KR102681549B1 - Apparatus and method for preventing retinal force on an inclined vibrating screen using a multi-channel wave dancing vibration module - Google Patents

Abstract

In the present invention, the existing vibrating screen retinal force removal device cannot remove the retinal force area 1:1 from the area corresponding to the entire screen net surface of the vibrating screen, so the foreign matter screening rate of the vibrating screen is low, and the human In the case of this method of entering the vibrating screen directly and drilling the screen net surface of the vibrating screen one by one using an awl and hammer, it is not only a safety issue but also takes too much time, and as a result, the operation of the vibrating screener is stopped for a long time. Therefore, in order to improve the problem of lowering the vibration screening rate, an inclined vibrating screen main body (100) and a multi-channel wave dancing vibration shaking module (200) are constructed, so that a person can directly vibrate through the multi-channel wave dancing vibration shaking module. Even without entering the screen, the retinal force phenomenon can be solved by shaking and dancing with the force of vibration and transmitting the vibration force and striking force to the screen network, making it safer and more movable than the existing manual method. By operating the multi-channel wave dance type vibration module during operation, continuous work is possible without stopping the operation of the vibrating screen, and the retinal force improvement rate through the vibrating screen can be improved by more than 80% compared to the existing one, and the multi-channel wave dance type vibration can be improved by more than 80%. Through the head-type multi-channel winch unit and wire connected to the rattle unit, the multi-channel wave dance type vibrating rattle unit moves the network of the inclined vibrating screen up and down, and the screen is made into a wave dance that trembles with the power of vibration. When transmitting vibration force while in contact with the surface of the screen, the elastic spring-type bridge prevents the phenomenon of floating in the air without contacting the screen net through the elastic spring type bridge. This prevents high-quality It can create an atmosphere that transmits vibration and striking force, and the multi-channel wave dance type vibrating rattle shakes and dances with the power of vibration, solving the retinal force of the screen network with vibration and striking force, making the screen more sensitive than before. Inclined vibrating screen retinal force through a multi-channel wave-dancing vibrating rattle module that improves the sorting rate by 80% and makes the sorting speed by particle size 1.5 to 3 times faster than before up to the bottom of the screen of the inclined vibrating screen main body. The purpose is to provide prevention devices and methods.

Description

Apparatus and method for preventing retinal force on an inclined vibrating screen using a multi-channel wave dancing vibration module}

The present invention is applied to an inclined vibrating screen, and more specifically, it is installed on one side of the upper outer direction of the screen net, and when the retinal force of the screen net is generated, it is thrown in and trembles and dances with the force of vibration. The present invention relates to a device and method for preventing retinal force on an inclined vibrating screen using a multi-channel wave-dancing vibration rattle module that can shake off aggregates or dirt blocking the screen net with vibration and striking force and cause them to fall through the screen net.

An inclined vibrating screen is a device that separates selected objects by size when producing recycled aggregate from aggregate collected from stone mountains or construction waste.

This inclined vibrating screen is equipment that receives aggregates from a crusher or crusher and classifies them by particle size.

In other words, among the aggregates, aggregates smaller than the eye size of the mesh of the inclined vibrating screen pass through the net installed at the top and fall into the small eye-sized net installed below, while aggregates larger than the eye size of the mesh do not pass through the net. Therefore, aggregates are classified according to size according to the mesh size.

However, in order to reduce the generation of dust during the crushing or sorting process, the powder generated in the process of crushing the aggregate through a process such as spraying or the originally contained dirt clumps with water and acquires a certain degree of viscosity. A retinal force phenomenon occurs in the screen network of an inclined vibrating screen.

This phenomenon occurs particularly frequently when selecting recycled aggregates in the construction waste intermediate treatment process that recycles construction waste.

In order to eliminate the retinal force phenomenon of the existing inclined vibrating screen, a device that strikes the retinal force area through a non-powered hitting rod, or a surface contact with aggregates, foreign substances, and lumps of dirt using the force of vibration through an elastic member vibrating whisk. Although a device that simultaneously shakes it off is mentioned, it is not possible to apply a 1:1 blow to the entire surface of the net where the retinal force occurs in an inclined vibrating screen, so the retinal force is sorted by particle size to the extent of resolving the retinal force only in a portion. As efficiency decreased, problems such as aggregate or soil of the particle size that should fall through the mesh below continued to pass through.

In addition, there is a method in which a person directly enters the inside of the inclined vibrating screen and punches the retinal force of the vibrating screen one by one using a striking tool such as a hammer. However, this has safety issues and is too time-consuming. Since there was no choice but to stop the vibration separator, there was a problem that reduced overall work efficiency.

Domestic Patent Publication No. 10-1256484

In order to solve the above problems, the present invention uses a multi-channel wave dance type vibrating module to wave dance while shaking with the power of vibration without a person directly entering the inclined vibrating screen, You can shake off stones or viscous dirt blocking the snow and let them fall through the screen net, and the multi-channel wave dance-type vibrating rattle transmits the vibration force by contacting the surface of the screen net with a wave dance that trembles with the power of vibration. The purpose is to provide a device and method for preventing the retinal force of an inclined vibrating screen through a multi-channel wave dance type vibration rattling module that can prevent the phenomenon of floating in the air, first and second, without contacting the screen net. .

In order to achieve the above object, an inclined vibrating screen retinal force prevention device using a multi-channel wave dance type vibration rattling module according to the present invention is provided.

It is installed on one side of the upper outer side of the screen net, and when the retinal force of the screen net is generated, it is thrown in, shaking and dancing with the force of vibration, and the aggregate or dirt blocking the screen net with the vibration force and impact force. This is achieved by shaking the screen and making it fall through the screen net.

More specifically, the inclined vibrating screen retinal force prevention device through the multi-channel wave dancing vibration shaking module is,

An inclined vibrating screen body (100) that spreads construction waste or soil containing foreign substances such as vinyl or wood chips and sorts them by particle size through the force of vibration and an inclined structure,

A multi-channel wave dance type vibration module that is installed on the outside of the inclined vibrating screen body while being supported by a winch wire, and shakes and dances with the force of vibration, improving the retinal force phenomenon of the screen network with vibration force and striking force. It is characterized by being composed of (200).

As described above, in the present invention

First, through the multi-channel wave dance type vibration module, even if a person does not enter the vibrating screen directly, the retinal force phenomenon can be solved by shaking and dancing with the power of vibration and transmitting the vibration force and striking force to the screen network. , It has excellent safety compared to the existing human-based method, and by operating the multi-channel wave-dancing vibration vibration module even during operation, continuous work is possible without stopping the operation of the vibrating screen, which increases the retinal force through the vibrating screen compared to the existing method. The improvement rate can be increased by more than 80%.

Second, through the head-type multi-channel winch unit and wire connected to the multi-channel wave dancing vibration rattling unit, the multi-channel wave dancing vibrating rattling unit moves up and down the network of the inclined vibrating screen, and the force of vibration When the vibration force is transmitted by contacting the surface of the screen net with a trembling wave dance, the elastic spring-type bridge prevents the screen from touching the screen net and floating into the air in the first and second ways. , It is possible to create a high-quality vibration and striking force transmission atmosphere on the screen network surface.

Third, the multi-channel wave dance type vibrating device dances while trembling with the power of vibration and resolves the retinal force of the screen network with vibration and striking force, improving the selection rate by screen by 80% compared to the existing one, and improving the selection rate by 80%. The speed of sorting by particle size up to the bottom of the screen of the main vibrating screen can be 1.5 to 3 times faster than before.

Figure 1 is a block diagram showing the components of an inclined vibrating screen retinal force prevention device (1) using a multi-channel wave dance type vibration rattling module according to the present invention;
Figure 2 is a perspective view showing the components of the inclined vibrating screen retinal force prevention device (1) using the multi-channel wave dance type vibration rattling module according to the present invention;
Figure 3 is a side cross-sectional view showing the components of the inclined vibrating screen retinal force prevention device (1) using the multi-channel wave dance type vibration rattling module according to the present invention;
Figure 4 is a block diagram showing the components of the vibration generator according to the present invention;
Figure 5 is a block diagram showing the components of the multi-channel wave dance type vibration rattle module according to the present invention;
Figure 6 is a perspective view showing the components of the multi-channel wave dancing vibration vibration module according to the present invention;
Figure 7 is a perspective view showing the components of a head-type multi-channel winch according to the present invention;
Figure 8 is a front view showing the components of a head-type multi-channel winch according to the present invention;
Figure 9 is a perspective view showing the components of the head-type wire reel part according to the present invention;
Figure 10 is a block diagram showing the components of the multi-channel wave dance type vibration rattle unit according to the present invention;
Figure 11 is a configuration diagram showing the components of the multi-channel wave dance type vibration rattle unit according to the present invention;
Figure 12 is an enlarged view showing the components of the left guide wing according to the present invention;
Figure 13 shows a structure in which the guide entrance of the twin-axis anti-dropping guide rail part is widened to allow the multi-channel wave dance type vibrating rattle unit according to the present invention to easily enter the inclined vibrating screen main body, An embodiment showing that the vibration ratter rides on the twin-axis drop-prevention type guide rail part and does not escape to the outside, but moves along the twin-axis drop-prevention type guide rail part,
Figure 14 is a perspective view showing the components of the first wave dance type vibration rattle according to the present invention;
Figure 15 is an exploded perspective view showing the components of the first wave dancing vibration rattle according to the present invention;
Figure 16 is a perspective view showing that the first screen network contact part according to the present invention is composed of a first screen network contact type protrusion module;
Figure 17 is an exploded perspective view showing the components of the first, second, third, and fourth double-arm motor units according to the present invention;
18 is an enlarged view showing the components of the first elastic spring-type bridge portion according to the present invention;
Figure 19 is an enlarged view showing the components of the light guide wing according to the present invention;
Figure 20 shows that in the inclined vibrating screen main body according to the present invention, through the force of vibration and the inclined structure, construction waste or soil containing foreign substances such as vinyl or wood chips are spread out and sorted by particle size. Example diagram,
Figure 21 is an embodiment showing that when screen blockage occurs according to the present invention, the multi-channel wave dance type vibration rattle part of the multi-channel wave dance type vibration rattle module is located at the top of the inclined vibrating screen body in the rest area,
Figure 22 shows that the multi-channel wave dance type vibrating rattle part according to the present invention is formed in a straight horizontal structure at the screen net position where the retinal force phenomenon of the inclined vibrating screen main body occurs, and dances while shaking with the force of vibration. , an embodiment showing that foreign substances clogged in the screen network are shaken off using vibration and striking force and made to fall through the screen network,
Figure 23 is a flowchart showing the specific process of the screen net foreign matter removal method on the surface of the vibrating screen through the multi-channel wave dance type vibration shaking module according to the present invention.

