KR102677734B1 - Ball mill capable of revolution and rotation - Google Patents

Abstract

The present invention relates to a rotating ball mill, and more specifically, to a rotating ball mill that not only pulverizes the raw material but also induces a more effective stirring action by rotating the grinding drum in multiple axes in different directions during the grinding process of the raw material. will be.

Description

Ball mill capable of revolution and rotation}

The present invention relates to a rotating ball mill, and more specifically, to a rotating ball mill that not only pulverizes the raw material but also induces a more effective stirring action by rotating the grinding drum in multiple axes in different directions during the grinding process of the raw material. will be.

A ball mill device is typically used to grind raw materials to powder them.

A typical ball mill generally has a structure in which grinding is performed using the impact of balls falling from a high place to a low place when a cylindrical grinding container rotates around an eccentric horizontal rotation axis.

Meanwhile, before or after such ball mill grinding, a process of reacting the raw material or powder with a reactive agent and a dispersion process are performed under special conditions in order to improve the physical properties of the raw material or powder or to manufacture a specific compound.

Due to the nature of this powder manufacturing process, the ball mill, reactor, and disperser are inseparable, so equipment for the disperser and reactor is essential.

Therefore, powder manufacturers must also build a reactor and disperser system, which not only imposes a burden on facility costs and manpower, but also in the powder manufacturing process, the process of causing a reaction must first be carried out, followed by a physical grinding process using a ball mill, or On the other hand, since the process of reacting the reactant with the powder produced after the grinding process had to be performed, the powder manufacturing process became very complicated and cumbersome, and there was a problem that impurities were introduced or contamination frequently occurred during this process.

Therefore, this method not only cannot guarantee marketability, but also causes the problem of unnecessary increase in production costs.

Registered Patent 10-1852690

The present invention was created to solve the above-mentioned problems in the prior art, by rotating the grinding drum in multiple axes in different directions during the grinding process of raw materials, thereby not only pulverizing the raw materials but also inducing a more effective stirring action. The purpose is to provide ball mills.

The present invention is a means for achieving the above object, and includes a grinding unit for pulverizing raw materials, wherein the grinding unit includes a case; a hollow injection pipe and discharge pipe installed inside the case so as to be rotatable in place, and spaced apart from each other on the same axis at a predetermined distance; A drum with a crushing space formed inside and mounted between the injection pipe and the discharge pipe; A plurality of grinding members installed to be rotatable in place in the grinding space of the drum, at least one of which is arranged coaxially between the injection pipe and the discharge pipe, and the others are arranged eccentrically at a certain distance from the injection pipe and the discharge pipe; a first rotation driver that rotates the drum; a second rotation driver that rotates the discharge pipe; And a power connection device that connects the discharge pipe and the plurality of crushing members so that each crushing member rotates in place according to the rotation of the discharge pipe.

In addition, the plurality of grinding members may include: a first grinding member disposed at the center of the grinding space and coaxially between the injection pipe and the discharge pipe; and a plurality of second pulverizing members disposed at a predetermined distance eccentric around the first pulverizing member and spaced apart from each other on the outside of the pulverizing space.

In addition, a second injection passage is formed at one end of the drum to communicate with the first injection passage of the injection pipe and guide the raw material injected into the injection pipe to the grinding space, and the second injection passage is used to control each second grinding member. It is formed to branch radially toward the second injection furnace and is characterized in that the raw material is supplied only to the plurality of second pulverizing members.

In addition, the first grinding member may include a first grinding shaft rotatably installed on the inner wall of the grinding space; A first one-side cover coupled to one side of the first crushing shaft; a first other side cover rotatably installed on the inner wall of the grinding space at a predetermined distance from the other end of the first grinding shaft to face the first one side cover; and a plurality of first crushing modules coupled along the axial direction to the outside of the first crushing shaft in a section between the first one side cover and the first other cover, wherein the first other side cover includes the first discharge pipe of the discharge pipe. A second discharge passage communicating with the furnace is formed to discharge the powder formed from the grinding module toward the first discharge passage.

In addition, the first crushing member may further include a first spacer bar that is coupled to the first one side cover and the first other cover and supports the first one side cover and the first other cover to be spaced apart.

In addition, each of the plurality of second pulverizing members includes a second one-side cover rotatably installed at a corresponding position of the branched second injection passage; a second grinding shaft rotatably installed on the inner wall of the grinding space; a second other side cover coupled to the other side of the second crushing shaft; and a plurality of second crushing modules coupled along the axial direction to the outside of the second crushing shaft in a section between the second one side cover and the second other side cover, wherein the second one side cover includes the second injection passage and A third injection passage is formed to inject the raw material injected from the second injection passage toward the second grinding module.

In addition, each of the plurality of second crushing members further includes a second spacer bar that is coupled to the second one side cover and the second other cover and supports the second one side cover and the second other cover to be spaced apart. Do it as

In addition, each of the plurality of first grinding modules and the second grinding module includes a ring-shaped inner housing that is respectively coupled to the outer peripheral surfaces of the first grinding shaft and the second grinding shaft and has an internal receiving groove recessed in the outer peripheral surface; An outer housing that has a ring shape and is positioned to accommodate the inner housing inside, and has an external receiving groove recessed on its inner circumferential surface; and a plurality of grinding balls interposed between the inner and outer receiving grooves and rolling between the inner housing and the outer housing.

In addition, a first spacer plate is disposed between adjacent first and second crushing modules.

In addition, a support portion provided with a rotation space inside; and a swing driving unit connected to the pulverizing unit to rotate and drive the pulverizing unit to rotate within the rotating space, wherein the swing driving unit is installed on the inner wall of the rotating space to be rotatable in place and is connected to the pulverizing unit. shaft member; A swing motor installed on the support part; And a power connection means that connects the shaft member and the swing motor to transmit the driving force of the swing motor to the shaft member.

The present invention provides the advantageous effect of not only pulverizing the raw materials but also inducing a more effective stirring action by rotating the pulverizing drum in multiple axes in different directions during the pulverizing process of the raw materials.

