An intelligent classification device suitable for multi-specification sorting of calcium silicate boards

By designing an intelligent sorting device, pneumatic suction cups and electric railcars are used to automate the sorting and handling of calcium silicate boards, solving the problem of easy cracking of calcium silicate boards during manual sorting and improving sorting efficiency and accuracy.

CN224332805UActive Publication Date: 2026-06-09ANHUI JIAYU BUILDING MATERIALS CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ANHUI JIAYU BUILDING MATERIALS CO LTD
Filing Date
2025-06-14
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

In existing technologies, calcium silicate boards are prone to cracking during manual sorting and handling due to the difficulty in controlling the force applied, making it difficult to achieve efficient and stable multi-specification sorting.

Method used

An intelligent sorting device was designed, including an incoming material conveyor belt, a calcium silicate board moving mechanism, a detection platform, a conveyor belt, and a sorting platform. It uses pneumatic suction cups and electric railcars for automated sorting and handling, and combines CCD cameras and webcams to determine specifications and quality. It achieves precise control through wireless data connection.

Benefits of technology

This technology enables specification testing and quality assessment of calcium silicate boards, preventing board breakage, improving handling efficiency and precision, and ensuring the accuracy and stability of classification.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

The utility model discloses a kind of intelligent classification devices suitable for calcium silicate board multi-specification sorting, it is related to intelligent classification device technical field, the intelligent classification device suitable for calcium silicate board multi-specification sorting, including incoming material conveyor belt, calcium silicate board moving mechanism one, temporary storage conveyor belt, detection platform, inferior product conveyor belt, two-way conveyor belt, distribution box, host computer, superior product conveyor belt, calcium silicate board moving mechanism two and classification platform;The temporary storage conveyor belt is connected with incoming material conveyor belt;The utility model can carry out specification detection and good or bad determination to the calcium silicate board to be classified, while the good or bad calcium silicate board can be distinguished, and the superior product calcium silicate board can be classified and placed according to different specifications, the carrying of calcium silicate board is carried out by calcium silicate board moving mechanism one and calcium silicate board moving mechanism two, and the force of the calcium silicate board grasping is more controllable, and the calcium silicate board is not easy to break.
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Description

Technical Field

[0001] This utility model relates to the field of intelligent sorting device technology, specifically an intelligent sorting device suitable for sorting calcium silicate boards of various specifications. Background Technology

[0002] Calcium silicate board, as a new type of green and environmentally friendly building material, not only has the functions of traditional gypsum board, but also has the advantages of superior fire resistance, moisture resistance, and ultra-long service life.

[0003] Calcium silicate boards are produced in different specifications to meet different needs, so they need to be classified. Currently, classification is mainly done manually. However, since calcium silicate boards are relatively fragile, it is not easy to control the force during manual classification and handling, which can easily cause the calcium silicate boards to crack. Utility Model Content

[0004] This invention provides an intelligent sorting device suitable for sorting calcium silicate boards of various specifications, in order to solve the problems mentioned in the background art.

[0005] This utility model provides the following technical solution: an intelligent sorting device suitable for sorting calcium silicate boards of multiple specifications, including an incoming material conveyor belt, a calcium silicate board moving mechanism one, a temporary storage conveyor belt, a detection platform, a defective product conveyor belt, a bidirectional conveyor belt, a power distribution box, a main unit, a superior product conveyor belt, a calcium silicate board moving mechanism two, and a sorting platform;

[0006] The temporary storage conveyor belt is connected to the incoming material conveyor belt. The temporary storage conveyor belt is used to transport the calcium silicate boards to be sorted to the temporary storage conveyor belt and to temporarily store the calcium silicate boards to be sorted that are transported by the incoming material conveyor belt.

[0007] The temporary storage conveyor belt, the testing platform, and the bidirectional conveyor belt are arranged side by side in sequence. The calcium silicate board moving mechanism 1 spans the temporary storage conveyor belt, the testing platform, and the bidirectional conveyor belt. The calcium silicate board moving mechanism 1 is used to move the calcium silicate boards to be classified stored on the temporary storage conveyor belt to the testing platform and the bidirectional conveyor belt in sequence. The testing platform is used to test and identify the specifications and quality of the calcium silicate boards placed on it.

[0008] The inferior product conveyor belt and the superior product conveyor belt are respectively connected to both ends of the bidirectional conveyor belt. The inferior product conveyor belt is used to transport inferior calcium silicate boards, the superior product conveyor belt is used to temporarily store superior calcium silicate boards, and the bidirectional conveyor belt is used to transport superior and inferior calcium silicate boards to the inferior product conveyor belt and the superior product conveyor belt respectively.