First, the standard for preventing retinal force described in the inclined vibrating screen retinal force prevention device described in the present invention is based on the time of driving the inclined vibrating screen, by shaking off the aggregate or dirt blocking the screen mesh and penetrating the screen mesh. By dropping, it refers to solving the retinal force phenomenon that occurs during the operation of the inclined vibrating screen during operation.

Hereinafter, a preferred embodiment according to the present invention will be described with accompanying drawings.

Figure 1 is a block diagram showing the components of an inclined vibrating screen retinal force prevention device (1) using a multi-channel wave dance type vibration rattle module according to the present invention, and Figure 2 is a block diagram showing the components of a multi-channel wave dance type vibration rattle module according to the present invention. It relates to a perspective view showing the components of an inclined vibrating screen retinal force prevention device (1) through a vibration rattle module, and Figure 3 shows retinal force prevention of an inclined vibrating screen through a multi-channel wave dance type vibration rattle module according to the present invention. This is a side cross-sectional view showing the components of the device 1, which is installed on one side of the upper outer side of the screen net, and is inserted when the retinal force of the screen net is generated, shaking and dancing with the force of vibration. As it dances, it is designed to shake off the aggregate or dirt blocking the screen mesh with vibration and striking force, allowing it to fall through the screen mesh.

More specifically, the inclined vibrating screen retina force prevention device 1 through the multi-channel wave dancing vibration shaking module is composed of an inclined vibrating screen main body 100 and a multi-channel wave dancing vibration shaking module 200.

First, the inclined vibrating screen body 100 according to the present invention will be described.

The inclined vibrating screen body 100 uses the force of vibration and an inclined structure to spread construction waste or soil containing foreign substances such as vinyl or wood chips and to sort them by particle size.

As shown in FIG. 2, it is formed in a longitudinal box shape with one side open, and a construction waste input portion 110 is formed on one side of the front end of the upper surface, and an discharge portion 130 is formed on one side of the lower end of the upper surface. , the screen unit 120 equipped with a screen for sorting by particle size is formed in 1st, 2nd, or up to 3rd stages, and guide rails are formed in a vertical partition structure on both sides of the screen part of the inclined vibrating screen main body, and the upper surface A discharge part 130 is formed on one side of the lower part, a vibration generating part 140 is formed on one side of the side, and a head-type multi-channel winch part 210 is formed on the upper head part of the inclined vibrating screen main body. , the head-type multi-channel winch is formed so that the wire can be wound around the straight horizontal structure by pulling or releasing the multi-channel wave dance type vibration rattle part 230 to go down, and the twin shaft is prevented from falling off on one side of the guide rail. A type guide rail portion 240 is formed and configured.

In addition, a shelter portion 150 for mounting the multi-channel wave dance type vibration rattle module is formed on one outer side of the upper head portion.

Here, the rest area 150 is a resting space where the multi-channel wave dance type vibration module is mounted, and guides the inclined vibrating screen to be input to the screen network where retinal force is severe, and when there is no retinal force phenomenon, the multi-channel wave dance type vibrating module is placed to rest. The vibrating module is mounted and induced to rest. When retinal force phenomenon occurs, the winch wire is released through the head-type multi-channel winch unit, and the wires of the head-type wire reel unit are released, and the retinal force is generated by gravity on the screen. It guides the insertion of a multi-channel wave dance type vibration rattling module into the network.

In addition, as shown in FIGS. 13 and 21, the guide inlet 240a of the twin-axis anti-dropping guide rail portion 240 is installed so that the multi-channel wave dance type vibrating rattle portion can easily enter the inclined vibrating screen main body. It has an open structure, so that the multi-channel wave dance-type vibration rattle part 230 rides on the twin-axis drop-prevention type guide rail part and moves along the twin-axis drop-prevention type guide rail part without being separated to the outside.

The construction waste input unit 110 is located on one side of the upper front end of the inclined vibrating screen main body and serves to receive construction waste or earth and sand containing foreign substances such as vinyl or wood chips and transfer them to the screen unit.

This injects construction waste or soil containing foreign substances such as plastic or wood chips.

The screen unit 120 receives the force of vibration generated from the vibration generator of the inclined vibrating screen, and spreads the construction waste containing foreign substances such as vinyl or wood chips introduced through the force of vibration and the inclined structure to remove particles. It serves to sort by size.

This is configured by selecting one of a single network screen, a double network screen, and a triple screen.

And, a tilt screen with a tilt angle of 14 degrees to 30 degrees is selected and configured.

The eye size of the screen net installed in the screen unit varies depending on the particle size to be sorted, but is formed in various eye sizes ranging from a minimum of 5 mm to a maximum of 50 mm.

The discharge unit 130 is located on one side of the lower part of the screen, and serves to discharge the particles that fall after being sorted by particle size through a belt structure that transports each particle.

It falls freely and is discharged through the force of gravity and vibration.

The vibration generator 140 is formed on one side of the vibrating screen main body and serves to generate a vibration force in the vibrating screen main body.

As shown in FIG. 4, it consists of an eccentric weight 141 and a motor 142.

The eccentric weight 141 receives the force of vibration generated by the motor and rotates, generating a vibration force in the vibrating screen body according to the weight of the eccentric weight.

The motor 142 generates rotational force and transmits it to the eccentric weight to rotate the eccentric weight.

Next, the multi-channel wave dance type vibration rattle module 200 according to the present invention will be described.

The multi-channel wave dance vibration vibration module 200 is installed on the outside of the inclined vibrating screen main body while being supported by a winch wire, and waves dance while shaking with the force of vibration, and touches the retina of the screen network with vibration force and striking force. It plays a role in improving force phenomena.

As shown in FIGS. 5 and 6, this includes a head-type multi-channel winch unit 210, a head-type wire reel unit 220, a multi-channel wave dance type vibration ratter unit 230, and a twin-axis drop-off prevention type guide. It consists of a rail part (240).

First, the head-type multi-channel winch unit 210 according to the present invention will be described.

The head-type multi-channel winch unit 210 is located in an area where vibration of the vibrating screen main body is not transmitted, and winds and unwinds the winch wire to move the multi-channel wave dance type vibration rattle back and forth to the screen part of the vibrating screen main body. It plays a role.

As shown in Figures 7 and 8, the main winch drive motor 211, the rotating shaft 212, the first winch roll part 213, the second winch roll part 214, the third winch roll part 215, It consists of a fourth winch roll unit (216).

The main winch driving motor 211 is located on one side of the rotating shaft and serves to generate rotational force and transmit it to the rotating shaft.

The rotating shaft rod 212 is formed in a straight horizontal structure in a place where the vibration of the inclined vibrating screen main body is not transmitted, and penetrates the central axis of the first winch roll part, the second winch roll part, the third winch roll part, and the fourth winch roll part. As it passes, it receives rotational force from the main winch drive motor and serves to rotate the first winch roll part, the second winch roll part, the third winch roll part, and the fourth winch roll part at the same time.

The first winch roll unit 213 is located close to the main winch drive motor when viewed from a plane, receives rotational force from the rotary shaft, and is connected to the first wave dance type vibration rattle of the multi-channel wave dance type vibration rattle unit. It serves to wind or unwind the wire.

Here, the winch wire is connected to the first wave dance type vibration rattle of the multi-channel wave dance type vibration rattle part.

In addition, the first winch roll part causes the first wave dancing vibration part of the multi-channel wave dancing vibration part to move back and forth across the screen network of the vibrating screen main body, and then moves back and forth between the multi-channel wave dancing type vibration shaking parts at a place where the vibration of the vibrating screen is not transmitted. It serves to move the first wave of the dance-type vibration rattle towards the rest area, which is a resting space located outside the upper head part.

The second winch roll unit 214 is located on one side of the first winch roll unit when viewed from a plane, receives rotational force from the rotating shaft, and connects the winch wire connected to the second wave dancing vibration rattle of the multi-channel wave dancing vibration rattling unit. It has the role of winding or unwinding.

Here, the winch wire is connected to the second wave dance type vibration rattle of the multi-channel wave dance type vibration rattle part.

And, in the second winch roll unit, the second wave dancing type vibration rattle of the multi-channel wave dancing type vibrating rattling unit moves back and forth across the screen network, which is the screen part of the vibrating screen main body, and then moves back and forth between the multi-channel wave dancing type vibrating rattling unit at a place where the vibration of the vibrating screen is not transmitted. It serves to move the second wave dance-type vibrating rattle toward the rest area, which is a resting space located on the outside of the upper head.

The third winch roll unit 215 is located on one side of the third winch roll unit when viewed from a plane, receives rotational force from the rotating shaft, and connects the winch wire connected to the third wave dancing vibration rattle of the multi-channel wave dancing vibrating rattle unit. It has the role of winding or unwinding.

Here, the winch wire is connected to the third wave dancing vibration rattle of the multi-channel wave dancing vibration rattling part.

And, in the third winch roll unit, the third wave dancing vibration rattling part of the multi-channel wave dancing type vibrating rattling unit moves back and forth across the screen network, which is the screen part of the vibrating screen main body, and then moves to a place where the vibration of the vibrating screen is not transmitted. It serves to move the third wave dance-type vibrating rattle toward the rest area, which is a resting space located on the outside of the upper head.

The fourth winch roll unit 216 is located on one side of the fourth winch roll unit when viewed on a plane, receives rotational force from the rotating shaft, and connects the winch wire connected to the fourth wave dancing vibration rattle of the multi-channel wave dancing vibration rattling unit. It plays a role in winding or unwinding.

Here, the winch wire is connected to the fourth wave dance type vibration rattle of the multi-channel wave dance type vibration rattle part.

And, in the fourth winch roll unit, the fourth wave dancing vibration rattling part of the multi-channel wave dancing type vibrating rattling unit moves back and forth through the screen network, which is the screen part of the vibrating screen main body, and then moves to a place where the vibration of the vibrating screen is not transmitted. It serves to move the 4th wave dance-type vibrating rattle toward the rest area, which is a resting space located on the outside of the upper head.

Second, the head-type wire reel unit 220 according to the present invention will be described.

The head-type wire reel unit 220 is located on one side of the upper part of the head-type multi-channel winch, and serves to supply electricity to the multi-channel wave dance type vibrating rattle while winding and unwinding the wire.

As shown in FIG. 9, it is composed of a first wire reel 221, a second wire reel 222, a third wire reel 223, and a fourth wire reel 224.

[1st wire reel (221)]

The first wire reel 221 is located on one side of the upper part of the first winch roll unit, and winds and unwinds the wire connected to the first wave dance-type vibration rattle of the multi-channel wave dance-type vibration rattle while guiding the multi-channel wave dance-type vibrating rattle part. It plays a role in supplying electricity to the first wave dance type vibration.

As shown in FIG. 9, it is composed of a first wire reel body 221a and a first wire 221b.

