KR101708376B1 - Bead mill - Google Patents

Abstract

The present invention relates to a bead mill dispersing product particles of various fields such as aircraft material, nanoparticle material, coloring paint, special chemical product, cosmetics, food and drug material, and pharmaceutical material and, more particularly, to a bead mill that is highly durable against vibration occurring during rotor rotation, is excellent in product particle dispersion efficiency, and is excellent in product particle dispersion rate. The present invention includes: an outer housing; a chamber coupled with the inside of the outer housing and having an injection port in the upper portion thereof; a rotor forming a dispersion section in the chamber by being placed with a gap inside the chamber and including a first dispersion projection protruding toward the dispersion section; an inner housing placed inside the rotor and including a screen adjacent to the dispersion section and a discharge port provided in a lower portion; and a bead member with which the chamber is filled.

Description

BEAD MILL}

The present invention relates to a bead mill for dispersing product particles in various fields such as aircraft related materials, nanoparticle materials, colored paints, special chemicals, cosmetics, pharmaceutical materials, pharmaceutical materials, The present invention relates to a bead mill which is superior in dispersion efficiency of product particles and superior in dispersing speed of product particles.

Bead mills have been used as means for spraying product particles in various fields such as aircraft-related materials, nanoparticle materials, coloring paints, specialty chemicals, cosmetics, pharmaceutical materials, pharmaceutical materials and the like to obtain appropriate fine particles.

1, the conventional bead mill Mt includes an injection port 21 into which product particles are injected, a discharge port 11 through which the dispersed product particles are discharged, a housing 1, A bead member B for colliding with the product particles to disperse the product particles, a rotor 3 mounted inside the chamber 2 to rotate, a rotor 3 And a dispersing protrusion 43 provided on the bead member B for imparting mobility to the bead member B through rotation.

Conventional bead mill Mt has a horizontal structure. According to the conventional technique of such a horizontal bead mill, Japanese Patent Application Laid-Open No. 10-2016-0010991 (Jan. 29, 2016) [Bead Mill] Prior art).

In the prior art, there is proposed a technique capable of increasing the productivity by inducing the flow of the bead and the raw material smoothly, and increasing the agitation time of the raw material to increase the grinding effect.

However, the horizontal type bead mill is suitable as a mass ejecting method, but disadvantageous in that the dispersion speed of the product particles is slow.

Also, since the prior art bead mill Mt and the conventional art have a single housing 1 structure, there is a problem that the durability of the conventional bead mill Mt can be deteriorated because it does not have a proper buffering means for the vibration generated by the rotation of the rotor 2 have.

In addition, since the inefficiency of the buffer means can be directly linked to the lowering of the dispersion efficiency of the product particles, the necessity of a technique capable of solving the above problems is reconsidered.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems,

And to provide a bead mill in which buffering is performed against vibrations generated during rotor rotation through a double housing structure.

It is also an object of the present invention to provide a bead mill in which product particles and bead members themselves are free-falling speed by weight through a vertical housing and a chamber structure, whereby the dispersion speed of product particles is excellent.

It is another object of the present invention to provide a compact bead mill which minimizes an occupied space by installing a bead mill while enhancing dispersion efficiency through a double dispersion structure and a circulation structure of a bead member.

 It is another object of the present invention to provide a bead mill which can further improve dispersing efficiency and dispersing speed through a triple dispersed projecting structure and a bead member of an appropriate size.

The present invention having the above object

A first dispersion protrusion protruded toward the dispersion unit, and a second dispersion protrusion protruded toward the dispersion unit, wherein the first dispersion protrusion is disposed on the inner side of the chamber, An inner housing disposed on the inner side of the rotor, the inner housing including a screen disposed adjacent to the dispersion unit and an outlet provided in a lower portion; and a bead member filled in the chamber.

Wherein the bead member comprises a first dispersing portion and an inner second dispersing portion, the first dispersing portion being connected to the injecting portion and the inner second dispersing portion, And the second dispersion protrusions may further include a second dispersion protrusion that protrudes from the inner wall of the inner housing toward the second dispersion portion, the first dispersion protrusions protruding from the partition wall portion toward the first dispersion portion .

And a third dispersion protrusion protruding from the inner wall of the chamber toward the first dispersion unit, wherein the first dispersion protrusion and the third dispersion protrusion are alternately arranged in a staggered manner, and the diameter of the bead member is 0.2 to 1.5 mm .

And a controller for controlling the rotation speed of the rotor through a control signal. The controller includes a level adjusting unit for adjusting a voltage level of the control signal to a predetermined level, a noise detecting unit for detecting noise introduced into the control signal, And a signal generating unit including a filtering unit for removing the detected noise and a filter driving unit for driving the filtering unit when the noise is detected.

