KR102251236B1 - tandem type emulsifying and dispersing device using ultrasonic transducer - Google Patents

Abstract

The present invention relates to a tandem type emulsifying and dispersing device using an ultrasonic transducer, which includes: a container containing a fluid containing a dispersion sample; a body for accommodating the container and cooling water through an inner receiving space; a first transducer disposed at regular intervals along an upper end circumferential surface of the body to apply ultrasonic waves of a constant band toward an upper end of the container; and a second transducer disposed at regular intervals along the circumferential surface of the lower end of the body to apply ultrasonic waves of a band different from that of the first transducer toward a lower end of the container. According to the present invention, not only the dispersion of the dispersion sample contained in the fluid can be smoothly dispersed, but also the emulsification of an emulsified sample contained in the fluid can be smooth.

Description

Tandem type emulsifying and dispersing device using ultrasonic transducer}

The present invention relates to an emulsifying and dispersing device, and more particularly, an ultrasonic transformer that not only facilitates dispersion of a dispersed sample contained in a fluid, but also facilitates the emulsification of an emulsified sample contained in a fluid. It relates to a tandem emulsifying and dispersing device using a ducer.

Nanoparticles have a diameter of 1-100 nm and have electrical, optical, and magnetic properties different from those of ordinary materials due to the feature of having a large surface area compared to the volume.

Accordingly, the nano-convergence industry is attracting attention to the manufacturing of nanocomposite materials having various and complex functions such as mechanical, chemical, and optical properties by adding nanoparticles into a polymer resin.

On the other hand, nanoparticles have a relatively large cohesive force between particles, so there is a problem that the physical properties of the nanoparticles cannot be exhibited due to the property of the particles to form an aggregate.

In order to solve such a problem, research is being conducted to ensure that nanoparticles have high dispersibility in various polymer resins.

For example, as disclosed in Korean Patent Publication No. 10-1583752, ultrasonic waves are applied to an epoxy mixture in which an epoxy resin and nanoparticles are mixed to achieve dispersion of the nanoparticles.

However, conventional nanoparticle dispersing devices using ultrasonic waves are difficult to generate strong acoustic power by using planar ultrasonic waves such as an ultrasonic bath or homogenizer, and there is a problem in that the dispersion of nanoparticles is not uniform due to the anaari standing wave sound field distribution. .

In addition, the conventional nanoparticle dispersing device using ultrasonic waves has a problem in that it is difficult to supply electrical energy because the electrical input impedance is extremely low as a cylindrical transducer having a large diameter is used.

Accordingly, a'nano particle dispersion device using ultrasonic streaming and shock waves' of Korean Patent Publication No. 10-1814103 has been proposed.

In the'nanoparticle dispersion device using ultrasonic streaming and shock waves', the transducer is not only disposed along the circumferential surface of the body, but also disposed inclined at a certain angle, so that a vortex is formed in the suspension by ultrasonic waves applied from the transducer. In addition, since the shock wave is driven, the dispersion of the nanoparticles could be smooth.

However, the'nanoparticle dispersing apparatus using ultrasonic streaming and shock wave' had no choice but to apply only a certain band of ultrasonic waves, and thus there was a problem in that the dispersion effect of the nanoparticles was limited.

Korean Registered Patent Publication No. 10-1583752

The present invention has been proposed in order to solve the problems of the prior art as described above, and is an ultrasonic transformer that not only makes the dispersion of the dispersion sample contained in the fluid smooth, but also makes the emulsification of the emulsified sample contained in the fluid smooth. Its purpose is to provide a tandem emulsifying and dispersing device using a ducer.

In order to achieve the above object, the present invention,

A container containing a fluid containing a dispersion sample; A main body for accommodating the container and cooling water through an inner receiving space; A first transducer disposed at regular intervals along the circumferential surface of the upper end of the main body to apply a predetermined band of ultrasonic waves toward the upper end of the container; And a second transducer disposed at regular intervals along the circumferential surface of the lower end of the main body to apply ultrasonic waves of a band different from that of the first transducer toward the lower end of the container. And a dispersing device.

The container includes a circulation line for circulating the fluid.

The circulation line may include a fluid storage tank for storing the fluid and a pump for forcibly flowing the fluid.

In the main body, as a step is formed between the upper end and the lower end, the open width of the upper end is smaller than the open width of the lower end.

The main body includes a blocking member coupled to the first and second transducer coupling portions.

The blocking member may be a rubber plate having a certain thickness.

The first transducer applies a high frequency in the MHz band.

The second transducer applies a low frequency in the KHz band.

As the first and second transducers move forward and backward by a moving member, a distance between the first and second transducers may be adjusted.

The second transducer may apply ultrasonic waves at the same time or at a time difference with the first transducer.

