KR20200109797A - Polymer dispersion system - Google Patents

Abstract

The present invention relates to a polymer dispersion system which uses a homogenizer designed to mix polymer powder and a liquid fluid in order to disperse the polymer in a liquid phase. More specifically, the present invention relates to a polymer dispersion system using a homogenizer, which is equipped with a plurality of mixers for mixing the polymer powder and the liquid fluid to improve a mixing ratio of the polymer composed of fine powder particles and the liquid fluid, and also can independently control each mixer to provide reliability.

Description

Polymer dispersion system using a homogenizer {Polymer dispersion system}

The present invention relates to a polymer dispersion system using a homogenizer designed to mix a polymer powder and a liquid fluid in order to disperse the polymer in a liquid phase. A polymer composed of fine powder particles is provided with a plurality of mixers for mixing the polymer powder and the fluid. The present invention relates to a polymer dispersion system using a homogenizer that improves the mixing ratio of and liquid fluid, and provides reliability by controlling each mixer independently.

In general, various industrial materials composed of fine powder particles such as cosmetics, paints, abrasives, etc. are generally manufactured through a process of mixing various raw materials and then milling them into fine particles.

To this end, conventionally, raw materials are mixed by rotating a mixing blade in a container using a separate mixing device, and then the mixture is put in a grinder to perform pulverization treatment.

The mixing device includes an inlet portion for introducing a mixture of raw materials, a screw shaft for transferring the input mixture into the chamber, and a repelling plate and a rotor portion for pulverizing the mixture introduced into the chamber.

According to this configuration, when the raw material mixed through the mixing device is supplied through the inlet, the raw material is transferred into the chamber by rotation of the screw shaft. In addition, in the chamber, the rotor part rotates at a low speed or high speed with respect to the repelling plate. At this time, the hammer and the repelling plate movably coupled along the outer circumference of the rotor part mechanically contact each other with the raw material interposed therebetween, thereby crushing It goes on.

However, such a conventional mixing and pulverizing system is very cumbersome and requires a lot of work time because it is necessary to put the raw materials mixed through the mixing device in a predetermined container and put it back into the pulverizing device, and due to the time interval between the mixing operation and the pulverizing operation. There was a problem in that the mixed raw materials precipitated or aggregated again.

In addition, due to the agglomeration phenomenon between the input raw materials, the mixing ratio between the fluid and the raw materials is lowered, or malfunctions and defects of the apparatus occur frequently due to the transfer of the aggregated raw materials.

In addition, the powder mixing device as described above has a vulnerability of increasing the volume of the device as well as power consumption because a separate screw shaft must be configured to rotate so as to introduce raw materials into the chamber.

Accordingly, there is a need to develop a polymer mixing device with diversity because it improves the mixing ratio of the fluid and the raw material, reduces the occurrence of malfunction of the device, and allows the mixing ratio of the fluid and raw material to be adjusted.

The present invention has been devised to solve the above problems, and provides an optimum mixing ratio by measuring the input amount of the polymer in the form of a fine powder and the weight of the fluid in the liquid state, and distributing the mixture according to the process of using the mixed mixture. Thus, it provides a polymer dispersion system using a homogenizer that can be stored separately.

The polymer dispersion system using the homogenizer of the present invention comprises: a raw material input unit 1000 receiving a raw material from one side; A fluid supply unit 2000 receiving a liquid fluid introduced from the outside; and a raw material mixing unit 3000 receiving raw materials and fluids from the raw material input unit 1000 and the fluid supply unit 2000 and mixing them into a homogenized mixture; And a raw material transfer unit 4000 receiving raw material from the raw material input unit 1000 and transferring the raw material to the raw material mixing unit 2000. And a control unit 5000 for controlling the supply amount of the raw material and the fluid and controlling the driving of the raw material mixing unit 3000.

