Intelligent dry separator with anti-interference function and anti-interference method

By introducing removal, restriction, and dispersion devices into the intelligent dry separator, the problem of foreign objects and dust blocking the identification position is solved, thereby improving the anti-interference ability of the detection device and the effect of dry ore separation.

CN117719847BActive Publication Date: 2026-07-14HUANENG TONGCHUAN ZHAOJIN COAL POWER CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
HUANENG TONGCHUAN ZHAOJIN COAL POWER CO LTD
Filing Date
2024-01-03
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

During use, the recognition position of the intelligent dry separator may be blocked by foreign objects and dust, which will reduce the recognition accuracy and affect the dry separation effect of the ore.

Method used

The device employs a removal and limiting device. Dust at the bottom of the detection device is removed by suction pipe and suction plate. An arc rod and baffle are used to remove obstructions. Rollers and limiting plates are used to control the movement of ore. Separation and dispersion devices prevent ore accumulation and improve detection accuracy.

Benefits of technology

It effectively prevents the detection device from being interfered with by dust, prevents ore accumulation, and improves the detection accuracy and efficiency of dry ore beneficiation.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses an intelligent dry separator with an anti-interference function and an anti-interference method, and relates to the technical field of dry separators. The device comprises a device body, a removing device and a limiting device. The surface of the device body is fixedly provided with a supporting frame. The top of the supporting frame is fixedly provided with an inlet plate. The inside of the device body is provided with a conveying device. The inner wall top of the device body is fixedly provided with a detection device. The inner wall bottom of the device body is fixedly provided with a pop-up device. The removing device comprises a hollow frame, an air suction pipe, an air suction plate, a connecting frame, a cover plate, a push rod, a baffle and an arc-shaped rod. When the cover plate rotates, the push rod is pushed to move. When the push rod moves, the arc-shaped rod is pushed against the surface of the detection device to rotate, so that dust floating at the bottom of the detection device is prevented from adhering to the bottom of the detection device and interfering with the detection device.
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Description

Technical Field

[0001] This invention relates to the field of dry separator technology, specifically to an intelligent dry separator with anti-interference function and an anti-interference method. Background Technology

[0002] Dry separators typically refer to ore dry separation equipment, which is a type of mechanical device used to separate useful minerals from ores. This equipment is widely used in the mining and metallurgical industries to separate useful minerals from waste rock using physical and mechanical methods.

[0003] Patent publication number CN209406873U relates to an intelligent dry ore separator, comprising: a feeding system, a material distribution device, an identification system, an air supply system, an actuator, a dust removal system, and a heat dissipation device. The feeding system includes a discharge port and a dust removal port. A cleaner chute is located below the identification system, and a dust removal port is located above the actuator. All dust removal ports are connected to the dust removal air inlet of the dust removal system. A dust collector discharge port is located below the dust removal system. The heat dissipation device is connected to the identification system. Compared with existing technologies, this machine features a reasonable and precise structural design, high dry separation efficiency, excellent dry separation effect, complete heat dissipation, dust removal, and protection functions, a well-designed system, a good user experience, convenient maintenance, and stable dry separation performance.

[0004] The aforementioned patent features a reasonable and precise structural design, fast dry separation efficiency, good dry separation effect, complete heat dissipation, dust removal and protection functions, a complete system design, good customer user experience, convenient maintenance, and stable dry separation effect. However, during the use of the intelligent dry separator, it is necessary to separate other rocks in the ore. During the dry separation process, the identification position may be blocked by foreign objects and dust, which will affect the accuracy of identification and reduce the dry separation effect of the ore. Summary of the Invention

[0005] To address the shortcomings of existing technologies, this invention provides an intelligent dry separator with anti-interference capabilities and an anti-interference method, thus solving the problems mentioned in the background section.