The tandem type emulsifying and dispersing device using the ultrasonic transducer according to the present invention includes a first transducer and a second transducer, so that high-frequency and low-frequency are transmitted to the fluid in the container by the first and second transducers. As a result, a relatively large agglomerated dispersion sample is dispersed in a lump form by a low frequency, and a relatively small agglomerated dispersion sample is finely dispersed by a high frequency, so that the dispersion of the dispersed sample can be smoothly dispersed by a double dispersion.

In addition, the tandem emulsifying and dispersing device using the ultrasonic transducer according to the present invention is a bar in which the first transducer and the second transducer are moved by the moving member, and the distance from the first transducer to the container and the second transducer Since the distance from the transducer to the container is adjusted, high-frequency and low-frequency waves by the first and second transducers can be smoothly transmitted to the dispersed and emulsified samples contained in the fluid, further dispersing the dispersed sample and emulsifying the emulsified sample. It can be smooth.

1 is a perspective view showing the appearance of a tandem emulsifying and dispersing device using an ultrasonic transducer according to the present invention.
2 is a cross-sectional view illustrating the structure of a tandem emulsifying and dispersing device using an ultrasonic transducer according to the present invention.
3 is an exemplary view showing an arrangement of a first transducer in a tandem emulsifying and dispersing device using an ultrasonic transducer according to the present invention.
4 is an exemplary view showing another arrangement of the first transducer in the tandem emulsifying and dispersing device using the ultrasonic transducer according to the present invention.
5 is an exemplary view showing dispersion of a dispersion sample by a first transducer in a tandem emulsifying and dispersing apparatus using an ultrasonic transducer according to the present invention.
6 is an exemplary view showing dispersion of a dispersion sample by a second transducer in a tandem emulsifying and dispersing apparatus using an ultrasonic transducer according to the present invention.
7 is an exemplary view showing the emulsification of an emulsified sample using a tandem emulsifying and dispersing device using an ultrasonic transducer according to the present invention.
8 is an exemplary view showing the forward and backward movement of the first transducer in the tandem emulsifying and dispersing device using the ultrasonic transducer according to the present invention.
9 is an exemplary view showing the forward and backward movement of a second transducer in a tandem emulsifying and dispersing device using an ultrasonic transducer according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figures 1 and 2, the tandem type emulsifying and dispersing apparatus (A) using the ultrasonic transducer according to the present invention includes a container 10; Main body 20; A first transducer 30; And a second transducer 40;

The container 10 of the present invention accommodates the fluid 100 containing the dispersion sample 110.

Therefore, mixing of the fluid 100 and the cooling water 200 in the body 20 is prevented by the container 10.

At this time, the container 10 includes a circulation line 11 for circulating the fluid 100, so that the dispersion sample 110 may be continuously dispersed.

Here, the circulation line 11 includes a fluid storage tank 11b and a pump 11a for storing the fluid 100, so that the fluid 100 stored in the fluid storage tank 11b is forced to flow by the pump 11a. Accordingly, the circulation of the fluid 100 within the container 10 may be smooth.

On the other hand, the container 10 may be any kind of ordinary as long as it can smoothly accommodate the fluid 100, and may be a glass container 10 as an example.

In addition, the fluid 100 containing the dispersion sample 110 accommodated in the container 10 may be of any kind of general, and an example may be a suspension containing nanoparticles.

In addition, the fluid 100 including the dispersion sample 110 accommodated in the container 10 may include an emulsified sample 120 such as oil.

The main body 20 of the present invention accommodates the container 10 and the cooling water 200 through the inner receiving space 21.

Therefore, the fluid 100 is cooled by the body 20.

At this time, in the main body 20, a step is formed between the upper end and the lower end, so that the open width of the upper end is smaller than the open width at the lower end.

Accordingly, the first transducer 30 disposed on the upper circumferential surface of the main body 20 is closer to the container 10 than the second transducer 40 disposed on the lower circumferential surface of the main body 20.

In addition, the body 20 includes a blocking member 22 that is coupled to a coupling portion of the first and second transducers 30 and 40, and thus the body 20 and the first transducer are formed by the blocking member 22. As the mechanical separation of 30 and the mechanical separation of the main body 20 and the second transducer 40 are performed, the main body in the process of applying ultrasonic waves by the first transducer 30 and the second transducer 40 (20) Vibration and noise generation, etc. are suppressed.

Here, since the blocking member 22 is a rubber plate having a certain thickness, the vibration of the main body 20 is suppressed by the blocking member 22, and the first and second transducers 30 and 40 are coupled to each other. Through the cooling water 200 can be prevented from leaking.

The first transducer 30 of the present invention is disposed at regular intervals along the circumferential surface of the upper end of the main body 20 to apply a certain band of ultrasonic waves toward the upper end of the container 10.

