KR101455629B1 - One pass type dispersing and emulsifying apparatus - Google Patents

Abstract

The present invention relates to a stator having a fixed shearing protrusion on a shaft rotatably installed in a chamber of a dispersion and emulsification apparatus and a rotor having a rotating shearing protrusion, By applying a shearing force to the dispersion emulsification object inserted while rotating by the rotation of the shaft, dispersion emulsification object to be dispersed emulsified can be improved, and dispersion emulsification object having low viscosity and low viscosity as well as dispersion emulsification object having low viscosity can be treated The present invention relates to a one-pass type dispersion and emulsification apparatus.

Description

[0001] 1. One-Pass Type Dispersing and Emulsifying Apparatus [

The present invention relates to a stator having a fixed shearing protrusion on a shaft rotatably installed in a chamber of a dispersion and emulsification apparatus and a rotor having a rotating shearing protrusion, By applying a shearing force to the dispersion emulsification object inserted while rotating by the rotation of the shaft, dispersion emulsification object to be dispersed emulsified can be improved, and dispersion emulsification object having low viscosity and low viscosity as well as dispersion emulsification object having low viscosity can be treated The present invention relates to a one-pass type dispersing and emulsifying apparatus.

In general, the basic materials industry, ranging from foods, cosmetics, ink, paint, adhesives, coatings, fine chemicals and nano-new materials to advanced electronic materials, has a great influence on the quality of the finished product due to precise dispersion and emulsification. Currently, various types of dispersion emulsification apparatuses for dispersion emulsification have been developed and used.

As an embodiment of the dispersion and emulsification apparatus, Korean Patent Application No. 10-2012-29911 discloses a method in which the applicant of the present invention discloses an apparatus for dispensing a liquid material and a discharge port for discharging the liquid material, ; A shaft rotatably installed inside the chamber; A motor installed to rotate the shaft; A rotating impeller having a plurality of first blades extending in a circumferential direction and extending in a circumferential direction, the plurality of first blades extending in a circumferential direction; And a plurality of second blades extending in the longitudinal direction of the shaft at an inner surface of the chamber so as to be positioned around the rotation impeller, each of the second blades extending toward the center and spaced apart in the circumferential direction, And a stationary impeller disposed between the rotating impellers and causing the first blade to generate a shear force in the liquid material passing through the chamber by rotation relative to the second blade when the first blade rotates. Pass type dispersion and emulsification apparatus. &Quot;

However, in the conventional one-pass type dispersion and emulsification apparatus, there is still a limit in processing the dispersion-emulsified object having a high viscosity due to the structure of the first blade of the rotating impeller and the second blade of the fixed impeller in units of NANO, There is a desperate need to develop a dispersion and emulsification apparatus capable of treating a dispersion-emulsified object having a high viscosity in nanoseconds.

In order to solve the above-mentioned problems, the present invention is characterized in that a stator having a fixed shearing protrusion in a shaft rotatably installed in a chamber of a dispersion-emulsifying apparatus and a rotor having a rotating shearing protrusion are combined into a plurality of layers, By applying a shear force to the object of dispersed emulsification which is introduced while rotating by the rotation of the shaft relative to the fixed non-rotating shear projections, the efficiency of dispersion emulsification for the object to be emulsified is improved and the object of dispersion emulsification having low viscosity, The present invention also provides a one-pass type dispersion and emulsification apparatus capable of processing a dispersion emulsification object of the present invention.

In order to achieve the above-mentioned object, the present invention provides a method of manufacturing a semiconductor device, comprising: a chamber having a charging port for discharging a dispersion emulsified object and a discharging port for discharging a dispersion emulsified object; A shaft rotatably installed in the chamber; A motor connected to the shaft for rotating the shaft by driving; A shaft of a dispersing and emulsifying apparatus, which is rotatably provided on a shaft, and which is formed by a plurality of stages and is formed in a shaft and which does not move during rotation of the shaft, the shaft having an inlet for dispersed emulsification object formed perforated at the center, A stator having a fixed shear protrusion formed at an interval to be spaced apart from each other; And is rotatable together with the shaft so as to be positioned between the stacked stator and rotates together with the shaft so as to be sandwiched between the fixed shear projections formed concentrically from the center of one surface and spaced concentrically from the stator, And a rotor provided with a fixed shear projection that does not rotate and a rotating shear protrusion that disperses and emulsifies the object by applying a shearing force to the dispersed and emulsified object which is rotated while being rotated by the rotation of the shaft. .

