KR20090008008A - Apparatus for milling and dispersing without clogging for dispersion of carbon nano tube - Google Patents

Abstract

A crushing dispersion device having an ultrasonic generator is provided to disperse efficiently slurry including a carbon nanotube and having a constant concentration or more and to prevent plug situation by dispersing crushing corpuscles uniformly. A crushing dispersion device contains a rotation rotor(103) accommodating a pulverizing medium and rotated by an axis, a vessel(10) accommodating the rotation rotor, an impeller(102) adding pressure to raw slurry which is installed at an upside of the vessel and conducting flow of the slurry, a milling disc(101) installed with the impeller, an influx passage(16) flowing in the slurry, an outflow passage(14) discharging the slurry, a collection tank(12) collecting the pulverized slurry, an ultrasonic generator(13) installed at a cycle of the slurry in order to generate an ultrasonic wave inside the vessel and a cooling unit(15) for supplying cooling water to the vessel.

Description

Apparatus for Milling and Dispersing without Clogging for Dispersion of Carbon Nano Tube}

The present invention relates to a pulverizing and dispersing apparatus capable of preventing clogging of an outlet using an ultrasonic generator, and specifically, pulverized in a bead mill and a bead mill for uniformly dispersing pulverized particles in the process of pulverizing the particles to a predetermined size or less. The present invention relates to a grinding and dispersing apparatus having an ultrasonic generator capable of preventing the slurry outlet from being blocked by the fine particles, thereby preventing the circulation of the slurry.

Crushers are used to grind and disperse inks, paints, abrasives, ceramics or pharmaceuticals and various forms such as continuous wet mills are known in the art.

The known grinder is a sealed grinding container 41 consisting of an inner housing 43 and a separating pin housing 44, a separating pin housing 44 surrounding a grinding container 41 with a plurality of slits, as shown in FIG. , A rotating rotor 45 for stirring the slurry, a through hole 46 serving as a flow path for the grinding medium and the grinding slurry, and an inlet and an outlet for introducing the slurry and discharging the grinding slurry. do. Known grinders grind the slurry using the stresses and frictional forces that occur due to collisions with the slurry, which are caused by irregular movement of the grinding media when the rotary rotor 45 rotates. However, in the case of a slurry having a high viscosity, irregularities of the grinding media are reduced, thereby reducing the grinding and dispersing efficiency.

Patent Publication No. 2004-12438 is a prior art for solving such a problem. The prior art proposes a grinder in which a disc having a rotating arm is installed in the container body in order to solve the problem of the known grinder. The prior art has the advantage that it is possible to prevent the reduction of the grinding efficiency due to the increase in viscosity. However, there is a problem that the grinding slurry is agglomerated or entangled, which makes it difficult to separate the grinding slurry efficiently by the separating plate.

The dispersion of the carbon nanotubes is a method of dispersion and surface functionalization using a solvent and a dispersant, a dispersion using a polymer, and mechanical dispersion. The method using a solvent is a method in which a single-walled carbon nanotube (SWCNT) is added to an aqueous solution of sodium dodecyl sulphhate (SDS), which is a surfactant, dispersed by ultrasonication, and centrifuged again. In this case, there is an advantage that can maintain the properties and length of the single-wall carbon nanotubes inherent, but there is a disadvantage that the removal of the surfactant in a later process can be a big problem and the maximum dispersion concentration is 1% level. Surface functionalization can be used in applications requiring high conductivity as a method of chemically modifying the polarity inherent in the graphite structure in order to weaken the intermolecular force by efficient dispersing. However, it is very difficult to obtain pure single-walled carbon nanotubes in the synthesis step, and the solubility of carbon nanotubes in the liquid phase is low, making it difficult to use the molecular single-walled carbon nanotubes. The method of using a polymer to disperse carbon nanotubes in a polymer chain and disperse them in a solution shows more uniform dispersion than physical force. This method is efficient when producing carbon nanotube-polymer composites. In the case of mechanical dispersion, a basket mill, dyno mill, and attrition mill are used, and the separator is passed through a grid or filter at intervals to separate the beads and the dispersion medium. However, carbon nanotubes having a high aspect ratio have a problem that it is difficult to disperse more than a certain concentration due to clogging of a grid or a filter as the viscosity increases by itself as the dispersion process proceeds.

The present invention is to solve the problems of the prior art has the following object.

An object of the present invention is to provide a grinding and dispersing apparatus having an ultrasonic generator capable of preventing clogging by uniformly dispersing the ground fine particles in the process of grinding the particles to a predetermined size or less.

It is another object of the present invention to provide a grinding and dispersing apparatus having an ultrasonic generator for efficiently dispersing and preventing clogging of a slurry including carbon nanotubes having a predetermined concentration or more.