In this case, the raw material mixing unit 3000 includes a first mixer 3100 that receives a fluid from the fluid supply unit 3000 and first mixes the fluid and the raw material; A second mixer (3200) for receiving the mixture from the first mixer (3100) and pulverizing the aggregated raw material contained in the mixture and mixing the fluid and the raw material into a homogenized mixture; And a third mixer 3300 for receiving the mixture from the second mixer 3200 and receiving a predetermined amount of the mixture, but stirring the received mixture to prevent separation of the fluid and the raw material in the received mixture.

In addition, the present invention further comprises at least one storage tank 6000 connected to the third mixer 3300 to separately accommodate the mixture discharged from the third mixer 3300 according to the intended use. It features.

In the present invention, the fluid supply unit 2000 includes a first oil pipe 2110 connected to the first mixer 3100 on one side and a second oil pipe 2120 having a predetermined diameter so that a liquid fluid flows from the other side. The main supply pipe 2100 including a; A main valve 2200 mounted between the first oil pipe 2110 and the second oil pipe 2120 to control opening and closing of the main supply pipe 2100; When the main valve 2200 blocks the main supply pipe 2100, the first oil pipe 2110 and the second oil pipe 2110 bypass and supply the fluid flowing into the first oil pipe 2110 to the second oil pipe 2120. An auxiliary supply pipe 2300 connecting the 2120; Including an auxiliary valve 2400 for controlling the opening and closing of the auxiliary supply pipe 2300, the auxiliary supply pipe 2300 is characterized in that it is formed to have a diameter smaller than the diameter of the main supply pipe 2100.

In the present invention, the second mixer 3200 includes a motor 3210; A stator holder 3220 having a main inlet h on one side and having a space formed therein; A stator assembly 3230 in which at least two stators 3231, 3232, and 3233 are fixed in the space of the stator holder 3220; And a rotor assembly 3240 including at least two rotors 3241, 3242, 3234 coupled with a rotation shaft of the motor 3210 to rotate about the rotation shaft with respect to the stator assembly 3230; and , At one side of the stator holder 3220, a gas inlet 3221 for introducing a gas having a predetermined pressure from the outside into the internal space of the stator holder 3220 is further provided.

In the present invention, the raw material transfer unit 4000 has an inner hollow and an outer casing 4100 that receives raw materials from one side and discharges the raw materials to the other side; and is provided on the inner side of the outer casing 4100 and rotates to one side. A transfer screw 4200 having a plurality of blades 4210 on an outer surface to transfer the raw material; Including, but the edge of the blade (4210) is spaced at regular intervals, a plurality of anti-adhesion parts (4211) for pulverizing the raw material fixed to the inner surface of the outer casing (4100); is formed, and the transfer screw. (4200) It is characterized in that a plurality of injection holes 4220 are formed on side surfaces of the transfer screw 4200 so that air of a predetermined pressure is introduced into the interior, and the raw material is scattered while the introduced air is discharged.

In addition, in the injection hole 4220 of the present invention, a blocking plate 4221 is formed to prevent the raw material scattered into the inside of the hollow transfer screw 4200, and the blocking plate 4221 has a constant air. When delivered at pressure, it is opened to discharge air, and when it is less than a certain pressure, it is sealed.

In the present invention, the mixing ratio of the raw material and the fluid can be adjusted according to the type of raw material by measuring the amount of the polymer in the form of a fine powder and the weight of the liquid supplied to the fluid supply unit, and before mixing the raw material. There is an advantage in that the mixing performance of the polymer and the fluid can be further improved by further performing the premixing process.

1 is a schematic diagram showing the overall flow and configuration of the present invention.
Figure 2 is an exploded perspective view showing the main configuration of the raw material mixing unit of the present invention.
3 is an exploded perspective view showing the main configuration of a part of the second mixer of the present invention.
4 is an exploded perspective view showing the main configuration of a part of the second mixer of the present invention.
Figure 5 is a partial cross-sectional perspective view showing an embodiment of the raw material transfer unit of the present invention.
Oh 6 is a cross-sectional view showing a part of the cross-section of the material transfer part of the present invention.

Hereinafter, a powder dispersion system using a homogenizer of the present invention will be described in detail with reference to the drawings.