Figure 1 is a view showing the overall cross-sectional configuration of the pulverizing unit.
Figure 2 is a diagram showing the cross-sectional configuration of the main part of the pulverizing part.
Figure 3 is a diagram schematically showing the front configuration of Figure 2.
Figure 4 is a view showing a first crushing member.
Figure 5 is a view showing a second crushing member.
Figure 6 is a view showing the exploded configuration of the grinding module and the separation plate.
Figures 7 and 8 are diagrams showing the cross-sectional configuration of the grinding module.
Figure 9 is an enlarged view showing the main part of Figure 2.
Figure 10 is a diagram showing the overall configuration of a co-rotating ball mill according to the present invention.
Figure 11 is a diagram illustrating a process in which the pulverizing unit is first rotated.
Figure 12 is a diagram illustrating the direction in which the reactive agent is injected.
Figures 14 and 15 are enlarged views of the portion where the branch pipes are coupled.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. This example is provided to more completely explain the present invention to those with average knowledge in the art. Therefore, the shapes of elements in the drawings may be exaggerated to emphasize a clearer description. It should be noted that identical members in each drawing may be indicated by the same reference numerals. Detailed descriptions of well-known functions and configurations that are judged to unnecessarily obscure the gist of the present invention are omitted.

The revolving ball mill according to the present invention can be broadly defined as including a grinding unit 100, a support unit 1, a swing driving unit 3, a raw material injection unit 80, and a reactant injection unit 90.

First, the support part 1 constitutes the overall framework of the ball mill system and can support the pulverizing part 100, the swing driving part 3, the raw material injection part 80, and the reactant injection part 90. In particular, the support part 1 supports the grinding unit 100 at a certain height from the ground to prevent interference with the ground when the grinding unit 100 rotates in place.

A rotation space (1a) may be provided inside the support portion (1), and the pulverizing portion (100) is connected to the swing drive portion (3) within the rotation space (1a). Rotation in place may occur depending on the drive.

Next, the swing driving unit 3 is connected to the grinding unit 100 and serves to rotate the grinding unit 100 so that the grinding unit 100 rotates within the rotation space 1a.

For example, the swing driving unit 3 may largely include a shaft member 4, a swing motor 5, and a power connection means 6.

The shaft member 4 is a shaft configuration that serves as a rotation reference for the pulverizing unit 100, and is installed on the inner wall of the rotation space 1a so as to be rotatable in place, and is connected to the pulverizing unit 100 to provide the pulverizing unit 100. Supports so that it can rotate.

At this time, the shaft member 4 is not coupled through the inside of the grinding unit 100, and the first shaft member 4a and the second shaft member 4b, which are segmented from each other, are placed on opposite walls of the rotation space 1a. It can be equipped with a structure that is coaxially connected to both sides of the pulverizing unit 100 in a condensed state.

A pulley may be coupled to at least one of the first shaft member 4a and the second shaft member 4b.

The swing motor 5 may be installed inside the support unit 1 and provides power to rotate the pulverizing unit 100, and a pulley may be coupled to the drive shaft.

The power connection means (6) is a component that connects the shaft member (4) and the swing motor (5) to transmit the driving force of the swing motor (5) to the shaft member (4), and the pulley of the shaft member (4) It may be composed of a belt structure that is mutually bent to the pulley of the swing motor (5).

As the swing driving unit 3 provided in this way rotates the grinding unit 100, the grinding unit 100 itself rotates while grinding the raw materials, thereby strongly agitating the raw materials, powders, etc. inside. The rotation of the pulverizing unit 100 by the swing driving unit 3 is called the first rotation.

Next, the grinding unit 100 is a component responsible for grinding the raw material injected from the raw material injection unit 80. Instead of cutting and grinding the raw material with a sharp blade, etc., the grinding unit 100 applies strong friction to the raw material to crush the raw material. It can be manufactured as a powder with a fine particle size.

For this purpose, the crushing unit 100 is largely comprised of a case 110, an injection pipe 120, a discharge pipe 130, a drum 140, a crushing member 150 and 160, a first rotary actuator 170, and a second rotary actuator. It can be exemplified as including (180).

The case 110 constitutes the overall exterior of the crushing unit 100 and includes an injection pipe 120, a discharge pipe 130, a drum 140, a crushing member 150 and 160, a first rotary driver 170, and a second rotary drive 170. The rotation actuator 180 can be supported in the right place.

At this time, the shaft member 4 of the swing driving unit 3 may be coupled to the outside of the case 110.

The injection pipe 120 is installed from the outside toward the inside of the case 110 to move raw materials toward the drum 140, and the discharge pipe 130 is installed from the inside of the case 110 toward the outside to move the raw materials toward the drum 110. It is a configuration that provides a passage for discharging the pulverized powder to the outside within (140), and the injection pipe 120 and discharge pipe 130 are located on one side and the other of the drum 140 with the drum 140 in between. Each can be connected.

In particular, the injection pipe 120 and the discharge pipe 130 can be installed inside the case 110 in a supported state to be rotatable in place, and are arranged coaxially with each other and spaced apart at a certain interval, with a drum ( 140) can be installed.

The injection pipe 120 and discharge pipe 130 can be inserted to a certain depth into one side and the other side of the drum 140, and are hollow in shape to enable movement of raw materials and powder. At this time, the inside of the injection pipe 120 is called the first injection passage 121, and the inside of the discharge pipe 130 is called the first discharge passage 131.

Next, the drum 140 has a cylindrical structure inside which a grinding space 141 is formed where raw materials are pulverized, and grinding members 150 and 160, which will be described later, are disposed in the grinding space 141 to form a grinding space 141. The raw materials introduced can be pulverized.

Raw materials may be injected into one side of the grinding space 141 through the injection pipe 120, and the pulverized powder may be discharged through the discharge pipe 130 on the other side.

The raw materials injected into one side of the grinding space 141 may be pulverized by the grinding action of the grinding members 150 and 160 and then collected in the center and discharged to the outside of the drum 140.

At one end of the drum 140, there is a second injection passage that communicates with the first injection passage 121 of the injection pipe 120 and guides the raw material injected into the injection pipe 120 to the grinding space 141 of the drum 140. (142) can be formed.