The first wire reel body 221a is formed in a rotatable cylindrical drum structure, and serves to flexibly support the first electric wire by winding and unwinding it while guiding the first electric wire wound along the edge of the body.

This is configured by selecting either a manual handle rotation type or an automatic motor rotation type.

In addition, the release is of a semi-automatic type that is released by the pulling force when the rattle is lowered by gravity, and is wound like a clockwork when wound.

The first wire 221b is wound around the first wire reel body, and is wound and unwound according to the rotation of the first wire reel body, and serves to supply electricity to the first wave dance type vibration rattle of the multi-channel wave dance type vibration rattle part. .

It is composed of a copper wire wire formed inside a protective cable.

Here, supplying electricity to the first wave-dancing vibration side of the multi-channel wave dancing-type vibrating rattle while maintaining the position of the first wave-dancing vibrating rattle of the multi-channel wave dancing-type vibrating rattle is more specifically explained. A first electric wire is connected to the first double-arm motor section of the vibrating rattle, and while supplying electricity to the first double-arm motor section, the position of the first double-arm motor section is not distorted and the adjacent second double-arm motor section and This means positioning it so that it is in the same position.

In order to prevent the first wire connected to the first double-arm motor unit from being broken due to external pressure, a joint cap connector surrounding the first wire is formed as an auxiliary means.

[2nd wire reel (222)]

The second wire reel 222 is located on one side of the upper part of the second winch roll unit, and winds and unwinds and guides the wire connected to the second wave dance-type vibration rattle of the multi-channel wave dance-type vibration rattle part. It plays a role in supplying electricity to the second wave dance-type vibration.

As shown in FIG. 9, it is composed of a second wire reel body 222a and a second wire 222b.

The second wire reel body 222a is formed in a rotatable cylindrical drum structure, and serves to flexibly support the second electric wire by winding and unwinding it while guiding the second electric wire wound along the edge of the body.

This is configured by selecting either a manual handle rotation type or an automatic motor rotation type.

In addition, the release is of a semi-automatic type that is released by the pulling force when the rattle is lowered by gravity, and is wound like a clockwork when wound.

The second wire 222b is wound around the second wire reel body and is wound and unwound as the second wire reel body rotates, serving to supply electricity to the second wave dance type vibration rattle of the multi-channel wave dance type vibration rattle part. .

It is composed of a copper wire wire formed inside a protective cable.

Here, supplying electricity to the second wave dancing vibration side of the multi-channel wave dancing vibration vibration section and maintaining the position of the second wave dancing vibration vibration section of the multi-channel wave dancing vibration vibration section is more specifically explained. A second electric wire is connected to the second double-arm motor section of the vibrating rattle, and while supplying electricity to the second double-arm motor section, the position of the second double-arm motor section is not distorted and the adjacent second double-arm motor section This means positioning it so that it is in the same position.

In order to prevent the second wire connected to the second double-arm motor unit from being broken due to external pressure, a joint cap connector surrounding the second wire is formed as an auxiliary means.

[3rd wire reel (223)]

The third wire reel 223 is located on one side of the upper part of the third winch roll unit, and winds and unwinds the electric wire connected to the third wave dance-type vibration rattle of the multi-channel wave dance-type vibrating rattle part, and guides the wire connected to the multi-channel wave dancing-type vibrating rattle part. It plays a role in supplying electricity to the third wave dance type vibration.

As shown in FIG. 9, it is composed of a third wire reel body 223a and a third wire 223b.

The third wire reel body 223a is formed in a rotatable cylindrical drum structure, and serves to flexibly support the third electric wire by winding and unwinding it while guiding the third electric wire wound along the edge of the body.

This is configured by selecting either a manual handle rotation type or an automatic motor rotation type.

In addition, the release is of a semi-automatic type that is released by the pulling force when the rattle is lowered by gravity, and is wound like a clockwork when wound.

The third wire 223b is wound around the third wire reel body, and is wound and unwound according to the rotation of the third wire reel body, and serves to supply electricity to the third wave dance type vibration rattle of the multi-channel wave dance type vibration rattle part. .

It is composed of a copper wire wire formed inside a protective cable.

Here, supplying electricity to the third wave dancing vibration side of the multi-channel wave dancing vibration vibration section and fixing the position of the third wave dancing vibration vibration section of the multi-channel wave dancing vibration vibration section is more specifically explained. A third electric wire is connected to the third double-arm motor section of the vibrating rattle, supplying electricity to the third double-arm motor section, without distorting the position of the third double-arm motor section, and connecting the third double-arm motor section to the neighboring third double-arm motor section. This means positioning it so that it is in the same position.

In order to prevent the third wire connected to the third double-arm motor unit from breaking due to external pressure, a joint cap connector surrounding the third wire is formed as an auxiliary means.

[4th wire reel (224)]

The fourth wire reel 224 is located on one side of the upper part of the fourth winch roll unit, and winds and unwinds the wire connected to the fourth wave dance-type vibration rattle of the multi-channel wave dance-type vibrating rattle while guiding the multi-channel wave dancing-type vibrating rattle part. It plays a role in supplying electricity to the 4th wave dance-type vibration.

As shown in FIG. 9, it is composed of a fourth wire reel body 224a and a fourth wire 224b.

The fourth electric wire reel body 224a is formed in a rotatable cylindrical drum structure, and serves to flexibly support the fourth electric wire by winding and unwinding it while guiding the fourth electric wire wound along the edge of the body.

This is configured by selecting either a manual handle rotation type or an automatic motor rotation type.

In addition, the release is of a semi-automatic type that is released by the pulling force when the rattle is lowered by gravity, and is wound like a clockwork when wound.

The fourth wire 224b is wound around the fourth wire reel body, and is wound and unwound according to the rotation of the fourth wire reel body, and serves to supply electricity to the fourth wave dance type vibration rattle of the multi-channel wave dance type vibration rattle part. .

It is composed of a copper wire wire formed inside a protective cable.

Here, supplying electricity to the fourth wave dancing vibration side of the multi-channel wave dancing vibration vibration section and fixing the position of the fourth wave dancing vibration vibration section of the multi-channel wave dancing vibration vibration section is more specifically explained. A fourth electric wire is connected to the fourth double-arm motor section of the vibrating rattle, supplying electricity to the fourth double-arm motor section, without distorting the position of the fourth double-arm motor section, and connecting the fourth double-arm motor section to the neighboring fourth double-arm motor section. This means positioning it so that it is in the same position.

In order to prevent the fourth wire connected to the fourth double-arm motor unit from breaking due to external pressure, a joint cap connector surrounding the fourth wire is formed as an auxiliary means.

Third, the multi-channel wave dance type vibration rattle unit 230 according to the present invention will be described.

The multi-channel wave dance type vibrating part 230 is supported by a winch wire formed on a head-type multi-channel winch part and is located at any one of the screen top, middle, and bottom of the inclined vibrating screen main body, It is formed as a straight horizontal structure, and while shaking and dancing with the power of vibration, it shakes off foreign substances clogged in the screen network with the force of vibration and striking force, causing them to penetrate the screen network and fall.

As shown in Figures 10 and 11, the left guide wing part 231, the first wave dance type vibration rattle (232), the first elastic spring type bridge part 233, and the second wave dance type vibration rattle (234) , second elastic spring type bridge part (235), third wave dancing type vibration rattle (236), third elastic spring type bridge part (237), fourth wave dancing type vibrating rattle (238), light guide wing part (239) It consists of

[Left guide wing part (231)]

The left guide wing portion 231 is " "It is formed with a shaped wing structure, and is in contact with one side of the left part of the twin axis drop-prevention guide rail part, and is formed into a straight horizontal structure. The first wave dance type vibration rattle, the second wave dance type vibration rattle, and the third wave dance type vibration It serves as a guide to move the 4th wave dance type vibration rattle to any selected position among the top, middle, or bottom of the screen of the inclined vibrating screen main body, and at the same time, the 1st wave dance type vibration rattle and the 2nd wave dance type vibration rattle , It serves to prevent the 3rd wave dance type vibration rattle and the 4th wave dance type vibration rattle from being twisted or separated from the screen network.

As shown in Figure 12, this is made of a steel plate or SUS plate material with a thickness of 5mm to 15mm. It is formed as a wing structure in the shape of a wing, and half of the center line is formed by a first wave dance type vibration rattle and a combination of screws and bolts, and when viewed from the top view, the left twin axis of the twin axis drop-prevention guide rail part It is formed by contact with a rod-shaped guide rail and a rod-shaped rolling roller in the longitudinal direction of the twin axis.

In addition, depending on the purpose and form of use, an elastic spring is included in order to allow the left guide wing and the first wave dance-type vibration rattle to move elastically when coupled with screws and bolts.

The left guide wing is " "As it is formed as a wing structure in the shape, as shown in Figure 12, it is in rolling contact with the twin-axis drop-off prevention type guide rail part and is in contact with the twin-axis drop-off prevention type guide rail part." "The shaped part is located on the twin axis drop-prevention guide rail, so it can be held in place to prevent it from falling out.

[1st wave dancing vibration rattle (232)]

When viewed from a plan view, the first wave dance type vibration rattle 232 is supported by the winch wire formed in the first winch roll part of the head-type multi-channel winch and is located on the first line on the left of the entire straight horizontal structure. , It transmits the vibration force as it comes in contact with the surface of the screen net through a wave dance that trembles with the force of vibration, and plays the role of eliminating the retinal force phenomenon of the screen net through the vibration force and hitting force.

As shown in Figures 14 and 15, the first double-arm motor part 232a, the first motor plate part 232b, the first weight control steel plate part 232c, and the first screen net contact plate It consists of a portion 232d and a first screen network contact portion 232e.

The first two-arm motor unit 232a is located at the center of the upper surface of the first weight control steel plate unit and serves to generate vibration of both arms.

As shown in FIG. 17, the first rotor shaft 232a-1, the first induction coil 232a-2, the first base cover 232a-3, the first twin balance weight 232a-4, It consists of a first side cover (232a-5).

The first rotor shaft 232a-1 serves to rotate the first twin balance weight by receiving rotational force due to electromagnetic induction generated from the first induction coil.

The first induction coil 232a-2 serves to generate rotational force by electromagnetic induction.

The first base cover 232a-3 passes through the first rotor shaft from left to right, includes a first induction coil, and serves to protect and support each device from external pressure.

The first twin balance weights 232a-4 are formed on one left side and one right side of the first rotor shaft, respectively, and serve to generate vibration by converting the centrifugal force generated by rotating the first rotor shaft into vibration. . This is configured to form two (=twin) balance weights by eccentrically combining one balance weight on one left side and one right side of the first rotor shaft. As a result, vibration is generated in one balance weight formed on the left side of the first rotor shaft, and vibration is generated in another balance weight formed on the right side of the first rotor shaft, so that the first weight adjustment steel plate portion It generates the power of twin vibrations towards.

