KR102463565B1 - An eco-friendly laundry detergent composition containing a post-biotic component and a laundry detergent composition manufacturing device for manufacturing an eco-friendly laundry detergent composition containing the post-biotic component - Google Patents

Abstract

The present invention relates to an eco-friendly laundry detergent composition containing a postbiotic mixture and a laundry detergent composition manufacturing apparatus for manufacturing the same. The eco-friendly laundry detergent composition, according to the present invention, comprises a postbiotic mixture formed by mixing a first lactic acid bacteria raw material, a second lactic acid bacteria raw material, and a third lactic acid bacteria raw material. Therefore, the washing effect can be improved so that not only contaminants but also fine dust can be removed.

Description

An eco-friendly laundry detergent composition containing a post-biotic component and a laundry detergent composition manufacturing device for manufacturing an eco-friendly laundry detergent composition containing the post-biotic component}

The present invention relates to an eco-friendly laundry detergent composition containing a postbiotic mixture and an apparatus for manufacturing the laundry detergent composition for the same.

Laundry refers to removing contaminants from the laundry, such as clothes.

The contaminants become discharges such as sebum and sweat discharged from the body of the wearer who wears the laundry, or dust and oil that are outside and are caught between the minute gaps in the laundry, and the laundry detergent is composed of a surfactant In general, the contaminants are removed from the laundry contaminated by the contaminants by being put in a washing machine together with the laundry to separate the contaminants from the laundry.

Those of the patent literature presented below that can be presented as examples of such laundry detergents.

However, conventional laundry detergents including the following patent documents are made of chemical substances, and if all of the laundry detergent is not removed from the laundry and remains, it comes into contact with the skin of the wearer who wears the laundry, which has been washed, and causes skin troubles. Eco-friendly laundry detergent composition that can cause not only non-toxicity but also improve washing effect because it causes or aggravates water pollution by being thrown into sewage in a state where the laundry detergent is mixed with the water used to wash the laundry Although various studies on manufacturing have been conducted, the development of an eco-friendly laundry detergent is actively progressing, but a solution for improving the washing effect is still unclear.

In addition, in the prior art, it is necessary to homogeneously mix the eco-friendly raw materials constituting the eco-friendly laundry detergent composition in order to manufacture the eco-friendly laundry detergent composition. As the various eco-friendly raw materials are stirred by a simple stirring device, the eco-friendly laundry detergent composition is Although they were stirred together in the stirring device, there was a problem in that the washing effect was different.

Patent Publication No. 10-2018-0007521, Publication Date: 2018.01.23., Title of the Invention: Eco-friendly cleaning composition and manufacturing method thereof Registered Patent No. 10-0436171, Registration Date: 2004.06.04., Title of Invention: Tablet-type detergent composition and manufacturing method thereof

The present invention is called fourth-generation biotics, and contains Post-Biotics, which are metabolites of lactic acid bacteria produced by lactic acid bacteria that are beneficial to humans. An object of the present invention is to provide an eco-friendly laundry detergent composition containing a postbiotic mixture capable of improving the effect.

Another object of the present invention is to provide an apparatus for manufacturing a laundry detergent composition for manufacturing an eco-friendly laundry detergent composition containing a postbiotic mixture that homogeneously mixes the postbiotic mixture constituting the eco-friendly laundry detergent composition.