Next, the grinding members 150 and 160 are installed to be rotatable in place in the grinding space 141, and at least one is disposed on the coaxial axis between the injection pipe 120 and the discharge pipe 130, and the other is disposed in the injection pipe 120. ) and the discharge pipe 130 are eccentrically spaced at regular intervals and are evenly distributed within the grinding space 141, allowing the raw materials in the grinding space 141 to be pulverized more efficiently.

For example, the plurality of grinding members 150 and 160 include a first grinding member 150 and a first grinding member disposed at the center of the grinding space 141 and coaxially between the injection pipe 120 and the discharge pipe 130. It may be illustrated as including a plurality of second crushing members 160 that are disposed at a predetermined distance eccentric around the member 150 and spaced apart from each other on the outside of the crushing space 141 .

The first crushing member 150 is a single component and can be placed in the exact center of the crushing space 141, and the remaining second crushing members 160 are rotated and arranged at equal intervals around the first crushing member 150. Equipped with

In this embodiment, four second crushing members 160 are rotated at 90-degree intervals around the first crushing member 150, but the number and spacing of the second crushing members 160 can be modified as needed. It states that it can be done.

Meanwhile, in the case of the second injection passage 142 formed on one side of the drum 140, it has a structure that branches out radially toward each of the second pulverizing members 160, so that the raw materials of the second injection passage 142 are respectively It is ensured that supply can be made only towards the second grinding member 160.

Accordingly, the raw materials injected into the grinding space 141 first pass through the second grinding member 160 disposed on the outside of the grinding space 141, undergo primary grinding, and then gather at the center of the grinding space 141 to undergo first grinding. After passing through the member 150, it may be finally discharged to the outside of the drum 140.

In other words, the rotating ball mill according to the present invention does not inject the raw material directly toward the center of the grinding space 141, but first distributes and supplies it to the outside, and after primary grinding through each second grinding member 160, the raw material is pushed to the center. As a method of re-grinding and discharging the primary grinding material, not only uniform grinding of the raw materials but also a dispersion effect through stirring can be expected.

Meanwhile, in the case of the drum 140, rotation in place is achieved inside the case 110 through the first rotation driver 170, which will be described later, and at this time, the rotation of the drum 140 through the first rotation driver 170 is controlled. It is called 2 rotations.

At this time, the arrangement direction of the drum 140 in the case 110 may be set so that the rotation axes of the first rotation and the second rotation can be set in directions orthogonal to each other, and accordingly, the first rotation and the second rotation may be set in directions that are orthogonal to each other. When simultaneously moved, the drum 140 rotates in at least two different directions, thereby providing a structure in which grinding and stirring efficiency within the drum 140 can be maximized due to multi-directional rotation.

Meanwhile, as a configuration for rotating the drum 140 in place within the case 110, a pulley 143 is integrally provided at one end of the drum 140, and the first rotation driver 170 is a motor, and the motor Since it can be implemented in various modifications, such as consisting of a belt connecting the drive shaft of and the pulley 143 of the drum 140, detailed description will be omitted below.

Next, the second rotation driver 180 is a component for rotating the discharge pipe 130. As the discharge pipe 130 itself rotates in the process of discharging the powder, the powder being discharged to the first discharge passage 131 A vortex is formed to enable agitation and discharge at a faster rate.

In the case of the second rotation driver 180, like the above-described first rotation driver 170, it can be modified in various ways, such as consisting of a motor, a belt connecting the drive shaft of the motor and the pulley of the discharge pipe 130, etc. Detailed description is omitted below.

On the other hand, the power connection device 190 connects the first grinding member 150 and the second grinding member 160 arranged in the grinding space 141 to the discharge pipe 130, so that the grinding space ( 141), which is configured to rotate in place within the discharge pipe 130, is axially connected to the first crushing member 150, and the power connection device 190 is a gear coupled to the outside of the discharge pipe 130 and the second crushing member. (160) It can be implemented as a gear set including gears coupled to the outside of each but meshed with gears coupled to the discharge pipe 130.

Accordingly, as the second rotary driver 180 rotates the discharge pipe 130, the first grinding member 150 and the second grinding member 160 rotate in place within the grinding space 141 to grind the raw materials. A structure that can be used is in place.

The first crushing member 150 and the second crushing member 160 may have the same configuration. However, in the case of the second crushing member 160, raw materials are received from the second branched injection passage 142, and then crushed. This is discharged to the grinding space 141, and in the case of the first grinding member 150, the primary grinding material discharged from the second grinding member 160 is received, re-grinded, and then discharged to the outside of the drum 140. There is a difference.

First, the first crushing member 150 is largely divided into a first crushing shaft 151, a first one side cover 152, a first other side cover 153, a first crushing module 154, and a first spacer bar 156. ) can be exemplified as including.

The first grinding shaft 151 may be installed on the inner wall of the grinding space 141 so that it can rotate in place. At this time, one end of the first grinding shaft 151 may be coupled to one inner wall of the grinding space 141 via a bearing, and the other end may be in the form of a free end extending toward the other inner wall of the grinding space 141.

The first one side cover 152 and the first other side cover 153 are configured to limit the movement of the first crushing module 154 coupled to the outside of the first crushing shaft 151, and the first crushing module 154 It can be compressed and stored between the first one side cover 152 and the first other side cover 153.

The first one side cover 152 may be coupled to one side of the first crushing shaft 151, and the first other side cover 153 may be attached to the other end of the first crushing shaft 151 so as to face the first one side cover 152. It can be installed on the inner wall of the other side of the grinding space 141 to be able to rotate in place via a bearing while being spaced apart at a certain distance.

Accordingly, a certain gap can be secured between the first other cover 153 and the first grinding shaft 151, and this clearance allows the pulverized powder to pass through the first grinding module 154 and the discharge pipe 130. It can be discharged to the first discharge passage 131.

At this time, a second discharge passage (153a) communicating with the first discharge passage 131 of the discharge pipe 130 is formed on the first other cover 153 to transfer the powder formed from the first grinding module 154 to the first discharge passage 153a. It can be discharged toward the discharge passage 131.