According to the present invention,

And has improved durability by buffering vibration caused by rotor rotation.

In addition, because of the vertical housing-chamber structure, the dispersion speed of the product particles is superior to that of the conventional bead mill.

In addition, through the double dispersion structure and the circulation structure of the bead member, the space occupied by the bead mill installation can be minimized while increasing the dispersion efficiency.

Furthermore, it has an effect of having improved dispersing efficiency and dispersing speed through a triple dispersed projection structure and a bead member of an appropriate size.

1 shows a conventional bead mill.
2 is a conceptual view of a bead mill.
3 is a configuration diagram of a bead mill according to the present invention;
4 and 5 are explanatory diagrams of the bead member of the present invention.
6 is an embodiment of the present invention.

Before describing the present invention, it is to be understood that the present invention may be embodied with various changes, may take various forms, and embodiments (or embodiments) are described in detail herein. It is to be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

In the drawings, the same reference numerals are used for the same reference numerals, and in particular, the numerals of the tens and the digits of the digits, the digits of the tens, the digits of the digits and the alphabets are the same, Members referred to by reference numerals can be identified as members corresponding to these standards.

In the drawings, the components are expressed by exaggeratingly larger (or thicker) or smaller (or thinner) in size or thickness in consideration of the convenience of understanding, etc. However, It should not be.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the term " comprising " or " consisting of ", or the like, refers to the presence of a feature, a number, a step, an operation, an element, a component, But do not preclude the presence or addition of one or more other features, integers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

It is to be understood that the first to second aspects described in the present specification are merely referred to in order to distinguish between different components and are not limited to the order in which they are manufactured, It may not match.

The present invention relates to a bead mill for dispersing product particles in various fields such as aircraft related materials, nanoparticle materials, colored paints, special chemicals, cosmetics, pharmaceutical materials, pharmaceutical materials, The present invention relates to a bead mill which is superior in dispersion efficiency of product particles and superior in dispersing speed of product particles.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a bead mill (hereinafter, bead mill M) according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a conceptual diagram for explaining the concept of a bead mill.

2, a conventional bead mill includes a housing 1, a chamber 2, a rotor 3, and a bead member B. As shown in Fig.

In brief, the housing 1 is configured to protect the internal structure from external factors, and may be made of various materials such as a metal material or a reinforced synthetic resin.

The chamber (2) is provided inside the housing (1) with a structure for providing an internal space in which product particles are dispersed.

The rotor 3 rotates about the rotation axis and provides the activity of the bead member B by the centrifugal force through the dispersion projections 43 disposed inside the chamber 2, (2).

The bead member B freely moves inside the chamber 2 by the rotor 3 to disperse the product particles through impact, shearing, pressing, or the like caused by collision with the input product particles.

The bead mill disperses and discharges the product particles finely so that the product particles can be dispersed to a desired size so as to be suitably used in the product.

3 is a configuration diagram showing each configuration of the present invention. Hereinafter, each configuration of the bead mill M will be described in detail with reference to FIG.

3, the bead mill M includes an outer housing 1A, a chamber 2, a rotor 3, an inner housing 1B, and a bead member B. As shown in Fig.

First, the housing 1 is divided into an outer housing 1A and an inner housing 1B. The outer housing 1A protects the inner structure from external factors.

The inner housing 1B is spaced apart from the outer housing 1A to form a space portion in which a chamber 2 and a rotor 3 are mounted. More specific features of the inner housing 1B will be described later do.

3, the chamber 2 is provided with an internal space in which product particles are dispersed as described above. The present bead mill M is arranged such that the chamber 2 is connected to the outer housing 1A, And an injection port 21 is provided at an upper portion.

Therefore, when the product particles are injected into the chamber 2 through the injection port 21, the product drops freely by the weight of the product particles and falls, and dispersion by the present bead mill M is performed.

3, the rotor 3 is configured to rotate around a rotation axis. The bead mill M is disposed so that the rotor 3 is spaced apart from the inside of the chamber 2, And a first dispersion protrusion 431 protruding toward the dispersion portion 41. The first dispersion protrusion 431 is formed on the surface of the dispersion portion 41,

Here, the dispersion part 41 means a space separated between the rotor 3 and the chamber 2, and the product particles introduced through the injection port 21 descend and flow into the dispersion part 41.

The first dispersion protrusion 431 has the same structure as the dispersion protrusion 43 described above and not only provides the bead member B with activity but also distributes the bead member B evenly inside the chamber 2. [ In addition, the grinding of the product particles by the first dispersion protrusions 431 is also partially possible.