The apparatus for manufacturing a laundry detergent composition according to one aspect of the present invention is for manufacturing an eco-friendly laundry detergent composition containing a postbiotic mixture, -biotics) The first lactic acid bacteria raw material obtained by fermenting Lactobacillus acidophilus to form a mixture and centrifugation, and Lactobacillus casei obtained by fermenting Lactobacillus casei, followed by centrifugation 2 a post-biotic mixture generator for mixing lactic acid bacteria raw materials and a third lactic acid bacteria raw material obtained by fermenting Lactobacillus rhamnosus and then centrifuging; and a composition accommodating member connected to the postbiotic mixture generator and capable of accommodating the eco-friendly laundry detergent composition containing the postbiotic mixture, wherein the postbiotic mixture generator is disposed on an upper portion of the composition accommodating member. A mixture mixing unit installed to mix the postbiotic mixture, a first lactic acid bacteria raw material inlet pipe connected to the mixture mixing unit to supply the first lactic acid bacteria raw material into the mixture mixing unit, and the mixture mixing unit Doedoe, the first lactic acid bacteria raw material inlet pipe and a second lactic acid bacteria raw material inlet pipe for supplying the second lactic acid bacteria raw material into the interior of the mixture is separated from the inlet pipe, and connected to the mixture mixing unit, the first lactic acid bacteria raw material an inlet pipe and a third lactic acid bacteria raw material inlet pipe arranged to be spaced apart from the inlet pipe and the second lactic acid bacteria raw material inlet pipe, and supplying the third lactic acid bacteria raw material into the mixture mixing unit, wherein the mixture mixing unit is the composition accommodating member A mixing case member that is formed in an empty shape while standing on the top, and the first lactic acid bacterium raw material inlet pipe, the second lactic acid bacterium raw material inlet pipe and the third lactic acid bacterium raw material inlet pipe are spaced apart and connected to each other, and the mixing An upper diffusion member disposed to face the first lactic acid bacteria raw material inlet pipe inside the case member and diffusing the first lactic acid bacteria raw material supplied through the first lactic acid bacteria raw material inlet pipe to the entire upper part of the mixing case member; Among the mixing case members, the first lactic acid bacteria raw material is formed in a curved shape with a predetermined curvature, respectively, at both corners of the upper end to which the first lactic acid bacteria raw material inlet pipe is connected, and the first lactic acid bacteria raw material diffused by the upper diffusion member is the lower inner side of the mixing case member. The curved edge portion to be guided to, and the second lactic acid bacteria raw material inlet pipe is connected to spray the second lactic acid bacteria raw material, so that the first lactic acid bacteria raw material and the second lactic acid bacteria raw material can be mixed at the curved edge portion each A curved corner-directed injection nozzle member capable of spraying the second lactic acid bacteria raw material in a sector shape of a predetermined range toward the curved corner portion, and formed in the central portion of one side of the mixing case member, as the lower side of the mixing case member moves toward the lower side of the mixing case member, the mixing Formed in the shape of a curved surface that gradually protrudes toward the inside of the case member, the mixed material of the first lactic acid bacteria raw material and the second lactic acid bacteria raw material falling along one side of the mixing case member toward the inner space of the mixing case member One side of the drop-inducing curved body for inducing, and the other side of the mixing case member is formed from the central portion to the lower portion of the mixing case member, a curved surface that gradually protrudes toward the inside of the mixing case member toward the lower side of the mixing case member The other side drop-inducing curved body for guiding the mixed material of the first lactic acid bacteria raw material and the second lactic acid bacteria raw material falling along the other side of the mixing case member toward the inner space of the mixing case member, and the mixing case member Installed in the lower corner of one side, the first lactic acid bacterium raw material and the second lactic acid bacterium raw material induced along the one-side fall-inducing curved body and the other-side fall-inducing curved body, respectively, the mixed material of the first lactic acid bacterium raw material and the second lactic acid bacterium raw material, the one-side fall-inducing curved body and the other side fall-inducing An inner space-side diffusion member for diffusing into the entire inner space of the mixing case member while backflowing into a curved body, and connected to the third lactic acid bacteria raw material inlet pipe to spray the third lactic acid bacteria raw material, to the inner space-side diffusion member The inner space of the mixing case member including the surface of the one-side fall-inducing curved body and the other-side fall-inducing curved body so that the mixed material of the first lactic acid bacteria raw material and the second lactic acid bacteria raw material and the third lactic acid bacteria raw material are mixed a centrally directed injection nozzle member capable of spraying the third lactic acid bacteria raw material in a predetermined sector shape toward the The postbiotic mixture formed by mixing the first lactic acid bacteria raw material, the second lactic acid bacteria raw material, and the third lactic acid bacteria raw material inside the mixing case member is discharged into the composition accommodating member, toward the composition accommodating member. and a discharge pipe formed in a direction to be relatively spaced apart from the inner space-side diffusion member toward the other side of the drop-inducing curved body, wherein the upper diffusion member rotates the rotation shaft disposed toward the first lactic acid bacteria raw material inlet tube. A diffusion rotation means, and the central portion is connected to the rotation shaft of the upper diffusion rotation means, from the central portion connected to the rotation shaft of the upper diffusion rotation means toward the outer side of the upper side formed in a curved shape that gradually rises toward the curved edge portion A diffusion curved body and an upper diffusion protrusion protruding from the center of the upper diffusion curved body toward the first lactic acid bacterium raw material inflow pipe, connected to the surface of the upper diffusion curved body by a curved surface, and integral with the upper diffusion curved body; The upper diffusion lifting piston connected to the lower side of the upper diffusion rotating means, and the upper diffusion lifting piston connected to the upper diffusion rotating means are relatively close to or relatively far from the upper inner surface of the mixing case member. and an upper diffusion raising/lowering means that causes the upper diffusion and lifting means to be lifted and lowered by the upper diffusion raising/lowering means and placed in a preset position, and the upper diffusion curved body and the upper diffusion protrusion are integrated with the upper diffusion rotating means by the upper diffusion rotating means In the rotating state, when the first lactic acid bacteria raw material is supplied through the first lactic acid bacteria raw material inlet pipe, the first lactic acid bacteria raw material is spread over the entire upper diffusion curved body by the upper diffusion protrusion, and then the upper diffusion curved body is spread over the entire upper portion of the mixing case member, and the curved edge-directed injection nozzle member protrudes from the second lactic acid bacteria raw material inlet pipe toward the curved edge. The curved surface corner-directed injection nozzle body connected in a curved shape, and formed on the surface of the curved corner-direction injection nozzle body, so that the second lactic acid bacterium raw material can be sprayed in a sector shape of a predetermined range toward the curved corner portion. A plurality of curved corner-directed radial injection holes are arranged radially in a predetermined range toward the corner, and the inner space-side diffusion member is a rotating shaft disposed toward the one formed above the third lactic acid bacteria raw material inlet pipe among the curved corners. an inner space-side diffusion rotation means for rotating the inner space-side diffusion rotation means, the central portion of which is connected to the rotation shaft of the inner space-side diffusion rotation means, and progressively toward the outside from the central portion connected to the rotation shaft of the inner space-side diffusion rotation means The inner space-side diffusion curved body formed in a shape rising toward the one-side fall-inducing curved body and the other-side fall-inducing curved body, and from the center of the inner space-side diffusion curved body to the upper side of the third lactic acid bacteria raw material inflow pipe among the curved corners and an inner space-side diffusion protrusion that protrudes toward the formed one, and is connected to the surface of the inner space-side diffusion curved body by a curved surface and is integral with the inner space-side diffusion curved body, wherein the inner space-side diffusion rotating means enables the inner space side diffusion rotating means As the space-side diffusion curved body and the inner space-side diffusion protrusion are integrally rotated, the mixed material of the first lactic acid bacteria raw material and the second lactic acid bacteria raw material flowing along the one-side fall-inducing curved body and the other-side fall-inducing curved body is formed in the inner space. The one side of the fall-inducing curved body and the other side of the falling-inducing curved body flow backward by the side diffusion curved body, and are diffused into the inner space of the mixing case member, and diffused into the inner space of the mixing case member by the inner space-side diffusion member. The mixed material of the first lactic acid bacteria raw material and the second lactic acid bacteria raw material is mixed with the third lactic acid bacteria raw material supplied through the third lactic acid bacteria raw material inlet pipe in the inner space of the mixing case member, The embossed injection nozzle member is formed in the centrally directed injection nozzle body connected in a protruding form from the third lactic acid bacteria raw material inflow pipe toward the inner space of the mixing case member, and is formed on the centrally directed injection nozzle body, the third lactic acid bacteria and a plurality of centrally oriented radial injection holes arranged radially in a predetermined range toward the inner space of the mixing case member so that the raw material can be sprayed in a sector shape of a predetermined range toward the inner space of the mixing case member. do.

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According to the environment-friendly laundry detergent composition containing the postbiotic mixture and the apparatus for manufacturing the laundry detergent composition for manufacturing the same according to an aspect of the present invention, the environment-friendly laundry detergent composition containing the postbiotic mixture is Lactobacillus acidophilus (Lactobacillus acidophilus) The first lactic acid bacteria raw material obtained by centrifugation after fermentation, the second lactic acid bacteria raw material obtained by fermenting Lactobacillus casei and then centrifuging, and Lactobacillus rhamnosus (Lactobacillus rhamnosus) As the third lactic acid bacteria raw material obtained by fermenting and centrifuging includes a post-biotics mixture formed by mixing with each other, it is eco-friendly and improves the washing effect so that not only contaminants but also fine dust can be removed. can have an effect.

According to another aspect of the present invention, an eco-friendly laundry detergent composition containing a postbiotic mixture and a laundry detergent composition manufacturing apparatus for manufacturing the same, the laundry detergent composition manufacturing apparatus includes a postbiotic mixture generator and a composition receiving member and the postbiotic mixture generator includes a mixture mixing unit, a first lactic acid bacteria raw material inlet pipe, a second lactic acid bacteria raw material inlet pipe, and a third lactic acid bacteria raw material inlet pipe, wherein the mixture mixing unit includes a mixing case member, The upper diffusion member, the curved edge portion, the curved edge direction injection nozzle member, one side of the drop guide curved body, the other side of the falling guide curved body, the inner space side diffusion member, the central jet nozzle member, and the discharge pipe. , there is an effect that the postbiotic mixture constituting the eco-friendly laundry detergent composition containing the postbiotic mixture can be homogeneously mixed.

1 is a view showing the appearance of a laundry detergent composition manufacturing apparatus according to an embodiment of the present invention.
Figure 2 is an enlarged cross-sectional view of a part of the interior of the laundry detergent composition manufacturing apparatus according to an embodiment of the present invention.