It is also preferable that a center of the rotor is provided with a hollow shaft protruding from the center of the surface on which the rotation shear protrusion is formed so as to be freely rotatable on the shaft and positioned at the center of the dispersion emulsification object inlet when engaged with the stator.

In addition, the fixed shear projections preferably have a shape in which the end surface of the fixed shear projections becomes larger toward the fixed shear projections forming the outer concentric circles in the fixed shear projections forming the inner concentric circles.

”와 같은 부채꼴 형상으로 형성됨이 바람직하다.In addition, the fixed shear projections are formed such that both sides face the center of the stator,

&Quot; is preferable.

In addition, the rotary shear projections are formed by connecting the center of the rotor and the inner center of the rotary shear projections, as viewed from the bottom, as the end surface of the rotary shear projections increases from the rotary shear projections forming the inner concentric circle toward the rotation shear projections forming the outer concentric circular projections So as to form an acute angle.

In addition, it is preferable that an annular projection protruding along the circumference is formed on the upper surface edge of the stator, and an annular fitting portion depressed along the circumference is provided at the bottom edge of the stator so that the protruding protrusion can be fitted thereto correspondingly.

A stator and a rotor are vertically arranged on the shaft so as to be rotatable inside the chamber. The stator is fixed on the inner circumferential surface of the chamber so as to be vertically stacked, and a charging port is formed at the lower end of the chamber. It is preferable that a discharge port is provided on one side of the chamber so that the object to be dispersed and emulsified can be discharged from the chamber.

It is also preferable that the chamber provides a space through which the stator and the rotor can be combined into a plurality of layers, and a cover for opening and closing the inside of the chamber is coupled to the lower end of the chamber.

According to the one-pass type dispersion emulsification apparatus of the present invention, a stator having a fixed shearing protrusion on a shaft rotatably installed in a chamber of a dispersion emulsification apparatus and a rotor having a rotating shearing protrusion are combined into a plurality of layers, By applying a shearing force to the dispersed emulsion object inserted while rotating by the rotation of the shaft relative to the fixed shear projections of which the projections do not rotate, the dispersing emulsion efficiency of the dispersed emulsion object is improved and the fluidity It is possible to process a dispersion emulsification object having a low viscosity.

In addition, the effect of desired dispersion emulsification can be obtained by itself only by passing the dispersion emulsification object once along the path, and since the dispersion emulsification object to be forcedly fed to the inside of the chamber by the pump is intensively performed at high speed dispersion emulsification, Dispersed and emulsified with low viscosity and high viscosity can be dispersed and emulsified not only in micron units but also in nano units.

In addition, cavitation can be prevented to control the flow rate of the object to be dispersed and emulsified, and the stator and the rotor can be used variously for various applications by variously exchanging them, adding and removing them.

In addition, it is possible to carry out a defoaming function through treatment of a dispersion-emulsified object having bubbles, which can be rotated at a high speed while maintaining a precise gap, and air can be injected as needed to inject bubbles into the object to be dispersed and emulsified.

In addition, since the stator and the rotor are combined with each other in a plurality of layers, it is possible to achieve the effect that the dispersion emulsification object passes through the dispersing emulsification process only by passing through the object once, thereby enabling precise dispersion emulsification. By having the effect of installing the equipment, time and cost for maintenance and repair can be greatly reduced.

1 is a front view according to an embodiment of the present invention;
2 is a front sectional view according to an embodiment of the present invention;
FIG. 3 is a drawing of the main part according to the embodiment of the present invention. FIG.
4 is an exploded perspective view of an impeller according to an embodiment of the present invention.
5 is a cross-sectional view of an impeller according to an embodiment of the present invention.
6 is a plan view of a stator according to an embodiment of the present invention.
7 is a bottom view of a stator according to an embodiment of the present invention.
8 is a bottom view of a rotor according to an embodiment of the present invention.
9 is an enlarged view of a rotation shear projection according to an embodiment of the present invention;

Hereinafter, a configuration of a one-pass type dispersion and emulsification apparatus according to the present invention will be described with reference to the accompanying drawings.