[0009] The classification platform is provided in multiple ways and is arranged in parallel with the premium product conveyor belt. The second calcium silicate board moving mechanism spans the classification platform and the premium product conveyor belt. The multiple classification platforms are used to store calcium silicate boards of different specifications. The second calcium silicate board moving mechanism is used to transport calcium silicate boards of different specifications from the premium product conveyor belt to the corresponding classification platform.

[0010] As a preferred technical solution of this utility model, the calcium silicate board moving mechanism consists of a beam frame, a track, a pneumatic suction cup lifting device, a lifting device crossbeam, an electric telescopic rod, and an electric railcar. The track is fixed below the crossbeam of the beam frame, and the electric railcar is installed on the track. The bottom of the electric railcar is fixedly connected to the lifting device crossbeam through the electric telescopic rod. A pneumatic suction cup lifting device is fixed at each end of the lifting device crossbeam.

[0011] As a preferred technical solution of this utility model, the second calcium silicate board moving mechanism consists of a second beam frame, a second track, an electric telescopic rod, a pneumatic suction cup lifting device, and a second electric railcar. The second track is fixed below the crossbeam of the second beam frame, and the second electric railcar is installed on the second track. The bottom of the second electric railcar is fixedly connected to a pneumatic suction cup lifting device through the electric telescopic rod.

[0012] As a preferred technical solution of this utility model, the pneumatic suction cup lifting device consists of a pneumatic suction cup mounting frame, a pneumatic suction cup, a top plate, a spring, and connecting screws. The pneumatic suction cup mounting frame is I-shaped, with a pneumatic suction cup installed at each of the four corners and the middle of the bottom of the pneumatic suction cup mounting frame. The top plate is located above the pneumatic suction cup mounting frame, and the top plate is connected to the pneumatic suction cup mounting frame by two connecting screws. The spring is sleeved on the connecting screws and is located between the top plate and the pneumatic suction cup mounting frame.

[0013] As a preferred technical solution of this utility model, two triggers are installed on the crossbeam of the beam frame one, the triggers corresponding to the positions of the temporary storage conveyor belt and the detection platform respectively, and a trigger plate that cooperates with the triggers is fixed on the electric railcar one.

[0014] As a preferred technical solution of this utility model, the crossbeam of the second beam frame is equipped with triggers in the same number as the sorting platform and the premium product conveyor belt. The triggers correspond to the positions of the sorting platform and the premium product conveyor belt, respectively. The electric railcar 2 is fixed with a trigger plate that cooperates with the triggers.

[0015] As a preferred embodiment of this utility model, the trigger consists of a grating transmitter, a grating receiver, and a grating mounting bracket. Both the grating transmitter and the grating receiver are mounted on the grating mounting bracket, and the grating transmitter and the grating receiver correspond to each other.

[0016] As a preferred embodiment of this utility model, the sorting platform consists of an electric flatbed cart, a scissor lift, and a calcium silicate board tray. The scissor lift is installed on the top of the electric flatbed cart, and the calcium silicate board tray is installed on the top of the scissor lift.

[0017] As a preferred technical solution of this utility model, the crossbeam of the second beam is equipped with a classification platform position detection device that is equal in number and corresponds one-to-one with the number of classification platforms. The classification platform position detection device consists of a camera and a camera mounting bracket, and the camera is installed at the end of the camera mounting bracket.

[0018] As a preferred technical solution of this utility model, the desktop of the detection platform is made of transparent tempered glass, and a calcium silicate board detection device is installed on the side of the detection platform. The calcium silicate board detection device consists of a CCD camera and a camera mounting bracket. A CCD camera is installed at the top and bottom of the camera mounting bracket, and the two CCD cameras are respectively located above and below the desktop of the detection platform.

[0019] Compared with the prior art, this utility model provides an intelligent sorting device suitable for sorting calcium silicate boards of multiple specifications, which has the following beneficial effects:

[0020] 1. This utility model can perform specification testing and quality judgment on calcium silicate boards to be classified. It can also distinguish between high-quality and low-quality calcium silicate boards and classify and place high-quality calcium silicate boards according to different specifications. The calcium silicate boards are transported by calcium silicate board moving mechanism one and calcium silicate board moving mechanism two. The gripping force on the calcium silicate boards is more controllable and the calcium silicate boards are not easy to break.

