milk powder manufactured in the fluidized bed dryer according to the present invention.
6 is an enlarged view showing a second injection nozzle according to the present invention.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings illustrating preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, the present invention will be described in detail by describing preferred embodiments of the present invention with reference to the accompanying drawings. Like reference numerals in each figure indicate like elements.

Hereinafter, in this embodiment, the lactic acid bacteria powder is defined as a powder containing lactic acid bacteria, and in this embodiment, a lactic acid bacteria powder having a content ratio of lactic acid bacteria and white powder of 1.4%:98.4% may be used, but the scope of the present invention is limited to this is not limited by

On the other hand, the types of lactic acid bacteria used in this example are currently widely used commercially: reuteri, Lactobacillus, Bifidobacterium (Bifidobacterium), Streptococcus, There are conostoc (Leuconostoc), Pediococcus (Pediococcus), Lactococcus (Lactococcus) and the like, and these lactic acid bacteria can be used individually or in combination.

Lactobacillus relieves diarrhea symptoms when acute diarrhea occurs due to food poisoning bacteria or harmful bacteria, and has the effect of weakening the activity of harmful bacteria and reducing the production of intestinal putrefactive substances. In addition to inhibiting the growth of putrefactive bacteria in the intestine, lactic acid bacteria also suppresses the toxicity of harmful substances in the intestine, mainly produces vitamin B complex as a nutrient, and at the same time has great efficacy in lowering blood cholesterol level, anticancer action, and immune enhancement action. has been reported In addition, lactic acid bacteria are known to have the effect of improving digestion and absorption of proteins and fats, suppressing gastrointestinal disorders, and promoting peristalsis of the intestines and improving constipation.

1 is a structural diagram schematically showing a milk powder manufacturing system according to the present invention, FIG. 2 is a cross-sectional view showing a lactic acid bacteria powder supply unit according to the present invention, and FIG. 3 is a cross-sectional view showing a first relief valve according to the present invention, FIG. 4 is an exploded perspective view showing a first relief valve according to the present invention, FIG. 5 is an operation state diagram showing a mixing operation of lactic acid bacteria powder and manufactured powdered milk powder in a fluidized bed dryer according to the present invention, and FIG. 6 is a second view according to the present invention It is an enlarged view showing the injection nozzle.

Referring to FIG. 1 , a milk powder manufacturing system 100 capable of uniformly mixing lactic acid bacteria powder according to the present invention includes a fluidized bed dryer 500 for drying and cooling the powdered formula, and a fluidized bed dryer 500 with lactic acid bacteria powder. A lactic acid bacterium powder supply device 400 for uniformly mixing the powdered milk powder and lactic acid bacteria powder by spraying the air contained therein, an air supply device 200 for supplying compressed air, and a nitrogen supply device 300 for supplying nitrogen gas ) is included.

The milk powder manufacturing system 100 capable of uniformly mixing the lactic acid bacteria powder according to the present invention is manufactured by spraying air containing the lactic acid bacteria powder to the manufactured powdered milk powder dried and cooled in the fluidized bed dryer 500. to be uniformly mixed.

First, the air supply device 200 according to the present embodiment supplies compressed air to the lactic acid bacteria powder supply device 400 after the dehumidification and sterilization process. For example, air compressed to 6-7 bar pressure by an air compressor is removed and dehumidified by going through a number of filters and oil/water separators, and it is sterilized while going through a sterilization filter to which steam is supplied. do.

The air that has undergone the dehumidification and sterilization process described above is supplied to the lactic acid bacteria powder supply device 400 and the fluidized bed dryer 500 . And the air supplied from the air supply device 200 to the lactic acid bacteria powder supply device 400 passes through the lactic acid bacteria powder supply device 400 and is sprayed into the fluidized bed dryer 500 in a state containing the lactic acid bacteria powder.

And the nitrogen supply device 300 according to this embodiment removes foreign substances while passing through a plurality of filters, and maintains a stable pressure (for example, 7 atm (bar)) while passing through a plurality of pressure regulators, and lactic acid bacteria powder to be described later It is supplied to the storage tank 410 and the refill hopper 430 of the supply device 400 .