The one-pass type dispersion and emulsification apparatus 100 according to the present invention disperses and emulsifies the dispersed and emulsified object as shown in FIGS. 1 to 3 to discharge the dispersed and emulsified object to the outside, A shaft 120 in which the rotor 140 and the stator 150 are fitted to each other in a portion provided in the chamber 110 and a motor 130 for rotating the shaft 120.

Here, the object of dispersion and emulsification according to the present invention may be used as a material for dispersing and emulsifying a material, such as a source, mayonnaise, cosmetic cream, toothpaste, adhesive, pigment of ink or paint, film coating agent, various thickener, foaming agent, Recycling solution. In the case of the environmentally-friendly recycling solution, it is possible to physically produce small particles by means of the one-pass type dispersion and emulsification apparatus according to the present invention to facilitate chemical environment treatment.

Meanwhile, the chamber 110 and the motor 130 of the one-pass type dispersion and emulsification apparatus according to the present invention are installed in the frame 160. The frame 160 is fixed by the shaft cover 161 so that the chamber 110 faces downward and the motor 130 is fixed by the fixing bracket 162 so as to be positioned at the upper end of the shaft cover 161. [ A coupling 132 connecting the shaft 131 of the motor 130 and the shaft 120 protruding to the upper end of the chamber 110 is installed in the shaft cover 161. The motor 130 and other components may be wrapped by the protective cover 163.

At the lower end of the chamber 110 is provided a discharge port 111 for discharging the object to be dispersed and emulsified and a discharge port 112 for discharging the dispersion and emulsification object in which dispersion and emulsification is completed is provided at one end of the chamber 110 side.

The inlet port 111 is connected to the inlet line 10 so as to supply the dispersion and emulsification object and the discharge port 112 is connected to the discharge port 112 for supplying the dispersion and emulsification object that has been dispersed or emulsified in the chamber 110 to an external storage tank or the like And is connected to the discharge line.

The discharge port 111 can maintain the discharging pressure of the dispersion emulsification object through the discharge port 112 as the dispersion emulsification object is supplied through the injection line 10 by the operation of an external pump.

As shown in FIG. 3, the shaft 120 is vertically installed in the chamber 110, so that the rotor 140 can be arranged vertically and the stator 150 can be fixed to be stacked up and down.

The chamber 110 provides a stacking space for stacking the stator 150. A cover 114 for opening and closing the inside of the chamber 110 is provided at the bottom of the chamber 110 and a cover 114 is coupled by bolts 115 for supporting the stator 150.

The inside of the chamber 110 can be opened and closed by the cover 114 so that the bolt 115 is released when the rotor 140 or the stator 150 breaks down and the cover 114 is detached, The rotor 140 or the stator 150 can be replaced.

The shaft 120 is rotatably installed inside the chamber 110 and is connected to the shaft 131 of the motor 130 by a coupling 132 while being installed to penetrate the chamber 110. The shaft 120 is preferably installed in the chamber 110 or the frame 160 through a bearing so that the shaft 120 can smoothly rotate within the chamber 110. In addition, an O-ring or the like may be provided at a coupling portion with the chamber 110 to maintain the airtightness of the chamber 110.

The motor 130 is mounted on the frame 160 so as to rotate the shaft 120. The rotational speed of the shaft 120 can be controlled by adjusting the rotational speed of the motor 130 by operating the frame 160 or a control panel 170 provided outside the frame 160. A cap 121 is coupled to one end of the shaft 120 to prevent detachment of the rotor 140.

The impeller installed inside the chamber 110 is composed of a combination of a stator 150 which is a fixed blade and a rotor 140 which is a rotating blade and the stator 150 and the rotor 140, 120 in the longitudinal direction.