Accordingly, as ultrasonic waves are applied from the first transducer 30, the dispersion sample 110 is dispersed in the fluid 100 accommodated in the container 10.

At this time, the first transducer 30 is disposed to be inclined at a predetermined angle with respect to the inner tangent line of the main body 20 so that the vortex flows into the fluid 100 in the container 10 by ultrasonic waves from the first transducer 30. Can be formed.

In addition, the first transducer 30 applies a high frequency in the MHz band, whereby the relatively small agglomerated dispersion sample 110 is finely dispersed.

In addition, since the first transducer 30 moves forward and backward by the moving member 31, the distance between the first transducer 30 and the container 10 is adjusted, so that high frequency transmission to the fluid 100 may be smoothly performed.

Here, the moving member 31 may be of any conventional structure and method as long as it is capable of moving the first transducer 30 forward and backward, and as an example, the tip is helically engaged with the circumferential surface of the body 20 It may be in the form of a tube in which the first transducer 30 is inserted and installed inside.

Therefore, by rotating the tube-shaped moving member 31, the first transducer 30 can be moved forward and backward simply.

The second transducer 40 of the present invention is disposed at regular intervals along the circumferential surface of the lower end of the main body 20 to apply ultrasonic waves of a band different from that of the first transducer 30 to the lower end of the container 10. .

Accordingly, as ultrasonic waves are applied from the second transducer 40, the dispersion sample 110 is dispersed in the fluid 100 accommodated in the container 10.

At this time, the second transducer 40 applies a low frequency in the KHz band, thereby dispersing the relatively largely agglomerated dispersion sample 110 in a lump form.

In addition, since the second transducer 40 moves back and forth by the moving member 41, the distance between the container 10 and the container 10 is adjusted, so that low-frequency transmission to the fluid 100 may be smoothly performed.

Here, the moving member 41 is the same as the moving member 31 for moving the first transducer 30, and further detailed description of the moving member 41 will be omitted.

Meanwhile, the second transducer 40 may operate simultaneously with the first transducer 30 or at a time difference.

Accordingly, high-frequency and low-frequency waves may be applied to the fluid 100 at the same time or may be applied at a time difference.

The tandem emulsifying and dispersing apparatus (A) using the ultrasonic transducer according to the present invention enables the dispersion of the dispersion sample 110 included in the fluid 100 to be smooth. This will be described in detail as follows.

In the container 10 of the present invention, a fluid 100 containing a dispersion sample 110, for example, a suspension containing nanoparticles is accommodated.

And the container 10 is accommodated in the receiving space 21 inside the body 20.

Meanwhile, ultrasonic waves are applied to the container 10 accommodated in the main body 20, that is, the fluid 100.

That is, in the present invention, the first transducers 30 disposed at regular intervals along the upper circumferential surface of the main body 20 and the second transducers 40 disposed at regular intervals along the lower circumferential surface of the body 20 ), the ultrasonic waves from the first and second transducers 30 and 40 are applied to the fluid 100.

Here, the first transducer 30 applies a high frequency in the MHz band, and the second transducer 40 applies a low frequency in the KHz band, so that the high frequency and the low frequency are sequentially applied to the fluid 100.

Therefore, among the dispersion samples 110 included in the fluid 100, the dispersion sample 110 at the lower end of the container 10 is dispersed by a low frequency applied from the second transducer 40, especially as shown in FIG. The largely agglomerated dispersion sample 110 is dispersed in a lump form by a low frequency, and among the dispersion samples 110 included in the fluid 100, the dispersion sample 110 at the upper end of the container 10 is the first transducer 30 Dispersion by the high frequency applied from ), in particular, since the relatively small agglomerated dispersion sample 110 is finely dispersed by the high frequency as shown in FIG. 5, the dispersion of the dispersion sample 110 can be smooth.

At this time, only the low frequency by the second transducer 40 is applied to the dispersion sample 110 at the lower end of the container 10, and only the high frequency by the first transducer 30 is applied to the dispersion sample 110 at the upper end of the container 10. Although it may seem only to be affected, this is only divided for convenience of description, and the fluid 100 in the container 10 is circulated by the circulation line 11, regardless of the position in the container 10. 110) can be applied evenly to high and low frequencies.

In addition, the first transducer 30 of the present invention is disposed at regular intervals along the circumferential surface of the upper end of the main body 20 as shown in FIG. 3, and the first transducer 30 of the main body 20 as shown in FIG. Since the high-intensity ultrasonic sound field is generated by the first transducer 30, a shock wave is generated by the ultrasonic cavitation, and a vortex is formed in the fluid 100 so that the shear force is generated. Therefore, dispersion of the dispersion sample 110 may be smoothly performed by the shock wave and shear force.