The description of the dispersion projections 43 as the first dispersion projections 431 is for explaining a plurality of dispersion projection structures (first to third dispersion projections) which are one of the features of the present invention. The second dispersion projections 431 432 and the third dispersion projection 433 will be described later.

3, the inner housing 1B is spaced apart from the outer housing 1A to form a space in which the chamber 2 and the rotor 3 are mounted. Is characterized in that the inner housing 1B is disposed inside the rotor 3 and includes a screen 13 disposed adjacent to the dispersion portion 41 and an outlet 11 provided at the lower portion.

Here, the screen 13 has a configuration in which product particles passing through the dispersing unit 41 are selectively passed through. The screen 13 is provided with a through hole (not shown) It is preferable to have a size corresponding to the size of the product particles.

Therefore, product particles dispersed smaller than the through-holes of the screen 13 are discharged to the discharge port 11 through the screen 13, and product particles larger than the through-holes move again to the dispersion portion 41 to be finely dispersed .

The bead mill M having the above-described constitutions and features has a double housing 1 structure and is excellent in durability against vibration and shock generated by the rotation of the rotor 3. [ The vibration of the rotor 3 due to the rotation of the rotor 3 is buffered by the structure of the double housing 1, so that the dispersion efficiency of the product particles is excellent. Further, the product particles and the bead member B move by free fall, It has an effect that the dispersion speed is superior to that of the bead mill.

Hereinafter, additional features of the present invention will be described in more detail.

3, the bead mill M further includes a partition wall 31 having the rotor 3 protruded downward. The bead mill M includes an outer member 31 connected to the injection port 21, The bead member B circulates the first dispersing unit 411 and the second dispersing unit 412 by a pump and the first dispersing unit 411 and the second dispersing unit 412 are rotated by the pump, 1 dispersion protrusions 431 protrude from the partition wall portion 31 toward the first dispersion portion 411 side.

The bead mill M further includes a second dispersion protrusion 432 protruding from the inner housing 1B toward the second dispersion unit 412 side.

The first dispersing unit 411 and the second dispersing unit 412 are formed on both sides of the partition 31 and the bead member B is separated from the first dispersing unit 411 by the pump. And product particles are also circulated through the first dispersion unit 411 and the second dispersion unit 412 so that the dispersion efficiency of the product particles compared to the chamber 2 of the same size is excellent .

For the sake of clarity, the embodiment of the present invention for the provision of the first dispersion part 411 and the second dispersion part 412 through the provision of the partition wall part 31 will be described. First, In the course of descending product particles along the first dispersing part 411, the primary dispersion process by the bead member B proceeds. At this time, the first dispersion protrusion 431 imparts activity to the bead member B and provides dispersion of the even bead member B together. Also, the dispersion of the product particles can proceed even by the collision of the first dispersion protrusion 431 itself.

Thereafter, the product particles and the bead member B which have reached the lower end of the first dispersing unit 411 rise by the pump and pass through the second dispersing unit 412. In this process, The difference dispersion process proceeds. At this time, the second dispersion protrusion 432 also imparts the activity to the bead member B and provides the dispersion of the even bead member B together.

Thereafter, the product particles having passed through the second dispersion unit 412 pass through the through holes of the screen 13 and are discharged to the discharge port 11. At this time, when the product particles are larger than the through holes of the screen 13, And enters the first dispersion unit 411 again together with the bead member B.

The present invention can provide a compact bead mill through the provision of the first dispersing unit 411 and the second dispersing unit 412, , It is possible to minimize the space occupied by the bead mill installation while increasing the dispersion efficiency.

In addition, the detailed description of the pump and the illustration of the drawings are omitted, but these are well known to those skilled in the art, and it is expected that a person skilled in the art will be able to carry out the present invention.

3, the bead mill M further includes a third dispersion projection 433 protruding from the inner wall of the chamber 2 toward the first dispersion portion 411 side, and the first dispersion projection 431 And the third dispersion projections 433 are alternately arranged in an alternating manner.

The present invention can increase the dispersion efficiency for the product particles through the above-described constitutions and features.

The central axis of the first dispersion projection 431 and the central axis of the third dispersion projection 433 are displaced from each other when the first dispersion projection 431 and the third dispersion projection 433 are viewed to the upper viewpoint It can be deduced from FIG.

Here, the central axis means an extension line extending the center of each of the dispersion projections in the horizontal direction. In other words, the center of the first dispersion protrusion 431 is extended in the longitudinal direction of the first dispersion protrusion 431 and the center of the third dispersion protrusion 433 is extended in the longitudinal direction of the third dispersion protrusion 433 One extension line is not on the same line, but parallel to each other.