Hereinafter, an eco-friendly laundry detergent composition containing a postbiotic mixture according to embodiments of the present invention and an apparatus for manufacturing the laundry detergent composition will be described with reference to the drawings.

1 is a view showing the appearance of an apparatus for manufacturing a laundry detergent composition according to an embodiment of the present invention, and FIG. 2 is an enlarged cross-sectional view of a part of the interior of the apparatus for manufacturing a laundry detergent composition according to an embodiment of the present invention.

1 and 2 together, the eco-friendly laundry detergent composition containing the postbiotic mixture according to this embodiment is a first lactic acid bacteria obtained by fermenting Lactobacillus acidophilus and then centrifuging A raw material, a second lactic acid bacterium raw material obtained by centrifugation after fermenting Lactobacillus casei, and a third lactic acid bacterium raw material obtained by fermenting Lactobacillus rhamnosus and then centrifuging are mixed with each other Contains a post-biotics mixture formed by

The Lactobacillus acidophilus has an accession number of KCTC 3142, which is a kind of lactic acid bacilli of probiotics, is acid-resistant, has intestinal action, anti-cancer effect, lowering blood cholesterol, and has the ability to synthesize vitamin B group.

The Lactobacillus casei has an accession number of KCTC 3109, and is an anaerobic microorganism of the genus Lactobacillus found in the intestine or mouth of a person, and is isolated from milk and cheese.

The Lactobacillus rhamnosus has an accession number of KCTC 5033, and is used as a raw material for health functional food that helps in lactic acid bacteria proliferation, suppression of harmful bacteria, and defecation activity.

In the postbiotic mixture, the first lactic acid bacteria raw material, the second lactic acid bacteria raw material, and the third lactic acid bacteria raw material are mixed in a weight ratio of 1:1:1.

In this embodiment, when the Lactobacillus acidophilus, the Lactobacillus casei, and the Lactobacillus rhamnosus are fermented, mixed nutrients are supplied, respectively.

The mixed nutrients consist of a mixture of fructooligosaccharide, galactooligosaccharide, and maltooligosaccharide.

In detail, the first lactic acid bacteria raw material is the Lactobacillus acidophilus strain, and the fructooligosaccharide, the galactooligosaccharide, and the maltooligosaccharide are mixed under anaerobic fermentation conditions by supplying the mixed nutrients in the fermenter at 30 to 50 ° C. It is obtained by growing under the conditions of 3 to 8 days, then separating each component using a centrifuge, lyophilizing the separated component formed on the upper layer, concentrating it, and pulverizing it.

The second lactic acid bacteria raw material is the Lactobacillus casei strain and the fructooligosaccharide, the galactooligosaccharide, and the maltooligosaccharide are mixed under anaerobic fermentation conditions by supplying the mixed nutrients in the fermenter at 30 to 50 ° C. After growing for 8 days, each component is separated using a centrifuge, and the separated component formed on the upper layer is freeze-dried, concentrated, and then pulverized.

The third raw material for lactic acid bacteria is the Lactobacillus rhamnosus strain and the fructooligosaccharide, the galactooligosaccharide, and the maltooligosaccharide are mixed under anaerobic fermentation conditions by supplying the mixed nutrients in the fermenter at 30 to 50 ° C. After growing for 8 days, each component is separated using a centrifuge, and the separated component formed on the upper layer is freeze-dried, concentrated, and then pulverized.

Here, the anaerobic fermentation condition is a condition in which oxygen is removed so that the microorganisms obtain energy by decomposing organic matter.

In this embodiment, the postbiotic mixture may be included in an amount of 0.01 to 5 parts by weight based on 100 parts by weight of the eco-friendly laundry detergent composition containing the postbiotic mixture.

Hereinafter, a manufacturing experimental example for the eco-friendly laundry detergent composition containing the postbiotic mixture according to this embodiment will be described.

The constituent materials of the manufacturing experimental example for the eco-friendly laundry detergent composition containing the postbiotic mixture according to this embodiment are as shown in Table 1 below, and Comparative Example 1 for comparison is also shown in Table 1 below.

Experimental Example Components (Unit: %) ingredient Experimental Example 1 Experimental Example 2 Experimental Example 3 Comparative Example 1 Sodium Laureth Sulfate (28%) 10 10 10 10 straight chain alkylbenzenesulfonic acid 3 3 3 3 NaOH (50%) 1.0 1.0 1.0 1.0 citric acid 0.05 0.05 0.05 0.05 Methylparaben 0.3 0.3 0.3 0.3 Postbiotic Blend 5.0 2.0 0.5 - Purified water to 100% to 100% to 100% to 100%

In accordance with KS M 2709 8.1 Method for Evaluation of Detergent Power of Synthetic Detergents for Clothing, the soiled cloth was washed with the laundry detergents prepared in the Experimental Examples and Comparative Examples shown in Table 1 above, and the washing effect was visually evaluated. .

The visual evaluation of the washing of the stained fabric was evaluated by a total of 5 people on a 5-point scale (1. No washing, 2. Weak, 3. Normal, 4. Excellent, 5. Very good), and the results are shown in Table 2 below. same as

Visual evaluation result for dirty cloth washing
Experimental Example 1 Experimental Example 2 Experimental Example 3 Comparative Example 1 rater 1 5 3 3 2 rater 2 5 4 3 One rater 3 4 4 4 One rater 4 4 3 3 One rater 5 5 4 3 2

As can be seen from Table 2 above, it can be seen that the washing effect of the eco-friendly laundry detergent composition containing the postbiotic mixture is relatively high, and as the content of the postbiotic mixture increases, the washing effect is also relatively high.

Table 3 below compares the washing effect of the eco-friendly laundry detergent composition containing the postbiotic mixture on fine dust.

For fine dust, a self-made fine dust-contaminated cloth was used, and the particle size of the fine dust-contaminated cloth was set to 5 μm or less.

In accordance with KS M 2709 8.1 Method for Evaluation of Detergent Power of Synthetic Detergents for Clothes, the fine dust-contaminated cloth was used to wash with the laundry detergents prepared in the Experimental Examples and Comparative Examples shown in Table 1 above, and the washing effect thereof was visually observed. Comparative evaluation was performed.

The visual evaluation of the washing of the fine dust-contaminated cloth was evaluated by a total of 5 people on a 5-point scale (1. not washed, 2. weak, 3. normal, 4. excellent, 5. very good), and the results are as follows. Table 3 shows.

Visual evaluation result for washing contaminated cloth with fine dust
Experimental Example 1 Experimental Example 2 Experimental Example 3 Comparative Example 1 rater 1 4 4 3 One rater 2 4 3 4 One rater 3 5 3 2 2 rater 4 4 4 3 One rater 5 5 4 4 2

As can be seen from Table 3 above, it can be seen that the washing effect of the eco-friendly laundry detergent composition containing the postbiotic mixture is relatively high, and as the content of the postbiotic mixture increases, the washing effect is also relatively high.

Table 4 below shows the test results for the biodegradability of the eco-friendly laundry detergent composition containing the postbiotic mixture.