4 to 7, the stator 150 is formed in a circular shape conforming to the inside of the chamber 110, and includes a shaft 120 provided to be rotatable within the chamber 110 of the dispersion and emulsification apparatus 100, Lt; / RTI > layer. 3, the uppermost stator 150 and the lowermost stator 150 are fixedly installed at the end of the chamber 110 or by other fixing means, so that the stator 150 is in a fixed state when the shaft 120 rotates .

The stator 150 is formed with a dispersed emulsion object inlet 151 so as to allow the object to be dispersed and emulsified. Accordingly, the dispersion emulsification object introduced into the chamber 110 flows into the stator 150, which is a plurality of layers, through the dispersion emulsification object inlet 151.

The inner surface of the stator 150 is formed in a recessed shape so that the rotor 140 can be completely inserted into the inner surface 155 of the stator 150, The fixed shear projections 152 are formed at intervals. The fixed shear projections 152 are formed to protrude upward from the obverse face 155. The fixed shear protrusion 152 is formed to have a length that does not deviate from the inside of the stator 150.

”와 같은 부채꼴 형상으로 형성된다.
At this time, the end face 156 of the fixed front end protrusion 152 gradually increases from the fixed concentric shear protrusion 152 to the fixed concentric shear protrusion 152, To the center of the stator (150). The shape of the fixed shear projections 152 is "

&Quot; as shown in Fig.

The fixed shear protrusions 152 are protruded so as to be concentric with the edge of the dispersion emulsified object inlet port 151 of the inner face 155 and the center of the outer circumferential edge of the dispersed emulsification object inlet 155 and a larger circumference, The fixed shear protrusions 152 may be formed so as to form two or more concentric circles according to the degree of dispersion emulsification with respect to the object to be emulsified.

The end surface 156 of the fixed front end protrusion 152 is lower than the upper surface of the stator 150 and the stator 150 is inserted into the stator 150. Therefore, The fixed shear projections 152 of the rotor 140 and the rotary shear projections 142 of the rotor 140 preferably have the same length.

An annular protrusion 153 protruding along the upper surface of the stator 150 is formed so that the stator 150 can be firmly stacked on the stator 150. The protrusion 153 is engaged with the bottom surface of the stator 150, A recessed annular fitting portion 154 conforming to the protruding protrusion 153 is formed. Therefore, the state 150 can be securely stacked in such a manner that the fitting portion 154 of the bottom surface of the other stator 150 is engaged with the projecting step 153 on the upper surface of the stator 150. [

The rotor 140 rotates together with the shaft 120 as it is installed in the shaft 120 so as to be positioned between the multi-layered stator 150. Specifically, the rotor 140 is inserted into the stator 150 in a fully inserted state, and a hollow shaft 141, which can be axially supported on the shaft 120, As shown in Fig. The hollow shaft 141 is positioned at the center of the dispersion emulsification object inlet 151 when coupled with the stator 150.

The other surface of the rotor 140 opposite to the rotation shear protrusion 142 is formed in a flat plane so as to coincide with the upper surface of the stator 150 when coupled to the inside of the stator 150.

A rotation shear protrusion 142 concentrically protruding from the center of one side except for the hollow shaft 141 is formed. The rotary shear projections 142 are formed so as to be positioned between the fixed shear projections 152 concentric with the rotary shear projections 142 concentrically formed when the stator 150 and the rotor 140 are coupled. 8, a rotation shear protrusion 142 protrudes from the center of the rotor 140 to form three concentric circles gradually increasing inward from the center of the rotor 140. However, the rotation shear protrusions 142 are not limited thereto, The rotation shear projections 142 may be formed so as to form at least one concentric circle.

The end surface 145 of the rotation shear protrusion 142 gradually increases from the rotation shear protrusion 142 forming the inner concentric circle toward the rotation shear protrusion 142 concentric with the outer circumference. The rotation shear projections 142 are formed in a shape inclined in the rotation direction at a line 143 connected to the center of the rotor 140 and the center of the rotation shear projections 142.

9 is a bottom view of a rotor according to an embodiment of the present invention. The rotation shear projections 142 are formed so that the rotation shear projections 142 are formed from the line 143 connecting the center of the rotor 140 and the inner center of the rotation shear projections 142 when viewed from the bottom surface of the rotor 140 And is formed to be turned in one direction of the rotor 140.