The first grinding module 154 is configured to grind the raw materials collected in the center of the grinding space 141 while rotating according to the rotational drive of the first grinding shaft 151. In particular, the raw materials are cut and crushed with a sharp blade, etc. Its characteristic is that it applies a strong frictional force to the raw material, allowing the raw material to be formed into a powder with a fine particle size.

A plurality of first crushing modules 154 may be configured to be continuously coupled along the axial direction to the outside of the first crushing shaft 151 in the section between the first one side cover 152 and the first other cover 153. At this time, a first spacer plate 155 is interposed between adjacent first crushing modules 154 to space each first crushing module 154 at a certain distance.

First, the first grinding module 154 may be illustrated as largely including an inner housing 10, an outer housing 20, and grinding balls 30.

The inner housing 10 has a ring shape, is coupled to the outer peripheral surface of the first crushing shaft 151, and has a structure in which an internal receiving groove 11 is recessed on the outer peripheral surface.

The inner diameter of the internal housing 10 is made to be the same as the diameter of the first grinding shaft 151, so that the inner housing 10 is fitted on the first grinding shaft 151, so that the first grinding shaft 151 is formed. When rotating, rotate in conjunction with this.

The inner receiving groove 11 is recessed along the circumferential direction of the inner housing 10, and a portion of the plurality of grinding balls 30 in the inner direction can be rolled and accommodated in this inner receiving groove 11.

Next, the outer housing 20 may be formed in a ring shape like the inner housing 10 described above, and is positioned to accommodate the inner housing 10 inside, and an external receiving groove 21 is recessed on the inner peripheral surface. It consists of a structure.

The external receiving groove 21 is recessed along the circumferential direction of the external housing 20, and the external receiving groove 21 includes an outer part of the plurality of grinding balls 30 that are not accommodated in the internal receiving groove 11. cloud can possibly be accommodated.

The inner diameter of the outer housing 20 is formed to be larger than the outer diameter of the inner housing 10, so that it can be spaced apart in the outward direction on the concentric circle of the inner housing 10, and the inner housing 10 and the outer housing 20 are spaced apart from each other. The crushing balls 30 are interposed between the outer housing 20, the inner housing 10, and the crushing balls 30 to provide a structure in which each is relatively slippable.

Although not shown, the outer housing 20 may be configured to not rotate even if the inner housing 10 rotates by compressing the outside of the outer housing 20.

The crushing balls 30 are interposed between the internal receiving groove 11 and the external receiving groove 21 and are rolled between the inner housing 10 and the outer housing 20, and are formed between the inner housing 10 and the outer housing ( 20) The crushing balls 30 interposed between the outer housing 20 and the inner housing 10 serve to support the outer housing 20 and the inner housing 10 at a certain interval so that they can be rotated relative to each other, and also support the internal receiving groove 11 to the external receiving groove 21. It performs the role of pulverizing the raw materials by applying shear or compression force due to friction to the raw materials introduced into the .

A plurality of grinding balls 30 may be arranged along the circumferential direction, and the raw material flows into the finely spaced space between the grinding balls 30 and the internal receiving groove 11 and the external receiving groove 21, As the first grinding shaft 151 is rotated and the inner housing 10 rotates together, the raw materials interposed between the inner housing 10, the outer housing 20, and the grinding balls 30 may be pulverized. there is.

At this time, since the outer diameter of the inner housing 10 is formed to be smaller than the inner diameter of the outer housing 20, the outer housing 20 and the inner housing 10 may be configured to be spaced apart from each other at a certain distance, and accordingly, the first pulverization Opening portions 40 in the form of a closed ring are opened on one side and the other side of the module 154 in the direction toward the crushing balls 30 to allow the raw material to be moved between the adjacent first crushing modules 154.

For example, the raw material introduced through the opening 40 on one side may be pulverized inside the first crushing module 154 and then discharged to the outside of the first crushing module 154 through the opening 40 on the other side.

At this time, the openings 40 of each of the plurality of first grinding modules 154 are provided on the same line so that the raw material that has passed through one first grinding module 154 is transferred back to the adjacent first grinding module 154. This can be done repeatedly to carry out a chain grinding action of raw materials.

That is, the raw material introduced into the first grinding member 150 can be pulverized into powder while passing in line through the plurality of first grinding modules 154 coupled to the outside of the first grinding shaft 151. The raw material that is pulverized by the first pulverizing module 154 and moved to the first pulverizing module 154 located on the most other side is the It can be discharged to the first discharge passage 131 of the discharge pipe 130 through the second discharge passage 153a formed in the other cover 153.

The first spacer plate 155 may be interposed between each adjacent first crushing module 154 to space the adjacent first crushing modules 154 apart at a predetermined distance.

At this time, each of the plurality of first spacer plates 155 is in the form of a circular thin plate, and has a structure in which a shaft coupling hole 155a is formed through the center so that it can be coupled to the outside of the first crushing shaft 151. In particular, The outer diameter of the first spacer plate 155 is made to be the same as the outer diameter of the inner housing 10 so that the first spacer plate 155 does not block the opening portion 40.

If a portion of the first spacer plate 155 blocks the opening portion 40, the movement of raw materials to the opening portion 40 may not be smooth, resulting in a problem of reduced fluidity of the raw materials.

In addition, the first separation plate 155 seals the space between the inner housings 10 of adjacent first crushing modules 154, so that the raw material discharged from the first crushing module 154 passes through the first crushing shaft 151. Make sure it does not stick to the small area it is facing.

A separation space 155b equal to the thickness of the first separation plate 155 may be formed between adjacent first crushing modules 154 by the first separation plate 155, and the separation space 155b may be used to form the first crushing module 154. Allows raw materials to flow in or out toward the inside of the grinding module 154.

That is, among the raw materials that have been pulverized through the second pulverizing member 160 and moved to the center of the drum 140, the powder having an appropriate particle size that can be introduced into the separation space 155b is divided into the first powder through the separation space 155b. While the raw material flows into the crushing module 154, the raw material flowing into the first crushing module 154 according to the raw material injection pressure continuously passes through the plurality of first crushing modules 154 and goes through the crushing process again to the other side. While moving toward, it can be discharged through the discharge pipe 130 with an appropriate particle size.