[0006] To achieve the above objectives, the present invention provides the following technical solution: an intelligent dry separator with anti-interference function, comprising a device body, a removal device, and a limiting device; wherein, a support frame is fixedly mounted on the surface of the device body, a feed plate is fixedly mounted on the top of the support frame, a conveying device is provided inside the device body, a detection device is fixedly mounted on the top of the inner wall of the device body, and a pop-out device is fixedly mounted on the bottom of the inner wall of the device body; wherein, the removal device comprises a hollow frame, a suction pipe, a suction plate, a connecting frame, a cover plate, a push rod, a baffle, and an arc-shaped rod, wherein when the cover plate rotates, it pushes the push rod to move, and when the push rod moves, it pushes the arc-shaped rod to abut against the detection device. The surface of the device rotates, and the rotating arc rod pushes the baffle to move. The hollow frame is fixedly installed on the top of the device body, and the suction pipe is fixedly installed through the bottom of the hollow frame. An exhaust fan is installed on the top of the suction pipe. The suction plate is fixedly installed at the bottom of the suction pipe. The connecting frame is fixedly installed between the suction pipes. The cover plate is rotatably installed on the surface of the suction pipe. The push rod slides through the connecting frame. The baffle is slidably installed at the bottom of the detection device. The bottom of the arc rod is hinged to the baffle, and the top of the arc rod is hinged to the push rod. This design prevents dust floating at the bottom of the detection device from adhering to the bottom of the detection device and interfering with the detection device, thus improving the anti-interference effect of the detection device.

[0007] According to the above technical solution, the arc-shaped rod contacts the detection device and is elastic. A first torsion spring is provided between the cover plate and the suction pipe, a first spring is provided between the push rod and the connecting frame, a second spring is provided between the baffle and the detection device, a scraper is slidably installed inside the hollow frame, a pull rod is fixedly installed on the surface of the scraper, water is generated inside the hollow frame, and a drain port is provided on the surface of the hollow frame to prevent excessive dust inside the hollow frame from causing an explosion. Pulling the pull rod and the scraper to move will push the sediment generated at the bottom of the hollow frame to be discharged from the drain port.

[0008] According to the above technical solution, the limiting device includes a fixed frame, rollers, protrusions, a fixed rod, and a limiting plate. When the fixed rod moves upward, it will drive the limiting plate to move. The fixed frame is fixedly installed inside the main body of the device. The rollers are rotatably installed on the surface of the fixed frame. The protrusions are fixedly installed on the surface of the rollers. The fixed rod is slidably installed on the surface of the fixed frame. The limiting plate is fixedly installed on the surface of the fixed rod. The up-and-down movement of the limiting plate will intermittently restrict the ore on the feed plate from moving onto the conveying device, preventing excessive accumulation of ore on the conveying device and affecting the accuracy of the detection device for ore detection.

[0009] According to the above technical solution, it also includes a separation device and a dispersion device. The separation device is fixedly installed on the surface of the limiting plate. The separation device includes a rod, a concave plate, a clamping plate, a bending plate, and a triangular block. After the clamping plate opens, larger ore will roll between the clamping plates. When the limiting plate, the concave plate, and the clamping plate move upward, the rod is fixedly installed on the surface of the device body, the concave plate is fixedly installed on the surface of the limiting plate, the clamping plate is slidably installed inside the concave plate, the bending plate is fixedly installed on the top of the clamping plate, and the triangular block is fixedly installed on the surface of the rod. The clamping plate will clamp larger ore to prevent larger ore from accumulating on one side of the limiting plate and affecting the movement of other ore to the conveying device.

[0010] According to the above technical solution, a No. 4 spring is provided between the clamping plate and the concave plate. A connecting plate is fixedly installed on the surface of the device body. A transmission plate is rotatably installed on the surface of the connecting plate. An arc plate is fixedly installed at the bottom of the transmission plate. A vertical rod is fixedly installed at the top of the concave plate. A linkage rod is hinged to the top of the vertical rod. The linkage rod is hinged to the arc plate. When the linkage rod moves upward, it will pull the arc plate to rotate towards the bottom of the concave plate. The ore falling from the clamping plate will move to the arc plate. Larger ore will roll out of the feed plate from the arc plate, avoiding the large ore from affecting the feed again.

[0011] According to the above technical solution, the dispersing device includes a rotating rod, a circular plate, a forked plate, an open plate, and a contact rod. The rotating rod is rotatably mounted on the surface of the device body. The circular plate is fixedly mounted on the bottom of the rotating rod. The forked plate is rotatably mounted on the bottom of the circular plate. The open plate is slidably mounted inside the device body. The contact rod is fixedly mounted on the surface of the fixed rod. The rotating rod has a spiral groove. The forked plate is mounted at an eccentric position on the circular plate. The contact rod pushes the rotating rod to rotate. When the rotating rod rotates, it drives the circular plate to rotate. When the forked plate moves, it pushes the ore on the conveying device to disperse, which can prevent the ore from accumulating on the conveying device and improve the dry separation effect of the ore.