In addition, the first transducer 30 and the second transducer 40 of the present invention are moved by the moving members 31 and 41, and the first transducer as shown in FIGS. 8 and 9 ( 30) and the second transducer 40, the distance between the container 10 and the container 10 is adjusted by the forward and backward movement of the second transducer 40, so that the high-frequency and low-frequency waves by the first and second transducers 30 and 40 are applied to the fluid 100. Since it can be more smoothly delivered to the included dispersion sample 110, the dispersion of the dispersed sample 110 may be more smooth.

Meanwhile, the dispersion of the dispersion sample 110 has been described above, but the tandem emulsification and dispersion device A using the ultrasonic transducer according to the present invention not only enables the dispersion of the dispersion sample 110 to be smooth, but also The emulsification of the emulsified sample 120 is also made to be smooth.

That is, in the present invention, since the dispersion sample 110 and the emulsified sample 120 are forcibly circulated through the pump 11a, the dispersion effect is generated by the fluid shearing force action caused by the flow of the fluid 100, and thus the emulsified sample 120 Oil painting can also be smooth.

However, when the temperature of the fluid 100 increases during the dispersion and emulsification process as described above, dispersion and emulsification may be slow.

However, in the main body 20 of the present invention, not only the container 10 but also the cooling water 200 is accommodated, so that the fluid 100 maintains a constant temperature by cooling by the cooling water 200, the dispersion sample 110 The dispersion and emulsification of the emulsified sample 120 may be more smooth.

In addition, when dispersion and emulsification of a large amount of fluid 100 is required in the dispersion and emulsification process as described above, since the fluid 100 must be repeatedly injected into the container 10, it may be cumbersome.

However, in the present invention, since the container 10 includes a circulation line 11 for circulating the fluid 100, the dispersion sample 110 is dispersed as the fluid 100 is circulated by the circulation line 11 This can be done in succession.

That is, as the large amount of fluid 100 stored in the fluid storage tank 11b circulates through the container 10 by the circulation line 11, the dispersion sample 110 may be continuously dispersed.

At this time, since the circulation line 11 includes a pump 11a, the fluid 100 may be smoothly circulated as the fluid 100 is forced to flow by the pump 11a.

The present invention as described above is not limited to the above-described embodiments, and thus can be changed within the scope not departing from the gist of the present invention claimed in the claims, and such changes are defined by the following claims. It is within the scope of the invention.

10: container 11: circulation line
11a: pump 11b: fluid storage tank
20: main body 21: accommodation space
22: blocking member 30: first transducer
31: moving member 40: second transducer
41: moving member 100: fluid
110: dispersion sample 120: emulsified sample
200: cooling water A: emulsifying and dispersing device

Claims (10)

A container containing a fluid containing a dispersion sample;
A main body for accommodating the container and cooling water through an inner receiving space;
A first transducer disposed at regular intervals along the circumferential surface of the upper end of the main body to apply a predetermined band of ultrasonic waves toward the container; And
Including; a second transducer disposed at regular intervals along the circumferential surface of the lower end of the main body to apply ultrasonic waves of a band different from that of the first transducer toward the container,
The first transducer applies a high frequency in the MHz band, but applies high frequency in a state inclined at a predetermined angle with respect to the inner surface tangent of the main body, thereby generating a high-intensity ultrasonic sound field through a shock wave and a shear force due to the formation of a eddy current. Dispersing the dispersion sample contained in the fluid,
The second transducer disperses the dispersion sample contained in the fluid by applying a low frequency in the KHz band, but applying a low frequency at the same time or at a time difference with the first transducer,
The first and second transducers are inserted and installed in a tube-shaped moving member that is helically engaged with the circumferential surface of the body, and the distance with the container is adjusted according to the forward and backward movement of the moving member, and each of the moving members A tandem emulsifying and dispersing device using an ultrasonic transducer, characterized in that the contact with the main body is completely blocked as it is fitted into the blocking member coupled to the inside of the tip, and the circumference of the tip is wrapped by the blocking member. The method of claim 1,
The container is a tandem emulsifying and dispersing device using an ultrasonic transducer, characterized in that it includes a circulation line for circulating the fluid. The method of claim 2,
The circulation line is a tandem emulsifying and dispersing device using an ultrasonic transducer, characterized in that it comprises a fluid storage tank for storing the fluid and a pump for forcibly flowing the fluid. The method of claim 1,
The body is a tandem type emulsifying and dispersing device using an ultrasonic transducer, characterized in that as a step is formed between the upper end and the lower end, the open width of the upper end is smaller than the open width of the lower end. delete The method of claim 1,
The blocking member is a tandem emulsifying and dispersing device using an ultrasonic transducer, characterized in that the rubber plate of a certain thickness. delete delete delete delete

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