Referring to Figure 1, the powder dispersion system using the homogenizer of the present invention is provided with a raw material input unit 1000 to receive a raw material from one side. The raw material input unit 1000 has an opening for supplying raw materials at an upper end, a filtration filter unit 1100 for filtering impurities contained in the raw material is further provided at the opening, and a lower side for measuring the capacity of the raw material. The raw material measuring instrument 1200 is further installed.

In addition, it includes a fluid supply unit 2000 that receives a liquid fluid introduced from the outside, and receives the fluid introduced through the fluid supply unit 2000 and the raw material supplied from the raw material input unit 1000, and agitates each other and homogenizes It includes a raw material mixing unit 3000 for generating a mixture.

In addition, a raw material transfer unit 4000 for receiving raw materials from the raw material input unit 1000 and transferring the raw materials to the raw material mixing unit 2000 is provided. The raw material transfer unit 4000 receives the raw material from the raw material input unit 1000 and transfers the raw material to the raw material mixing unit 3000, which pulverizes the raw material into a predetermined size while being transferred. That is, the raw material is a powder having fine particles, and these raw materials are agglomerated with each other depending on the ingredients of the raw material. When the raw materials are transported to the raw material mixing unit 3000 while the raw materials are aggregated, there is a problem that the raw materials cannot be well mixed with the liquid fluid.

Therefore, if the raw materials aggregated in the raw material transfer unit 4000 are pulverized to a certain size or transferred to the raw material mixing unit 3000 while maintaining the raw materials in a powder form, the mixing ratio in the raw material mixing unit 300 can be further improved. have.

The above raw materials may correspond to various powders used in chemical products such as ECA powder, polymer, bentonite, etc., and are quantitatively supplied while being accommodated in a certain amount in the raw material input unit 100.

On the other hand, when the raw material is discharged from the raw material input unit 1000, a phenomenon in which the outlet of the raw material input unit 1000 is blocked due to a phenomenon of cohesion between the raw materials occurs below the raw material input unit 1000. In order to solve this problem, a separate vibrating unit 1300 that sprays compressed air having a predetermined pressure or transmits vibration crushes the aggregated raw material due to agglomeration, thereby inducing smooth discharge of the raw material.

Referring to FIG. 1, a control unit 5000 for measuring an input amount of a raw material transferred from the raw material input unit 1000 to the raw material mixing unit 3000 and a supply amount of a fluid supplied from the fluid supply unit 2000 is further provided. The control unit 500 may adjust the mixing ratio of the raw material of the mixture and the fluid by adjusting the respective input and supply amounts, and the second and third mixers 3200 and 3300 described below according to the conditions of the input raw material and the type and viscosity of the fluid. ) Can be controlled to increase the quality of the homogenized mixture.

Referring to FIG. 1, the raw material mixing unit 300 includes a first mixer 3100, a second mixer 3200, and a third mixer 3300.

The first mixer 3100 receives a raw material from the raw material transfer unit 4000 and a fluid from the fluid supply unit 2000 to primarily mix the fluid and the raw material. The first mixer 3100 is formed in a cylindrical shape having a hollow inside, but is manufactured in a shape whose diameter decreases toward the bottom, and a plurality of stirring protrusions are formed along the inner surface.

In more detail, the raw material flows into the upper side of the first mixer 3100, and the fluid flows into the side of the first mixer 3100. At this time, the fluid causes a vortex along the inner surface of the first mixer 3100 by the stirring protrusion, moves downward, and the raw material is supplied to the fluid causing the vortex, so that the fluid and the raw material are mixed with each other. Since the raw material and the fluid are firstly mixed in the first mixer 3100, the mixture may be smoothly introduced into the second mixer 3200.

The second mixer 3200 receives the mixed mixture from the first mixer 3100 and secondarily mixes the fluid and the raw material while pulverizing the raw material aggregated to a predetermined size in the first mixed mixture.