[0012] According to the above technical solution, the contact rod contacts the spiral groove, the forked plate contacts the opening plate, and the opening plate restricts the rotation of the forked plate.

[0013] An anti-interference method for an intelligent dry separator with anti-interference function includes:

[0014] Step 1: Turn on the conveyor and exhaust fan. When the exhaust fan is working, it will draw air from the bottom of the suction pipe and suction plate.

[0015] Step 2: The suction plate removes dust from the bottom of the detection device, and the air flow pushes the cover plate to rotate when the suction pipe is sucking air.

[0016] Step 3: When the cover plate rotates, it pushes the push rod to move. When the push rod moves, it pushes the arc-shaped rod against the surface of the detection device to rotate.

[0017] Step 4: When the arc-shaped rod rotates, it pushes the baffle to move, and when the baffle moves, it removes the obstruction to the bottom of the detection device.

[0018] This invention provides an intelligent dry separator with anti-interference function and an anti-interference method. It has the following beneficial effects:

[0019] (1) The invention uses a suction pipe and suction plate to suck up foreign objects from the bottom of the detection device, preventing dust floating at the bottom of the detection device from adhering to the bottom of the detection device and interfering with the detection device. At the same time, when the suction pipe is working, it will push the cover plate to rotate. When the cover plate rotates, it will push the push rod to move. The push plate will push the arc rod to rotate. When the arc rod rotates, it will push the baffle to move. When the baffle moves, it will remove the obstruction to the bottom of the detection device, which improves the protection of the detection device and prevents the detection device from being damaged when it is not in use.

[0020] (2) In this invention, when the conveying device moves, it will drive the roller to rotate. When the roller rotates, the arc block will push the fixed rod and the limiting plate to move up and down. The up and down movement of the limiting plate will intermittently restrict the ore on the feed plate from moving to the conveying device, so as to prevent the ore on the conveying device from accumulating too much and affecting the accuracy of the detection device for ore detection.

[0021] (3) In this invention, when the limiting plate moves downward, the triangular block will push the curved plate and the clamping plate to open. When the concave plate moves upward, the curved plate will separate from the triangular block. The clamping plate will hold the larger ore, preventing the larger ore from accumulating on one side of the limiting plate and affecting the movement of other ore to the conveying device. When the concave plate moves upward, it will pull the arc plate to rotate towards the bottom of the concave plate. The arc plate will catch the larger ore, allowing the larger ore to roll out of the feed plate from the arc plate.

[0022] (4) In this invention, when the fixed rod moves up and down, it will drive the contact rod to move. When the contact rod moves up and down inside the spiral groove, it will push the rotating rod to rotate. When the rotating rod rotates, it will drive the circular plate to rotate. When the circular plate rotates, it will push the forked plate to move. When the forked plate moves, it will push the ore on the conveying device to disperse, which can prevent the ore from piling up on the conveying device and improve the dry separation effect of the ore. Attached Figure Description

[0023] Figure 1 This is a schematic diagram of the overall structure of the present invention;

[0024] Figure 2 This is a schematic diagram of the internal structure of the device body of the present invention;

[0025] Figure 3 This is a schematic diagram of the internal structure of the hollow frame of the present invention;

[0026] Figure 4 This is a schematic diagram of the internal structure of the connecting frame of the present invention;

[0027] Figure 5 This is a schematic diagram of the position structure of the fixing frame and rollers in this invention;

[0028] Figure 6 This is a schematic diagram of the positional structure of the limiting plate and the concave plate of the present invention.

[0029] Figure 7 For the present invention Figure 6 Enlarged schematic diagram of section A in the middle;

[0030] Figure 8 This is a schematic diagram of the positional structure of the concave plate and clamping plate of the present invention.