The biodegradability test was performed according to the KS M 2716 biodegradability test standard, and the test results for the biodegradability test are shown in Table 4 below.

Biodegradability test results Experimental Example 1 Experimental Example 2 Experimental Example 3 Comparative Example 1 biodegradability 94 90

As can be seen from Table 4 above, it can be seen that the biodegradability of the eco-friendly laundry detergent composition containing the postbiotic mixture is relatively high, and the higher the content of the postbiotic mixture, the higher the biodegradability.

On the other hand, the laundry detergent composition manufacturing apparatus 100 according to this embodiment is for manufacturing an eco-friendly laundry detergent composition containing a postbiotic mixture, and includes a postbiotic mixture generator 125 and a composition receiving member 110 . include

The post-biotic mixture generator 125 ferments Lactobacillus acidophilus to form a post-biotics mixture constituting the eco-friendly laundry detergent composition containing the post-biotic mixture. Then, the first lactic acid bacteria raw material obtained by centrifugation, the second lactic acid bacteria raw material obtained by fermenting Lactobacillus casei and then centrifuging, and Lactobacillus rhamnosus fermented and then centrifuged By mixing the obtained third lactic acid bacteria raw materials with each other, a detailed description thereof will be described later.

The composition accommodating member 110 is connected to the postbiotic mixture generator 125 , and an eco-friendly laundry detergent containing the postbiotic mixture and the postbiotic mixture generated by the postbiotic mixture generator 125 . An eco-friendly laundry detergent composition containing the postbiotic mixture formed by mixing together other raw materials except for the postbiotic mixture in the composition may be accommodated.

Reference numeral 114 indicates that the postbiotic mixture generator 125 and the composition receiving member 110 are connected, and the postbiotic mixture generated by the postbiotic mixture generator 125 is transferred to the composition receiving member 110 . It is a postbiotic mixture transfer tube that moves to the side.

Reference numeral 115 denotes a non-alcoholic raw material inlet pipe for introducing a non-alcoholic raw material, which is a raw material other than the post-biotic mixture, from among the eco-friendly laundry detergent composition containing the post-biotic mixture toward the composition accommodating member 110 .

The non-alcoholic raw material introduced into the non-alcoholic raw material inlet pipe 115 may be the components listed in Table 1 above, and the non-alcoholic raw material flows through the non-alcoholic raw material inlet pipe 115 through a pipe. Since it is the same as the general flow of components, a detailed description is omitted in this embodiment.

The non-mainstream raw material may be at least one, and a plurality of the non-mainstream raw material inlet pipe 115 may be formed according to the type of the non-mainstream raw material.

Reference numeral 116 denotes a discharge nozzle formed under the composition accommodating member 110 and through which the eco-friendly laundry detergent composition containing the postbiotic mixture accommodated in the composition accommodating member 110 is discharged to the outside.

The postbiotic mixture generator 125 includes a mixture mixing unit 130 , a first lactic acid bacteria raw material inlet pipe 126 , a second lactic acid bacteria raw material inlet pipe 127 , and a third lactic acid bacteria raw material inlet pipe 128 . include

The mixture mixing unit 130 is installed on the composition accommodating member 110 to mix the postbiotic mixture, a detailed description thereof will be given later.

The first lactic acid bacteria raw material inlet pipe 126 is connected to the mixture mixing unit 130 to supply the first lactic acid bacteria raw material into the mixture mixing unit 130 .

The second lactic acid bacteria raw material inlet pipe 127 is connected to the mixture mixing unit 130, and is disposed to be spaced apart from the first lactic acid bacteria raw material inlet pipe 126, and the second It is to supply lactic acid bacteria raw materials.

The third lactic acid bacteria raw material inlet pipe 128 is connected to the mixture mixing unit 130, and the first lactic acid bacteria raw material inlet pipe 126 and the second lactic acid bacteria raw material inlet pipe 127 are spaced apart from each other, and the The third lactic acid bacteria raw material is supplied into the mixture mixing unit 130 .

Reference numeral 120 denotes a first lactic acid bacteria raw material supplier that is installed outside and is connected to the first lactic acid bacteria raw material inlet pipe 126 to supply the first lactic acid bacteria raw material through the first lactic acid bacteria raw material inlet pipe 126 .

Reference numeral 121 denotes a second lactic acid bacteria raw material supplier that is installed outside and is connected to the second lactic acid bacteria raw material inlet pipe 127 to supply the second lactic acid bacteria raw material through the second lactic acid bacteria raw material inlet pipe 127 .

Reference numeral 122 denotes a third lactic acid bacteria raw material supplier that is installed outside and is connected to the third lactic acid bacteria raw material inlet pipe 128 to supply the third lactic acid bacteria raw material through the third lactic acid bacteria raw material inlet pipe 128 .

The mixture mixing unit 130 includes a mixing case member 131 , an upper diffusion member 140 , curved edge portions 132 and 133 , curved edge-directed spray nozzle members 150 and 153 , and one side drop induction It includes a curved body 134 , the other drop-inducing curved body 135 , an inner space side diffusion member 146 , a centrally directed jet nozzle member 156 , and a discharge pipe 136 .

In this embodiment, the mixture mixing unit 130 further includes a curved edge-side air injection member 160 .

The mixing case member 131 is erected on top of the composition accommodating member 110 and is formed in an empty shape, the first lactic acid bacteria raw material inlet pipe 126 and the second lactic acid bacteria raw material inlet pipe 127 ) and the third lactic acid bacteria raw material inlet pipe 128 are connected while being spaced apart from each other.

The upper diffusion member 140 is disposed to face the first lactic acid bacteria raw material inlet pipe 126 inside the mixing case member 131 and is supplied through the first lactic acid bacteria raw material inlet pipe 126 . By diffusing the lactic acid bacteria raw material over the entire upper portion of the mixing case member 131 , the upper diffusion rotating means 141 , the upper diffusion curved body 142 , the upper diffusion protrusion 143 , and the upper diffusion lifting piston 144 . ) and an upper diffusion lifting means 145 .

The upper diffusion rotation means 141 rotates a rotation shaft disposed toward the first lactic acid bacteria raw material inlet pipe 126, and an electric motor may be presented as an example.

The upper diffusion curved body 142 has a central portion connected to the rotation shaft of the upper diffusion rotation means 141, and gradually toward the outside from the central portion connected to the rotation shaft of the upper diffusion rotation means 141, the curved edge It is formed in the form of a curved surface rising toward the parts 132 and 133, and is formed in the form of a hemispherical antenna as a whole.

The first lactic acid bacteria supplied into the mixing case member 131 through the first lactic acid bacteria raw material inlet pipe 126 in a state in which the upper diffusion curved body 142 is rotated by the upper diffusion rotating means 141 . When the raw material falls to the upper diffusion curved body 142 , the first lactic acid bacteria raw material is diffused in all directions by the rotation of the upper diffusion curved body 142 .