The staggered arrangement of the first dispersion protrusions 431 and the third dispersion protrusions 433 is characterized in that the number of times of collision between the first dispersion protrusions 431 or the third dispersion protrusions 433 and the bead member B To give more activity to the bead member (B). In addition, it is possible to increase the possibility of collision with the product particles, thereby increasing the dispersion efficiency.

The present invention is also applicable to the case where the product particles and the bead member B move in the first dispersing portion 411 through the feature of the continuous arrangement of the first dispersing projections 431 and the third dispersing projections 433 in a staggered arrangement It is possible to reduce the width and to lower the speed more quickly, thereby adding the speed of the dispersing operation.

Figs. 4 and 5 are explanatory diagrams of the bead member B of the present invention. Fig. Fig. 4 is a view showing the principle of dispersion through the bead member B, and Fig. 5 is a view showing a preferred embodiment of the bead member B. Fig.

As can be seen in Fig. 4, the bead member B filled in the chamber 2, in particular the dispersing part 41, collides with the product particles to disperse the product, and the two bead members B), the product particles are impacted or pressed from both symmetrical directions to be crushed.

The bead member (B) is preferably made of a material having rigidity such as iron, glass, reinforced plastic, or tungsten, and preferably has a surface with strong abrasion resistance and friction.

Fig. 5 shows a preferred embodiment of the bead member B, which shows the size of the preferred bead member B. Fig.

Fig. 5 [B] shows an embodiment in which the bead member B is too small compared to the product particle. In this case, since the product particles are not appropriately dispersed, the dispersion efficiency may be lowered.

In Fig. 5 [C], an embodiment in which the bead member B is too large compared to the product particle is shown. In this case, product particles are not dispersed when the product particles are placed in the space formed between the adjacent bead members B because of the circumference of the bead member B, so that the dispersion efficiency may be lowered.

Therefore, it is preferable that the bead member B has an appropriate size, and in consideration of the type of products to be dispersed, more preferably, the bead member B has a diameter of 0.2 to 1.5 mm.

6, the bead mill M further includes a controller C having a control unit C10 for controlling the rotation speed of the rotor 3 through a control signal .

However, there is a possibility that noise may be introduced into the control signal of the control unit C10 due to influence of a high frequency, interference by a strong electric field of a power source unit, influence by an external environment, and the like. The noise introduced into the control signal rapidly increases or decreases the voltage level of the control signal, causing unstable operation of each structure, and further, it may cause malfunction and failure.

In order to solve the problem, the present invention provides a signal generating apparatus comprising: signal generating means for adjusting a voltage level of a control signal according to an operation of each configuration, detecting and removing noise introduced into the control signal, (5) was further introduced.

Hereinafter, the signal generating means 5 according to an embodiment of the present invention will be described in detail with reference to FIG. 6 attached hereto.

(For the sake of convenience, it is not necessary to distinguish the names of the device units in the following description.) Therefore, it is preferable to deduce through the corresponding circuit including each element,

6, the signal generating means 5 includes a level adjusting portion 51 for adjusting the voltage level of the control signal to a predetermined level, a noise detecting portion 52 for detecting the noise introduced into the control signal, And a filter driving unit 53 for driving the filtering unit 54 at the time of noise detection.

6, the level adjusting unit 51 for adjusting the voltage level of the control signal to a predetermined level includes a switching circuit 51 for supplying operating power, an input terminal circuit 512 for receiving a control signal, A grounding single circuit 513 for stabilizing the level adjusting operation of the control signal, and an output terminal circuit 514 for adjusting and outputting the control signal to a predetermined level.

More specifically, the switching circuit 51 determines whether the npn transistor Q101 constituting the output stage circuit 514 operates according to the voltage level of the input control signal. Although the specific configuration and the description of the configuration of the switching circuit 51 are omitted, those skilled in the art will be able to understand and infer the configuration as much as possible.

The input stage circuit 512 includes a capacitor C101 connected to an input terminal to which a control signal is input and two resistors R11 and R11 connected to the base of the transistor Q101 and having one end connected to the capacitor C101, ) R12.

Next, the ground short circuit 513 is composed of a capacitor C102 and a resistor R105 and a resistor R06 connected in parallel between the emitter of the transistor Q101 and the ground and connected in series.

The output stage circuit 514 includes npn transistor Q101 and two parallel resistors R103 and R104 connected to the collector end of the transistor Q101 and a capacitor C103. In particular, the two parallel resistors R103 and R104 are connected to the resistor R101 of the input stage circuit 512.

When the voltage level of the control signal is lower than a preset voltage level, the level adjusting unit 51 configured as described above supplies power to the transistor Q101 through the switching circuit 511 to drive the transistor Q101, The voltage level of the signal is raised by a predetermined voltage level.