[0031] In the diagram: 1. Device body; 2. Support frame; 3. Feed plate; 4. Conveying device; 51. Detection device; 52. Pop-out device; 53. Hollow frame; 54. Suction pipe; 55. Suction plate; 56. Connecting frame; 57. Cover plate; 58. Push rod; 59. Baffle; 510. Arc rod; 511. Scraper; 512. Pull rod; 61. Fixing frame; 62. Roller; 63. Protrusion; 64. Fixing rod; 65. Limiting plate; 66. Shovel plate; 71. Insert rod; 72. Concave plate; 73. Clamping plate; 74. Bending plate; 75. Triangular block; 76. Connecting plate; 77. Transmission plate; 78. Arc plate; 79. Vertical pole; 710. Linkage rod; 81. Rotating rod; 82. Circular plate; 83. Forked plate; 84. Opening plate; 85. Contact rod. Detailed Implementation

[0032] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0033] Please see Figure 1-5One embodiment of the present invention is as follows: an intelligent dry separator with anti-interference function, comprising a device body 1, a removal device, and a limiting device; wherein, a support frame 2 is fixedly installed on the surface of the device body 1, a feed plate 3 is fixedly installed on the top of the support frame 2, a conveying device 4 is provided inside the device body 1, a detection device 51 is fixedly installed on the top of the inner wall of the device body 1, and a pop-out device 52 is fixedly installed on the bottom of the inner wall of the device body 1; wherein, the removal device comprises a hollow frame 53, a suction pipe 54, a suction plate 55, a connecting frame 56, a cover plate 57, a push rod 58, a baffle 59, and an arc rod 510, the suction pipe 54 draws air from the bottom of the suction plate 55, the suction plate 55 draws air to remove dust from the bottom of the detection device 51, and at the same time, when the suction pipe 54 draws air, the gas flow pushes the cover plate 57 to rotate, and when the cover plate 57 rotates, it pushes the push rod 58 to enter the device body. When the push rod 58 moves, it pushes the arc rod 510 to rotate against the surface of the detection device 51. When the arc rod 510 rotates, it pushes the baffle 59 to move. The hollow frame 53 is fixedly installed on the top of the device body 1. The suction pipe 54 is fixedly installed through the bottom of the hollow frame 53. The top of the suction pipe 54 is equipped with an exhaust fan. The suction plate 55 is fixedly installed at the bottom of the suction pipe 54. The connecting frame 56 is fixedly installed between the suction pipes 54. The cover plate 57 is rotatably installed on the surface of the suction pipe 54. The push rod 58 slides through the connecting frame 56. The baffle 59 is slidably installed at the bottom of the detection device 51. The bottom of the arc rod 510 is hinged to the baffle 59, and the top of the arc rod 510 is hinged to the push rod 58. This prevents dust floating at the bottom of the detection device 51 from adhering to the bottom of the detection device 51 and interfering with the detection device 51, thus improving the anti-interference effect of the detection device 51.

[0034] The arc-shaped rod 510 contacts the detection device 51. The arc-shaped rod 510 is elastic. A first torsion spring is provided between the cover plate 57 and the suction pipe 54. A first spring is provided between the push rod 58 and the connecting frame 56. A second spring is provided between the baffle 59 and the detection device 51. A scraper 511 is slidably installed inside the hollow frame 53. A pull rod 512 is fixedly installed on the surface of the scraper 511. Water is generated inside the hollow frame 53. A drain port is provided on the surface of the hollow frame 53 to prevent excessive dust inside the hollow frame 53 from causing an explosion. Pulling the pull rod 512 and the scraper 511 to move will push the sediment generated at the bottom of the hollow frame 53 to be discharged from the drain port.

[0035] The limiting device includes a fixed frame 61, a roller 62, a protrusion 63, a fixed rod 64, and a limiting plate 65. When the roller 62 rotates, it drives the protrusion 63 to rotate. When the protrusion 63 rotates, it contacts the fixed rod 64 and pushes the fixed rod 64 to move. When the fixed rod 64 moves upward, it drives the limiting plate 65 to move. The fixed frame 61 is fixedly installed inside the main body 1 of the device. The roller 62 is rotatably installed on the surface of the fixed frame 61. The protrusion 63 is fixedly installed on the surface of the roller 62. The fixed rod 64 is slidably installed on the surface of the fixed frame 61. The limiting plate 65 is fixedly installed on the surface of the fixed rod 64. The up and down movement of the limiting plate 65 will intermittently restrict the ore on the feed plate 3 from moving to the conveying device 4, preventing excessive accumulation of ore on the conveying device 4 and affecting the accuracy of the detection device 51 in detecting the ore.