At this time, since the upper diffusion curved body 142 is formed to have a predetermined curvature, the first lactic acid bacteria raw material is relatively close to the upper inner surface of the mixing case member 131 and is diffused toward the curved edge portions 132 and 133. .

The upper diffusion protrusion 143 protrudes from the central portion of the upper diffusion curved body 142 toward the first lactic acid bacteria raw material inlet pipe 126, and is connected to the surface of the upper diffusion curved body 142 by a curved surface, It is integral with the upper diffusion curved body 142 .

The upper diffusion lifting piston 144 is connected to the lower side of the upper diffusion rotating means 141 .

The upper diffusion raising/lowering means 145 is configured to move the upper diffusion lifting and lowering so that the upper diffusion curved body 142 connected to the upper diffusion rotating means 141 is relatively close to or relatively far from the upper inner surface of the mixing case member 131 . As for lifting the piston 144 , a pneumatic cylinder may be exemplified.

When the upper diffusion elevating piston 144 protrudes from the upper diffusion elevating means 145 and rises, the upper diffusion rotating means 141 to which the upper diffusion elevating piston 144 is connected moves the mixing case member 131 . When the upper diffusion lifting piston 144 is inserted into the upper diffusion lifting means 145 and descending relatively close to the upper inner surface, the upper diffusion rotating means 141 to which the upper diffusion lifting piston 144 is connected is It is relatively far away from the upper inner surface of the mixing case member 131 .

By being configured as described above, the upper diffusion lifting piston 144 is raised and lowered by the upper diffusion lifting means 145 to be placed in a preset position, and the upper diffusion curved body 142 by the upper diffusion rotating means 141 ) and the upper diffusion protrusion 143 are integrally rotated, when the first lactic acid bacteria raw material is supplied through the first lactic acid bacteria raw material inlet pipe 126, the first lactic acid bacteria raw material is the upper diffusion protrusion After being spread over the entire upper diffusion curved body 142 by 143 , it is spread over the entire upper portion of the mixing case member 131 by the upper diffusion curved body 142 .

In addition, when configured as described above, the distance between the upper inner surface of the mixing case member 131 and the upper diffusion curved body 142 can be varied, so that the diffusion direction and diffusion range of the first lactic acid bacteria raw material can be determined. become adjustable.

For example, when the upper diffusion lifting piston 144 is raised by the upper diffusion lifting means 145 and the upper diffusion curved body 142 is relatively close to the upper inner surface of the mixing case member 131, the As the first lactic acid bacterium raw material first diffuses toward the upper inner surface of the mixing case member 131 , the diffusion area of the first lactic acid bacterium raw material toward the curved edge portions 132 and 133 becomes relatively small.

On the other hand, when the upper diffusion lifting piston 144 is lowered by the upper diffusion lifting means 145 and the upper diffusion curved body 142 is relatively farther from the upper inner surface of the mixing case member 131, the first 1 Lactobacillus raw material does not diffuse toward the upper inner surface of the mixing case member 131, but spreads directly toward the curved edge portions 132 and 133, and the first lactic acid bacteria toward the curved edge portions 132 and 133 The diffusion area of the raw material becomes relatively wide.

The lifting position of the upper diffusion lifting piston 144 is adjusted by a controller (not shown) that controls the operation of the laundry detergent composition manufacturing apparatus 100 .

In the above, the preset position may be the height of the upper diffusion lifting piston 144 stored in advance in the control unit according to the supply amount of the first lactic acid bacteria raw material introduced through the first lactic acid bacteria raw material inlet pipe 126, etc. .

The curved edge portions 132 and 133 are respectively formed in a curved shape with a predetermined curvature at both edges of the upper end of the mixing case member 131 to which the first lactic acid bacteria raw material inlet pipe 126 is connected, and the upper diffusion member The first lactic acid bacterium raw material diffused by (140) is to be guided to the inner lower side of the mixing case member (131).

Each of the curved edge portions 132 and 133 is formed at a corner connecting the upper surface of the mixing case member 131 and each side surface of the mixing case member 131 .

The curved edge-directed spray nozzle members 150 and 153 are connected to the second lactic acid bacteria raw material inlet pipe 127 to spray the second lactic acid bacteria raw material, and the first lactic acid bacteria raw material from the curved edge portions 132 and 133 And the second lactic acid bacteria raw material to be able to spray the second lactic acid bacteria raw material in a sector shape in a predetermined range toward each of the curved corner portions 132 and 133 so that the second raw material can be mixed, the curved corner direction injection nozzle body 151, 154), and a plurality of curved edge-directed radial injection holes 152 and 155.

The curved edge-directed injection nozzle members 150 and 153 are configured in plurality, and each of the curved edge portions 132 in the portion corresponding to the inside of the mixing case member 131 of the second lactic acid bacteria raw material inlet pipe 127 . , 133) toward each other.

The curved edge-directed spray nozzle bodies 151 and 154 are connected in a protruding form from the second lactic acid bacteria raw material inlet pipe 127 toward the curved edge portions 132 and 133 .

A plurality of the curved corner-direction radial injection holes 152 and 155 are formed on the surfaces of the curved corner-direction injection nozzle bodies 151 and 154, and the second lactic acid bacteria raw material forms the curved corner portions 132 and 133. They are arranged radially in a predetermined range toward the curved edge portions 132 and 133 while being spaced apart from each other so that they can be sprayed in a fan-shaped shape of a predetermined range.

The one-side drop-inducing curved body 134 is formed in the central portion of one side of the mixing case member 131 , and gradually protrudes toward the inside of the mixing case member 131 toward the lower side of the mixing case member 131 . Formed in a curved shape, the mixed material of the first lactic acid bacteria raw material and the second lactic acid bacteria raw material falling along one side of the mixing case member 131 is guided toward the inner space of the mixing case member 131 .

The other drop-inducing curved body 135 is formed from the central portion of the other side of the mixing case member 131 to the lower portion of the mixing case member 131 , and toward the lower side of the mixing case member 131 , the mixing case member Formed in the shape of a curved surface that gradually protrudes toward the inside of the mixing case member 131, the mixed material of the first lactic acid bacteria raw material and the second lactic acid bacteria raw material falling along the other side of the mixing case member 131 is mixed with the mixing case member It is to guide toward the inner space of (131).

The inner space-side diffusion member 146 is installed at a lower edge portion of one side of the mixing case member 131 , and the first drop-inducing curved body 134 and the second falling-inducing curved body 135 are respectively guided along the other side. The mixed material of the first lactic acid bacteria raw material and the second lactic acid bacteria raw material is backflowed to the one side of the fall-inducing curved body 134 and the other side of the falling-inducing curved body 135, and is diffused throughout the internal space of the mixing case member 131. , an inner space-side diffusion rotating means 147 , an inner space-side diffusion curved body 148 , and an inner space-side diffusion protrusion 149 .

The inner space-side diffusion rotation means 147 rotates a rotation shaft disposed toward the one formed on the upper side of the third lactic acid bacteria raw material inlet pipe 128 among the curved edge portions 132 and 133, and an electric motor is an example of this. can be presented.