In addition, when the voltage level of the control signal is higher than the predetermined voltage level, the level adjusting unit 51 cuts off the power applied to the transistor Q101 through the switching circuit 511 to stop the operation of the transistor Q101, The voltage level of the control signal is lowered by a predetermined voltage level.

At this time, the resistors R101 to R106 and the capacitors C101 to C103 of the input stage circuit 512, the ground short circuit 513 and the output stage circuit 514 determine the gain of the transistor Q101 to set the set voltage level The capacitor C101 of the input stage circuit 512 removes the DC component of the input control signal and the capacitor C103 of the output stage circuit 514 can remove the DC component of the control signal having the adjusted level .

6, the noise detector 52 for detecting the noise introduced into the control signal includes a first amplifier circuit 521 connected to the output terminal of the level adjuster 51 for first amplifying the control signal, A second amplifying circuit 522 connected to the first amplifying circuit 521 and secondarily amplifying the amplified control signal, a detecting circuit 523 connected to the second amplifying circuit 522 and detecting noise included in the control signal, And a backflow prevention circuit 524 provided at an output terminal of the detection circuit 523 for preventing reverse flow of current and noise.

More specifically, the first amplifying circuit 521 includes an amplifier A101, a resistor R107 connected at one end to the (+) terminal of the amplifier A101 and at the other end to the output terminal of the level adjusting section 51, A resistor R108 and a capacitor C104 connected to the (+) terminal of the amplifier A101 and the other end connected to the ground and arranged in parallel with each other, a resistor R110 disposed between the (-) terminal of the amplifier A101 and the ground, And a resistor R109 and a capacitor C105 interposed between the (-) terminal and the output terminal of the amplifier A101 and arranged in parallel with each other.

The second amplifying circuit 522 includes an amplifier A102, a capacitor C106 connected to the (-) terminal of the amplifier A102, and a resistor C106 connected to the capacitor C106, one end of which is connected to the output terminal of the level adjusting section 51 (R111), a resistor (R112) and a capacitor (C107) connected to the capacitor (C106) and having one end connected to the ground and arranged in parallel to each other, And a resistor R113 and a capacitor C108.

And the (+) terminal of the second amplifying circuit 522 is connected to the output terminal of the first amplifying circuit 521.

The first amplifying circuit 521 and the second amplifying circuit 522 amplify the control signal so that the noise can be detected more reliably.

The detection circuit 523 includes a first comparator A103 and a second comparator A104. One end of the first comparator A103 is connected to the output terminal of the level adjusting section 51, The negative terminal of the first comparator A103 is connected to the resistor R115 of the second amplifier circuit 522 and the resistor R117 and the capacitor C110 of which one end is connected to the ground, (A102) and the (+) terminal of the second comparator A104 are connected.

The (-) terminal of the second comparator A104 is connected to the (-) terminal of the first comparator A103. The (-) terminal of the second comparator A104 is connected to the output terminal of the level adjusting unit 51 A resistor R114 and a resistor R116 and a capacitor C109 connected in parallel and having one end connected to the ground are connected.

 Therefore, the first comparator A103 operates as a high-pass filter and the second comparator A104 operates as a low-pass filter to detect and output a noise signal corresponding to the set level reference range.

In particular, the level reference range setting of such a noise signal is performed by setting the resistor R117 connected to the (+) terminal of the first comparator A103 and the capacitor C110 connected to the (-) terminal of the second comparator A104, (R114) R116 and the capacitor C109. For this purpose, it is also possible to configure the two resistors R116 and R117 as variable resistors.

The backflow prevention circuit 524 is composed of reverse diodes D101 and D102 connected to the output terminals of the first comparator A103 and the second comparator A104 of the detection circuit 523, respectively.

The backflow prevention circuit 524 serves to prevent the current passing through the detection circuit 523 from flowing backward so as not to reentry and to prevent the noise from being introduced from the filter driving part 53 described later.

6, the filter driving unit 53 for driving the filtering unit 54 at the time of noise detection is connected to the output terminal of the delay circuit 531 and the delay circuit 531 connected to the output terminal of the noise detecting unit 52 A driving circuit 532 for generating a driving signal, a bias circuit for providing a stable operating point, and a relay circuit 534 connected to the driving circuit 532 and the bias circuit 533 and driven by a driving signal .

More specifically, the delay circuit 531 is connected to the output terminal of the detection circuit 523 and comprises a resistor R118 and a reverse diode D103 which are arranged in parallel with each other.

The delay circuit 531 prevents the shortening of the lifetime of the component by repeatedly turning on and off the relay circuit 534. After the relay circuit 534 is operated once, (534) is not turned off, the time is reset every time the noise is detected, and stable driving through delay setting is provided.