For example, the rotation shear protrusion 142 is formed to be rotated in the rotation direction so as to form an acute angle? With the line 143 connecting the center of the rotor 140 and the inner center of the rotation shear protrusion 142 as shown in FIG. The rotation shear projections 142 preferably have a line 143 connecting the center of the rotor 140 and the inner center of the rotation shear projections 142 and a center line 144 of the rotation shear projections 142 extending from 30 to 45 degrees It is better to form an angle.

When the shear force is applied to the object to be dispersed and emulsified in a state where the rotation shear protrusion 142 is inclined, the resistance of the object to be dispersed and emulsified decreases as compared with when the rotation shear protrusion 142 is formed in a radial direction from the center of the rotor 140 without tilting While the shear force is increased, thereby further improving the efficiency of dispersion emulsification.

The length of the rotary shear protrusion 142 is preferably equal to the length of the fixed shear protrusion 152 so that the rotor 140 can be completely inserted into the stator 150. The end surface 145 of the rotation shear protrusion 142 may be provided in close contact with the inner surface 155 of the stator 150 when the stator 150 and the rotor 140 are coupled with each other, It is preferable that the stator 150 and the stator 150 are spaced apart from each other at a finer interval than the stator 150 is in close contact with the stator surface 155.

When the stator 150 is stacked in a plurality of layers, the stator 150 may be tightly coupled to the stator 150 by compressing and joining the stator 150 with an O-ring or a packing. .

The stator 150 having the fixed shear projections 152 and the rotary shear projections 142 are provided on the shaft 120 installed to be rotatable in the chamber 110 of the dispersing and emulsifying apparatus 100. [ The rotor 140 is combined into a plurality of layers so that the shear force is applied to the dispersed and emulsified object inserted while being rotated by the rotation of the shaft 120 relative to the fixed shear protrusion 152 in which the rotating shear protrusion 142 does not rotate, It is possible to process a dispersion-emulsified object having a low viscosity as well as a dispersion-emulsified object having a low viscosity as well as a dispersion-emulsified object having a high viscosity to have a high efficiency of dispersion emulsification for a dispersion-emulsified object. .

As shown in Figs. 1 to 3, the motor 130 is driven and the object to be dispersed and emulsified is poured into the inlet 111 using the pumping force of the pump. The dispersion emulsification object charged into the chamber 110 through the inlet port 111 is connected to the fixed shear projections 152 of the stator 150 coupled to the plurality of layers through the dispersion emulsification object inlet 151 of the stator 150 disposed at the lowermost stage And the interval between the rotation shear projections 142 of the rotor 140. [

4 to 7, when the stator 150 is stacked in a plurality of layers, the annular protrusion 153 formed on the upper surface of the stator 150 has an annular fitting portion 154 formed on the bottom surface of the other stator 150 Since the stator 150 is coupled in a stacked manner, the stator 150 is firmly engaged with the stator 150. [

The rotary shear projections 142 of the rotor 140 are positioned between the fixed shear projections 152 of the concentric stator 150 and are fixed to the fixed shear projections 152 And applies a shear force to the dispersion emulsification object flowing into the rotor 140 to disperse and emulsify the dispersion emulsification object.

Here, since the dispersion emulsification object is dispersed and emulsified several times while passing through the rotation shear protrusions 142 of the rotor 140 having a plurality of concentric circles as shown in Fig. 8, the dispersion emulsification object can not be compared with the conventional dispersion emulsification apparatus It is possible to disperse and emulsify a dispersed and emulsified object having a high viscosity and low fluidity in a micron unit as well as a nano unit due to a high shearing effect.

9, since the rotation shear protrusion 142 is inclined toward the rotation direction of the rotor 140 from the center of the rotor 140, the rotation shear protrusion 142 does not tilt, The shear force can be maximized while minimizing the resistance when the object of dispersion and emulsification collides with the rotary shear protrusion 142 as compared with the case where the object is radially formed from the center of the rotating shear protrusion 142.