According to a preferred embodiment of the present invention, the grinding and dispersing device includes a rotating rotor for receiving a grinding medium and rotated by a shaft; A vessel containing a rotating rotor; An impeller installed at the top of the vessel and applying pressure to a raw material slurry to induce a flow of the slurry; Milling discs installed under the impeller; An inflow passage for introducing a slurry; An outlet passage for discharging the slurry; A collection tank for collecting the ground slurry; An ultrasonic generator installed in a circulation path of the slurry to generate ultrasonic waves inside the vessel; And a cooler for supplying coolant to the vessel.

According to another suitable embodiment of the present invention, it further comprises a metering pump installed outside the vessel to forcibly circulate the ground slurry.

According to another suitable embodiment of the invention, the slurry comprises carbon nanotubes.

The grinding and dispersing apparatus according to the present invention has the advantage of preventing uniform clogging of the finely ground grinding slurry to enable uniform dispersion. And through the forced circulation of the slurry supply due to the adjustment of the pressure has the advantage that the efficient circulation and pulverization is made.

In addition, by overcoming the problems of the conventional dispersion of carbon nanotubes, it is possible to efficiently disperse the carbon nanotubes by separating and cutting the carbon nanotubes respectively by mechanical treatment after primary dispersion. Therefore, the pulverizing and dispersing apparatus of the present invention has the advantage that the dispersion of the carbon nanotubes more than a certain concentration is effective by preventing the carbon nanotubes to be blocked by the ultrasonic treatment.

Hereinafter, the present invention will be described in detail using the embodiments set forth in the accompanying drawings. The examples presented are exemplary for clarity of understanding and are not intended to limit the scope of the invention.

1 shows a schematic configuration of a grinding and dispersing apparatus according to the present invention.

Referring to Figure 1, the dispersing device receives the grinding media and rotates by rotating the rotor 103 by the shaft, the vessel 10 for receiving the rotary rotor, the pressure applied to the raw material slurry is installed above the vessel downwards An impeller 102 to flow, a milling disc 101 installed below the impeller, an inlet passage 16 for introducing the slurry, an outlet passage 14 for discharging the slurry, an ultrasonic generator 13 for generating ultrasonic waves, The metering pump 11 may include a cooler 15 for supplying cooling water and a tank 12 for collecting pulverized powder or fine particles.

The vessel 10 includes a rotor 103 held by a central axis, and an impeller 102 formed above the vessel. The impeller 102 compresses and flows the introduced raw material slurry to prevent backflow. The circulation of the raw material slurry is effected by the action of the impeller and the pump. Although not shown in FIG. 1, another impeller may be installed below the vessel as needed. Another impeller at the bottom discharges the ground slurry using the pressure difference of the vessel. The central axis is connected to the motor to rotate. The coolant is circulated between the cooler and the vessel by being introduced into the vessel through the coolant inlet through the valve from the cooler and discharged through the coolant outlet. The ground slurry may be discharged through the slurry outlet passage 14 or to the outside through the central axis. A metering pump 11 is installed for circulating or discharging such a pulverized slurry. The metering pump 11 forces the slurry into the vessel via the inlet passage 16 and discharges it through the outlet passage 14 or through the central axis. As such, the grinding and dispersing apparatus according to the present invention is characterized by forced circulation of the slurry by the metering pump 11. The raw material slurry injected into the vessel 10 is pulverized and discharged by beads between the rotors 103 while flowing upward by the rotation of the impeller 102. As the wet stirring mill is known, the slurry is pulverized by stirring and mixing a medium and a raw material slurry such as steel beads or aluminum zirconia beads present in the basket by the rotation of the rotor.

The metering pump 11 artificially generates a force like a pressure pump so that the slurry is forcedly circulated. The rotary rotor 103 can be of any shape known in the art and the grinding media can be a plurality of balls. The rotary rotor 103 may be accommodated in the vessel 10, rotated by a central axis connected through the vessel 10, and a portion where the central axis passes through the vessel 10 may be a seal.

An ultrasonic generator 13 may be installed in the slurry outlet passage as shown in FIG. 1. The slurry introduced into the vessel continues to circulate while being pulverized. If the pulverized slurry is agglomerated in this process, the slurry is not smoothly discharged. Ultrasonic waves generated by the ultrasonic generator are delivered to the inside of the vessel and the outlet passage to prevent agglomeration of the slurry to induce a smooth flow of the pulverized slurry. When the outlet passage 14 is installed inside the ultrasonic generator 13, the efficiency of dispersion can be improved. Also, the ultrasonic generator may be installed on the inflow passage 16 side. In this way, the ultrasonic waves generated by the ultrasonic generator 13 are transferred into the vessel to prevent agglomeration of the ground slurry.