The first side cover 232a-5 serves to protect and support the first twin balance weight by preventing foreign substances from entering the first twin balance weight.

In this way, the first double-arm motor unit is composed of the first rotor shaft, the first induction coil, the first base cover, the first twin balance weight, and the first side cover, thereby generating vibration of both arms and reducing the force of vibration of both arms. 1 It is passed through the motor plate part and the first weight control steel plate part to the first screen network contact plate part.

The first double-arm motor unit 232a is connected to one side of the first electric wire formed on the first electric wire reel of the head-type electric wire reel part, and is driven by receiving electricity applied through the first electric wire.

And, through the first wire, the position of the first double-arm motor unit is maintained to prevent the phenomenon of floating in the air, and through the first wire wound on the first wire reel, the multi-channel including the first double-arm motor unit The first wave dance type vibration rattle of the wave dance type vibration rattle part is moved toward the rest part.

That is, as the winch wire is wound through the first winch roll portion of the head-type multi-channel winch formed on the winch wire connected to the plate portion for the first motor of the first wave dancing vibration rattle, the first wave dancing vibrating rattle The plate portion for the first motor is first moved toward the rest portion, and then secondarily moved toward the rest portion through the first wire wound on the first wire reel.

On the contrary, the plate for the first motor of the first wave dance type vibrator is used to transfer the vibration force while contacting the surface of the screen network with a wave dance shaking with the force of vibration and to eliminate the retinal force phenomenon of the screen network through the vibration force and hitting force. Through the first winch roll part of the head-type multi-channel winch formed on the winch wire connected to the side, the winch wire is unwound, and the plate part for the first motor of the first wave dance type vibrating rattle is primarily connected to the retinal force part of the screen net. It is moved towards, and secondarily moved towards the retinal force portion of the screen network through the first wire released from the first wire reel.

The first motor plate portion 232b supports the lower part of the first double-arm motor portion and serves to receive the force of vibration of both arms generated from the first double-arm motor portion and transfer it to the first weight control steel plate portion. Do it.

Here, the first motor plate portion supports the first double-arm motor portion in a plate structure, and receives the force of vibration of both arms through the plate structure and transmits it to the first weight control steel plate portion, so that the first weight control steel plate portion It forms a trembling wave dance on the side.

That is, when viewed from the front view direction, the first motor plate portion is made of a rectangular plate structure, and the force of the vibration of both arms is transmitted and converted into a wave dance pattern that trembles on the first weight control steel plate portion.

In addition, the first motor plate portion 232b is connected to the winch wire formed in the first winch roll portion of the head-type multi-channel winch portion on one side of the front facing the head-type multi-channel winch portion, and is supported. A first winch wire connection is formed and configured.

Here, the first winch wire connection serves to prevent the phenomenon of floating in the air due to the force of vibration of both arms and to position the plate for the first motor so that it is in the correct position through the winch wire.

The first weight control steel plate portion 232c is located between the first motor plate portion and the first screen net contact plate portion, forms a rectangular plate structure, and has a weight of 1Kg to 15Kg, so that the first It receives the force of the vibration of both arms transmitted from the motor plate part to form a trembling wave dance, and then transmits the trembling wave dance to the first screen network contact plate part.

As shown in Figure 15, it is formed as a rectangular plate structure weighing 1Kg to 15Kg, is located between the first motor plate portion and the first screen network contact plate portion, and is connected with screws and bolts. do.

Here, the first weight control steel plate portion is formed in a rectangular plate structure with a weight of 1Kg to 15Kg, so that the force of vibration of both arms is transmitted from the first motor plate portion, and the weight is light so that it does not float in the air and weighs between 1Kg and 15Kg. A trembling wave dance can be formed through a rectangular plate structure weighing 15kg.

The first screen net contact plate part 232d is formed on the lower surface of the first weight control steel plate plate part, receives the shaking wave dance generated by the first weight control steel plate plate part, and transmits it to the first screen net contact part. It plays a role.

It is connected to the first screen network contact part by fastening screws and bolts on one side of the bottom surface, or is connected to the first screen network contact part by soldering and welding.

The first screen net contact portion 232e is located on the lower surface of the first screen net contact plate portion, and while in contact with the screen net surface, transmits vibration force toward the screen net surface, thereby generating the retinal force of the screen net through the vibration force and hitting force. It serves to eliminate the phenomenon.

This is configured by selecting one of the first screen network contact type wheel module (232e-1) and the first screen network contact type protrusion module (232e-2).

As shown in FIG. 14, the first screen net contact type wheel module 232e-1 is in rolling contact with the screen net surface and transmits vibration force toward the screen net surface, thereby generating the retinal force of the screen net through vibration force and striking force. It acts as a wheel to move back and forth on the surface of the screen net while removing the phenomenon.

It consists of a rolling wheel or a ball wheel.

As shown in FIG. 16, the first screen net contact type protrusion module 232e-2 is in contact with the screen net surface and the wedge-shaped protrusion, and transmits vibration force toward the screen net surface, thereby damaging the screen net through vibration force and striking force. It performs the role of sliding along the surface of the screen mesh through its inclined structure, eliminating the retinal force phenomenon.

It is made of iron or plastic material and is formed as a wedge-shaped protrusion structure that protrudes in a circular shape toward the bottom, and the gap between neighboring wedge-shaped protrusion structures is formed at intervals of 5 mm to a maximum of 50 mm to match the mesh size of the screen net surface. .

[First elastic spring type bridge part (233)]

The first elastic spring type bridge unit 233 is located between the first wave dancing type vibration rattle and the second wave dancing type vibration rattle, and the first wave dancing type vibration rattle and the second wave dancing type vibration are provided through the twin bridge-shaped elastic spring. It is formed as a bridge structure that connects the rattles, and serves to form a straight horizontal structure without distorting the connection between the first wave and the second wave dance type vibrating rattles due to the force of vibration.

As shown in FIG. 18, it is composed of a 1st left elastic spring coupling portion 233a, a first bridge plate 233b, and a 1b right elastic spring coupling portion 233c.

The 1a left elastic spring coupling portion 233a is coupled to one side of the first wave dance-type vibration rattle, cushioning the force of vibration generated from the first wave dance-type vibration rattle with an elastic spring, and rotating the first bridge plate. It plays a supporting role from the side.

It consists of screws, bolts, elastic springs, and vertical coupling pins.

The first bridge plate (233b) is located between the 1a left elastic spring coupling portion and the 1b right elastic spring coupling portion, and serves as a bridge connecting the first wave dance type vibration rattle and the second wave dance type vibration rattle.

The 1b light elastic spring coupling portion 233c is coupled to one side of the second wave dancing vibration rattle, and cushions the force of vibration generated from the second wave dancing vibration rattle with an elastic spring, while riding the first bridge plate. It plays a supporting role from the side.

It consists of screws, bolts, elastic springs, and vertical coupling pins.

[2nd wave dance type vibration rattle (234)]

When viewed from a plan view, the second wave dancing vibration rattle 234 is supported by the winch wire formed in the second winch roll part of the head-type multi-channel winch and is located on the first line on the left of the entire straight horizontal structure. , It transmits the vibration force as it comes in contact with the surface of the screen net through a wave dance that trembles with the force of vibration, and plays the role of eliminating the retinal force phenomenon of the screen net through the vibration force and hitting force.

As shown in Figures 14 and 15, the second double-arm motor part 234a, the second motor plate part 234b, the second weight control steel plate part 234c, and the second screen network contact plate It consists of a portion 234d and a second screen network contact portion 234e.

The second double-arm motor unit 234a is located at the center of the upper surface of the second weight control steel plate portion and serves to generate vibration of both arms.

As shown in FIG. 17, the second rotor shaft 234a-1, the second induction coil 234a-2, the second base cover 234a-3, the second twin balance weight 234a-4, It consists of a second side cover (234a-5).

The second rotor shaft 234a-1 serves to rotate the second twin balance weight by receiving rotational force due to electromagnetic induction generated from the second induction coil.

The second induction coil 234a-2 serves to generate rotational force by electromagnetic induction.

The second base cover 234a-3 passes through the rotor shaft from left to right, includes a second induction coil, and serves to protect and support each device from external pressure.

The second twin balance weights 234a-4 are formed on one left side and one right side of the second rotor shaft, respectively, and serve to generate vibration by converting the centrifugal force generated by rotating the second rotor shaft into vibration. . This is configured to form two (=twin) balance weights by eccentrically combining one balance weight on one left side and one right side of the second rotor shaft. As a result, vibration is generated in one balance weight formed on the left side of the second rotor shaft, and vibration is generated in another balance weight formed on the right side of the second rotor shaft, so that the second weight adjustment steel plate portion It generates the power of twin vibrations towards.

The second side cover 234a-5 serves to protect and support the second twin balance weight by preventing foreign substances from flowing into the second twin balance weight.

In this way, the second double-arm motor unit is composed of the second rotor shaft, the second induction coil, the second base cover, the second twin balance weight, and the second side cover, thereby generating vibration of both arms and reducing the force of vibration of both arms. 2 It is passed through the motor plate part and the second weight control steel plate part to the second screen network contact plate part.

The second double-arm motor unit 234a is connected to one side of the second electric wire formed on the second electric wire reel of the head-shaped electric wire reel part, and is driven by receiving electricity applied through the second electric wire.

And, through the second wire, the position of the second arm-type motor unit is maintained to prevent the phenomenon of floating in the air, and through the second wire wound on the second wire reel, the multi-channel including the second arm-type motor unit is connected. The second wave dance type vibration rattle of the wave dance type vibration rattle unit is moved toward the rest area.

That is, as the winch wire is wound through the second winch roll portion of the head-type multi-channel winch formed on the winch wire connected to the plate portion for the second motor of the second wave dancing vibration rattle, the second wave dancing vibrating rattle The plate portion for the second motor is first moved toward the rest portion, and then secondarily moved toward the rest portion through the second electric wire wound on the second wire reel.

On the contrary, the second motor plate of the second wave dance type vibrator is used to transmit the vibration force while contacting the surface of the screen network through a wave dance shaking with the force of vibration and to eliminate the retinal force phenomenon of the screen network through the vibration force and hitting force. Through the second winch roll part of the head-type multi-channel winch formed on the winch wire connected to the side, the winch wire is released, and the plate part for the second motor of the second wave dance type vibrating rattle is primarily connected to the retinal force part of the screen net. It moves towards the retinal force area of the screen net in a second way through the second wire released from the second wire reel.

The second motor plate portion 234b supports the lower part of the second double-arm motor portion, and receives the force of vibration of both arms generated from the second double-arm motor portion and transmits it to the second weight control steel plate portion. Do it.