Next, the drive circuit 532 is composed of a first amplifier A105, a second amplifier A106, a transistor Q102, a plurality of resistors R119 to R126, and capacitors C111 to C113, The collector of the transistor Q102 is connected to the relay circuit 534, the emitter to the ground, and the base to the output terminal of the second amplifier A106.

A resistor R119 having one end connected to the output terminal of the noise detector 52 and a resistor R120 and a capacitor C111 having one end connected to the ground and arranged in parallel are connected in parallel at the (+) terminal of the first amplifier A105, Lt; / RTI >

The output terminal of the delay circuit 531 is connected to the (-) terminal of the first amplifier A105.

The output terminal of the first amplifier A105 is connected to the output terminal of the bias circuit 533 and the output terminal of the first amplifier A105 at the (+) terminal of the second amplifier A106. And a reverse diode D104 is interposed therebetween.

A resistor R122 connected at one end to the output terminal of the delay circuit 531 and a resistor R124 and a resistor R124 connected at one end to the ground respectively are connected to the negative terminal of the second amplifier A106, ) Are connected in parallel.

The bias circuit 533 has one end connected to the relay circuit 534 and the other end connected to the output terminal of the first amplifier A105 of the drive circuit 532 and the positive terminal of the second amplifier A106, And two resistors R125 and R126 and a capacitor C113.

The relay circuit 534 has a generally known configuration, and a simple description of the relay circuit 534 may be omitted.

More specifically, the bias circuit 533 controls the operating point of the voltage applied to the first amplifier A105 and the second amplifier A106 of the driving circuit 532 Setting. The voltage determined by the bias circuit 533 is applied to the first amplifier A105 and the second amplifier A106.

Also, when a voltage is applied to the resistors R122, R123, and R124 connected to the (-) terminal of the second amplifier A106, the second amplifier A106 is switched to the standby state for driving.

At this time, if an operation signal (a signal which is output after the noise detection unit 52 detects noise) is given from the noise detection unit 52 through the delay circuit 531, the first amplifier A105 and the reverse diode D104, The second amplifier A106 in the standby state is driven to operate the transistor Q102 and the transistor Q102 drives the relay circuit 534. [

Thereafter, the relay circuit 534 drives the filtering unit 54 to remove the noise of the control signal.

6, the filtering section 54 driven by the relay circuit 534 and removing the noise receives the driving signal from the relay circuit 534 and receives the control signal from the signal input circuit 541 A main filter circuit 542 connected to the signal input circuit 541 to remove noise included in the control signal and a main filter circuit 542 connected to the output terminal of the main filter circuit 542 for removing residual noise included in the control signal, And a filter circuit 543.

More specifically, the signal input circuit 541 is connected to the relay circuit 534 of the filter driving unit 53 and receives a driving signal for driving the filtering circuits 542 and 543. And receives a control signal. In addition, when no noise is detected in the control signal, an output terminal is provided so that the control signal can be directly outputted without passing through the filtering circuits 542 and 543.

The signal input circuit 541 includes a selector such as a multiplexer. The signal input circuit 541 selects an output terminal for outputting an input terminal or a control signal of the main filter circuit 542, that is, It is preferable to transmit the control signal. Although the illustration and the detailed description of the drawing relating to the signal input circuit 541 are omitted, it will be appreciated by those skilled in the art that the signal input circuit 541 can be understood and inferred.

Next, the main filter circuit 542 includes a forward diode D105 connected to the output terminal of the signal input circuit 541, a resistor R127 and a capacitor C114 connected in series to each other and a capacitor C114, C115 and a forward diode D106.

The forward diode D105 cuts off the current flow in one direction to block the reverse flow of the current from the main filter circuit 542 to the signal input circuit 541 and the resistor R127 connected in parallel with each other, And the capacitor C114 remove the noise included in the control signal. The capacitor C115 and the diode D106 connected thereto increase the noise removing efficiency.

The subfilter circuit 543 connected to the output terminal of the main filter circuit 542 for eliminating the residual noise includes an amplifier A107, first and second transistors Q103 and Q104, and a biased resistor R128 to R135) and capacitors C116 and C117.

In the sub filter circuit 543, three resistors R128, R129 and R130 are connected to the (+) terminal of the amplifier A107. One R128 is connected to the output end of the main filter circuit 542, And the other two of the resistors R129 and R130 are connected in parallel and the positive terminal of the amplifier A107 is connected between the two resistors R129 and R130.

