KR20230127617A - Classification system - Google Patents

Abstract

The present invention relates to a classifier that can be implemented more economically. The classifier includes: a hopper that supplies raw materials to be separated; a first classifier that separates the raw materials received from the hopper into particles of a first size or smaller and particles that exceed the first size; and a second classifier that receives the particles of a first size or smaller separated from the first classifier and separates the same into particles of a second size or larger that are smaller than the first size and particles that are smaller than the second size.

Description

Classification system

The present invention relates to a classification system.

Patent Document 001 discloses a classifier for a positive electrode active material and a method for regenerating a lithium precursor using the same, comprising preparing a positive electrode active material mixture including active material powder containing lithium composite oxide particles and dust particles, and using the classifier to regenerate the positive active material mixture. Disclosed is a lithium precursor regeneration method comprising collecting the active material powder by separating the dust particles from the active material powder, forming a preliminary precursor mixture by reducing the active material powder, and recovering a lithium precursor from the preliminary precursor mixture. are doing

Patent Document 002 is a coal classifier for power plants, in a classifier composed of a multi-layer frame disposed above and below, a plurality of blades attached to the multi-layer frame in the longitudinal direction, and a bottom plate, each of the plurality of blades An upper connection member connected to the multilayer frame, a support bar arranged in the longitudinal direction facing the lower end of the inclined blade of the upper connection member, and a lower connection formed on the bottom plate and connected to the lower end of the support bar. member, and a fastening member connecting the support bar, the upper connection member, and the lower connection member, respectively, wherein the upper connection member includes a plate-shaped vertical blade and an inclined blade connected to the lower end of the vertical blade and formed inclined, The frame is formed by connecting a plurality of frame brackets, and the frame brackets are coupled to vertical blades and inclined blades of the upper connecting member at both ends, respectively.

Patent Document 003 is a classifier, a pulverizing classifier, and a pulverized coal combustion boiler, comprising a housing configured to take airflow from below into an outer circumferential region of an internal space, installed on an inner wall surface of the housing, and directing the airflow to the central axis side of the housing. a deflection portion configured to deflect the flow toward the housing, and an annular rotating portion rotatably installed in an inner circumferential region located on an inner circumferential side of the inner space of the housing and configured to classify particles accompanying the air flow. The annular rotation unit includes a plurality of rotary blades arranged with a gap around the rotation axis of the annular rotation unit, and the outer shape of the annular rotation unit formed by the plurality of rotation blades is formed at a side surface of the annular rotation unit. The angle θ formed by the outer shape of the annular rotation unit with respect to a line segment extending horizontally from the annular rotation unit toward the outer side in the radial direction is 75 ° or less, and each of the rotary blades has an upper end of the rotary vane. Disclosed is a classifier disposed obliquely with respect to the vertical direction so as to be located on the upstream side of the rotation direction of the annular rotation unit with respect to the lower end of the rotary blade.

Patent Document 004 is a centrifugal classifier, an upper cover in which a first discharge port through which fine particles are discharged is formed, located in the lower part of the upper cover, an inlet through which slurry flows in is formed on the lower surface, and a guide portion is formed on the side surface a lower case, located between the guide part and the upper cover, and having a second discharge port through which granulated particles are discharged, and a plurality of wings extending from the center and located between the upper cover and the lower case; Disclosed is a centrifugal classifier comprising a rotating plate, wherein the rotating plate is conical.

Patent Document 005 is a pocket blade classifier, which is a patented technology applied to the first classifier 200 of the present invention, which can be located in a pocket space formed with a predetermined space between the guide van and the blade through which raw materials and air flow. At this time, the classifier discloses a classifier in which particles exceeding a first size are induced to fall through their own weight, and particles having a first size or less are discharged into a predetermined space through a blade.

KR 10-2021-0117575 A (2021.09.29.) KR 10-2113194 B1(2020.06.02.) KR 10-2084866 B1(2020.04.20.) KR 10-2057912 B1(2019.12.20.) KR 10-1947443 (2020.07.31.)

The present invention relates to a classification system.

A classification system for solving the problems of the prior art includes a hopper for supplying raw materials to be separated and a first classifier for separating raw materials received from the hopper into particles of a first size or less and particles exceeding a first size. include

As a classification system to solve the problems of the prior art, the particles of a first size or less separated by the first classifier are supplied and separated into particles of a second size or more smaller than the first size and particles of a second size smaller than the first size. It includes a second classifier that

A classification system for solving the problems of the prior art, and includes a cyclone that collects particles of less than the second size by receiving air and particles of less than the second size separated from the second classifier.