[0036] A No. 3 spring is provided between the fixed rod 64 and the fixed frame 61. A shovel plate 66 is fixedly installed on the surface of the fixed frame 61. The shovel plate 66 restricts the movement of ore to the bottom of the roller 62, affecting the rotation of the roller 62.

[0037] An anti-interference method for an intelligent dry separator with anti-interference function includes:

[0038] Step 1: Turn on the conveyor 4 and the exhaust fan. When the exhaust fan is working, it will draw air from the bottom of the suction pipe 54 and the suction plate 55.

[0039] Step 2: The suction plate 55 removes dust from the bottom of the detection device 51, and the air flow pushes the cover plate 57 to rotate when the suction pipe 54 is suctioning.

[0040] Step 3: When the cover plate 57 rotates, it pushes the push rod 58 to move. When the push rod 58 moves, it pushes the arc rod 510 to abut against the surface of the detection device 51 and rotate.

[0041] Step 4: When the arc rod 510 rotates, it pushes the baffle 59 to move. When the baffle 59 moves, it releases the obstruction to the bottom of the detection device 51.

[0042] In this embodiment, when the ore is placed on the feed plate 3, the ore on the feed plate 3 will slide onto the conveying device 4. The conveying device 4 will transport the ore to the bottom of the detection device 51. The detection device 51 will detect the ore on the conveying device 4. Stones that are not ore will be ejected by the ejection device 52. When the conveying device 4 is working, the suction pipe 54 is opened. The suction pipe 54 will suck air from the bottom of the suction plate 55. The suction plate 55 will suck up the dust at the bottom of the detection device 51. At the same time, when the suction pipe 54 sucks air, the air flow will push the cover plate 57 to rotate. When the cover plate 57 rotates, it will push the push rod 58 to move. When the push rod 58 moves, it will push the arc rod 510 to abut against the surface of the detection device 51 and rotate. When the arc rod 510 rotates, it will push the baffle 59 to move. When the baffle 59 moves, it will remove the obstruction to the bottom of the detection device 51.

[0043] When the conveying device 4 moves, it drives the roller 62 to rotate. When the roller 62 rotates, it drives the protrusion 63 to rotate. When the protrusion 63 rotates, it contacts the fixed rod 64 and pushes the fixed rod 64 to move. When the fixed rod 64 moves upward, it drives the limiting plate 65 to move. After the protrusion 63 disengages from the fixed rod 64, the fixed rod 64 will reset under the action of the third spring, causing the limiting plate 65 to move up and down.

[0044] Please see Figure 1-8 Based on the above embodiments, another embodiment of the present invention further includes a separation device and a dispersion device. A separation device is fixedly installed on the surface of the limiting plate 65. The separation device includes a rod 71, a concave plate 72, a clamping plate 73, a bending plate 74, and a triangular block 75. When the clamping plate 73 moves downward, it will cause the bending plate 74 to contact the triangular block 75, so that the triangular block 75 will push the bending plate 74 and the clamping plate 73 to move in opposite directions. After the clamping plate 73 opens, larger ore will roll between the clamping plates 73. When the limiting plate 65, the concave plate 72, and the clamping plate 73 move upward, the rod 71 is fixedly installed on the surface of the device body 1, the concave plate 72 is fixedly installed on the surface of the limiting plate 65, the clamping plate 73 is slidably installed inside the concave plate 72, the bending plate 74 is fixedly installed on the top of the clamping plate 73, and the triangular block 75 is fixedly installed on the surface of the rod 71. The clamping plate 73 will clamp larger ore to prevent larger ore from accumulating on one side of the limiting plate 65 and affecting the movement of other ore to the conveying device 4.