Figure 2 shows an embodiment of the ultrasonic generator that can be applied to the grinding and dispersing apparatus according to the present invention.

In general, ultrasonic generators generate ultrasonic waves by piezoelectric ceramics and ultrasonic vibrators that convert electrical energy into mechanical vibration energy using reverse piezoelectric effect phenomena, as known in the art, and to increase the amplitude of the generated ultrasonic waves. It may include an ultrasonic oscillator for attaching and driving the booster and the horn.

Specifically, referring to FIG. 2, the ultrasonic generator 2 includes a frequency shaping circuit 22 which generates a low frequency and output ultrasonic wave to generate a waveform of a predetermined shape to generate ultrasonic waves of 10 to 30 Hz; A sinusoidal wave generator circuit 24 for generating a sinusoidal wave by inputting a commercial frequency; A synchronization circuit 25 for synchronizing the frequency generated by the oscillation circuit 21 with the input sine wave; An amplifier 23 for amplifying the generated ultrasonic waves; A divider circuit 26 for adjusting a generation period of the ultrasonic wave in the form of a pulse; And a gate signal circuit 27 for periodically inducing the generation of ultrasonic waves in the form of pulses; And a vibrator 28 vibrating by the generated ultrasonic waves.

The ultrasonic generator 2 applied to the grinding separator may be of any type known in the art and specifically the oscillator circuit 21 may comprise a crystal oscillator or a transistor oscillator and the frequency shaping circuit 22 Ultrasonic waves can be stably generated by a flip flop circuit. The sinusoidal wave generation signal 24 may adjust the ultrasonic output timing by receiving a commercially available 60 Hz signal. The synchronization circuit 25 is used to synchronize the output of the sinusoidal wave generation signal 24 to the ultrasonic oscillation frequency and the gate signal circuit 27 may be a silicon controlled rectifier (SCR). Transducer 24 may be any transducer known in the art for converting high frequency electrical signals to ultrasonic acoustic signals. In addition, the ultrasonic generator may generate ultrasonic waves of various frequencies in consideration of the type of fluid present in the vessel, and as described above, the ultrasonic generator generates ultrasonic waves inside the vessel of the grinding / dispersing apparatus. To prevent clogging or entanglement due to the ground slurry, leading to effective dispersion of the ground slurry.

Figure 3 schematically shows the grinding process of carbon nanotubes.

In general, the dispersion of carbon nanotubes may be performed by various methods, and the mechanical dispersing apparatus may include a roll mill, an attention mill, a basket mill, and a bead mill. ), Etc. There is also a method in which carbon nanotubes are placed in a solvent such as alcohol and sonicated by ultrasonic technology.

Specifically, referring to FIG. 3, the dispersion of the carbon nanotubes is pulverized into a small mass 31 by the agglomeration of the carbon nanotube agglomerates 30, and sonicated to each carbon nanotube 32 by an ultrasonic treatment. Separated and cut. In the present invention, the carbon nanotubes dispersed by the dispersion medium are separated and cut into respective carbon nanotubes by ultrasonic waves generated by an ultrasonic generator. The mill and disperser according to the present invention allows such a dispersion process to occur sequentially in a single device to enable efficient dispersion of carbon nanotubes. In addition, a solvent used for dispersing conventional carbon nanotubes such as alcohols, sodium dodecyl sulphate (SDS), and ethanol may be added through the carbon nanotube inlet for efficient dispersion. .

While the invention has been described in detail using the examples presented, those skilled in the art will recognize that various modifications and variations of the embodiments are possible. The present invention is not limited by these modifications and variations, but only by the appended claims.

1 shows a schematic configuration of a grinding and dispersing apparatus according to the present invention.

Figure 2 shows an embodiment of an ultrasonic generator that can be applied to the grinding and dispersing apparatus according to the present invention.

Figure 3 schematically shows the grinding process of carbon nanotubes.

4 shows a schematic configuration of a known grinding and dispersing apparatus.

Claims (3)

In the grinding and dispersing device, A rotary rotor that receives the grinding media and is rotated by the shaft; A vessel containing a rotating rotor; An impeller installed at the top of the vessel and applying pressure to a raw material slurry to induce a flow of the slurry; Milling discs installed under the impeller; An inflow passage for introducing a slurry; An outlet passage for discharging the slurry; A collection tank for collecting the ground slurry; An ultrasonic generator installed in a circulation path of the slurry to generate ultrasonic waves inside the vessel; And Grinding and dispersing device comprising a chiller for supplying coolant to the vessel. The grinding and dispersing device of claim 1, further comprising a metering pump installed outside the vessel to forcibly circulate the ground slurry. The grinding and dispersing device of claim 1, wherein the slurry comprises carbon nanotubes.

Images