As a classification system for solving the problems of the prior art, in the cyclone, a discharge end through which air used to collect particles smaller than the second size is discharged is connected to an air supply end of the first classifier.

As a classification system for solving the problems of the prior art, the passage is disposed between the discharge end of the cyclone and the air supply end of the first classifier and includes the first classifier, the second classifier, and the cyclone. Includes a first blower for controlling the circulation of.

As a classification system to solve the problems of the prior art, it is installed inside each of the first classifier and the second classifier to determine the flow rate or flow rate of air supplied to each of the first classifier and the second classifier. A sensor for sensing and a controller for controlling the output of the first blower according to the pressure, flow rate, or flow rate of air supplied to each of the first and second classifiers sensed by the sensor.

As a classification system for solving the problems of the prior art, it includes a balance unit (vent dust collector) connected to a line connecting the air supply end of the first blower and the first classifier to suck air from the line. ,

As a classification system for solving the problems of the prior art, it includes a second blower connected to the balance unit to adjust the static pressure and flow rate of air sucked from the balance unit.

As a classification system for solving the problems of the prior art, it is installed inside at least one of the first classifier, the second classifier, and the balance unit, so that each of the first classifier, the second classifier, and the balance unit A sensor for sensing the pressure or flow rate of supplied air and a control unit for controlling the operation of the first blower and the second blower according to the pressure or flow rate of the air sensed by the sensor.

As a classification system for solving the problems of the prior art, it is disposed between the lower part of the hopper and the first classifier, receives the raw material from the hopper and supplies a certain amount of raw material per hour to the first classifier using a variable rotational force Include a feeder.

As a classification system for solving the problems of the prior art, the feeder rotates in a housing receiving raw materials from the hopper and inside the housing to push a certain amount of raw materials to the discharge end of the housing, and into the first classifier. It includes a rotating rotor for discharging.

As a classification system to solve the problems of the prior art, the classification system is plural, and at least two classification systems share one hopper.

As described above, the classification system according to the present invention has an effect of enabling the classification system to be operated more efficiently by combining the two systems that existed independently as the primary and secondary classification systems into one system.

More specifically, there is an effect that a classification system can be implemented at a lower cost by using a single hopper to configure the classification system, and integrating the primary classifier and the secondary classifier to operate and control them simultaneously.

1 is a schematic diagram of a classification system according to an embodiment of the present invention;
2 is a schematic diagram of a classification system according to another embodiment of the present invention;
3 is a schematic diagram of a classification system according to another embodiment of the present invention;
4 is a schematic diagram of a classification system according to another embodiment of the present invention;
5 is a block diagram of a form in which a plurality of classification systems according to the present invention share one hopper.

Hereinafter, the most preferred embodiment of the present invention will be described in detail in order to explain the present invention in detail to the extent that those skilled in the art can easily practice the present invention.

Numbers cited in the examples below are not limited to the referenced subject and can be applied to all examples. An object that exhibits the same purpose and effect as the configuration presented in the embodiment corresponds to an equivalent replacement object. The high-level concept presented in the examples includes sub-concept objects that are not described.

(Example 1-1) The present invention relates to a classification system (1), in which a hopper (100) for supplying raw materials to be separated and raw materials received from the hopper (100) are separated from particles of a first size or smaller. It includes a first classifier 200 that separates into particles exceeding 1 size.

The hopper 100 is a funnel-shaped container used when dropping various raw materials to the lower part. In this embodiment, the raw material accommodated in the hopper 100 may be supplied to the first classifier 200 by dropping graphite used for the negative electrode material of the battery. An opening/closing means for opening or blocking a hole at the bottom may be installed in the hopper 100, and a predetermined blade (not shown) for accelerating the supply speed is installed inside the hopper 100, The fall of the raw material can be accelerated or kept constant. In this embodiment, the size of raw material particles supplied from the hopper 100 to the first classifier 200 may have a distribution of 1 to 100 micrometers.

The first classifier 200 classifies particles of a size desired by a user among raw materials. In this embodiment, the first size may be 40 micrometers. The first classifier 200 may receive the raw material supplied from the hopper 100 and separate particles larger than 40 micrometers from particles smaller than 40 micrometers in size.