Referring to FIG. 2, the second mixer 3200 includes a motor 3210, a stator holder 3220, a stator assembly 3230, and a rotor assembly 3240. The motor 3210 is a configuration for rotating the rotor assembly 3240 and operates by receiving power from the outside, and since various known motors can be used, a detailed description of the motor 3210 will be omitted.

Referring to FIGS. 2 and 3, the stator holder 3220 penetrates the inner central portion and includes a main inlet h through which substances can be introduced from the outside. The mixture mixed in the first mixer 3100 flows into the main inlet h, and a space in which the stator assembly 3230 is seated is formed inside the stator holder 3220.

At this time, a gas inlet 3221 penetrating inward is formed on one circumferential surface of the stator holder 3220. Gas having a predetermined pressure may be introduced into the internal space of the stator holder 3220 through the gas inlet 3221, and various fluids as well as gas may be introduced.

A stator assembly 3230 in which at least two stators 3231, 3232, and 3233 are provided is mounted and fixed in the inner space of the stator holder 3220. In addition, a plurality of stepped jaws 3222 having a stepped shape are formed in the inner space of the stator holder 3220, and stators 3231, 3232, and 3233 are seated and fixed to each stepped jaw 3222.

In the case of the present invention, the stators are divided into first to third stators 3231, 3232, and 3233. The first to third stators 3231, 3232, and 3233 are formed in a ring shape, and the diameters from the first stator 3231 to the third stator 3233 are shown to gradually increase. In addition, each stator may be smoothly seated and fixed to a plurality of stepped jaws 3222 having a stepped shape.

The first to third stators 3231, 3232, and 3233 are sequentially seated on the stepped portions 3222 of the stator holder 3220, and partially overlapped. Accordingly, when the third stator 3233 and the stator holder 3220 disposed outside are fixed to each other, the overlapped first and second stators 3231 and 3232 may be fixed.

In the first to third stators 3231, 3232, 3233 of the stator assembly 3230, the rotor assembly 3240 rotates at regular intervals along the outer edge to secure a contact area with the mixture flowing into the stator holder 3220. A plurality of contact protrusions (3231-1, 3232-2, 3233-1) that are spaced apart and formed are formed. Preferably, the spacing of the contact protrusions 3233-1 formed in the third stator 3233 is greater than the spacing of the contact protrusions 3231-1 formed in the first stator 3231 so that the raw material and the fluid can be better mixed. It becomes closer, and the number of contact protrusions may be greater in the third stator 3233 than in the first stator 3231.

2 and 4, the rotor assembly 3240 is coupled to the rotation axis of the motor 3210 to rotate about the rotation axis with respect to the stator assembly 3230, and at least two or more rotors 3241, 3242, 3243, 3244 ).

That is, the rotor assembly 3240 includes first to fourth rotors 3241, 3242, 3243, and 3244. A hole 3241-2 is perforated in the central portion of the first rotor 3241. The first rotor 3241 is rotated by a separate bolt passing through the hole 3241-2 and fastened with the shaft 3211 of the motor 3210.

A plurality of vanes 3241-1 are radially formed in the first rotor 3241 to induce the inflow of the primary mixture flowing into the main inlet h. The second to fourth rotors 3242, 3243, 3244 are manufactured in a ring shape, and at the edges of the second to fourth rotors 3242, 3243, 3244, a plurality of teeth 3242-1, 3243-1, 3244 -1) is formed. The spacing of the toothed portions is that the third rotor 3244 is tighter than the second rotor 3245 and the fourth rotor 3244 maintains a tighter spacing than the third rotor 3245. At this time, the number of the second to fourth rotors 3242, 3243, and 3244 gradually increases according to the diameter.

The rotor assembly 3240 further includes a rotor housing 3245, and the fourth rotor 3244 and the rotor housing 3245 are coupled to each other. A plurality of stepped stepped steps are provided on one side of the rotor housing 3245, a fourth rotor 3244 is provided on the outermost stepped step, a third rotor 3244 is provided on the adjacent second stepped step, and a second rotor ( 3242) is fastened.