The first separation plate 155 prevents the generation of frictional heat during rotation by preventing the adjacent first crushing modules 154 from interfering with each other, and the separation space 155b formed by the first separation plate 155 is It can be used as a passage for discharging not only the pulverized powder but also the heat generated during the pulverizing process, preventing overheating of the first pulverizing module (154) and further preventing deterioration due to thermal deformation of the powder to ensure sufficient marketability. make it possible

In particular, each space 155b is formed in a straight direction perpendicular to the axial direction of the first grinding shaft 151, so that it has a structure capable of maximizing the discharge efficiency of powder and hot air.

Meanwhile, in order to further improve grinding efficiency, grinding beads with a smaller diameter than the grinding balls 30 can be inserted between the inner housing 10 and the outer housing 20.

At this time, the grinding beads can be interposed in the opening 40 between the outer housing 20 and the inner housing 10 to prevent direct overlap with the grinding balls 30, and when the inner housing 10 rotates, While mixing with the raw materials within the opening area 40, the raw materials are pulverized by applying physical impact to the raw materials.

In other words, the grinding beads can perform an auxiliary grinding role to properly dissociate the raw materials immediately before grinding by the grinding balls 30.

In addition, the grinding beads allow grinding to occur at all times inside the grinding module even if the raw material does not reach the grinding balls 30, thereby maximizing grinding efficiency.

The grinding beads have a diameter smaller than that of the grinding balls 30, but are formed in a spherical shape with a larger diameter than the spacing of the spacing space 155b so that they are not discharged into the spacing space 155b, so that they are moved into the moving space together with the powder. A structure is in place to prevent arbitrary discharge.

The first spacer bar 156 is coupled to the first one side cover 152 and the first other cover 153 and plays the role of supporting the first one side cover 152 and the first other cover 153 apart. As a configuration, a plurality of units are rotated and arranged at equal intervals along the circumferential direction of the first one side cover 152 and the first other cover 153 at a predetermined distance apart from the first crushing module 154, so that the raw material passes without difficulty. This allows the surrounding raw materials to be appropriately stirred according to the self-rotation of the first grinding member 150 within the grinding space 141.

Next, each of the plurality of second crushing members 160 largely includes a second crushing shaft 161, a second one side cover 162, a second other side cover 163, a second crushing module 164, and a second spacer. It may be illustrated as including a rod 166.

First, the second grinding shaft 161 may be installed on the inner wall of the grinding space 141 so that it can rotate in place. At this time, one end of the second grinding shaft 161 is in the form of a free end facing one inner wall of the grinding space 141, and the other end may be coupled to the other inner wall of the grinding space 141 via a bearing.

The second one side cover 162 and the second other side cover 163 are configured to limit the movement of the second crushing module 164 coupled to the outside of the second crushing shaft 161, and the second crushing module 164 It can be compressed and stored between the second one side cover 162 and the second other side cover 163.

The second one-side cover 162 is installed to be rotatable in place at a corresponding position of the branched second injection path 142, and the second other side cover 163 is positioned on the second crushing shaft to face the second one-side cover 162. It can be coupled to the other side of (161).

At this time, the second one-side cover 162 may be installed on one inner wall of the grinding space 141 at a certain distance from one end of the second grinding shaft 161 to be rotatable in place via a bearing.

Accordingly, a certain gap can be secured between the second one-side cover 162 and the second grinding shaft 161, and this gap allows the raw material injected through the second injection passage 142 to pass through the second grinding module. It can flow into (164).

At this time, a third injection passage 162a communicating with the second injection passage 142 is formed in the second one-side cover 162, so that the raw material injected from the second injection passage 142 is transferred to the second grinding module 164. can be injected toward.

It should be noted that the second grinding module 164 has the same configuration and function as the above-described first grinding module 154, and therefore uses the same reference numeral as the above-described first grinding module 154.

For example, a plurality of second pulverizing modules 164 have a structure in which a plurality of them are continuously coupled along the axial direction to the outside of the second pulverizing shaft 161 in the section between the second one side cover 162 and the second other cover 163. It can be done, and similarly, a second spacer plate 165 can be interposed between adjacent second crushing modules 164.

First, the second grinding module 164 may be illustrated as largely including an inner housing 10, an outer housing 20, and grinding balls 30.

The inner housing 10 has a ring shape, is coupled to the outer peripheral surface of the second grinding shaft 161, and has a structure in which an internal receiving groove 11 is recessed on the outer peripheral surface.

The inner diameter of the inner housing 10 is made to be the same as the diameter of the second grinding shaft 161, so that the inner housing 10 is fitted on the second grinding shaft 161, so that the second grinding shaft 161 is formed. When rotating, rotate in conjunction with this.

The inner receiving groove 11 is recessed along the circumferential direction of the inner housing 10, and a portion of the plurality of grinding balls 30 in the inner direction can be rolled and accommodated in this inner receiving groove 11.

Next, the outer housing 20 may be formed in a ring shape like the inner housing 10 described above, and is positioned to accommodate the inner housing 10 inside, and an external receiving groove 21 is recessed on the inner peripheral surface. It consists of a structure.

The external receiving groove 21 is recessed along the circumferential direction of the external housing 20, and the external receiving groove 21 includes an outer part of the plurality of grinding balls 30 that are not accommodated in the internal receiving groove 11. cloud can possibly be accommodated.

The inner diameter of the outer housing 20 is formed to be larger than the outer diameter of the inner housing 10, so that it can be spaced apart in the outward direction on the concentric circle of the inner housing 10, and the inner housing 10 and the outer housing 20 are spaced apart from each other. The crushing balls 30 are interposed between the outer housing 20, the inner housing 10, and the crushing balls 30 to provide a structure in which each is relatively slippable.

Although not shown, the outer housing 20 may be configured to not rotate even if the inner housing 10 rotates by compressing the outside of the outer housing 20.