Classifying performed in the first classifier 200 means that the powder to be classified (the raw material described above) is introduced into a classifier in which classification air rotates at high speed, and the particles obtained with rotational force at high speed are separated from the blades of the classifier. It refers to a method of dividing relatively heavy coarse particles and small particles into required sizes using gravity, centrifugal force, and drag while colliding. Therefore, the first classifier 200 may include a housing and blades installed inside the housing to form centrifugal force, and to separate particles flying by the blades rotating inside the housing and particles falling through its own weight. In this way, the particles may be classified based on the first size.

At this time, in the present invention, the first classifier 200 is formed in a pocket type in which a predetermined space is formed between the hole through which the raw material flows and the blade, so that when the raw material first flows in through the hole and is located in the corresponding space , Particles exceeding the first size can be induced to fall through their own weight, and particles below the first size can be discharged into a predetermined space through the blade.

The first classifier 200 has a shape in which air flows in from the bottom and rises upward, and when the air rises, particles of a first size or less fall without passing through the classifier wheel during the first classification. By repeating the activity of re-raising, the efficiency of classification in the first classifier is increased.

(Example 1-2) The present invention relates to a classification system (1), and in (Example 1-1), particles of a first size or smaller separated by the first classifier 200 are supplied, It includes a second classifier 400 that separates particles of a second size or more smaller than the first size and particles smaller than the second size.

The second classifier 400 receives and classifies particles having a first size or less discharged from the first classifier 200 . As the form of the second classifier 400, a generally known classifier method may be used. The minimum particle of the second size, which is the criterion for classification in the second classifier 400, may be 5 micrometers. That is, inside the second classifier 400, particles having a size of 5 micrometers or more fall due to their own weight, and particles exceeding 5 micrometers are repeatedly floated, and the second classifier 400 It is discharged to the outside through a blade installed inside. Here, the particles falling from the second classifier 400 may be particles required in the present invention. That is, in this embodiment, as a result, through the first classifier 200 and the second classifier 400, the raw material having a particle distribution of 1 to 100 micrometers is converted into particles having a size of 5 to 40 micrometers. can be classified.

Conventionally, the first classifier 200 and the second classifier 400 are configured separately, and only two systems are used to classify particles in a predetermined range, that is, the second size to the first size range. For example, in order to obtain particles in the range of 5 to 40 micrometers as in this embodiment, raw materials are introduced into the primary classification system to separate particles of 40 micrometers or less, and then passed through a cyclone or bag filter. Air and powder had to be separated and stored. Thereafter, the separated powder was put into the secondary classification system, and the particles of 5 micrometers or less that passed through the classifier were collected and discarded in the dust collector, and the remaining particles of 5 to 40 micrometers were obtained.

The present invention uses one hopper 100, connects the discharge end from which light particles are discharged from the first classifier 200 and the supply end of the second classifier 400, and in the second classifier 400 Since the falling particles are obtained as the particles to be used by the present invention, there is an effect that relatively less devices are required (reducing the number of hoppers, cyclones, and dust collector devices) compared to using a conventional secondary classification system, Since the installation space is also reduced, the system can be implemented more economically, and the system is also relatively simple.

(Example 1-3) The present invention relates to a classification system (1), and in (Example 1-2), particles of less than the second size separated from the second classifier 400 and air It includes a cyclone 500 that receives the supply and collects particles smaller than the second size.

The cyclone 500 controls the flow of air flowing through the first classifier 200 and the second classifier 400 and is installed to separate air and particles smaller than the second size from each other. This centrifugal dust collector 500 can separate particles smaller than the second size from air in a cyclone method. Particles smaller than the second size separated by the cyclone 500, that is, particles smaller than 5 micrometers fall from the cyclone 500 and are separated.

(Example 1-4) The present invention relates to a classification system (1), and in (Example 1-3), the cyclone 500 is used to discharge particles smaller than the second size. The discharge end is connected to the air supply end of the first classifier 200.