Referring to FIG. 4, an adapter 3250 is further provided between the rotor assembly 3240 and the motor 3210. The adapter 3250 corresponds to a medium for connecting the motor 3210 and the rotor assembly 3240, and one side of the adapter 3250 is coupled to and fixed to the housing of the motor 3210.

A rotor assembly 3240 and a stator assembly 3230 are disposed inside between the adapter 3250 and the stator holder 3220, and an internal space is formed so that the primary mixture introduced into the stator holder 3220 can be accommodated. A casing 3260 is further provided. That is, as the adapter 3250 and the casing 3260 are mounted on both sides of the casing 3260 so that they are mutually sealed, the primary mixture may be accommodated in the inner space.

At this time, in the inner space of the casing 3260, as the rotor assembly 3240 rotates, the introduced primary mixture flows through the inner space of the rotor assembly 3240 and the casing 3260, and is homogenized by contacting the stator assembly 3230. Proceeds to form a secondary mixture. Then, an outlet 3261 is provided on the side of the casing 3260 so that the homogenized secondary mixture is discharged to the outside by the rotational force of the rotor assembly 3240.

Referring to the enlarged view of FIG. 2, a gas flow path 3223 for receiving gas flowing into the gas inlet 3221 of the stator holder 3220 is formed at the inner edge of the main inlet h.

In addition, the first and second stators 3231 and 3232 have gas holes 3231-2 and 3232 communicating with the gas flow path 3223 in order to introduce gas from the gas flow path 3223 into the internal space of the stator holder 3220. Each -2) is perforated. At least one gas hole 3231-2 and 3232-2 may be formed along the circumferential surfaces of the first and second stators 3231 and 3232. As gas of a predetermined pressure is introduced into the internal space of the gas stator holder 3220, the homogenized secondary mixture may be smoothly discharged to the outlet 3261 of the casing 3260.

Referring to FIG. 1, a third mixer 3300 having a hollow interior is provided to receive a secondary mixture homogenized by a second mixer 3200 and receive a predetermined amount. The third mixer 3300 continuously agitates the received mixture using a separate stirrer to prevent separation of fluid and raw materials from the received mixture. The above stirrer corresponds to a known stirrer including a motor and a stirring blade.

Referring to FIG. 1, the mixture accommodated in the third mixer 3300 is discharged to the outside according to the following process. At this time, a storage tank 6000 for receiving a predetermined amount of the mixture discharged from the third mixer 3300 is further provided. The storage tank 6000 has at least one first storage unit 6100 and a second storage unit 6200 connected in series or in parallel with the third mixer 3300. Due to the configuration of the storage tank 6000, the mixture can be separately accommodated according to the intended use, and additional additives or fluids can be supplied in each storage tank 6000 to store different concentrations. . A separate stirrer for stirring the mixture accommodated in each storage tank 6000 may be installed, respectively.

Referring to FIG. 1, the fluid supply unit 2000 includes a main supply pipe 2100, a main valve 2200, an auxiliary supply pipe 2300, and an auxiliary valve 2400. The main supply pipe 2100 includes a first oil pipe 2110 and a second oil pipe 2120. One side of the first oil pipe 2110 is connected to the first mixer 3100, and the second oil pipe 2120 is poured to the other side, so that a liquid fluid flows in. The first oil pipe 2110 and the second oil pipe 2120 are manufactured in a cylindrical shape having a predetermined diameter.

The main valve 2200 is mounted between the first oil pipe 2110 and the second oil pipe 2120 to control opening and closing of the main supply pipe 2100.

The auxiliary supply pipe 2300 connects the first oil pipe 2110 and the second oil pipe 2120. Accordingly, when the main valve 2200 blocks the main supply pipe 2100, the fluid flowing into the first oil pipe 2110 can be supplied by bypassing the second oil pipe 2120, and the auxiliary valve 2400 is an auxiliary supply pipe ( 2300) open and close.