Here, the second motor plate portion supports the second double-arm motor portion in a plate structure, and receives the force of vibration of both arms through the plate structure and transmits it to the second weight control steel plate portion, so that the second weight control steel plate portion It forms a trembling wave dance on the side.

That is, when viewed from the front view direction, the second motor plate part is made of a rectangular plate structure, and the force of the vibration of both arms is transmitted and converted into a wave dance pattern that trembles on the second weight control steel plate part.

In addition, the second motor plate portion 234b is connected to the winch wire formed in the second winch roll portion of the head-type multi-channel winch portion on one side of the front facing the head-type multi-channel winch portion, and is supported. A second winch wire connection is formed and configured.

Here, the second winch wire connection prevents the device from floating up into the air due to the force of vibration of both arms, and serves to position the plate for the second motor so that it is properly positioned through the winch wire.

The second weight control steel plate portion 234c is located between the second motor plate portion and the second screen net contact plate portion, forms a rectangular plate structure, and has a weight of 1Kg to 15Kg, so that the second It receives the force of the vibration of both arms transmitted from the motor plate part to form a trembling wave dance, and then transmits the trembling wave dance to the second screen network contact plate part.

As shown in Figure 15, it is formed as a rectangular plate structure weighing 1Kg to 15Kg, is located between the plate for the second motor and the plate for contacting the second screen network, and is connected with screws and bolts. do.

Here, the second weight control steel plate portion is formed in a rectangular plate structure with a weight of 1Kg to 15Kg, so that the force of vibration of both arms is transmitted from the second motor plate portion, and the weight is light so that it does not float in the air and weighs between 1Kg and 15Kg. A trembling wave dance can be formed through a rectangular plate structure weighing 15kg.

The second screen net contact plate part 234d is formed on the lower surface of the second weight control steel plate plate part, receives the shaking wave dance generated by the second weight control steel plate part, and transmits it to the second screen net contact part. It plays a role.

It is connected to the second screen network contact part by fastening screws and bolts on one side of the bottom surface, or is connected to the second screen network contact part by soldering and welding.

The second screen net contact portion 234e is located on the lower surface of the second screen net contact plate portion, and while in contact with the screen net surface, transmits vibration force toward the screen net surface, thereby generating the retinal force of the screen net through the vibration force and hitting force. It serves to eliminate the phenomenon.

This is configured by selecting one of the second screen network contact type wheel module (234e-1) and the second screen network contact type protrusion module (234e-2).

As shown in FIG. 14, the second screen net contact type wheel module 234e-1 is in rolling contact with the screen net surface and transmits vibration force toward the screen net surface, thereby generating the retinal force of the screen net through vibration force and striking force. It acts as a wheel to move back and forth on the surface of the screen net while removing the phenomenon.

It consists of a rolling wheel or a ball wheel.

As shown in FIG. 16, the second screen net contact type protrusion module 234e-2 is in contact with the screen net surface and the wedge-shaped protrusion, and transmits vibration force toward the screen net surface, thereby damaging the screen net through vibration force and striking force. It performs the role of sliding along the surface of the screen mesh through its inclined structure, eliminating the retinal force phenomenon.

It is made of iron or plastic material and is formed as a wedge-shaped protrusion structure that protrudes in a circular shape toward the bottom, and the gap between neighboring wedge-shaped protrusion structures is formed at intervals of 5 mm to a maximum of 50 mm to match the mesh size of the screen net surface. .

[Second elastic spring type bridge part (235)]

The second elastic spring-type bridge unit 235 is located between the second wave dancing vibration rattle and the third wave dancing vibration rattle, and the second wave dancing vibration rattle and the third wave dancing vibration vibration are provided through the twin bridge-shaped elastic spring. It is formed as a bridge structure that connects the rattles, and serves to form a straight horizontal structure without distorting the connection between the second wave dance-type vibration rattle and the third wave dance-type vibration rattle due to the force of vibration.

As shown in FIG. 18, it is composed of a 2a left elastic spring coupling portion 235a, a second bridge plate 235b, and a 2b right elastic spring coupling portion 235c.

The 2a left elastic spring coupling portion 235a is coupled to one side of the second wave dancing vibration rattle, and cushions the force of vibration generated from the second wave dancing vibration rattle with an elastic spring, and operates the second bridge plate. It plays a supporting role from the side.

It consists of screws, bolts, elastic springs, and vertical coupling pins.

The second bridge plate 235b is located between the 2a left elastic spring coupling portion and the 2b right elastic spring coupling portion, and serves as a bridge connecting the second wave dance type vibration rattle and the third wave dance type vibration rattle.

The 2b light elastic spring coupling portion 235c is coupled to one side of the third wave dancing vibration rattle, and cushions the force of vibration generated from the third wave dancing vibration rattle with an elastic spring, while riding the second bridge plate. It plays a supporting role from the side.

It consists of screws, bolts, elastic springs, and vertical coupling pins.

[3rd wave dance type vibration rattle (236)]

When viewed from a plan view, the third wave dancing vibration rattle 236 is supported by the winch wire formed in the third winch roll part of the head-type multi-channel winch and is located on the first line on the left of the entire straight horizontal structure. , It transmits the vibration force as it comes in contact with the surface of the screen net through a wave dance that trembles with the force of vibration, and plays the role of eliminating the retinal force phenomenon of the screen net through the vibration force and hitting force.

As shown in Figures 14 and 15, the third double-arm motor part 236a, the third motor plate part 236b, the third weight control steel plate part 236c, and the third screen net contact plate It consists of a portion 236d and a third screen network contact portion 236e.

The third two-arm motor unit 236a is located at the center of the upper surface of the third weight control steel plate unit and serves to generate vibration of both arms.

As shown in FIG. 17, the third rotor shaft 236a-1, the third induction coil 236a-2, the third base cover 236a-3, the third twin balance weight 236a-4, It consists of a third side cover (236a-5).

The third rotor shaft 236a-1 serves to rotate the third twin balance weight by receiving rotational force due to electromagnetic induction generated from the third induction coil.

The third induction coil 236a-2 serves to generate rotational force by electromagnetic induction.

The third base cover 236a-3 passes through the rotor shaft from left to right, includes a third induction coil, and serves to protect and support each device from external pressure.

The third twin balance weight 236a-4 is formed on one left side and one right side of the third rotor shaft, respectively, and serves to generate vibration by converting the centrifugal force generated by rotating the third rotor shaft into vibration. . This is configured to form two (=twin) balance weights by eccentrically combining one balance weight on one left side and one right side of the third rotor shaft. As a result, vibration is generated in one balance weight formed on the left side of the third rotor shaft, and vibration is generated in another balance weight formed on the right side of the third rotor shaft, and the third weight adjustment steel plate portion It generates the power of twin vibrations towards.

The third side cover 236a-5 covers the third twin balance weight to prevent foreign substances from flowing into it, thereby protecting and supporting it from external pressure.

In this way, the third double-arm motor unit is composed of the third rotor shaft, the third induction coil, the third base cover, the third twin balance weight, and the third side cover, thereby generating vibration of both arms and controlling the force of vibration of both arms. 3 It is passed through the motor plate part and the third weight control steel plate part to the third screen network contact plate part.

The third arm-type motor unit 236a is connected to one side of the third electric wire formed on the third electric wire reel of the head-type electric wire reel part, and is driven by receiving electricity applied through the third electric wire.

And, through the third wire, the position of the third double-arm motor unit is maintained to prevent the phenomenon of floating in the air, and through the third wire wound on the third wire reel, the multi-channel including the third double-arm motor unit The third wave dance type vibration rattle of the wave dance type vibration rattle unit is moved toward the rest area.

That is, as the winch wire is wound through the third winch roll portion of the head-type multi-channel winch formed on the winch wire connected to the plate portion for the third motor of the third wave dancing vibration rattle, the third wave dancing vibrating rattle The plate portion for the third motor is first moved toward the rest portion, and then secondarily moved toward the rest portion through the third electric wire wound on the third wire reel.

On the contrary, the third motor plate of the third wave dance type vibrator is used to transfer the vibration force by contacting the surface of the screen network with a wave dance shaking with the force of vibration and to eliminate the retinal force phenomenon of the screen network through the vibration force and hitting force. Through the third winch roll part of the head-type multi-channel winch formed on the winch wire connected to the side, the winch wire is released, and the plate part for the third motor of the third wave dance type vibrating rattle is primarily connected to the retinal force part of the screen net. It moves towards the retinal force area of the screen net in the second direction through the third wire released from the third wire reel.

The third motor plate portion 236b supports the lower part of the third double-arm motor portion and serves to receive the force of vibration of both arms generated from the third double-arm motor portion and transfer it to the third weight control steel plate portion. Do it.

Here, the third motor plate portion supports the third double-arm motor portion in a plate structure, and receives the force of vibration of both arms through the plate structure and transmits it to the third weight control steel plate portion, so that the third weight control steel plate portion It forms a trembling wave dance on the side.

That is, when viewed from the front view direction, the third motor plate portion is made of a rectangular plate structure, and the force of the vibration of both arms is transmitted and converted into a wave dance pattern that trembles on the third weight control steel plate portion.

In addition, the third motor plate portion 236b is connected to the winch wire formed in the third winch roll portion of the head-type multi-channel winch portion on one side of the front facing the head-type multi-channel winch portion, and is supported. A third winch wire connection is formed and configured.

Here, the third winch wire connection prevents the device from floating up into the air due to the force of vibration of both arms, and serves to position the third motor plate so that it is properly positioned through the winch wire.

The third weight control steel plate portion 236c is located between the third motor plate portion and the third screen net contact plate portion, forms a rectangular plate structure, and has a weight of 1Kg to 15Kg, so that the third It receives the force of the vibration of both arms transmitted from the motor plate part to form a trembling wave dance, and then transmits the trembling wave dance to the third screen network contact plate part.

As shown in Figure 15, it is formed as a rectangular plate structure weighing 1Kg to 15Kg, is located between the third motor plate portion and the third screen network contact plate portion, and is connected with screws and bolts. do.

Here, the third weight control steel plate part is formed in a rectangular plate structure with a weight of 1Kg to 15Kg, so that the force of vibration of both arms is transmitted from the third motor plate part, and the weight is light so that it does not float in the air and weighs between 1Kg and 15Kg. A trembling wave dance can be formed through a rectangular plate structure weighing 15kg.

The third screen net contact plate part 236d is formed on the lower surface of the third weight control steel plate plate part, receives the shaking wave dance generated by the third weight control steel plate part, and transmits it to the third screen net contact part. It plays a commanding role.

It is connected to the third screen network contact part by fastening screws and bolts on one side of the bottom surface, or is connected to the third screen network contact part by soldering and welding.

The third screen net contact portion 236e is located on the lower surface of the third screen net contact plate portion, and while in contact with the screen net surface, transmits vibration force toward the screen net surface, thereby generating the retinal force of the screen net through the vibration force and hitting force. It serves to eliminate the phenomenon.