The inner space-side diffusion curved body 148 has a central portion connected to the rotation shaft of the inner space-side diffusion rotation means 147 , and moves outward from the central portion connected to the rotation shaft of the interior space-side diffusion rotation means 147 . Gradually, each outer side is formed in a shape that rises toward the one side of the fall-inducing curved body 134 and the other side of the fall-inducing curved body 135 , and is generally formed in the form of a hemispherical antenna.

The inner space-side diffusion protrusion 149 protrudes from the central portion of the inner space-side diffusion curved body 148 toward the one formed above the third lactic acid bacteria raw material inlet pipe 128 among the curved edge portions 132 and 133 . However, it is connected to the surface of the inner space-side diffusion curved body 148 by a curved surface to form an integral body with the inner space-side diffusion curved body 148 .

The one-side fall-inducing curved body 134 , the other-side fall-inducing curved body 135 and the inner space-side diffusion curved body 148 are arranged in a curved shape while having a predetermined curvature, the mixing case member 131 in the lower part of the It is formed in the shape of a curved surface in which the trough is formed in the central part.

The inner space-side diffusion curved body 148 and the inner space-side diffusion protrusion 149 are integrally rotated by the inner space-side diffusion rotating means 147 , so that the one-side drop-inducing curved body 134 and the other-side fall The mixed material of the first lactic acid bacteria raw material and the second lactic acid bacteria raw material flowing along the inducing curved body 135 is caused by the inner space-side diffusion curved body 148 and the inner space-side diffusion protrusion to induce a drop on the one side of the curved body 134 . ) and the other side of the fall-inducing curved body 135, and diffused into the inner space of the mixing case member 131, and the one-side fall-inducing curved body 134 by the inner space-side diffusion member 146. The first lactic acid bacterium raw material and the second lactic acid bacterium raw material diffused into the inner space of the mixing case member 131 by the inner space side diffusion member 146 while broadly backflowing to the other side fall-inducing curved body 135 . The mixed material is supplied through the third lactic acid bacteria raw material inlet pipe 128 in the inner space of the mixing case member 131, as well as the surfaces of the one-side fall-inducing curved body 134 and the other-side fall-inducing curved body 135. It is mixed with the third raw material of lactic acid bacteria.

The central injection nozzle member 156 is connected to the third lactic acid bacterium raw material inlet pipe 128 to spray the third lactic acid bacterium raw material, and the first lactic acid bacterium raw material diffused by the inner space-side diffusion member 146 . And the inside of the mixing case member 131 including the surface of the one-side fall-inducing curved body 134 and the other-side fall-inducing curved body 135 so that the mixed material of the second lactic acid bacteria raw material and the third lactic acid bacteria raw material can be mixed It is capable of spraying the third lactic acid bacteria raw material in a predetermined fan shape toward the space, and includes a central injection nozzle body 157 and a plurality of centrally radial injection holes 158 .

The central injection nozzle body 157 is connected from the third lactic acid bacteria raw material inlet pipe 128 to the inner space of the mixing case member 131 in a protruding form.

The plurality of centrally directed radial injection holes 158 are formed in the centrally directed injection nozzle body 157 , and the third lactic acid bacteria raw material is sprayed in a sectoral shape within a predetermined range toward the inner space of the mixing case member 131 . The mixing case member 131 is spaced apart from each other toward the inner space of the mixing case member 131 so as to be radially arranged in a predetermined range.

The discharge pipe 136 is penetrated between the other side drop-inducing curved body 135 and the composition accommodating member 110, and inside the mixing case member 131, the first lactic acid bacteria raw material, the second lactic acid bacteria raw material, and The postbiotic mixture formed by mixing the third lactic acid bacteria raw material is discharged into the composition accommodating member 110 , and as it goes from the composition accommodating member 110 side toward the other side fall inducing curved body 135 toward the inside The space-side diffusion member 146 is inclined in a direction to be relatively spaced apart.

Then, while preventing the mixture of the first lactic acid bacteria raw material and the second lactic acid bacteria raw material mixed by the inner space-side diffusion member 146 from being discharged through the discharge pipe 136 , the postbiotic mixture is transferred to the other side It can be discharged toward the composition receiving member 110 through the discharge pipe 136 while sliding along the fall-inducing curved body 135 .

The discharge pipe 136 is connected to the postbiotic mixture moving pipe 114 , and the postbiotic mixture is transferred to the composition receiving member 110 through the discharge pipe 136 and the postbiotic mixture moving pipe 114 . ) is moved into the

The curved edge-side air injection member 160 is disposed on at least one of the curved edge portions 132 and 133 to spray air toward the curved edge-directed injection nozzle members 150 and 153, and the inflatable body 161 ), and a plurality of air injection holes 162 , an air supply means 164 , and an air flow pipe 163 .

In this embodiment, the curved edge-side air jet member 160 is described by taking as an example the one 133 disposed on the other side of the curved edge portions 132 and 133 of the other drop-inducing curved body 135 as an example. The invention is not limited thereto, and may be disposed together on each of the curved edge portions 132 and 133, and one of the curved edge portions 132 and 133 disposed on the upper portion of the one-side fall induction curved body 134 ( 132).

The inflatable body 161 is disposed on at least one of the curved edge portions 132 and 133, is formed toward the curved edge direction injection nozzle members 150 and 153, and is made of an elastic material to the curved edge direction injection nozzle. It is possible to inflate toward the members (150, 153).

In detail, the inflatable body 161 has both end portions of the curved edge portions 132 and 133 (in this embodiment, the other side of the curved edge portions 132 and 133) disposed on the top of the drop-inducing curved body 135. 133) are fixed to each other in a spaced apart state, and are formed to be inflated toward the curved edge-direction spray nozzle members 150 and 153 by the air supply means 164 .

A plurality of the air injection holes 162 are formed through the inflatable body 161 while being spaced apart from each other to spray the air toward the curved edge direction injection nozzle members 150 and 153 .

The air supply means 164 supplies the air to the inside of the inflatable body 161 , and an air pump or the like may be presented as an example.

The air flow pipe 163 connects the air supply means 164 and the inside of the inflatable body 161 to flow the air supplied from the air supply means 164 into the inflatable body 161 . will be.

When configured as described above, when the second lactic acid bacteria raw material is injected from the curved edge-directed injection nozzle members 150 and 153 , the inflatable body 161 from the air supply means 164 through the air flow pipe 163 . ) to generate a flow in the second lactic acid bacteria raw material sprayed from the curved edge-direction injection nozzle members 150 and 153 by spraying the air flowed through the air injection hole 162, and accordingly the curved edge direction The second raw material for lactic acid bacteria sprayed from the spray nozzle members 150 and 153 can be sprayed relatively widely.

Hereinafter, the operation of the laundry detergent composition manufacturing apparatus 100 according to the present embodiment will be described with reference to the drawings.