In this case, the auxiliary supply pipe 2300 is preferably formed to have a diameter smaller than the diameter of the main supply pipe 2100, and the main valve 2200 and the auxiliary valve 2400 are opened and closed by the control of the controller 5000.

When the operation of the fluid supply unit 2000 is described in detail, when the fluid is supplied to the first mixer 3100, the flow rate of the supplied fluid must be adjusted according to the input amount of the raw material. At this time, since it is difficult to control the precise supply amount only by opening and closing the valve, when a certain amount of flow is supplied to the first mixer 3100, the supply of the residual fluid is assisted by shutting off the main valve 2200 and opening the auxiliary valve 2400. The fluid is bypassed through the supply pipe 2300 and supplied to the first mixer 3100.

That is, about 90% of the supplied flow rate is supplied to the main supply pipe 2100 after blocking the auxiliary valve 2400, and about 10% of the remaining flow is supplied to the auxiliary supply pipe 2300 after blocking the main valve 2200. To supply.

Referring to FIGS. 1 and 5, the raw material transfer unit 4000 includes an outer casing 4100 and a transfer screw 2400. The outer casing 4100 forms a hollow shape so that the raw material is accommodated therein in order to receive the raw material to one side and discharge the raw material to the other side.

The transfer screw 4200 is provided inside the outer casing 4100 and rotates in one direction. A separate motor for rotating the transfer screw 4200 is provided at an end of the transfer screw 4200. A plurality of blades 4210 are provided on the outer surface of the transfer screw 4200. The blade 4210 transfers the raw material contained in the outer casing 4100 and at the same time pulverizes the agglomerated raw material.

In this case, at the edge of the blade 4210, a plurality of anti-adhesion parts 4211 are provided spaced apart at a predetermined interval. The anti-adhesion part 4211 has a shape that is recessed into the inside of the blade 4210 or protruded outward. Accordingly, as the transfer screw 4200 rotates, the raw material adhered to the inner surface of the outer casing 4100 may be eliminated or the raw material contained in the bottom of the outer casing 4100 may be crushed more efficiently.

Referring to FIG. 5, the inside of the transfer screw 4200 has a hollow shape, and a plurality of injection holes 4220 communicating with the hollow interior space are formed on the side surface. At this time, air of a predetermined pressure is introduced into the hollow transfer screw 4200, and the air of a predetermined pressure is injected into the outer casing 4100 through the injection hole 4220. When air of a predetermined pressure is continuously injected from the injection hole 4220, the raw material passing through the outer casing 4100 scatters inside the outer casing 4100, thereby preventing the occurrence of coagulation (agglomeration phenomenon). have.

Referring to FIG. 6, a blocking plate 4221 is formed in the injection hole 4220 to prevent the raw material scattered into the transfer screw 4200 from flowing into the hollow interior of the transfer screw 4200. The blocking plate 4221 is inside of the transfer screw 4200, and when the incoming air is delivered at a certain pressure, a part of the blocking plate 4221 is opened to discharge air. It blocks the inflow to the inside of the outer casing 4100.

On the other hand, the blocking plate 4221 is made of a soft material such as rubber, urethane, silicone, and the like, and a discharge hole 4221-h through which air is discharged is formed in the center of the blocking plate 4221. At this time, when the pressure of the air flowing into the transfer screw 4200 is less than a certain pressure, the center of the blocking plate 4221 is raised to the outside of the transfer screw 4200 so that the discharge hole 4221-h is sealed. It has a shape (refer to the enlarged view of FIG. 6).

In order to improve the durability of the blocking plate 4221, the blocking plate 4221 is a two-ply consisting of a first blocking plate 421-1 and a second blocking plate 4221-2, and the first blocking plate 4221-1 ), it is preferable that the second blocking plate 4221-2 is made of a material having high ductility and elasticity.