And the lactic acid bacteria powder supply device 400 according to this embodiment supplies a fixed amount of lactic acid bacteria powder to the fluidized bed dryer 500, and serves to spray the lactic acid bacteria powder into the powdered milk manufactured in the fluidized bed dryer 500 to be sprayed.

Lactobacillus powder supply device 400 is a storage tank 410 in which lactic acid bacteria powder is stored, a refill hopper 430 that receives lactic acid bacteria powder from the storage tank 410, and supplies a quantity of lactic acid bacteria powder from the refill hopper 430. It includes a receiving unit 450 for receiving and receiving, and a lactic acid bacteria powder supply unit 470 for supplying the air containing the lactic acid bacteria powder to the fluidized bed dryer (500).

The storage tank 410 according to this embodiment stores the lactic acid bacteria powder and supplies the lactic acid bacteria powder to the refill hopper 430 . The lactic acid bacteria powder is supplied to the refill hopper 430 through the control valve 417 provided at the lower part of the storage tank 410 .

And a plurality of vibrators 416 may be installed on the lower outer surface of the storage tank 410 so that the lactic acid bacteria powder accumulated in the storage tank 410 can fall or move toward the control valve 417 .

The storage tank 410 stores the lactic acid bacteria powder and has a tank body 411 having an opening thereon, and a first cover part that is rotatably installed on the upper portion of the tank body 411 to open and close the opening of the tank body 411 . (412), a second cover portion 413 rotatably installed on the first cover portion 412, and a third cover installed to surround the first cover portion 412 on the upper portion of the tank body 411 It includes a portion 414 and a second load cell 415 installed under the tank body 411 to check the amount of the lactic acid bacteria powder stored in the tank body 411 .

The tank body 411 accommodates the lactic acid bacteria powder, and is formed in a structure in which a thermal insulation material is embedded in order to prevent dew condensation due to a temperature difference between inside and outside. An opening into which the lactic acid bacteria powder is put is formed in the upper portion of the tank body 411 .

On the other hand, in order to check the amount of lactic acid bacteria powder accommodated in the tank body 411, a second load cell 415 is installed under the tank body 411. The operator can monitor the second load cell 415 to check the amount of lactic acid bacteria powder in the tank body 411 in real time, and accordingly, when it is insufficient, it is possible to supplement the lactic acid bacteria powder in the tank body 411 . In this embodiment, the lactic acid bacteria powder accommodated in the tank body 411 is about 60Kg.

In addition, first to third cover parts 412 , 413,414 are installed on the upper portion of the tank body 411 in which the opening is formed. The first cover part 412 is rotatably installed on the upper part of the tank body 411 to open and close the opening of the tank body 411 . When it is necessary to supplement the tank body 411 with the lactic acid bacteria powder, the first cover part 412 is rotated to open the opening, and then the lactic acid bacteria powder is put into the tank body 411 .

In addition, when the operator needs to check the inside of the tank body 411 , the inside of the tank body 411 can be checked by rotating the second cover part 413 installed on the first cover part 412 .

In addition, the third cover part 414 is installed on the upper part of the tank body 411 so as to surround the first cover part 412 to prevent the occurrence of dew condensation due to the temperature difference between the inside and outside of the tank body 411 .

On the other hand, in order to improve the preservation of the lactic acid bacteria powder accommodated in the tank body 411 and to prevent vacuum jamming that may occur inside the tank body 411 when the lactic acid bacteria powder is supplied to the refill hopper 430, the tank body 411 is Fill with nitrogen gas.

To this end, a first nitrogen supply passage P5 connecting the nitrogen supply device 300 and the tank body 411 in communication is provided, and the first nitrogen supply passage P5 includes a fourth flow control valve V4 and a fourth A flow meter F4 is provided. ^{In this embodiment, nitrogen gas having a flow rate of 0.36 m 3} /h (air reference) is supplied to the tank body 411 by adjusting the fourth flow rate control valve V4.

In addition, a second relief valve 650 is installed in the first nitrogen supply passage P5 so that the pressure of the nitrogen gas supplied to the tank body 411 is maintained constant. In this embodiment, the second relief valve 650 prevents the pressure of the nitrogen gas supplied to the tank body 411 from exceeding _{17.5 mmH 2 O.}

In addition, the refill hopper 430 according to this embodiment receives the lactic acid bacteria powder from the storage tank 410 and temporarily stores it, and serves to supply a quantity of the lactic acid bacteria powder to the receiving unit 450 .