In this embodiment, through the configuration as described above, each flow path of the first classifier 200, the second classifier 400, and the cyclone 500 forms a closed circuit, so that the air is closed. can be circulated within. To this end, the discharge end of the cyclone 500 is connected to the air supply end of the first classifier 200 so that the air discharged from the first classifier 200 is supplied to the first classifier 200 again. there is. Although not shown in the drawing, between the cyclone 500 and the first classifier 200, a suction bag filter (& a second blower is installed for the purpose of controlling the air balance (static pressure) on the closed circuit, Powder concentration contained in the air supplied from the cyclone 500 to the first classifier 200 among the circulation passages of air formed through the first classifier 200, the second classifier 400, and the cyclone 500 At this time, a predetermined sensor for measuring the contamination level of the filter may be further included, and the predetermined sensor notifies the user of the filter condition and replaces the filter when the pollution level of the filter is higher than a predetermined reference value. can make it

(Example 1-5) The present invention relates to a classification system 1, and in (Example 1-4), between the discharge end of the cyclone 500 and the air supply end of the first classifier 200 and a first blower 600 that is disposed on and controls circulation of a flow path including the first classifier 200, the second classifier 400, and the cyclone 500.

When configuring the closed air circulation circuit in the foregoing (Examples 1-4), an attractive force for circulating air is required. The first blower 600 is for this purpose, and is disposed between the discharge end of the cyclone 500 and the air supply end of the first classifier 200 and operates. The first blower 600 may be a device that generates pressure to suck air, and may typically have a turbo fan shape in which blades rotate.

(Example 1-6) The present invention relates to a classification system 1, and in (Example 1-5), the first classifier 200 and the second classifier 400 are respectively connected A sensor installed outside the duct to sense the pressure or flow rate of air supplied to the first classifier 200 and the second classifier 400, respectively, and the first fraction sensed by the sensor A control unit controlling the output of the first blower 600 according to the pressure or flow rate of the air supplied to the supply air 200 and the second classifier 400, respectively.

The control unit may be implemented as a communicable electronic device to enable transmission and reception of information to and from the first blower 600 and the sensor. To this end, each of the first blower 600 and the sensor may include a communication module capable of communicating with the control unit. The control unit controls the first blower 600 through information on the flow rate and flow rate of air sensed by the sensor according to circumstances. In particular, it is necessary to artificially control the position of the pressure level (+ & -) to control the air inside the circulation passage through the first blower 600, which is a source of attraction for one air. The speed of the first blower 600 is controlled based on the air pressure and flow rate information sensed by the sensors installed at the front and rear ends of each of the second classifiers 400, so that the first classifier 200 and the second classifier 200 are more efficiently The second classifier 400 can be controlled.

(Example 1-7) The present invention relates to a classification system 1, and in (Example 1-5), the air supply end of the first blower 600 and the first classifier 200 It includes a vent dust collector 700 and a second blower 800 connected to a connecting line and sucking air from the line to control the air balance of the classifier.

The fresh air damper 900 repeats the action of re-dispersing particles having a size of 5 microns or less among the particles that do not pass and fall to the lower hopper among the particles colliding with the blade in the second classifier several times, It is responsible for introducing outside air to discharge particles of 5 microns or less to remain.

(Example 1-8) The present invention relates to a classification system 1, and in (Example 1-7), the flow rate of air that is connected to the balance unit 700 and sucked from the balance unit 700 And a second blower 800 for adjusting the flow rate.

The second blower 800 serves to control the flow rate and flow rate of air sucked/discharged through the balance unit 700 . The flow rate of the second blower 800 may be controlled by a damp control device.

(Example 1-9) The present invention relates to a classification system 1, and in (Example 1-8), the first classifier 200, the second classifier 400 and the balance unit ( 700) installed before and after at least one of the first classifier 200, the second classifier 400, and the balance unit 700, respectively. It includes a control unit for controlling the operation of the first blower 600 and the second blower 800 according to the pressure or flow rate of the.

The control unit may be implemented as a communicable electronic device to enable transmission and reception of information to and from the first blower 600 and the sensor. To this end, each of the first blower 600 and the sensor may include a communication module capable of communicating with the control unit. The control unit controls the first blower 600 through information on air pressure and flow rate sensed by a sensor according to circumstances. The configuration of the above-described sensor is the same as that described in the above-described (Embodiment 1-6) except that it is further included in the balance unit 700.

(Example 2-1) The present invention relates to a classification system 1, and in (Example 1-1), disposed between the hopper 100 and the first classifier 200, the hopper It includes a feeder 300 receiving raw materials from 100 and supplying a constant amount of raw materials per hour to the first classifier 200.

The feeder 300 supplies a constant amount of raw material per hour to the first classifier 200 through variable rotation of the rotor. This is because the classification efficiency of the first classifier 200 can be further improved only when a certain amount of raw material is supplied to the first classifier 200 per unit time.