1000: raw material input unit 2000: fluid supply unit
3000: raw material mixing unit 3100: first mixer
3200: second mixer 3300: third mixer
4000: material transfer unit 5000: control unit
6000: storage tank

Claims (5)

A raw material input unit 1000 receiving raw materials from one side; A fluid supply unit 2000 receiving a liquid fluid introduced from the outside; and a raw material mixing unit 3000 receiving raw materials and fluids from the raw material input unit 1000 and the fluid supply unit 2000 and mixing them into a homogenized mixture; And a raw material transfer unit 4000 for receiving raw materials from the raw material input unit 1000 and transferring the raw materials to the raw material mixing unit 2000. And In the polymer dispersion system using a homogenizer comprising a; and a control unit 5000 for controlling the supply amount of the raw material and fluid and controlling the driving of the raw material mixing unit 3000,
The raw material mixing unit 3000 includes a first mixer 3100 that receives a fluid from the fluid supply unit 3000 and first mixes the fluid and the raw material;
A second mixer (3200) for receiving the mixture from the first mixer (3100) and pulverizing the aggregated raw material contained in the mixture and mixing the fluid and the raw material into a homogenized mixture;
Including; a third mixer (3300) for receiving the mixture received from the second mixer (3200), a predetermined amount, but stirring the received mixture to prevent separation of fluid and raw materials from the received mixture,
At least one storage tank (6000) connected to the third mixer (3300) to separately receive the mixture discharged from the third mixer (3300) according to the intended use;
Powder dispersion system using a homogenizer, characterized in that it comprises a. The method of claim 1,
The fluid supply unit 2000 is a main supply pipe including a first oil pipe 2110 connected to the first mixer 3100 on one side and a second oil pipe 2120 having a predetermined diameter so that a liquid fluid flows from the other side. (2100);
A main valve 2200 mounted between the first oil pipe 2110 and the second oil pipe 2120 to control opening and closing of the main supply pipe 2100;
When the main valve 2200 blocks the main supply pipe 2100, the first oil pipe 2110 and the second oil pipe 2110 bypass and supply the fluid flowing into the first oil pipe 2110 to the second oil pipe 2120. An auxiliary supply pipe 2300 connecting the 2120;
Including; an auxiliary valve 2400 for controlling the opening and closing of the auxiliary supply pipe 2300,
The auxiliary supply pipe 2300 is a powder dispersion system using a homogenizer, characterized in that formed in a diameter smaller than the diameter of the main supply pipe (2100). The method of claim 1,
The second mixer 3200 includes a motor 3210;
A stator holder 3220 having a main inlet h on one side and having a space formed therein;
A stator assembly 3230 in which at least two stators 3231, 3232, and 3233 are fixed in the space of the stator holder 3220; And
A rotor assembly 3240 including at least two rotors 3241, 3242, 3234 coupled to the rotation shaft of the motor 3210 and rotating about the rotation shaft with respect to the stator assembly 3230; includes,
Powder dispersion system using a homogenizer, characterized in that a gas inlet (3221) for introducing a gas having a predetermined pressure from the outside into the internal space of the stator holder 3220 is further provided at one side of the stator holder 3220 . The method of claim 1,
The raw material transfer unit 4000 has an outer casing 4100 that is hollow inside and supplies raw materials to one side and discharges the raw materials to the other side; and is provided inside the outer casing 4100 to transport the raw materials while rotating to one side. A transfer screw 4200 having a plurality of blades 4210 on the outer surface of the material; Including,
A plurality of anti-adhesion parts 4211 are formed at the edges of the blade 4210 at regular intervals and for pulverizing the raw material adhered to the inner surface of the outer casing 4100,
Air of a predetermined pressure is introduced into the transfer screw 4200, and a plurality of injection holes 4220 are formed on the side of the transfer screw 4200 to scatter raw materials while the introduced air is discharged. Polymer dispersion system using a homogenizer. The method of claim 4,
A blocking plate 4221 is formed in the injection hole 4220 to prevent the raw material scattered from flowing into the hollow transfer screw 4200,
The blocking plate 4221 is a polymer dispersion system using a homogenizer, characterized in that when air is delivered at a predetermined pressure, it is opened to discharge the air, and when the air is delivered at a predetermined pressure or less, it is closed.

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