In addition, a first load cell 431 is installed under the refill hopper 430 so that the operator can check the amount of lactic acid bacteria powder stored in the refill hopper 430 in real time. The operator monitors the first load cell 431 and, when the amount of lactic acid bacteria powder in the refill hopper 430 is insufficient, controls the control valve 417 provided at the lower part of the tank body 411 to put the lactic acid bacteria powder in the refill hopper 430. can be supplemented. In this embodiment, the amount of lactic acid bacteria powder supplied to the refill hopper 430 is 3.72Kg/h.

In addition, nitrogen gas is supplied to the refill hopper 430 to prevent vacuum jamming that may occur inside the refill hopper 430 and fill it.

To this end, a second nitrogen supply passage P6 connecting the nitrogen supply device 300 and the refill hopper 430 in communication is provided, and the second nitrogen supply passage P6 is branched from the first nitrogen supply passage P5. can be

The nitrogen gas supplied to the refill hopper 430 along the second nitrogen supply flow path P6 is supplied by the fourth flow control valve V4, the fourth flow meter F4, and the second relief valve 650 as described above. is adjusted

On the other hand, the receiving unit 450 according to the present embodiment receives and receives a quantity of lactic acid bacteria powder from the refill hopper 430 and serves to supply a quantity of lactic acid bacteria powder to the lactic acid bacteria powder supply unit 470 . That is, the receiving unit 450 maintains the quantity of the lactic acid bacteria powder contained in the air when the air is supplied and sprayed from the air supply device 200 to the lactic acid bacteria powder supply unit 470 .

The lactic acid bacteria powder accommodated in the receiving unit 450 is sucked into the lactic acid bacteria powder supply unit 470 by the venturi effect when air is sprayed from the lactic acid bacteria powder supply unit 470 .

And referring to Figure 2, the lactic acid bacteria powder supply unit 470 according to this embodiment is connected to the receiving unit 450 on one side in communication with the main body portion 471 connected in communication with the air supply device 200 on the other side and , It is coupled to communicate with the body portion 471 includes a first injection nozzle 473 for spraying air containing the lactic acid bacteria powder.

One side of the main body 471 is connected in communication with the receiving unit 450 disposed on the upper portion to receive lactic acid bacteria powder from the receiving unit 450 , and the other side of the main body 471 communicates with the air supply device 200 . connected to be supplied with air from the air supply device 200 . In this embodiment, a first air flow path P1 connecting the other side of the main body 471 and the air supply device 200 in communication with each other is provided.

And the air supplied to the other side of the body portion 471 is injected toward the fluidized bed dryer 500 to be described later through the first injection nozzle 473 coupled to the body portion 471, through the first injection nozzle 473. When air is sprayed, the lactic acid bacteria powder accommodated in the receiving unit 450 is mixed with the air sprayed by the venturi effect and sprayed together.

The first spray nozzle 473 uses the venturi effect to spray air containing the lactic acid bacteria powder to the fluidized bed dryer 500, so the lactic acid bacteria powder is sprayed in the fluidized bed dryer 500 to smoothly mix with the powdered milk powder. can do.

And the first air flow path (P1) is provided with a first flow rate control valve (V1) and a first flow meter (F1). ^{In this embodiment, air having a flow rate of 137.78 m 3} /h (air reference) is supplied to the main body 471 by adjusting the first flow rate control valve V1.

On the other hand, when the air is injected through the first injection nozzle 473, the lactic acid bacteria powder accommodated in the accommodation unit 450 by the venturi effect is sucked into the first injection nozzle 473 and injected together with the air, thereby receiving A vacuum may be applied to the unit 450 , and when a vacuum is applied to the receiving unit 450 , there is a problem in that the movement of the lactic acid bacteria powder from the receiving unit 450 to the first injection nozzle 473 is not smooth. Accordingly, in the present embodiment, air is supplied to the accommodation unit 450 to prevent the vacuum jamming phenomenon from occurring in the accommodation unit 450 .