(Example 2-2) The present invention relates to a classification system 1, and in (Example 2-1), the feeder 300 includes a housing receiving raw materials from the hopper and rotating inside the housing. and a screw-type conveyor that pushes a certain amount of raw material to the lower end of the housing and transfers it to the first classifier 200.

The housing 300 may be cylindrical. There may be a supply end and a discharge end of the housing 310. The supply end is an upper part receiving raw materials from the hopper 100, and the discharge end is a lower part from which raw materials are discharged from the housing 300.

Multi-blades are attached to the rotor by radiation, and a narrow gap can be formed between the tip of the blade and the inside of the housing so that the raw material does not leak. That is, the rotor rotates while receiving the raw material supplied from the hopper 100 and ejecting it downward, A constant amount of raw material may be supplied to the first classifier 200 for a period of time.

However, the present invention is not limited to the embodiment of the feeder 300 to the rotating rotor, and a uniform amount of raw material can be supplied to the first classifier 200 for a unit time through various methods.

(Embodiment 3-1) The present invention relates to a classification system 1, and in any one of the above embodiments, the classification system is plural, and at least two classification systems form one hopper 100. Share.

For example, when there is a first classification system 2 and a second classification system 3, the first classification system 2 and the second classification system 3 may share one hopper 100. there is. However, in any case, the two feeders 300 are not disposed at the bottom of the hopper 100 to supply raw materials to the first classification system 2 and the second classification system 3, respectively. Each of the first classification system 2 and the second classification system 3 can classify particles in different ranges, but cannot go directly to the second classifier without passing through the first classifier.

Since the present embodiment classifies particles individually in each system using the above method, it is economical and has an effect of reducing the volume required for implementation of the system.

1: Classification system
2: 1st classification system
3: 2nd classification system
100: Hopper
200: first classifier
300: feeder (raw material whey)
400: second classifier
500: Cyclone
600: first blower
700: balance vent filter part
800: second blower
900: Fresh Air Damper

Claims (13)

A hopper for supplying a separation target raw material to be separated; and
a first classifier that separates the raw material received from the hopper into particles having a first size or less and particles exceeding a first size;
Classification system comprising a.
According to claim 1,
a second classifier that receives the particles of a first size or less separated in the first classifier and separates them into particles of a second size or more smaller than the first size and particles smaller than the second size;
Classification system comprising a.
According to claim 2,
a cyclone receiving air and particles of less than the second size separated from the second classifier and discharging particles of less than the second size;
Classification system comprising a.
According to claim 3,
The cyclone,
A classification system in which a discharge end through which air used to discharge particles smaller than the second size is discharged is connected to an air supply end of the first classifier.
According to claim 4,
a first blower disposed between a discharge end of the cyclone and an air supply end of the first classifier to control circulation of a flow path including the first classifier, the second classifier, and the cyclone;
Classification system comprising a.
According to claim 5,
a sensor installed inside each of the first and second classifiers to detect a pressure or flow rate of air supplied to each of the first and second classifiers; and
a control unit controlling the output of the first blower according to the pressure or flow rate of the air supplied to each of the first and second classifiers sensed by the sensor;
Classification system comprising a.
According to claim 5,
a balance vent dust collector unit connected to a line connecting the first blower and the air supply end of the first classifier to suck air from the line;
Classification system comprising a.
According to claim 7,
a second blower connected to the balance unit to adjust the flow rate and flow rate of the air sucked from the balance unit;
Classification system comprising a.
According to claim 8,
It is installed at the front and rear ends of at least one of the first classifier, the second classifier, and the balance unit to sense the pressure or flow rate of air supplied to each of the first classifier, the second classifier, and the balance unit. sensor;
a control unit controlling operations of the first blower and the second blower according to the air pressure or flow rate sensed by the sensor;
Classification system comprising a.
According to claim 1,
a feeder disposed between the hopper and the first classifier to receive the raw material from the hopper and supply a constant amount of the raw material per hour to the first classifier;
Classification system comprising a.
According to claim 10,
The feeder,
a housing receiving raw materials from the hopper; and
Rotor blades that rotate inside the housing to push a certain amount of raw material to the discharge end of the housing and discharge it to the first classifier;
Classification system comprising a.
According to any one of claims 1 to 11,
The classification system is plural,
A classification system in which at least two classification systems share one hopper.
According to claim 2,
Installed at the bottom of the inlet that receives particles of the first size or less together with air from the first classifier
Classification system that re-disperses 5 micron particles falling into the hopper of the second classifier by controlling the air sucked in from the fresh air inlet.