This is configured by selecting one of the third screen network contact type wheel module (236e-1) and the third screen network contact type protrusion module (236e-2).

As shown in FIG. 14, the third screen net contact type wheel module 236e-1 is in rolling contact with the screen net surface and transmits vibration force toward the screen net surface, thereby generating the retinal force of the screen net through vibration force and striking force. It acts as a wheel to move back and forth on the surface of the screen net while removing the phenomenon.

It consists of a rolling wheel or a ball wheel.

As shown in FIG. 16, the third screen net contact type protrusion module 236e-2 is in contact with the screen net surface and the wedge-shaped protrusion, and transmits vibration force toward the screen net surface, thereby damaging the screen net through vibration force and striking force. It performs the role of sliding along the surface of the screen mesh through its inclined structure, eliminating the retinal force phenomenon.

It is made of iron or plastic material and is formed as a wedge-shaped protrusion structure that protrudes in a circular shape toward the bottom, and the gap between neighboring wedge-shaped protrusion structures is formed at intervals of 5 mm to a maximum of 50 mm to match the mesh size of the screen net surface. .

[Third elastic spring type bridge part (237)]

The third elastic spring-type bridge unit 237 is located between the third wave dancing vibration rattle and the third wave dancing vibration rattle, and the third wave dancing vibration rattle and the third wave dancing vibration vibration are provided through the twin bridge-shaped elastic spring. It is formed as a bridge structure that connects the rattles, and serves to form a straight horizontal structure without distorting the connection between the third wave dancing rattle and the third wave dancing vibrating rattle due to the force of vibration.

As shown in FIG. 18, it is composed of a 3a left elastic spring coupling portion 237a, a third bridge plate 237b, and a 3b right elastic spring coupling portion 237c.

The 3a left elastic spring coupling portion 237a is coupled to one side of the third wave dancing vibration rattle, and cushions the force of vibration generated from the third wave dancing vibration rattle with an elastic spring, while forming the third bridge plate. It plays a supporting role from the side.

It consists of screws, bolts, elastic springs, and vertical coupling pins.

The third bridge plate 237b is located between the 3a left elastic spring coupling portion and the 3b right elastic spring coupling portion, and serves as a bridge connecting the third wave dance type vibration rattle and the third wave dance type vibration rattle.

The 3b light elastic spring coupling portion 237c is coupled to one side of the third wave dancing vibration rattle, and cushions the force of vibration generated from the third wave dancing vibration rattle with an elastic spring, while riding the third bridge plate. It plays a supporting role from the side.

It consists of screws, bolts, elastic springs, and vertical coupling pins.

[4th wave dance type vibration rattle (238)]

When viewed from a plan view, the fourth wave dancing vibration rattle 238 is supported by the winch wire formed in the fourth winch roll part of the head-type multi-channel winch and is located on the first line on the left of the entire straight horizontal structure. , It transmits the vibration force as it comes in contact with the surface of the screen net through a wave dance that trembles with the force of vibration, and plays the role of eliminating the retinal force phenomenon of the screen net through the vibration force and hitting force.

As shown in Figures 14 and 15, the fourth double-arm motor part (238a), the fourth motor plate part (238b), the fourth weight control steel plate part (238c), and the fourth screen network contact plate It consists of a portion 238d and a fourth screen network contact portion 238e.

The fourth double-arm motor unit 238a is located at the center of the upper surface of the fourth weight control steel plate portion and serves to generate vibration of both arms.

As shown in FIG. 17, the fourth rotor shaft 238a-1, the fourth induction coil 238a-2, the fourth base cover 238a-3, the fourth twin balance weight 238a-4, It consists of a fourth side cover (238a-5).

The fourth rotor shaft 238a-1 serves to rotate the fourth twin balance weight by receiving rotational force due to electromagnetic induction generated from the fourth induction coil.

The fourth induction coil 238a-2 serves to generate rotational force by electromagnetic induction.

The fourth base cover 238a-3 passes through the rotor shaft from left to right, includes a fourth induction coil, and serves to protect and support each device from external pressure.

The fourth twin balance weight 238a-4 is formed on one left side and one right side of the fourth rotor shaft, respectively, and serves to generate vibration by converting the centrifugal force generated by rotating the fourth rotor shaft into vibration. . This is configured to form two (=twin) balance weights by eccentrically combining one balance weight on one left side and one right side of the fourth rotor shaft. As a result, vibration is generated in one balance weight formed on the left side of the fourth rotor shaft, and vibration is generated in another balance weight formed on the right side of the fourth rotor shaft, and the fourth weight adjustment steel plate portion It generates the power of twin vibrations towards.

The fourth side cover 238a-5 covers the fourth twin balance weight to prevent foreign substances from flowing into it, thereby protecting and supporting it from external pressure.

In this way, the fourth double-arm motor unit is composed of the fourth rotor shaft, the fourth induction coil, the fourth base cover, the fourth twin balance weight, and the fourth side cover, thereby generating vibration of both arms and controlling the force of vibration of both arms. 4 It is passed through the motor plate part and the fourth weight control steel plate part to the fourth screen network contact plate part.

The fourth arm-type motor unit 238a is connected to one side of the fourth electric wire formed on the fourth electric wire reel of the head-type electric wire reel part, and is driven by receiving electricity applied through the fourth electric wire.

And, through the fourth wire, the position of the fourth double-arm motor unit is maintained to prevent the phenomenon of floating in the air, and through the fourth wire wound on the fourth wire reel, the multi-channel including the fourth double-arm motor unit is connected. The fourth wave dance type vibration rattle of the wave dance type vibration rattle unit is moved toward the rest area.

That is, as the winch wire is wound through the fourth winch roll portion of the head-type multi-channel winch formed on the winch wire connected to the plate portion for the fourth motor of the fourth wave dancing vibration rattle, the fourth wave dancing vibrating rattle The plate portion for the fourth motor is first moved toward the rest portion, and then secondarily moved toward the rest portion through the fourth wire wound on the fourth wire reel.

On the contrary, the plate for the fourth motor of the fourth wave dance type vibrator is used to transfer the vibration force by contacting the surface of the screen network with a wave dance shaking with the force of vibration and to eliminate the retinal force phenomenon of the screen network through the vibration force and hitting force. Through the 4th winch roll part of the head-type multi-channel winch formed on the winch wire connected to the side, the winch wire is released, and the plate part for the 4th motor of the 4th wave dance type vibrating rattle is primarily connected to the retinal force part of the screen net. It is moved towards the retinal force area of the screen net in the second direction through the fourth wire released from the fourth wire reel.

The fourth motor plate portion 238b supports the lower portion of the fourth double-arm motor portion and serves to receive the force of vibration of both arms generated from the fourth double-arm motor portion and transfer it to the fourth weight control steel plate portion. Do it.

Here, the fourth motor plate part supports the fourth two-arm motor part in a plate structure, and receives the force of vibration of both arms through the plate structure and transmits it to the fourth weight control steel plate part, so that the fourth weight control steel plate part part It forms a trembling wave dance on the side.

That is, when viewed from the front view direction, the fourth motor plate portion is made of a rectangular plate structure, and the force of the vibration of both arms is transmitted and converted into a wave dance pattern that trembles on the fourth weight control steel plate portion.

In addition, the fourth motor plate portion 238b is connected to the winch wire formed in the fourth winch roll portion of the head-type multi-channel winch portion on one side of the front facing the head-type multi-channel winch portion, and is supported. A fourth winch wire connection is formed and configured.

Here, the fourth winch wire connection serves to prevent the phenomenon of floating in the air due to the force of vibration of both arms, and to position the fourth motor plate portion to be in the correct position through the winch wire.

The fourth weight control steel plate portion 238c is located between the fourth motor plate portion and the fourth screen net contact plate portion, forms a rectangular plate structure, and has a weight of 1Kg to 15Kg, so that the fourth It receives the force of the vibration of both arms transmitted from the motor plate part to form a trembling wave dance, and then transmits the trembling wave dance to the fourth screen network contact plate part.

As shown in Figure 15, it is formed as a rectangular plate structure weighing 1Kg to 15Kg, is located between the fourth motor plate portion and the fourth screen network contact plate portion, and is connected with screws and bolts. do.

Here, the fourth weight control steel plate part is formed in a rectangular plate structure with a weight of 1Kg to 15Kg, so that the force of vibration of both arms is transmitted from the fourth motor plate part, and the weight is light so that it does not float in the air and weighs between 1Kg and 15Kg. A trembling wave dance can be formed through a rectangular plate structure weighing 15kg.

The fourth screen net contact plate part 238d is formed on the lower surface of the fourth weight control steel plate plate part, receives the shaking wave dance generated by the fourth weight control steel plate plate part, and transmits it to the fourth screen net contact part. It plays a commanding role.

It is connected to the fourth screen network contact part by fastening screws and bolts on one side of the bottom surface, or is connected to the fourth screen network contact part by soldering and welding.

As shown in FIG. 14, the fourth screen net contact portion 238e is located on the lower surface of the fourth screen net contact plate portion, and while contacting the screen net surface, transmits vibration force toward the screen net surface to generate vibration force. It plays a role in eliminating the retinal force phenomenon of the screen network with excessive striking force.

This is configured by selecting one of the fourth screen network contact type wheel module and the fourth screen network contact type protrusion module.

As shown in FIG. 16, the fourth screen net contact type wheel module is in rolling contact with the screen net surface, transmitting vibration force toward the screen net surface, eliminating the retinal force phenomenon of the screen net through vibration force and striking force, and It functions as a wheel that moves back and forth on the surface of the net.

It consists of a rolling wheel or a ball wheel.

The fourth screen net contact type protrusion module is in contact with the screen net surface and the wedge-shaped protrusion, transmitting vibration force toward the screen net surface, eliminating the retinal force phenomenon of the screen net through vibration force and hitting force, and through an inclined structure, the screen It plays the role of sliding along the surface of the mesh.

It is made of iron or plastic material and is formed as a wedge-shaped protrusion structure that protrudes in a circular shape toward the bottom, and the gap between neighboring wedge-shaped protrusion structures is formed at intervals of 5 mm to a maximum of 50 mm to match the size of the mesh on the surface of the screen mesh. .

[Light guide wings (239)]

The light guide wing portion 239 is " It is formed with a wing structure in the shape of ", and is in contact with one side of the light (right) part of the twin-axis drop-prevention guide rail part, and is formed into a straight horizontal structure. The first wave dance-type vibration rattle, the second wave dance-type vibration rattle, and the third It serves as a guide to move the wave dancing type vibration rattle and the 4th wave dancing type vibration rattle to any selected position among the top, middle, or bottom of the screen of the inclined vibrating screen main body, and at the same time, the 1st wave dancing type vibrating rattle and the 2nd wave It plays a role in preventing the dance-type vibration rattle, third wave dance-type vibration rattle, and fourth wave dance-type vibration rattle from being twisted or separated from the screen network.