[0045] A No. 4 spring is provided between the clamping plate 73 and the concave plate 72. A connecting plate 76 is fixedly installed on the surface of the device body 1. A transmission plate 77 is rotatably installed on the surface of the connecting plate 76. An arc plate 78 is fixedly installed at the bottom of the transmission plate 77. A vertical rod 79 is fixedly installed at the top of the concave plate 72. A linkage rod 710 is hinged to the top of the vertical rod 79. The linkage rod 710 is hinged to the arc plate 78. When the concave plate 72 moves upward, it will drive the vertical rod 79 to move upward. When the vertical rod 79 moves upward, it will drive the linkage rod 710 to move upward. When the linkage rod 710 moves upward, it will pull the arc plate 78 to rotate towards the bottom of the concave plate 72. The ore falling from the clamping plate 73 will move to the arc plate 78. Larger ore will roll out of the feed plate 3 from the arc plate 78, preventing larger ore from affecting the feed again.

[0046] The dispersing device includes a rotating rod 81, a circular plate 82, a forked plate 83, an open plate 84, and a contact rod 85. The rotating rod 81 is rotatably mounted on the surface of the device body 1. The circular plate 82 is fixedly mounted on the bottom of the rotating rod 81. The forked plate 83 is rotatably mounted on the bottom of the circular plate 82. The open plate 84 is slidably mounted inside the device body 1. The contact rod 85 is fixedly mounted on the surface of the fixed rod 64. A spiral groove is formed on the surface of the rotating rod 81. The forked plate 83 is installed at an eccentric position on the circular plate 82. When the contact rod 85 moves, it moves inside the spiral groove, causing the contact rod 85 to push the rotating rod 81 to rotate. When the rotating rod 81 rotates, it drives the circular plate 82 to rotate. When the forked plate 83 moves, it pushes the ore on the conveying device 4 to disperse, which can prevent the ore from accumulating on the conveying device 4 and improve the dry separation effect of the ore.

[0047] The contact rod 85 contacts the spiral groove, and the forked plate 83 contacts the opening plate 84. The opening plate 84 restricts the rotation of the forked plate 83.

[0048] In this embodiment, when the limiting plate 65 moves downward, it causes the concave plate 72 and the clamping plate 73 to move downward. When the clamping plate 73 moves downward, it causes the curved plate 74 to come into contact with the triangular block 75, causing the triangular block 75 to push the curved plate 74 and the clamping plate 73 to move in opposite directions. After the clamping plate 73 opens, larger pieces of ore will roll between the clamping plates 73. When the limiting plate 65, the concave plate 72, and the clamping plate 73 move upward, the clamping plate 73 will cause the curved plate 74 to disengage from the triangular block 75. Under the elastic force of the fourth spring, the clamping plate 73 will resist larger pieces of ore. When the ore is clamped and the concave plate 72 rises to a certain height, the concave plate 72 will drive the clamping plate 73 and the bending plate 74 to contact the triangular block 75 above, causing the triangular block 75 to move again and the bending plate 74 and clamping plate 73 to open. At the same time, when the concave plate 72 moves upward, it will drive the upright rod 79 to move upward. When the upright rod 79 moves upward, it will drive the linkage rod 710 to move upward. When the linkage rod 710 moves upward, it will pull the arc plate 78 to rotate towards the bottom of the concave plate 72. The ore falling from the clamping plate 73 will move to the arc plate 78.

[0049] When the fixed rod 64 moves, it will drive the contact rod 85 to move. When the contact rod 85 moves, it will move inside the spiral groove, causing the contact rod 85 to push the rotating rod 81 to rotate. When the rotating rod 81 rotates, it will drive the circular plate 82 to rotate. When the circular plate 82 rotates, it will drive the bifurcated plate 83 to move. When the bifurcated plate 83 moves, the opening plate 84 will restrict the rotation of the bifurcated plate 83.