The negative terminal of the amplifier A107 is connected to a capacitor C116 and two resistors R131 and R132 connected in parallel to each other and a reference voltage input terminal Sref. The two resistors R131 and R132 One of which is connected in series to the reference voltage input terminal and the other of which is connected to the ground and the capacitor C116 is connected in parallel between the two resistors R131 and R132.

The first and second transistors Q103 and Q104 are connected to the output terminal of the amplifier A107 and a resistor R133 is provided between the first transistor Q103 and the amplifier A107, And generates an operating point for driving the first and second transistors Q103 and Q104 with a constant voltage drop.

The first transistor Q103 is an npn transistor, the base is connected to the output terminal of the amplifier A107, the emitter is connected to the ground, and the collector is connected to the base of the second transistor Q104.

The second transistor Q104 is a pnp transistor, the base is connected to the collector of the first transistor Q103 as described above, the collector is connected to the ground, and the emitter is connected to the control signal output terminal.

In particular, between the second transistor Q104 and the output terminal of the control signal, two resistors R134 and R135 arranged in series and a capacitor C117 connected in parallel between the two resistors R134 and R135 are provided.

First, the two resistors R131 and R132 and the capacitor C116 provided at the (-) terminal of the amplifier A107 are connected to the reference voltage input terminal Sref, To generate a reference voltage. This reference voltage serves as a reference for eliminating noise, and a voltage level higher or lower than the reference voltage is regarded as noise and eliminated.

Next, three resistors R128 (R129) (R130) provided at the (+) terminal of the amplifier drop the voltage level of the control signal passed through the main filter circuit 542 to be comparable to the reference voltage, May be omitted depending on the output voltage level of the circuit 542. [

The amplifier A107 operates as a comparator, compares the reference voltage level with the level of the control signal, and confirms whether there is residual noise.

The first transistor Q103 and the second transistor Q104 of the subfilter circuit 543 are turned on when the control signal includes the residual noise and is instantaneously higher or lower than the reference voltage (in general, the voltage is raised by noise). ), And charges the capacitor C117 with a voltage which is increased by the noise, and the voltage level of the control signal which is lowered by the capacitor C117 is equal to the reference voltage level.

Thereafter, if the voltage level of the control signal corresponds to the reference voltage level, the first transistor Q103 and the second transistor Q104 are turned off, and then the voltage stored in the capacitor C117 is connected through the resistor R135 connected in parallel Discharged and restored to the original state.

The configuration of the filtering section 54 is such that the noise is primarily removed through the main filter circuit 542 and the remaining noise and the instantaneous noise are secondarily removed through the sub filter circuit 543, And outputs a clean control signal that is not included, thereby providing an effect of preventing malfunction and failure of each configuration.

Of course, it is also possible to provide only the filtering unit 54. However, since the level adjusting unit 51 sets the voltage level of the stable signal, the control signal can be maintained at a constant level, The signal is amplified to detect the noise more sensitively and the driving of the filtering unit 54 can be selectively operated according to the noise detection through the filter driving unit 53 so that the life of the filtering unit 54, The life of the capacitors C114 to C117 provided in the capacitor 54 is extended.

In addition, the fact that the filtering unit 54 is not driven at all times and is selectively driven according to whether or not noise is detected can provide a remarkable effect in reducing power consumption.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

M: main bead mill B: bead member
1A: outer housing
1B: inner housing 11: outlet
13: Screen
2: chamber 21: inlet
3: rotor 31: partition wall portion
41: disperser 411: first disperser
412:
431: first dispersion projection 432: second dispersion projection
433: third dispersion projection
5: Signal generating means

Claims (4)