As shown in Figure 19, this is made of a steel plate or SUS plate material with a thickness of 5mm to 15mm. It is formed as a wing structure in the shape of ", and based on the center line, half is formed by a fourth wave dance type vibration rattle and a combination of screws and bolts. When viewed from the top view, the light twin axis of the twin axis drop-prevention guide rail part It is formed by contact with a rod-shaped guide rail and a rod-shaped rolling roller in the longitudinal direction of the twin axis.

In addition, depending on the purpose and form of use, an elastic spring is included in order to allow the left guide wing and the fourth wave dance-type vibration rattle to move elastically when coupled with screws and bolts.

Here, the light guide wings are " " As it is formed with a shaped wing structure, it is in contact with the twin-axis drop-prevention type guide rail portion and the rod-shaped rolling contact in the longitudinal direction of the twin shaft, and is in contact with the twin-axis drop-prevention type guide rail portion." "The shaped part is located on the twin axis drop-prevention guide rail, so it can be held in place to prevent it from falling out.

Fourth, the twin-axis fall-off prevention type guide rail part 240 according to the present invention will be described.

The twin-axis fall-off prevention type guide rail unit 240 is formed as a two-axis rod structure with an upright structure on one side of the guide rail formed as a vertical partition structure on both sides of the screen part of the inclined vibrating screen main body, and includes a left guide wing part and , the light guide wings prevent them from moving outward, and play a sliding role so that the inclined vibrating screen body moves back and forth to any selected position among the top, middle, and bottom of the screen.

As shown in FIGS. 12 and 19, it is composed of a left twin-axis rod-shaped guide rail 241 and a right twin-axis rod-shaped guide rail 242.

When viewed from a plan view, the left twin-axis rod-shaped guide rail 241 is located on the left side of the guide rails formed in a vertical partition structure on both sides of the screen part of the inclined vibrating screen main body, and is in contact with the left guide wing part. It is guided as much as possible, and the left guide wing, which is contacted and guided, is held so that it does not escape to the outside, and plays a sliding role to move back and forth to any one of the selected positions among the top, middle, and bottom of the screen of the inclined vibrating screen main body.

As shown in FIG. 12, it is composed of a 1a shaft rod 241a at the top and a 1b rod 241b at the bottom.

When viewed from a plan view, the light twin-axis rod-shaped guide rail 242 is located on the light (right) side among the guide rails formed in a vertical partition structure on both sides of the screen part of the inclined vibrating screen main body, and is in contact with the left guide wing part. It is guided as much as possible, and the light guide wings that are contacted and guided are held so as not to escape to the outside, and play a sliding role to move back and forth to any one of the selected positions among the top, middle, and bottom of the screen of the inclined vibrating screen body.

As shown in FIG. 19, it is composed of a 2a shaft rod 242a at the top and a 2b rod 242b at the bottom.

Hereinafter, the specific process of the screen net foreign matter removal method on the surface of the vibrating screen through the multi-channel wave dancing vibration shaking module according to the present invention will be described.

Figure 23 is a flowchart showing the specific process of the screen net foreign matter removal method on the surface of the vibrating screen through the multi-channel wave dance type vibration shaking module according to the present invention.

First, as shown in Figure 20, in the inclined vibrating screen main body, through the force of vibration and the inclined structure, construction waste or soil containing foreign substances such as vinyl or wood chips are spread out and sorted by particle size ( S10).

Next, after sorting on the inclined vibrating screen main body, when foreign matter accumulates on the screen net and the foreign matter selection rate drops, the head-type multi-channel winch of the multi-channel wave dancing vibration module is driven to pull the winch wire. While releasing, the multi-channel wave dance type vibrating rattle is positioned on the screen net where the retinal force phenomenon of the inclined vibrating screen main body occurs (S20).

That is, as shown in FIG. 21, the guide inlet of the twin-axis drop-prevention type guide rail part is provided so that the multi-channel wave dance type vibration rattle part of the multi-channel wave dance type vibration rattle module can easily enter the inclined vibrating screen main body. It has an open structure, so the multi-channel wave dance-type vibration rattle part rides on the twin-axis drop-prevention type guide rail part and moves along the twin-axis drop-prevention type guide rail part without falling out.

Next, as the head-type multi-channel winch part of the multi-channel wave dancing vibration module is driven, the head-type wire reel part is driven to wind and unwind the wire, supplying electricity to the multi-channel wave dancing vibration rattle part. Do it (S30).

At this time, through the wires (1st, 2nd, 3rd, and 4th wires), the multi-channel wave dance type vibrating rattle is positioned so that it is positioned correctly on the screen network where the retinal force phenomenon occurs.

Next, as shown in FIG. 22, the multi-channel wave dance-type vibrating rattle part is formed in a straight horizontal structure at the screen net position where the retinal force phenomenon of the inclined vibrating screen main body occurs, and shakes with the force of vibration to create a wave. While dancing, the vibration and striking force shake off foreign substances clogged in the screen net and cause them to fall through the screen net (S40).

At this time, in addition to the screen network where the retinal force phenomenon occurred, a multi-channel wave dance type vibrating rattle was placed at the top, middle, and bottom of the screen of the inclined vibrating screen body, and it trembled and danced with the power of vibration. The striking force shakes off foreign substances clogged in the screen net and causes them to fall through the screen net.

Finally, when the removal of the screen net retinal force on the surface of the vibrating screen is completed, the loosened winch wire is wound through the head-type multi-channel winch part of the multi-channel wave dance type vibrating rattle module, and at the same time, through the head-type wire reel part. , by winding the loose wire, the multi-channel wave dance-type vibrating rattle is positioned in the rest area located outside the upper head of the inclined vibrating screen main body (S50).

At this time, when the removal of the screen network retinal force on the surface of the vibrating screen is completed, the inclined vibrating screen body spreads the construction waste or soil containing foreign substances such as vinyl or wood pieces through the force of vibration and the inclined structure to remove the soil. Only the separated foreign substances and aggregates are selected.

In this way, through the multi-channel wave dance type vibration module, even without a person directly entering the vibrating screen, the retinal force phenomenon can be solved by shaking and dancing with the power of vibration and transmitting the vibration force and striking force to the screen network. , It has excellent safety compared to the existing human-based method, and by operating the multi-channel wave-dancing vibration vibration module even during operation, continuous work is possible without stopping the operation of the vibrating screen, which increases the retinal force through the vibrating screen compared to the existing method. The improvement rate can be increased by more than 80%.

1: Screen net foreign matter removal device on the surface of the vibrating screen
100: Inclined vibrating screen body
110: Construction waste input unit
120: screen unit
130: discharge unit
140: Vibration generator
200: Multi-channel wave dance type vibration rattle module
210: Head-type multi-channel winch unit
211: Main winch driving motor
212: Rotation shaft rod
213: 1st winch roll part
214: 2nd winch roll part
215: Third winch roll part
216: Fourth winch roll part
220: Head type wire reel part
221: 1st wire reel
222: 2nd wire reel
223: Third wire reel
224: 4th wire reel
230: Multi-channel wave dance type vibration rattle part
231: Left guide wing part
232: 1st wave dance type vibration rattle
233: First elastic spring type bridge part
234: 2nd wave dance type vibration rattle
235: Second elastic spring type bridge part
236: Third wave dance type vibration rattle
237: Third elastic spring type bridge part
238: 4th wave dance type vibration rattle
239: Light guide wing part
240: Twin axis drop-out prevention type guide rail part
241: Left twin axis rod guide rail
242: Light twin axis rod guide rail

Claims (12)