[0050] Although embodiments of the invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. An intelligent dry separator with anti-interference function, comprising a device body (1), characterized in that: It also includes removal devices, restraining devices, and dispersing devices; Among them, a support frame (2) is fixedly installed on the surface of the device body (1), a feed plate (3) is fixedly installed on the top of the support frame (2), a conveying device (4) is provided inside the device body (1), a detection device (51) is fixedly installed on the top of the inner wall of the device body (1), and a pop-out device (52) is fixedly installed on the bottom of the inner wall of the device body (1). The removal device includes a hollow frame (53), a suction pipe (54), a suction plate (55), a connecting frame (56), a cover plate (57), a push rod (58), a baffle (59), and an arc rod (510). The hollow frame (53) is fixedly installed on the top of the device body (1). The suction pipe (54) is fixedly installed through the bottom of the hollow frame (53). A fan is provided on the top of the suction pipe (54). The suction plate (55) is fixedly installed at the bottom of the suction pipe (54). The connecting frame (56) is fixedly installed between the suction pipes (54). The cover plate (57) is rotatably installed on the surface of the suction pipe (54). The push rod (58) slides through the connecting frame (56). The baffle (59) slides on the bottom of the detection device (51). The bottom of the arc rod (510) is hinged to the baffle (59), and the top of the arc rod (510) is hinged to the push rod (58). The limiting device includes a fixed frame (61), a roller (62), a protrusion (63), a fixed rod (64), and a limiting plate (65). The fixed frame (61) is fixedly installed inside the main body (1). The roller (62) is rotatably installed on the surface of the fixed frame (61). The protrusion (63) is fixedly installed on the surface of the roller (62). The fixed rod (64) is slidably installed on the surface of the fixed frame (61). The limiting plate (65) is fixedly installed on the surface of the fixed rod (64). A separation device is fixedly installed on the surface of the limiting plate (65). The separation device includes a rod (71), a concave plate (72), a clamping plate (73), a bending plate (74), and a triangular block (75). The rod (71) is fixedly installed on the surface of the device body (1). The concave plate (72) is fixedly installed on the surface of the limiting plate (65). The clamping plate (73) is slidably installed inside the concave plate (72). The bending plate (74) is fixedly installed on the top of the clamping plate (73). The triangular block (75) is fixedly installed on the surface of the rod (71). A No. 4 spring is provided between the clamping plate (73) and the concave plate (72). A connecting plate (76) is fixedly installed on the surface of the device body (1). A transmission plate (77) is rotatably installed on the surface of the connecting plate (76). An arc plate (78) is fixedly installed at the bottom of the transmission plate (77). A vertical rod (79) is fixedly installed at the top of the concave plate (72). A linkage rod (710) is hinged to the top of the vertical rod (79). The linkage rod (710) is hinged to the arc plate (78). The dispersing device includes a rotating rod (81), a circular plate (82), a forked plate (83), an open plate (84), and a contact rod (85). The rotating rod (81) is rotatably mounted on the surface of the device body (1). The circular plate (82) is fixedly mounted on the bottom of the rotating rod (81). The forked plate (83) is rotatably mounted on the bottom of the circular plate (82). The open plate (84) is slidably mounted inside the device body (1). The contact rod (85) is fixedly mounted on the surface of the fixed rod (64). The surface of the rotating rod (81) is provided with a spiral groove.

2. The intelligent dry separator with anti-interference function according to claim 1, characterized in that: The arc-shaped rod (510) contacts the detection device (51). The arc-shaped rod (510) is elastic. A torsion spring is provided between the cover plate (57) and the suction pipe (54). A spring is provided between the push rod (58) and the connecting frame (56). A second spring is provided between the baffle (59) and the detection device (51). A scraper (511) is slidably installed inside the hollow frame (53). A pull rod (512) is fixedly installed on the surface of the scraper (511).

3. The intelligent dry separator with anti-interference function according to claim 2, characterized in that: A No. 3 spring is provided between the fixing rod (64) and the fixing frame (61), and a shovel plate (66) is fixedly installed on the surface of the fixing frame (61).

4. The intelligent dry separator with anti-interference function according to claim 3, characterized in that: The contact rod (85) contacts the spiral groove, and the forked plate (83) contacts the opening plate (84).

5. The anti-interference method for an intelligent dry separator with anti-interference function according to claim 4, characterized in that, include: Step 1: Turn on the conveying device (4) and the exhaust fan. When the exhaust fan is working, it draws air from the bottom of the suction pipe (54) and the suction plate (55). Step 2: The suction plate (55) removes dust from the bottom of the detection device (51), and the air flow pushes the cover plate (57) to rotate when the suction pipe (54) is suctioning. Step 3: When the cover plate (57) rotates, it pushes the push rod (58) to move. When the push rod (58) moves, it pushes the arc rod (510) to abut against the surface of the detection device (51) and rotate. Step 4: When the arc rod (510) rotates, it pushes the baffle (59) to move. When the baffle (59) moves, it removes the obstruction to the bottom of the detection device (51).