In the present embodiment, a second air flow path P2 connecting the air supply device 200 and the accommodation unit 450 in communication with each other is provided. In addition, a second flow control valve (V2) and a second flow meter (F2) are provided in the second air flow path (P2). ^{In this embodiment, air having a flow rate of 5.0 m 3} /h (air reference) is supplied to the receiving unit 450 by adjusting the second flow rate control valve V2.

In addition, a first relief valve 600 is installed in the second air flow path P2 so that the pressure of the air supplied to the container is maintained constant. In this embodiment, the first relief valve 600 prevents the pressure of the air supplied to the receiving container from exceeding _{25mmH 2 O.}

3 and 4, the first relief valve 600 according to the present embodiment is connected to the second air flow path P2 in communication with the air supplied along the second air flow path P2 is introduced, and the center The valve body 610 having a plurality of partition walls 613 spaced apart from each other in a radial direction and continuously formed along the circumferential direction and a groove portion 612 having a plurality of through holes 614 penetrating the partition wall 613 in the radial direction is formed in the valve body 610 ) and a sealing plate 620 that is seated on the upper surface of the valve body 610 and supported by a plurality of bulkheads 613 and seals the upper surface of the valve body 610, and is seated on the upper surface of the sealing plate 620 The pressure plate 630 and the valve housing 640 seated on the upper surface of the pressure plate 630 and formed in a shape surrounding the valve body 610, the sealing plate 620 and the pressure plate 630, the lower surface of which is open.

A groove 612 is formed in the valve body 610 and an air inlet hole 611 through which air is introduced is formed in the center. In addition, a plurality of partition walls 613 spaced apart from the center in the radial direction and continuously formed in the circumferential direction are formed in the groove portion 612 of the valve body 610 . In addition, a plurality of through-holes 614 penetrating the partition walls 613 in a radial direction are formed in the plurality of partition walls 613 . The air introduced into the air inlet hole 611 is uniformly distributed inside the groove 612 along the through hole 614 formed in the partition wall 613 and is seated on the sealing plate 620 and the pressure plate 630. pressure evenly across the

And the pressure is adjusted by the weight of the sealing plate 620, the pressure plate 630, and the valve housing 640, which are sequentially seated on the upper part of the valve body 610. That is, when the air pressure introduced into the valve body 610 exceeds the weight of the sealing plate 620, the pressure plate 630 and the valve housing 640, the sealing plate 620, the pressure plate from the upper surface of the valve body 610 630 and the valve housing 640 are spaced apart, the excess pressure is discharged to the open lower surface of the valve housing 640, the air pressure is adjusted.

Meanwhile, since the configuration of the first relief valve 600 is the same as that of the aforementioned second relief valve 650 , a detailed description of the second relief valve 650 will be omitted.

On the other hand, the lactic acid bacteria powder supply device 400 according to the present invention may further include an ionizer (ionizer, 490) provided in the first air flow path (P1) to prevent fire due to static electricity. The air supplied along the first air passage P1 passes through the ionizer 490 and is then supplied to the other side of the main body 471 of the lactic acid bacteria powder supply unit 470 .

As described above, the lactic acid bacteria powder supply unit 470 supplies the air containing the lactic acid bacteria powder to the fluidized bed dryer 500 .

1, 5 and 6, the fluidized bed dryer 500 according to the present embodiment dries and cools the powdered formula, and uniformly distributes the lactic acid bacteria powder supplied from the lactic acid bacteria powder supply device 400 with the formula powder. plays a role in mixing.

The fluidized bed dryer 500 includes a dryer body 510 for drying and cooling the powdered formula, a vibration motor 550 mounted on the lower surface of the dryer body 510, and both sides of the dryer body 510. It includes a spring bracket 570 and a second injection nozzle 530 that is installed on the upper portion of the dryer body 510 in which the infant formula outlet 512 is formed and sprays the air containing the lactic acid bacteria powder downward.

An infant formula supply port 511 through which formula powder is supplied is formed at one upper end of the dryer body 510, and the dried and cooled formula powder is discharged at the other lower end of the dryer body 510. The powdered milk outlet 512 is formed, and a damper 517 protruding upward from the bottom is formed in front of the infant formula outlet 512 . In this embodiment, the amount of formula powder supplied to the infant formula supply port 511 is 3100Kg/h, and the infant formula powder flowing into the infant formula supply port 511 has a temperature of about 65° C., and the relative humidity is about 4.5%. to be.