An outer housing;
A chamber coupled to the inside of the outer housing and having an inlet at the top;
A rotor disposed on the inside of the chamber so as to be spaced apart from the chamber to form a dispersion part inside the chamber and including a first dispersion projection protruding toward the dispersion part;
An inner housing disposed inside the rotor, the inner housing including a screen disposed adjacent to the dispersing portion and an outlet provided at a lower portion; And
A bead member filled in the chamber;
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A controller for controlling a rotation speed of the rotor through a control signal; Further comprising:
A level adjusting unit for adjusting the voltage level of the control signal to a predetermined level, a noise detecting unit for detecting noise introduced into the control signal, a filtering unit for removing the detected noise, and a filter driving unit for driving the filtering unit at the time of noise detection Further comprising signal generating means,
The level adjusting unit includes a switching circuit for supplying operation power, an input terminal for receiving a control signal, a ground short circuit for stabilizing a level adjustment operation of the control signal, and a transistor Q101 for adjusting and outputting a control signal to a predetermined level And an output stage circuit,
The input stage circuit includes a capacitor C101 connected to an input terminal to which a control signal is input and two resistors R101 and R102 connected in parallel to each other while one end is connected to the capacitor C101 and the other end is connected to the base of the transistor Q101, ),
The ground stage circuit includes a capacitor C102 and a resistor R105 and a resistor R106 connected in parallel between the emitter of the transistor Q101 and the ground,
The output stage circuit further includes two parallel resistors R103 and R104 and a capacitor C103 connected to a collector terminal of the transistor Q101. The two parallel resistors R103 and R104 are connected to a resistor (R101)
The noise detector includes a first amplifier circuit connected to an output terminal of the level adjusting unit to primarily amplify a control signal, a second amplifier circuit connected to the first amplifier circuit to second amplify the amplified control signal, And a backflow prevention circuit provided at an output terminal of the detection circuit to prevent reverse flow of current and noise,
The first amplifying circuit includes an amplifier A101, a resistor R107 having one end connected to the (+) terminal of the amplifier A101 and the other end connected to the output terminal of the level adjusting unit, A resistor R110 disposed between the negative terminal of the amplifier A101 and the ground, and a resistor R110 connected between the negative terminal of the amplifier A101 and the ground, and a resistor R110 connected between the ground and the other end of the resistor R108 and the capacitor C104, And a resistor R109 and a capacitor C105 interposed between the (-) terminal and the output terminal of the capacitor C105,
The second amplifying circuit includes an amplifier A102, a capacitor C106 connected to the negative terminal of the amplifier A102, a resistor R111 connected to the capacitor C106 and having one end connected to the output terminal of the level adjuster, A resistor R112 and a capacitor C107 connected to the capacitor C106 and having one end connected to the ground and arranged in parallel with each other and a resistor C107 interposed between the negative terminal and the output terminal of the amplifier A102, R113) and a capacitor (C108), the (+) terminal of the second amplifying circuit being connected to the output terminal of the first amplifying circuit,
The detection circuit includes a resistor R115 having one end connected to the output terminal of the level adjusting unit and a resistor R117 and a capacitor C110 connected in parallel and having one end connected to the ground, A first comparator A103 connected to the amplifier A102 of the second amplifying circuit,
(-) terminal of the first comparator (A103), a resistor (R114) whose one end is connected to the output terminal of the level adjusting unit, and a resistor And a second comparator A104 to which a capacitor R116 and a capacitor C109 are connected,
The backflow prevention circuit comprises reverse diodes D101 and D102 respectively connected to the output terminals of the first comparator A103 and the second comparator A104 of the detection circuit,
The filter driving unit includes a delay circuit connected to an output terminal of the noise detecting unit, a driving circuit connected to an output terminal of the delay circuit and generating a driving signal, a bias circuit for providing a stable operating point, The relay circuit comprising:
The delay circuit includes a resistor R118 and a reverse diode D103 connected in parallel to an output terminal of the detection circuit,
The driving circuit includes a first amplifier A105, a second amplifier A106, a transistor Q102, a plurality of resistors R119 to R126, and capacitors C111 to C113,
The collector of the transistor Q102 is connected to the relay circuit, the emitter to the ground, and the base to the output terminal of the second amplifier A106,
A resistor R119 whose one end is connected to the output terminal of the noise detecting unit and a resistor R120 and a capacitor C111 whose one end is connected to the ground and which are arranged in parallel are connected in parallel to the (+) terminal of the first amplifier A105 The output terminal of the delay circuit is connected to the (-) terminal of the first amplifier A105,
The positive terminal of the second amplifier A106 is connected to the output terminal of the first amplifier A105 and the output terminal of the first amplifier A105 is connected to the positive terminal of the second amplifier A106. A resistor R122 having one end connected to the output terminal of the delay circuit and a resistor R123 having one end connected to the ground and the other end connected to the output terminal of the delay circuit are connected to the negative terminal of the second amplifier A106, A connected resistor R124 and a capacitor C112 are connected in parallel,
The bias circuit has one end connected to the relay circuit and the other end connected to the output terminal of the first amplifier A105 of the driving circuit and the (+) terminal of the second amplifier A106. The two resistors R125, (R126) and a capacitor (C113).
The method according to claim 1,
Wherein the bead member includes a first dispersing portion and a second separating portion, the first dispersing portion being connected to the injection port, and the inner second dispersing portion being connected to the injection port, Circulates the dispersion part,
The first dispersion protrusions project from the partition wall portion toward the first dispersion portion,
And a second dispersion protrusion protruding from the inner housing toward the second dispersion portion.
The method of claim 2,
And a third dispersion protrusion protruding from the inner wall of the chamber toward the first dispersion unit,
Wherein the first dispersion projections and the third dispersion projections are alternately arranged in an alternating manner,
Wherein the diameter of the bead member is 0.2 to 1.5 mm.
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