As described above, the present invention can concentrically and efficiently disperse and emulsify the disperse and emulsified objects passing through the rotary shear projections 142 rotating relatively to the fixed shear projections 152.

The object to be dispersed and emulsified, which is dispersed and emulsified in nano units while passing through the stator 150 and the rotor 140 constituting a plurality of layers, is discharged out of the chamber 110 through the final discharge port 112.

As described above, the present invention can disperse and emulsify a dispersion-emulsified object in its original state only by itself passing the dispersion-emulsified object once along the path, and prevent the cavitation phenomenon, And it is possible to perform multistage dispersion and emulsification treatment, and it is possible to precisely distribute multi-stage according to the use and use conditions, and also has the effect of installing several pieces of equipment in the existing process so that the time and cost Can be saved.

While the preferred embodiments of the present invention have been described in detail with reference to the accompanying drawings, it is to be understood that the invention is not limited to the details of the illustrated embodiments, but various modifications and changes may be made without departing from the scope of the present invention. Accordingly, the scope of the present invention should be defined by the following claims.

10: input line 100: dispersion emulsification device 110: chamber
111: inlet 112: outlet 114: cover
115: bolt 120: shaft 121: cap
130: motor 131: shaft 132: coupling
140: rotor 141: hollow shaft 142: rotary shear projection
143: ship 144: centerline 145: end face
150: stator 151: dispersion emulsification object inlet port 152: fixed shear projection
153: protruding jaw 154: fitted portion 155:
156: end face 160: frame 161: shaft cover
162: fixing bracket 163: protective cover 170: control panel

Claims (8)

A chamber provided with a discharge port for discharging the dispersion emulsified object and a discharge port for discharging the dispersion emulsified object; A shaft rotatably installed in the chamber; A motor connected to the shaft for rotating the shaft by driving; A shaft of a dispersing and emulsifying apparatus, which is rotatably provided on a shaft, and which is formed by a plurality of stages and is formed in a shaft and which does not move during rotation of the shaft, the shaft having an inlet for dispersed emulsification object formed perforated at the center, A stator having a fixed shear protrusion formed at an interval to be spaced apart from each other; And is rotatable together with the shaft so as to be positioned between the stacked stator and rotates together with the shaft so as to be sandwiched between the fixed shear projections formed concentrically from the center of one surface and spaced concentrically from the stator, A rotor having a fixed shear protrusion which does not rotate, and a rotary shear protrusion which is dispersed and emulsified by applying a shearing force to a dispersed and emulsified object inserted while being rotated by the rotation of the shaft; And,
At the center of the rotor,
A hollow shaft protruding from the center of the surface on which the rotation shear protrusion is formed so as to be able to freely condense on the shaft and positioned at the center of the dispersion-emulsified object inlet port when engaged with the stator,
In the fixed shear projections,
The end face of the fixed shear protrusion becomes larger toward the fixed shear protrusion forming the outer concentric circle from the fixed shear protrusion forming the inner concentric circle,
In the fixed shear projections,
Both sides face the center of the stator "

&Quot; and "
The rotating shear-
As the end surface of the rotating shear projections increases from the rotating shear projections forming the inner concentric circle to the rotating shear projections forming the outer concentric circle, the end surfaces of the rotating shear projections become larger, so as to form an acute angle with the line connecting the center of the rotor to the inner center of the rotary shear projections Is formed so as to be twisted,
An annular protrusion protruding along the circumference is formed on the upper surface of the stator. An annular fitting portion is formed at the bottom edge of the stator so as to be able to engage with the protrusion,
A stator and a rotor are vertically arranged in the chamber so that the shaft is rotatable inside the chamber. The stator and the rotor are vertically arranged on the shaft. The stator is fixed to be vertically stacked on the inner circumferential surface of the chamber. And a discharge port is provided on one side of the chamber so as to discharge the object of dispersion and emulsification from the chamber,
Wherein the chamber is provided with a space through which the stator and the rotor can be coupled in a plurality of layers, and a cover for opening and closing the chamber interior is coupled to the lower end of the chamber. delete delete delete delete delete delete delete

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