A perforation is formed in the inner bottom surface of the dryer body 510 to allow air to pass therethrough, and when it operates on the vibration motor 550 mounted on the lower surface of the dryer body 510 , a spring bracket mounted on the lower surface of the dryer body 510 . By the inclination angle of 570 , the powdered formula inside the dryer body 510 is floated 5 to 10 mm from the bottom surface of the dryer body 510 and is advanced in the direction of the formula outlet 512 . The infant formula powder is laminated on the inner bottom surface of the dryer body 510 to a thickness corresponding to the height of the damper 517 protruding from the inner bottom surface of the dryer body 510 .

And while the powdered formula powder advances in the direction of the formula outlet 512, the high temperature supplied through the first dry air supply port 514 and the second dry air supply port 515 formed in the lower part of the dryer body 510. The powdered formula is dried and cooled through dry air and low-temperature dry air. Accordingly, the powdered formula powder discharged to the formula outlet 512 has a temperature of about 30° C. and the relative humidity is about 2.5 to 3.0%. Meanwhile, a plurality of air outlets 516 are formed on the upper portion of the dryer body 510 .

On the other hand, the powdered formula that has undergone the drying and cooling process as described above is floated upward by the damper 517 formed in front of the infant formula outlet 512 and falls along the slope of the infant formula outlet 512 in a thinly spread state. do.

As such, in this embodiment, the infant formula powder falling to the infant formula outlet 512 floats to the top and spreads thinly, and the lactic acid bacteria powder is sprayed on the thinly spread formula powder so that the formula powder and the lactic acid bacteria powder are uniformly mixed.

To this end, the second injection nozzle 530 according to the present embodiment is installed on the upper portion of the dryer body 510 in which the infant formula outlet 512 is formed, and the air containing the lactic acid bacteria powder through the first injection nozzle 473 . is supplied and the air containing the lactic acid bacteria powder is sprayed downward in the direction of the powdered formula, so that the powdered milk powder and the lactic acid bacteria powder are uniformly mixed.

5 and 6, the second injection nozzle 530 receives the air containing the lactic acid bacteria powder from the first injection nozzle 473 and sprays it, but the nozzle body 531 has an increased cross-sectional area in the longitudinal direction. ) and an air supply port arranged to surround the nozzle body 531 and receiving air from the air supply device 200 on the side so that the air containing the lactic acid bacteria powder sprayed from the nozzle body 531 forms a swirling flow ( 534 includes a nozzle housing 533 formed thereon.

The nozzle body 531 is formed in a cone-shaped diffuser shape in which the cross-sectional area increases downward so that the air containing the lactic acid bacteria powder is sprayed in the form of a spray from the upper portion of the formula outlet 512 .

And while the air containing the lactic acid bacteria powder sprayed from the nozzle body 531 is sprayed downward, air is supplied to the side of the nozzle housing 533 so that the spraying speed is prevented from being lowered so that it comes into contact with the formula powder in a short time. . And the air supply port 534 is eccentrically disposed with respect to the center of the nozzle housing (533).

That is, the air supplied to the side of the nozzle housing 533 is rotated between the inner surface of the nozzle housing 533 and the outer surface of the nozzle body 531 and is sprayed to the upper part of the formula outlet 512, so that the air is sprayed from the nozzle body 531. The air containing the lactic acid bacteria powder turns in a cone shape, and it is sprayed downward in the form of enclosing the air containing the lactic acid bacteria powder.

In the nozzle body 531 while the powdered formula powder containing moisture with a relative humidity of about 2.5 to 3.0% is floated upward by the damper 517 and is dropped along the inclined surface of the formula outlet 512 in a thinly spread state. Lactobacillus powder with strong hygroscopic properties is adsorbed and mixed with formula powder.

And the powdered formula powder to which the lactic acid bacteria powder is adsorbed is more uniformly mixed while passing through at least one mesh network 513 installed to be spaced apart in the height direction at the formula outlet 512 .