First, as the first lactic acid bacteria raw material introduced through the first lactic acid bacteria raw material inlet pipe 126 falls toward the upper diffusion member 140 , the upper side of the mixing case member 131 is caused by the upper diffusion member 140 . The second lactic acid bacterium raw material introduced through the second lactic acid bacterium raw material inlet pipe 127 is diffused toward the curved corner portions 132 and 133 disposed at both ends, respectively, and the curved corner direction injection nozzle member 150, 153 ) by being sprayed toward the curved edge portions 132 and 133 through the curved edge portions 132 and 133, a mixture of the first lactic acid bacteria raw material and the second lactic acid raw material is formed in a wide range.

The mixed material of the first lactic acid bacteria raw material and the second lactic acid raw material formed as described above flows down on the one side of the fall-inducing curved body 134 and the other side of the fall-inducing curved body 135 toward the inner space-side diffusion member 146 . will be headed

The mixed material of the first lactic acid bacteria raw material and the second lactic acid raw material flowing toward the inner space side diffusion member 146 is the one side drop-inducing curved body 134 and the other side fall by the inner space side diffusion member 146 . Widespread counterflow from the induction curved body 135, as well as diffused into the inner space of the mixing case member 131, is introduced through the third lactic acid bacterium raw material inlet pipe 128 and the centrally directed injection nozzle member 156. By mixing with the third raw material for lactic acid bacteria injected into the inner space of the mixing case member 131 by the A mixture may be formed.

The postbiotic mixture formed by mixing the first lactic acid bacteria raw material, the second lactic acid bacteria raw material, and the third lactic acid bacteria raw material is discharged through the discharge pipe 136, and then passes the postbiotic mixture moving pipe 114. It is moved toward the composition receiving member 110 through the.

The postbiotic mixture moved toward the composition accommodating member 110 is mixed with the non-alcoholic raw material introduced into the composition accommodating member 110 through the non-alcoholic raw material inlet pipe 115 to form the postbiotic mixture. The contained eco-friendly laundry detergent composition can be manufactured.

As described above, the laundry detergent composition manufacturing apparatus 100 includes the postbiotic mixture generator 125 and the composition receiving member 110 , and the postbiotic mixture generator 125 includes the mixture mixing unit ( 130), the first lactic acid bacteria raw material inlet pipe 126, the second lactic acid bacteria raw material inlet pipe 127, and the third lactic acid bacteria raw material inlet pipe 128, wherein the mixture mixing unit 130 is The mixing case member 131 , the upper diffusion member 140 , the curved edge portions 132 and 133 , the curved edge direction injection nozzle members 150 , 153 , and the one-side drop inducing curved body 134 . ), the other side drop-inducing curved body 135 , the inner space side diffusion member 146 , the centrally directed injection nozzle member 156 , and the discharge pipe 136 , so that the postbiotics The postbiotic mixture constituting the eco-friendly laundry detergent composition containing the mixture can be homogeneously mixed.

In the above, the present invention has been shown and described with respect to specific embodiments, but those of ordinary skill in the art can variously modify the present invention within the scope without departing from the spirit and scope of the present invention as set forth in the claims below. and can be changed. However, it is intended to clearly state that all such modifications and variations are included within the scope of the present invention.

According to the environmentally friendly laundry detergent composition containing the postbiotic mixture according to an aspect of the present invention and the apparatus for manufacturing the laundry detergent composition for manufacturing the same, the environmentally friendly laundry detergent composition containing the postbiotic mixture is environmentally friendly and improves the laundry effect Since the postbiotic mixture constituting the eco-friendly laundry detergent composition containing the postbiotic mixture can be homogeneously mixed, its industrial applicability is high.

100: laundry detergent composition manufacturing apparatus 110: composition receiving member
125: postbiotic mixture generator 126: first lactic acid bacteria raw material inlet pipe
127: second lactic acid bacteria raw material inflow pipe 128: third lactic acid bacteria raw material inflow pipe
130: mixture mixing unit 131: mixing case member
140: upper diffusion member 132, 133: curved edge portion
134: one side fall induction curved body 135: the other side fall induction curved body
136: discharge pipe 146: inner space side diffusion member
150, 153: curved corner injection nozzle member 156: central injection nozzle member
160: curved edge side air injection member (160)

Claims (5)