The crushing balls 30 are interposed between the internal receiving groove 11 and the external receiving groove 21 and are rolled between the inner housing 10 and the outer housing 20, and are formed between the inner housing 10 and the outer housing ( 20) The crushing balls 30 interposed between the outer housing 20 and the inner housing 10 serve to support the outer housing 20 and the inner housing 10 at a certain interval so that they can be rotated relative to each other, and also support the internal receiving groove 11 to the external receiving groove 21. It performs the role of pulverizing the raw materials by applying shear or compression force due to friction to the raw materials introduced into the .

A plurality of grinding balls 30 may be arranged along the circumferential direction, and the raw material flows into the finely spaced space between the grinding balls 30 and the internal receiving groove 11 and the external receiving groove 21, As the second grinding shaft 161 is rotated and the inner housing 10 rotates along with it, the raw materials interposed between the inner housing 10, the outer housing 20, and the grinding balls 30 may be pulverized. there is.

At this time, since the outer diameter of the inner housing 10 is formed to be smaller than the inner diameter of the outer housing 20, the outer housing 20 and the inner housing 10 may be configured to be spaced apart from each other at a certain distance, and accordingly, the second pulverization Opening portions 40 in the form of a closed ring are opened on one side and the other side of the module 164 in the direction toward the crushing balls 30 to allow the raw material to be moved between the adjacent second crushing modules 164.

For example, the raw material introduced through the opening 40 on one side may be pulverized inside the second crushing module 164 and then discharged to the outside of the second crushing module 164 through the opening 40 on the other side.

At this time, the openings 40 of each of the plurality of second grinding modules 164 are provided on the same line so that the raw material that has passed through one second grinding module 164 is transferred back to the adjacent second grinding module 164. This can be done repeatedly to carry out a chain grinding action of raw materials.

That is, the raw material introduced into the second grinding member 160 can be pulverized into powder while passing in line through the plurality of second grinding modules 164 coupled to the outside of the second grinding shaft 161. The pulverized material pulverized by the second pulverizing module 164 may be discharged into the pulverizing space 141 of the drum 140 through the space 155b formed by the second spacer plate 165.

The second spacer plate 165 may be interposed between each adjacent second crushing module 164 to space the adjacent second crushing modules 164 apart at a predetermined distance.

At this time, each of the plurality of second spacer plates 165 is in the form of a circular thin plate, and has a structure in which a shaft coupling hole 165a is formed through the center so that it can be coupled to the outside of the second crushing shaft 161. In particular, The outer diameter of the second spacer plate 165 is made to be the same as the outer diameter of the inner housing 10 so that the second spacer plate 165 does not block the opening portion 40.

A separation space (165b) equal to the thickness of the second separation plate (165) may be formed between the second crushing modules (164) adjacent to each other by the second separation plate (165), and the ground space (165b) may be used to The pulverized material may flow out toward the pulverizing space 141.

That is, only the pulverized material that has been pulverized enough to pass through the separation space 165b can be discharged from the second pulverizing member 160 and transferred to the first pulverizing member 150.

Of course, the above-described grinding beads can also be applied to the second grinding member 160.

The second spacer bar 166 is coupled to the second one side cover 162 and the second other cover 163 and plays the role of supporting the second one side cover 162 and the second other cover 163 apart. As a configuration, a plurality of units are rotated and arranged at equal intervals along the circumferential direction of the second one-side cover 162 and the second other cover 163 at a predetermined distance apart from the second crushing module 164, so that the raw materials pass through without difficulty. This allows the surrounding raw materials to be appropriately stirred according to the self-rotation of the second grinding member 160 within the grinding space 141.

Although not shown, a cooling passage through which cooling fluid moves around the grinding space 141 may be formed in the drum 140. A cooling unit is connected to the cooling passage and circulates cooling water to the drum 140 to appropriately cool the heat generated during grinding of the raw materials in the grinding space 141.

At this time, in the case of the coolant pipe that transports the cooling fluid, one end is connected to the cooling passage, and the other end passes through the inside of the first shaft member (4a) and is connected to the end of the first shaft member (4a) to the first rotary joint (4c). It can be connected to , and the cooling unit can inject cooling fluid into the first rotary joint 4c and circulate the cooling fluid inside the drum 140. Accordingly, a structure is provided in which the cooling water pipe does not twist even when the grinding unit 100 rotates.

In addition, the co-rotating ball mill according to the present invention enables the production of higher quality powder by reacting the reactant with the raw material during the grinding process.

It is common for the reactive agent to be processed in a separate line after going through the pulverization process. As a result, the powder manufacturing process becomes complicated, and there is a problem of increasing the manufacturing cost due to the provision of additional equipment. However, in this embodiment, the pulverization and reactive agent are processed. It was designed to have a more effective structure that can carry out reactions simultaneously.

In this description, a reactive agent is a means to improve physical properties by causing a chemical reaction in the raw materials, and may vary depending on the type of raw materials, the purpose of use of the powder, etc., and for wet grinding purposes, it can be replaced by a lubricant to play a lubricating role. It is not particularly limited, and it is stated that various things can be used.

More specifically, a branch pipe 70 may be coupled to at least one of the injection pipe 120 and the discharge pipe 130.

At this time, the branch pipe 70 coupled to the injection pipe 120 is referred to as the first branch pipe 70-1, and the branch pipe 70 coupled to the discharge pipe 130 is referred to as the second branch pipe 70-2. .

In addition, the co-rotating ball mill according to the present invention is connected to the first branch pipe (70-1) and includes a raw material injection part (80) that injects the raw material to be pulverized toward the first branch pipe (70-1), and first and second It may further include a reactive agent injection unit 90 that is connected to at least one of the branch pipe 70 and the drum 140 and injects the reactive agent.

A raw material injection unit 80 and a reactive agent injection unit 90 are respectively connected to the first branch pipe 70-1 so that the raw material to be pulverized and the reactive agent can be injected toward the first branch pipe 70-1. do.

A reactive agent injection unit 90 and a recovery pipe 82 are each connected to the second branch pipe (70-2) to enable injection of the reactive agent and recovery of the powder toward the second branch pipe (70-2). .

First, the branch pipe 70 has a structure in which at least a first branch 71 and a second branch 72 are branched to both sides while connected to at least one of the injection pipe 120 and the discharge pipe 130.