On the other hand, in this embodiment, the nozzle body 531 of the first injection nozzle 473 and the second injection nozzle 530 to supply the air containing the lactic acid bacteria lactic acid bacteria powder to the nozzle body 531 of the second injection nozzle 530 . ) is provided with a powder supply flow path (P4) that connects to each other in communication.

Meanwhile, in this embodiment, a metal spring S is wound around the outer surface of the powder supply passage P4 to prevent fire due to static electricity and is grounded.

And, a third air flow path connecting the air supply device 200 and the nozzle housing 533 of the second nozzle body 531 to communicate with each other so as to supply air to the nozzle housing 533 of the second nozzle body 531 ( P3) is provided.

And the third air flow path (P3) is provided with a third flow rate control valve and a third flow meter (F3). ^{In this embodiment, air having a flow rate of 231.3 m 3} /h (air reference) is supplied to the nozzle housing 533 by adjusting the third flow control valve V3.

As such, the present invention is not limited to the described embodiments, and it is apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Accordingly, it should be said that such modifications or variations are included in the claims of the present invention.

100: milk powder manufacturing system 200: air supply device
300: nitrogen supply device 400: lactic acid bacteria powder supply device
410: storage tank 411: tank body
412: first cover portion 413: second cover portion
414: third cover part 415: second load cell
416: vibrator 417: control valve
430: refill hopper 431: first load cell
450: receiving unit 470: lactic acid bacteria powder supply unit
471: body portion 473: first injection nozzle
490: ionizer 500: fluidized bed dryer
510: dryer body 511: formula supply port
512: formula outlet 513: mesh network
514: first dry air supply port 515: second dry air supply port
516: air outlet 517: damper
530: second injection nozzle 531: nozzle body
533: nozzle housing 534: air inlet
550: vibration motor 570: spring bracket
600: first relief valve 610: valve body
611: air inlet 612: groove portion
613: bulkhead 614: through hole
620: sealing plate 630: pressure plate
640: valve housing 650: second relief valve

Claims (15)