delete delete For preparing an eco-friendly laundry detergent composition containing a postbiotic mixture,
The first lactic acid bacteria raw material obtained by fermenting Lactobacillus acidophilus and then centrifuging to form a post-biotics mixture constituting the eco-friendly laundry detergent composition containing the post-biotic mixture. And, a second lactic acid bacteria raw material obtained by centrifugation after fermenting Lactobacillus casei, and a third lactic acid bacteria raw material obtained by fermenting Lactobacillus rhamnosus and then centrifuging to mix with each other Postbiotic Mixture Generator; and
a composition receiving member connected to the postbiotic mixture generator and capable of accommodating the eco-friendly laundry detergent composition containing the postbiotic mixture;
The postbiotic mixture generator
a mixture mixing unit installed on the composition receiving member to mix the postbiotic mixture;
a first lactic acid bacteria raw material inlet pipe connected to the mixture mixing unit to supply the first lactic acid bacteria raw material into the mixture mixing unit;
A second lactic acid bacteria raw material inlet pipe connected to the mixture mixing unit, arranged spaced apart from the first lactic acid bacteria raw material inlet pipe, and supplying the second lactic acid bacteria raw material into the mixture mixing unit,
Doedoe connected to the mixture mixing unit, the first lactic acid bacteria raw material inlet pipe and the second lactic acid bacteria raw material inlet pipe are spaced apart, the third lactic acid bacteria raw material inlet pipe for supplying the third lactic acid bacteria raw material into the mixture mixing unit including,
The mixture mixing unit
A mixing case in which the first lactic acid bacteria raw material inlet pipe, the second lactic acid bacteria raw material inlet pipe, and the third lactic acid bacteria raw material inlet pipe are connected while being spaced apart from each other while standing on the upper part of the composition accommodating member. absence and
An upper diffusion member disposed to face the first lactic acid bacteria raw material inlet pipe inside the mixing case member and diffusing the first lactic acid bacteria raw material supplied through the first lactic acid bacteria raw material inlet pipe to the entire upper part of the mixing case member and ,
Of the mixing case member, the first lactic acid bacteria raw material is formed in a curved shape with a predetermined curvature, respectively, at both corners of the upper end to which the first lactic acid bacteria raw material inlet pipe is connected, and the first lactic acid bacteria raw material diffused by the upper diffusion member is inside the mixing case member. a curved edge to be guided downward, and
It is connected to the second lactic acid bacteria raw material inlet pipe to spray the second lactic acid bacteria raw material, and a fan shape of a predetermined range toward each curved corner portion so that the first lactic acid bacteria raw material and the second lactic acid bacteria raw material can be mixed at the curved corner portion. A curved corner-direction spray nozzle member capable of spraying the second lactic acid bacteria raw material in the form of,
It is formed in the central portion of one side of the mixing case member, is formed in a curved shape that gradually protrudes toward the inside of the mixing case member toward the lower side of the mixing case member, and is dropped along one side of the mixing case member. A one-side drop-inducing curved body for guiding the mixed material of the first lactic acid bacteria raw material and the second lactic acid bacteria raw material toward the inner space of the mixing case member;
The mixing case member is formed from the central portion of the other side of the mixing case member to the lower portion of the mixing case member, and is formed in a curved shape that gradually protrudes toward the inside of the mixing case member toward the lower side of the mixing case member, the mixing case member The other side drop-inducing curved body for guiding the mixed material of the first lactic acid bacteria raw material and the second lactic acid bacteria raw material falling along the other side of the mixing case member toward the inner space of the mixing case member,
Installed at the lower edge of one side of the mixing case member, the mixed material of the first lactic acid bacteria raw material and the second lactic acid bacteria raw material induced along the one side fall-inducing curved body and the other side fall-inducing curved body, respectively, with the one-side fall-inducing curved body an inner space-side diffusion member for diffusing into the entire inner space of the mixing case member while allowing the flow back to the other side drop-inducing curved body;
The third lactic acid bacteria raw material is connected to the inlet pipe to spray the third lactic acid bacteria raw material, and the mixed material of the first lactic acid bacteria raw material and the second lactic acid bacteria raw material diffused by the inner space side diffusion member and the third lactic acid bacteria raw material are A centrally directed injection nozzle member capable of spraying the third lactic acid bacterium raw material in a predetermined sector shape toward the inner space of the mixing case member including the surfaces of the one-side fall-inducing curved body and the other-side fall-inducing curved body to be mixed, and ,
The post-biotic mixture that penetrates between the other side drop-inducing curved body and the composition accommodating member and is formed by mixing the first lactic acid bacteria raw material, the second lactic acid bacteria raw material, and the third lactic acid bacteria raw material inside the mixing case member Doedoe discharging into the composition accommodating member, the composition accommodating member includes a discharge pipe formed in a direction to be relatively spaced apart from the inner space-side diffusion member toward the other side of the drop-inducing curved body,
The upper diffusion member is
an upper diffusion rotation means for rotating a rotation shaft disposed toward the first lactic acid bacteria raw material inlet pipe;
An upper diffusion curved surface having a central portion connected to the rotation shaft of the upper diffusion rotation means, and formed in a curved shape that gradually rises toward the curved corner portion from the central portion connected to the rotation shaft of the upper diffusion rotation means toward the outside thereof;
An upper diffusion protrusion that protrudes from the central portion of the upper diffusion curved body toward the first lactic acid bacteria raw material inflow pipe, is connected to the surface of the upper diffusion curved body by a curved surface, and is integral with the upper diffusion curved body;
an upper diffusion lifting piston connected to a lower side of the upper diffusion rotating means;
Upper diffusion elevating means for elevating the upper diffusion lifting piston so that the upper diffusion curved body connected to the upper diffusion rotating means is relatively close to or relatively far from the upper inner surface of the mixing case member,
In a state in which the upper diffusion lifting piston is raised and lowered by the upper diffusion lifting means and placed in a preset position, and the upper diffusion curved body and the upper diffusion protrusion are integrally rotated by the upper diffusion rotating means, the first lactic acid bacteria When the first lactic acid bacteria raw material is supplied through the raw material inlet pipe, the first lactic acid bacteria raw material is spread over the entire upper diffusion curved body by the upper diffusion protrusion, and then the entire upper part of the mixing case member by the upper diffusion curved body spread to,
The curved edge direction injection nozzle member is
a curved edge-directed spray nozzle body connected in a protruding form toward the curved edge from the second lactic acid bacteria raw material inlet pipe;
A plurality of curved surfaces formed on the surface of the curved corner-directed spray nozzle body and arranged radially in a predetermined range toward the curved corner so that the second lactic acid bacteria raw material can be sprayed in a sector shape of a predetermined range toward the curved corner. Containing a radial injection hole toward the corner,
The inner space side diffusion member is
an inner space-side diffusion rotation means for rotating a rotating shaft disposed toward the one formed on the upper side of the third lactic acid bacteria raw material inflow pipe among the curved edge portions;
The central portion is connected to the rotational shaft of the inner space-side diffusion rotation means, and each outer side gradually falls from the central portion connected to the rotation shaft of the inner space-side diffusion rotation means toward the outside thereof. An inner space-side diffusion curved body formed in a shape raised toward the curved body, and
The inner space-side diffusion curved body protrudes from the central portion of the curved edge portion toward the one formed on the upper side of the third lactic acid bacteria raw material inflow pipe, and is connected to the surface of the inner space-side diffusion curved body by a curved surface, and the inner space-side diffusion curved body and Including an inner space side diffusion protrusion forming an integral part,
The inner space side diffusion curved body and the inner space side diffusion protrusion are rotated integrally by the inner space side diffusion rotating means, so that the first lactic acid bacteria raw material and the first lactic acid bacteria flowing along the one side fall-inducing curved body and the other side fall-inducing curved body The mixed material of the second lactic acid bacteria raw material is diffused into the inner space of the mixing case member while flowing backward into the one-side fall-inducing curved body and the other-side fall-inducing curved body by the inner space-side diffusion curved body,
The mixed material of the first lactic acid bacterium raw material and the second lactic acid bacterium raw material diffused into the inner space of the mixing case member by the inner space-side diffusion member passes through the third lactic acid bacterium raw material inlet pipe in the inner space of the mixing case member. mixed with the supplied third lactic acid bacteria raw material,
The central spray nozzle member is
a centrally directed injection nozzle body connected from the third lactic acid bacteria raw material inlet pipe in a protruding form toward the inner space of the mixing case member;
Doedoe formed in the central injection nozzle body, the third lactic acid bacteria raw material is arranged radially in a predetermined range toward the inner space of the mixing case member so as to be sprayed in a sector shape of a predetermined range toward the inner space of the mixing case member. A laundry detergent composition manufacturing apparatus comprising a plurality of centrally oriented radial spray holes. delete 4. The method of claim 3,
The mixture mixing unit
Further comprising a curved edge-side air injection member for spraying air toward the curved edge-directed injection nozzle member from at least one of the curved edge portions,
The curved edge side air injection member is
an inflatable which is disposed on at least one of the curved edge portions, is formed toward the curved edge direction injection nozzle member, and is made of an elastic material and can inflate toward the curved edge direction injection nozzle member;
an air injection hole formed through a plurality of spaced apart from the inflatable body to inject the air toward the curved corner direction injection nozzle member;
an air supply means for supplying the air to the inside of the mixing case;
and an air flow pipe connecting the air supply means and the inside of the inflatable body to flow the air supplied from the air supply means into the inflatable body,
When the second lactic acid bacteria raw material is injected from the curved corner-direction injection nozzle member, the air supplying means injects the air that has flowed into the inflatable through the air flow tube through the air injection hole, thereby the curved corner-direction injection nozzle Laundry detergent composition manufacturing, characterized in that by generating a flow in the second lactic acid bacteria raw material sprayed from the member, and thus the second lactic acid bacteria raw material sprayed from the curved edge direction injection nozzle member can be sprayed relatively widely Device.

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