At this time, a reactive agent injection unit 90 is connected to the first branch 71 of the first branch pipe 70-1 to inject the reactive agent toward the first branch pipe 70-1, and the second branch pipe 70-1 A raw material injection unit 80 is connected to (72) so that the raw material can be injected toward the first branch pipe (70-1).

In addition, a reactive agent injection unit 90 is connected to the first branch 71 of the second branch pipe 70-2 to inject the reactive agent toward the second branch pipe 70, and the second branch 72 ) is connected to a recovery pipe 82, so that the powder in the discharge pipe 130 can be sucked in and recovered.

Accordingly, inside the first branch pipe 70-1, the reactant can be reacted primarily with the raw material before being injected into the drum 140, and the manufactured powder is discharged inside the second branch pipe 70-2. While this is happening, the reactive agent can be reacted secondarily.

Meanwhile, the raw material primarily reacted by the reactive agent in the first branch pipe 70-1 may be injected into the drum 140, and at this time, the second branch 72 is injected into the injection pipe 120. It extends in parallel and the first branch 71 extends in the vertical direction of the second branch 72 so that the reactant can be cross-injected in the direction perpendicular to the injection path of the raw material passing through the branch pipe 70. .

In addition, the second branch 72 of the second branch pipe 70 extends parallel to the discharge pipe 130, and the first branch 71 extends in the vertical direction of the second branch 72, so that the reactant is 2. Cross injection can be performed in a direction perpendicular to the injection path of the powder passing through the branch pipe 70.

That is, since the reactive agent and the raw material or powder injected into the branch pipe 70 may collide by crossing each other in the vertical direction, the possibility of contact between the reactive agent and the raw material or powder increases significantly, and the possibility of contact between the reactive agent and the raw material or powder within the branch pipe 70 It is strongly dispersed and has a structure that increases mixing efficiency.

In the attached drawing, the direction in which reactants and raw materials move is exemplarily shown through dotted lines.

In some cases, the reactive agent injection unit 90 may directly inject the reactive agent not only into the branch pipe 70 but also toward the grinding space 141 of the drum 140, exposing the raw material and the reactive agent to each other even during the grinding process.

That is, the reactive agent injection unit 90 in this embodiment may be simultaneously connected to the branch pipe 70 and the drum 140 to inject the reactive agent individually.

The reactive agent injection unit 90 in this embodiment includes, for example, a first reactive agent pipe 91, a first nozzle 92, a second reactive agent pipe 93, and a second nozzle 94. It can be exemplified.

First, the first reactive agent pipe 91 and the second reactive agent pipe 93 are pipes through which the reactive agent moves, and are the first branch of the branch pipe 70 coupled to the injection pipe 120 and the discharge pipe 130, respectively ( 71) It can be branched on both sides so that it can be directly connected.

The first reaction pipe 91 directly connected to the first branch 71 of the first branch pipe 70-1 and the second reaction pipe 91 directly connected to the first branch 71 of the second branch pipe 70-2. The first nozzle 92 and the second nozzle 94 are respectively coupled to the end of the second pipe 93 to spray the reactive agent moved to the first reactive agent pipe 91 and the second reactive agent pipe 93. It can be injected into the organ 70.

At this time, the first reactive agent pipe 91 and the second reactive agent pipe 93 pass through the inside of the second shaft member 4b and are connected to the end of the second shaft member 4b, similar to the connection method of the coolant pipe described above. It can be connected to the combined second rotary joint (4d), and a reactive agent supply tank (not separately shown) is connected to the second rotary joint (4d) to inject the reactive agent into the second rotary joint (4d) to crush the reactive agent. It can be supplied toward the unit 100, and thus, a structure can be provided in which the first reactive agent pipe 91 and the second reactive agent pipe 93 are not twisted by the rotation of the pulverizing unit 100.

Accordingly, since the reactive agent is directly mixed with the raw material and powder before and after pulverizing, a structure is provided that allows pulverization of the raw material and reaction of the reactive agent at the same time. Accordingly, the raw material and the reactive agent are mixed separately. Even if the composition for is excluded, a beneficial effect can be expected in that the raw materials and reactants can be dispersed more effectively.

In particular, the reactive agent injection unit 90 can inject the reactive agent toward the branch pipe 70 to primarily react the reactive agent on a single raw material before pulverization, and then secondarily react the reactive agent on the pulverized powder. Therefore, the possibility of contact between the raw material and the reactive agent is greatly increased, and the advantageous effect of greatly improving reaction efficiency can be expected.

Next, the raw material injection unit 80 can be implemented in various ways on a line that can inject raw materials toward the branch pipe 70. For example, in the case of the raw material transfer pipe 81 for transferring raw materials, the above-described cooling water pipe is used. In the same way as the connection method, it can pass through the inside of the second shaft member (4b) and be connected to the second rotary joint (4d) coupled to the end of the second shaft member (4b), and a raw material tank (not separately shown) is connected to the second rotary. Connected to the joint 4d, the raw material can be supplied to the grinding unit 100 by injecting the raw material into the second rotary joint 4d. Accordingly, the raw material transfer pipe 81 is connected to the rotation of the grinding unit 100. It has a structure that prevents twisting.

The connection method of the above-described cooling water piping, first and second reactive agent piping, raw material transfer piping, and recovery piping is a line that can continuously inject or recover cooling fluid, reactive agents, raw materials, etc. into the rotating grinding unit 100. Since it can be appropriately modified, detailed description will be omitted below.

Hereinafter, the process of moving raw materials within the grinding space 141 of the drum 140 will be described by way of example.

First, when injection of the raw material starts, the raw material moves to the first injection passage 121 of the injection pipe 120. Afterwards, it is appropriately distributed through the branched second injection passage 142 and delivered to the second crushing module 164 through the third injection passage 162a of the second crushing member 160.

Accordingly, the raw material passes through a plurality of second grinding modules 164 arranged adjacent to each other and moves in the other direction of the second grinding shaft 161 to be crushed, and the separation space between the adjacent second grinding modules 164 is formed. The pulverized material having a particle size sufficient to pass through (165b) exits between the second pulverizing modules (164) through the separation space (165b) and flows out into the pulverizing space (141) of the drum (140) under the constant injection pressure of the raw materials. According to the centrifugal force applied to the drum 140, etc., it is gradually pushed to the center of the grinding space 141 and naturally flows into the first grinding member 150.