a fluidized bed dryer for drying and cooling the powdered formula; and
A lactic acid bacteria powder supply device for supplying the lactic acid bacteria powder to the fluidized bed dryer so that the powdered milk powder and the lactic acid bacteria powder are uniformly mixed,
The lactic acid bacteria powder supply device,
a storage tank in which the lactic acid bacteria powder is stored;
a refill hopper receiving the lactic acid bacteria powder from the storage tank;
a receiving unit provided in communication with the refill hopper and receiving and accommodating a quantity of the lactic acid bacteria powder from the refill hopper; and
The accommodating unit is connected to one side in communication and the air supply device for supplying air to the other side is connected in communication with the main body part and the main body part is connected in communication to spray air, but the lactic acid bacteria powder accommodated in the receiving unit is a venturi effect A milk powder manufacturing system capable of uniformly mixing lactic acid bacteria powder, comprising a lactic acid bacteria powder supply unit for supplying air containing the lactic acid bacteria powder to the fluidized bed dryer by having a first injection nozzle mixed with the air sprayed by the .
According to claim 1,
A first air flow path connecting the air supply device and the other side of the main body in communication with the other side of the main body is provided so as to supply air to the other side of the main body,
When the air containing the lactic acid bacteria powder is sprayed through the first injection nozzle, the air supply device and the receiving unit are connected in communication with each other to supply air to the receiving unit in order to prevent a vacuum from being applied to the receiving unit A milk powder manufacturing system capable of uniformly mixing lactic acid bacteria powder provided with a second air flow path.
3. The method of claim 2,
A milk powder manufacturing system capable of uniformly mixing lactic acid bacteria powder in which a first relief valve for maintaining a constant pressure of air supplied to the accommodation unit is installed in the second air flow path.
4. The method of claim 3,
The first relief valve,
Connected in communication with the second air flow path, air supplied along the second air flow path flows in, and a plurality of partition walls spaced from the center in a radial direction and continuously formed along the circumferential direction and radially passing through the partition wall a valve body in which a groove portion having a plurality of through holes is formed;
a sealing plate seated on the upper surface of the valve body and supported by a plurality of the bulkheads and sealing the upper surface of the valve body;
a pressure plate seated on the upper surface of the sealing plate; and
A milk powder manufacturing system capable of uniformly mixing lactic acid bacteria powder, which is seated on the upper surface of the pressure plate and includes a valve housing having a shape surrounding the valve body, the sealing plate, and the pressure plate and having an open lower surface.
3. The method of claim 2,
The lactic acid bacteria powder supply device,
A milk powder manufacturing system capable of uniformly mixing lactic acid bacteria powder further comprising an ionizer provided in the first air flow path to prevent static electricity.
According to claim 1,
The lactic acid bacteria powder supply device,
The milk powder manufacturing system capable of uniformly mixing the lactic acid bacteria powder further comprising a first load cell installed under the refill hopper to confirm the amount of the lactic acid bacteria powder stored in the refill hopper.
According to claim 1,
The fluidized bed dryer,
An infant formula supply port through which the powdered formula is supplied is formed at one end, and an infant formula outlet through which the dried and cooled infant formula powder is discharged is formed at the other end. a dryer body with a damper protruding into the; and
The lactic acid bacteria powder is installed on the upper portion of the dryer body in which the infant formula outlet is formed and is connected to the first injection nozzle so that the powdered formula powder and the lactic acid bacteria powder are uniformly mixed and supplied through the first injection nozzle A milk powder manufacturing system capable of uniformly mixing lactic acid bacteria powder including a second injection nozzle that sprays the contained air downward.
8. The method of claim 7,
The second injection nozzle,
a nozzle body receiving the air containing the lactic acid bacteria powder from the first injection nozzle and spraying the nozzle body having an increased cross-sectional area along the longitudinal direction; and
Lactic acid bacteria powder disposed to surround the nozzle body and comprising a nozzle housing having an air supply port receiving air from the air supply device on the side so that the air containing the lactic acid bacteria powder sprayed from the nozzle body forms a swirling flow. A milk powder manufacturing system that can uniformly mix
9. The method of claim 8,
A third air flow path connecting the air supply device and the nozzle housing in communication with the nozzle housing is provided to supply air to the nozzle housing,
A milk powder manufacturing system capable of uniformly mixing lactic acid bacteria powder in which a powder supply passage connecting the first injection nozzle and the nozzle body is provided in communication with the nozzle body to supply the air containing the lactic acid bacteria powder to the nozzle body.
10. The method of claim 9,
A milk powder manufacturing system capable of uniformly mixing the lactic acid bacteria powder that is wound and grounded on the outer surface of the powder supply passage.
8. The method of claim 7,
A milk powder manufacturing system capable of uniformly mixing lactic acid bacteria powder in which at least one mesh network is installed to be spaced apart from each other in the height direction at the infant formula outlet.
According to claim 1,
The storage tank is
a tank body in which the lactic acid bacteria powder is stored, a thermal insulation material is built in, and an opening is formed in the upper part;
a first cover part rotatably installed on the upper part of the tank body to open and close the opening of the tank body;
a second cover part which is rotatably installed on the first cover part and enables confirmation of the inside of the tank body; and
A milk powder manufacturing system capable of uniformly mixing lactic acid bacteria powder including a third cover part installed to surround the first cover part on the upper part of the tank body.
13. The method of claim 12,
The storage tank is
The milk powder manufacturing system capable of uniformly mixing the lactic acid bacteria powder further comprising a second load cell installed in the lower part of the tank body to check the amount of the lactic acid bacteria powder stored in the tank body.
According to claim 1,
The milk powder manufacturing system capable of uniformly mixing lactic acid bacteria powder further comprising a nitrogen supply device for supplying nitrogen gas to the storage tank and the refill hopper to form a positive nitrogen pressure in the storage tank and the refill hopper.
15. The method of claim 14,
A first nitrogen supply passage connecting the nitrogen supply device and the storage tank in communication with the storage tank is provided to supply nitrogen gas to the storage tank,
A second nitrogen supply flow path is provided for connecting the nitrogen supply device and the refill hopper in communication with the refill hopper to supply nitrogen gas,
A milk powder manufacturing system capable of uniformly mixing lactic acid bacteria powder in which a second relief valve for maintaining a constant pressure of nitrogen gas supplied to the storage tank is installed in the first nitrogen supply passage.

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