It is installed on one side of the upper outer side of the screen net, and when the retinal force of the screen net is generated, it is thrown in, shaking and dancing with the force of vibration, and the aggregate or dirt blocking the screen net with the vibration force and impact force. It consists of an inclined vibrating screen retina force prevention device that shakes the screen and penetrates the screen net to make it fall.
The inclined vibrating screen retinal force prevention device is
An inclined vibrating screen body (100) that spreads construction waste or soil containing foreign substances such as vinyl or wood chips and sorts them by particle size through the force of vibration and an inclined structure,
A multi-channel wave dance type vibration module that is installed on the outside of the inclined vibrating screen body while being supported by a winch wire, and shakes and dances with the force of vibration, improving the retinal force phenomenon of the screen network with vibration force and striking force. In the inclined vibrating screen retinal force prevention device through the multi-channel wave dance type vibration rattling module consisting of (200),
The multi-channel wave dancing vibration vibration module 200 is
A head-type multi-channel winch unit (210) that is located in an area where vibration of the vibrating screen main body is not transmitted and moves the multi-channel wave dance type vibration rattle back and forth to the screen part of the vibrating screen main body while winding and unwinding the winch wire. ,
A head-type wire reel unit 220 that is located on one side of the upper part of the head-type multi-channel winch unit and supplies electricity to the multi-channel wave dance type vibration ratter while winding and unwinding the wire,
Supported by the winch wire formed on the head-type multi-channel winch, it is formed as a straight horizontal structure at any selected position among the top, middle, and bottom of the inclined vibrating screen main body, and is formed by the force of vibration. A multi-channel wave dance type vibrating rattle unit (230) that shakes and shakes and shakes foreign substances clogged in the screen net with vibration and striking force and causes them to fall through the screen net,
The guide rail, which is formed as a vertical partition on both sides of the screen part of the inclined vibrating screen main body, is formed as a two-axis rod structure with an upright structure on one side, preventing the left guide wing and the light guide wing from being separated to the outside, A multi-channel wave dance type, characterized in that it consists of a twin-axis anti-dropping guide rail portion (240) that performs a sliding role to move back and forth to any selected position among the top, middle, and bottom of the screen of the inclined vibrating screen main body. Inclined vibrating screen retinal force prevention device using a vibration rattling module.
delete delete The method of claim 1, wherein the head-type multi-channel winch (210) is
A main winch drive motor (211) located on one side of the rotating shaft, which generates rotational force and transmits it to the rotating shaft,
It is formed in a straight horizontal structure where the vibration of the inclined vibrating screen main body is not transmitted, and passes through the central axis of the first winch roll part, the second winch roll part, the third winch roll part, and the fourth winch roll part, and drives the main winch. A rotating shaft 212 that receives rotational force from the motor and rotates the first, second, third, and fourth winch roll parts at the same time,
When viewed from a plane, the first winch is located close to the main winch drive motor, receives rotational force from the rotating shaft, and winds or unwinds the winch wire connected to the first wave dancing vibrating rattle of the multi-channel wave dancing vibrating rattle. A roll unit 213,
When viewed from a plane, the second winch roll unit is located on one side of the first winch roll unit, receives rotational force from the rotating shaft, and winds or unwinds the winch wire connected to the second wave dancing vibrating rattle of the multi-channel wave dancing vibrating rattling unit ( 214) Wow,
When viewed from a plan view, the third winch roll unit is located on one side of the third winch roll unit, receives rotational force from the rotating shaft, and winds or unwinds the winch wire connected to the third wave dancing vibrating rattle of the multi-channel wave dancing vibrating rattle ( 215) Wow,
When viewed from a plan view, the fourth winch roll part is located on one side of the fourth winch roll part, receives rotational force from the rotating shaft, and winds or unwinds the winch wire connected to the fourth wave dancing vibration rattle of the multi-channel wave dancing vibrating rattle ( 216) An inclined vibrating screen retinal force prevention device through a multi-channel wave dance type vibration rattling module, characterized in that it consists of.
The method of claim 1, wherein the head-type wire reel unit 220 is
It is located on one side of the upper part of the first winch roll unit, and while winding and unwinding the electric wire connected to the first wave dancing rattle side of the multi-channel wave dancing vibrating rattling unit, electricity is connected to the first wave dancing vibrating rattling side of the multi-channel wave dancing vibrating rattling unit. A first wire reel 221 that supplies
It is located on one side of the upper part of the second winch roll unit, and while winding and unwinding the electric wire connected to the second wave dancing rattle side of the multi-channel wave dancing vibrating rattling unit, electricity is connected to the second wave dancing vibrating rattling side of the multi-channel wave dancing vibrating rattling unit. A second wire reel 222 that supplies
It is located on one side of the upper part of the third winch roll unit, and while winding and unwinding the electric wire connected to the third wave dancing rattle side of the multi-channel wave dancing vibrating rattling unit, electricity is connected to the third wave dancing rattling side of the multi-channel wave dancing vibrating rattling unit. A third wire reel (223) that supplies
It is located on one side of the upper part of the fourth winch roll unit, and while winding and unwinding the electric wire connected to the fourth wave dancing rattle side of the multi-channel wave dancing vibrating rattling unit, electricity is connected to the fourth wave dancing rattling side of the multi-channel wave dancing vibrating rattling unit. An inclined vibrating screen retinal force prevention device through a multi-channel wave dance type vibrating rattle module, characterized in that it consists of a fourth wire reel (224) that supplies.
The method of claim 1, wherein the multi-channel wave dance type vibration rattle unit (230)
" "It is formed with a shaped wing structure, and is in contact with one side of the left part of the twin axis drop-prevention guide rail part, and is formed into a straight horizontal structure. The first wave dance type vibration rattle, the second wave dance type vibration rattle, and the third wave dance type vibration It serves as a guide to move the 4th wave dance type vibration rattle to any selected position among the top, middle, or bottom of the screen of the inclined vibrating screen main body, and at the same time, the 1st wave dance type vibration rattle and the 2nd wave dance type vibration rattle , a left guide wing portion 231 that prevents the third wave dance type vibration rattle and the fourth wave dance type vibration rattle from being twisted or separated from the screen network,
When viewed from a plan view, it is supported by the winch wire formed in the first winch roll part of the head-type multi-channel winch and is located on the first line on the left side of the entire straight horizontal structure, and the screen moves in a wave dance that trembles with the force of vibration. A first wave dance-type vibrating rattle (232) that transmits vibration force while in contact with the surface of the network and eliminates the retinal force phenomenon of the screen network through vibration force and striking force,
It is located between the first wave dance type vibration rattle and the second wave dance type vibration rattle, and is formed as a bridge structure connecting the first wave dance type vibration rattle and the second wave dance type vibration rattle through a twin bridge-shaped elastic spring, so that the power of vibration A first elastic spring-type bridge portion 233 that forms a straight horizontal structure without distortion of the connection between the first wave dance type vibration rattle and the second wave dance type vibration rattle,
When viewed from a plan view, it is supported by the winch wire formed in the second winch roll part of the head-type multi-channel winch and is located on the first line on the left side of the entire straight horizontal structure, and the screen moves in a wave dance that trembles with the force of vibration. A second wave dance-type vibrating rattle (234) that transmits vibration force while contacting the surface of the net and eliminates the retinal force phenomenon of the screen net through vibration force and striking force,
It is located between the second wave dance type vibration rattle and the third wave dance type vibration rattle, and is formed as a bridge structure connecting the second wave dance type vibration rattle and the third wave dance type vibration rattle through a twin bridge-shaped elastic spring, so that the power of vibration A second elastic spring-type bridge portion 235 that forms a straight horizontal structure without distortion of the connection between the second wave dance type vibration rattle and the third wave dance type vibration rattle,
When viewed from a plan view, it is supported by the winch wire formed in the third winch roll part of the head-type multi-channel winch and is located on the first line on the left side of the entire straight horizontal structure, and the screen moves in a wave dance that trembles with the force of vibration. A third wave dance-type vibrating rattle (236) that transmits vibration force while contacting the surface of the network and eliminates the retinal force phenomenon of the screen network through vibration force and striking force,
It is located between the third wave dance type vibration rattle and the third wave dance type vibration rattle, and is formed as a bridge structure connecting the third wave dance type vibration rattle and the third wave dance type vibration rattle through a twin bridge-shaped elastic spring, so that the power of vibration A third elastic spring-type bridge portion 237 that forms a straight horizontal structure without distortion of the connection between the third wave dance-type vibration rattle and the third wave dance-type vibration rattle,
When viewed from a plan view, it is supported by the winch wire formed in the fourth winch roll part of the head-type multi-channel winch and is located on the first line on the left side of the entire straight horizontal structure, and the screen moves in a wave dance that trembles with the force of vibration. A fourth wave dance-type vibrating rattle (238) that transmits vibration force while contacting the surface of the network and eliminates the retinal force phenomenon of the screen network through vibration force and striking force,
" It is formed with a wing structure in the shape of, and is in contact with one side of the light (right) part of the twin-axis drop-prevention guide rail part, and is formed into a straight horizontal structure. The first wave dance type vibration rattle, the second wave dance type vibration rattle, and the third It serves as a guide to move the wave dancing type vibration rattle and the 4th wave dancing type vibration rattle to any selected position among the top, middle, or bottom of the screen of the inclined vibrating screen main body, and at the same time, the 1st wave dancing type vibrating rattle and the 2nd wave A multi-channel wave dancing vibration module characterized by consisting of a light guide wing portion 239 that prevents the dancing vibration shaking, the third wave dancing shaking shaking, and the fourth wave dancing shaking shaking from being distorted or separated from the screen network. Inclined vibrating screen retinal force prevention device.
The method of claim 6, wherein the first wave dancing vibration rattle (232)
A first double-arm type motor unit (232a) located at the center of the upper surface of the first weight control steel plate portion and generating double-arm vibration,
A first motor plate portion 232b that supports the lower part of the first double-arm motor portion and receives the force of vibration of the arms generated from the first double-arm motor portion and transmits it to the first weight control steel plate portion;
It is located between the first motor plate part and the first screen network contact plate part, has a rectangular plate structure, and has a weight of 1Kg to 15Kg, so that the force of the vibration of both arms transmitted from the first motor plate part is applied. A first weight control steel plate portion 232c that receives the wave dance and forms a trembling wave dance and then transmits the trembling wave dance to the first screen network contact plate portion,
A first screen net contact plate part (232d) formed on the lower surface of the first weight control steel plate part, which receives the shaking wave dance generated by the first weight control steel plate part and transmits it to the first screen net contact part; ,
A first screen net contact portion ( 232e) An inclined vibrating screen retinal force prevention device through a multi-channel wave dance type vibration rattling module, characterized in that it consists of.
The method of claim 7, wherein the first double-arm motor unit (232a)
A first rotor shaft (232a-1) that rotates the first twin balance weight by receiving rotational force due to electromagnetic induction generated from the first induction coil,
A first induction coil (232a-2) that generates rotational force by electromagnetic induction,
A first base cover (232a-3) that penetrates the first rotor shaft from left to right, includes a first induction coil, and protects and supports each device from external pressure;
A first twin balance weight (232a-4) formed on one left side and one right side of the first rotor shaft, respectively, to generate vibration by converting the centrifugal force generated by rotating the first rotor shaft into vibration, and
Inclined vibration through a multi-channel wave dance type vibration module, which consists of a first side cover (232a-5) that protects and supports external pressure by covering it to prevent foreign substances from entering the first twin balance weight. Screen retinal force prevention device.
The method of claim 7, wherein the first screen network contact portion (232e) is
The first screen net contact performs the role of a wheel that moves back and forth on the screen net surface while being in rolling contact with the screen net surface, transmitting vibration force toward the screen net surface and eliminating the retinal force phenomenon of the screen net through vibration and striking force. type wheel module (232e-1),
As the wedge-shaped protrusions come into contact with the surface of the screen net, vibration force is transmitted toward the screen net surface, eliminating the retinal force phenomenon of the screen net through vibration and striking force, and playing the role of sliding along the screen net surface through the inclined structure. An inclined vibrating screen retina force prevention device through a multi-channel wave dance type vibrating rattle module, characterized in that one of the first screen net contact type protrusion modules (232e-2) is selected and configured.
The method of claim 6, wherein the first elastic spring-type bridge portion 233 is
A 1a left elastic spring coupling portion ( 233a) and,
A first bridge plate (233b) located between the 1a left elastic spring coupling portion and the 1b right elastic spring coupling portion, and serving as a bridge connecting the first wave dance type vibration rattle and the second wave dance type vibration rattle,
A 1b light elastic spring coupling portion that is coupled to one side of the second wave dancing vibration rattle and supports the first bridge plate on the other side while cushioning the force of vibration generated from the second wave dancing vibration rattle with an elastic spring ( 233c) An inclined vibrating screen retinal force prevention device through a multi-channel wave dance type vibrating rattle module, characterized in that it consists of:
The method of claim 1, wherein the twin axis drop-prevention type guide rail portion 240 is
When viewed from a plan view, it is located on the left side of the guide rails formed in a vertical partition structure on both sides of the screen part of the inclined vibrating screen main body, and is guided to contact the left guide wing part, and the left guide wing guided by contact is A left twin-axis rod-shaped guide rail (241) that prevents the unit from falling out and plays a sliding role to move it back and forth to any selected position among the top, middle, and bottom of the screen of the inclined vibrating screen main body;
When viewed from a plan view, it is located on the light (right) side among the guide rails formed in a vertical partition structure on both sides of the screen part of the inclined vibrating screen main body, and is guided to contact the left guide wing part, and the light guide wing guided by contact is guided. It consists of a light twin-axis rod-shaped guide rail (242) that holds the unit from falling out and plays a sliding role to move it back and forth to any selected position among the top, middle, and bottom of the inclined vibrating screen main body. An inclined vibrating screen retinal force prevention device using a multi-channel wave dance type vibration rattling module. delete