At this time, the raw material flowing into the first crushing member 150 may flow into the first crushing member 150 through the separation space 155b between the adjacent first crushing modules 154, and the above-described second crushing member 150 may be used. In the same way as the grinding action in the member 160, the powder thus formed moves in the other direction of the first grinding shaft 151 and is pulverized, and then passes through the second discharge passage 153a of the first other side cover 153 and the discharge pipe ( It can be discharged into the first discharge passage 131 of 130).

In summary, the ball mill according to the present invention significantly lowers the manufacturing cost by enabling fine pulverization of raw materials through strong friction force through a grinding module of a radial bearing structure with a simple structure and low cost, even without a sharply refined blade, and also, Since the grinding module itself is not structured to form a sharp blade, it guarantees significantly improved durability compared to existing blades that wear out with repeated use, eliminating the cost of various maintenance such as blade replacement. provides.

In addition, it prevents the deterioration of raw materials due to heat during the grinding process, allows the raw materials to be more finely divided, and heat generation is appropriately eliminated not only when grinding dry raw materials, but also wet raw materials, so the raw materials do not easily stick and grind smoothly. It provides an effect that allows this to happen.

The embodiments of the present invention described above are merely illustrative, and those skilled in the art will understand that various modifications and other equivalent embodiments are possible. Therefore, it will be understood that the present invention is not limited to the forms mentioned in the detailed description above. Therefore, the true scope of technical protection of the present invention should be determined by the technical spirit of the attached patent claims. In addition, the present invention should be understood to include all modifications, equivalents and substitutes within the spirit and scope of the present invention as defined by the appended claims.

1: support
3: Swing driving part
100: Grinding unit
110: case
120: Injection tube
130: discharge pipe
140: drum
150: First crushing member
160: Second crushing member

Claims (10)

It includes a grinding unit that grinds the raw materials,
The crushing unit,
case;
a hollow injection pipe and discharge pipe installed inside the case so as to be rotatable in place, and spaced apart from each other on the same axis at a predetermined distance;
A drum having a crushing space formed inside and mounted between the injection pipe and the discharge pipe;
A plurality of grinding members installed to be rotatable in place in the grinding space of the drum, at least one of which is arranged coaxially between the injection pipe and the discharge pipe, and the others are arranged eccentrically at a certain distance from the injection pipe and the discharge pipe;
a first rotation driver that rotates the drum;
a second rotation driver that rotates the discharge pipe; and
A co-rotating ball mill comprising a power linkage device that connects the discharge pipe and a plurality of pulverizing members so that each pulverizing member rotates in place as the discharge pipe rotates. In claim 1,
The plurality of grinding members,
a first grinding member disposed at the center of the grinding space and coaxially between the injection pipe and the discharge pipe; and
A co-rotating ball mill comprising a plurality of second pulverizing members disposed at a predetermined distance eccentric around the first pulverizing member and spaced apart from each other on the outskirts of the pulverizing space. In claim 2,
At one end of the drum, a second injection passage is formed in communication with the first injection passage of the injection pipe to guide the raw material injected into the injection pipe to the grinding space, and the second injection passage is radial toward each second grinding member. A co-rotating ball mill is branched and formed so that raw materials from the second injection furnace are supplied only to the plurality of second grinding members. In claim 3,
The first crushing member,
a first grinding shaft rotatably installed on the inner wall of the grinding space;
A first one-side cover coupled to one side of the first crushing shaft;
a first other side cover rotatably installed on the inner wall of the grinding space at a predetermined distance from the other end of the first grinding shaft to face the first one side cover; and
It includes a plurality of first crushing modules coupled along the axial direction to the outside of the first crushing shaft in the section between the first one side cover and the first other side cover,
A co-rotating ball mill, characterized in that a second discharge passage communicating with the first discharge passage of the discharge pipe is formed on the first other cover to discharge the powder formed from the first grinding module toward the first discharge passage. In claim 4,
The first crushing member,
A first spacer bar is coupled to the first one side cover and the first other cover and supports the first one side cover and the first other cover to be spaced apart from each other. In claim 4,
Each of the plurality of second crushing members,
A second one-side cover installed to be rotatable in place at a corresponding position of the branched second injection channel;
a second grinding shaft rotatably installed on the inner wall of the grinding space;
a second other side cover coupled to the other side of the second crushing shaft; and
It includes a plurality of second grinding modules coupled along the axial direction to the outside of the second grinding shaft in the section between the second one side cover and the second other side cover,
A co-rotating ball mill, wherein a third injection passage communicating with the second injection passage is formed on the second one side cover to inject the raw material injected from the second injection passage toward the second grinding module. In claim 6,
Each of the plurality of second crushing members,
A second spacer bar is coupled to the second one side cover and the second other cover to support the second one side cover and the second other cover apart from each other. In claim 6,
Each of the plurality of first grinding modules and second grinding modules,
An inner housing that has a ring shape, is coupled to the outer peripheral surfaces of the first grinding shaft and the second grinding shaft, and has an internal receiving groove recessed in the outer peripheral surface;
An outer housing that has a ring shape and is positioned to accommodate the inner housing inside, and has an external receiving groove recessed on its inner circumferential surface; and
A co-rotating ball mill comprising: a plurality of grinding balls interposed between the inner and outer receiving grooves and rolling between the inner housing and the outer housing. In claim 8,
A co-rotating ball mill, characterized in that a first spacer plate is interposed between adjacent first and second crushing modules. In claim 1,
A support portion provided with a rotation space inside; and
It further includes a swing driving part that is connected to the grinding unit and rotates the grinding unit so that it rotates within the rotation space,
The swing driving part,
A shaft member installed on the inner wall of the rotation space to be rotatable in place and connected to the crushing unit;
A swing motor installed on the support part; and
An idle rotating ball mill comprising a power connection means that connects the shaft member and the swing motor so that the driving force of the swing motor is transmitted to the shaft member.