[0021] 2. Both calcium silicate board moving mechanism one and calcium silicate board moving mechanism two use pneumatic suction cups to grab the calcium silicate boards, which are then transported by corresponding electric railcars, resulting in higher and more stable transport efficiency.

[0022] 3. The calcium silicate board moving mechanism is equipped with two pneumatic suction cups, and the two pneumatic suction cups operate simultaneously. This allows the calcium silicate board moving mechanism to move the calcium silicate board on the temporary conveyor belt to the testing platform, while simultaneously moving the calcium silicate board on the testing platform to the bidirectional conveyor belt. This can effectively increase the efficiency of calcium silicate board specification testing and quality judgment.

[0023] 4. The pneumatic suction cup lifting device of this utility model has a spring between the pneumatic suction cup mounting frame and the top plate, so that when the electric telescopic rod drives the pneumatic suction cup lifting device to grab the calcium silicate board, the contact between the pneumatic suction cup lifting device and the calcium silicate board has a certain buffering effect, thereby avoiding excessive impact force during grabbing and causing the calcium silicate board to break.

[0024] 5. Both the calcium silicate board moving mechanism one and the calcium silicate board moving mechanism two are equipped with triggers, and the triggers correspond to their respective different positions. The triggers can determine the position of the electric railcar, thereby making the operation of the electric railcar more controllable and the operation accuracy higher.

[0025] 6. The sorting platform is used to store calcium silicate boards of different specifications. The sorting platform consists of an electric flatbed cart, a scissor lift, and calcium silicate board pallets. The scissor lift is used to lift the calcium silicate board pallets, thereby compensating for the problem of the effective extension length of the electric telescopic rod. The electric flatbed cart can realize the automatic handling of calcium silicate boards.

[0026] 7. The platform position detection device on beam frame 2 captures the position image of the corresponding sorting platform and the stacking image of calcium silicate boards on the sorting platform through a camera. The host analyzes the position image information and controls the movement of the sorting platform accordingly, so that the stopping position and stopping angle of the sorting platform meet the stacking requirements of calcium silicate boards (the host and the sorting platform are connected wirelessly). The host analyzes the stacking image and controls the sorting platform to move the boards after the stacking height reaches a certain level.

[0027] 8. The desktop of the testing platform is made of transparent tempered glass, which facilitates the two CCD cameras on the calcium silicate board testing device to capture images of the top and bottom of the calcium silicate board. Attached Figure Description

[0028] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0029] Figure 2 This is a schematic diagram of the calcium silicate board moving mechanism of this utility model;

[0030] Figure 3 This is a schematic diagram of the second calcium silicate board moving mechanism of this utility model;

[0031] Figure 4 This is a schematic diagram of the structure of the trigger of this utility model;

[0032] Figure 5 This is a schematic diagram of the classification platform of this utility model;

[0033] Figure 6 This is a schematic diagram of the structure of the detection platform of this utility model.

[0034] In the diagram: 1. Incoming material conveyor belt; 2. Calcium silicate board moving mechanism one; 3. Temporary storage conveyor belt; 4. Inspection platform; 5. Inferior product conveyor belt; 6. Bidirectional conveyor belt; 7. Distribution box; 8. Main unit; 9. Superior product conveyor belt; 10. Calcium silicate board moving mechanism two; 11. Sorting platform; 12. Beam frame one; 13. Track one; 14. Trigger; 15. Electric telescopic rod; 16. Lifting beam; 17. Pneumatic suction cup mounting bracket; 18. Top plate; 19. Pneumatic suction cup lifting device; 20. Pneumatic suction... 21. Disc; 22. Spring; 23. Connecting screw; 24. Electric railcar 1; 25. Beam frame 2; 26. Track 2; 27. Classification platform position detection device; 28. Electric railcar 2; 29. ​​Electric flatbed car; 30. Scissor lift frame; 31. Calcium silicate board tray; 32. Groove; 33. Grating transmitter; 34. Grating receiver; 35. Trigger plate; 36. CCD camera; 37. Calcium silicate board detection device; 38. Camera mounting frame. Detailed Implementation

[0035] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0036] Please see Figure 1-6 This utility model discloses an intelligent sorting device suitable for sorting calcium silicate boards of multiple specifications, including an incoming material conveyor belt 1, a calcium silicate board moving mechanism 1 2, a temporary storage conveyor belt 3, a detection platform 4, a defective product conveyor belt 5, a bidirectional conveyor belt 6, a power distribution box 7, a main unit 8, a superior product conveyor belt 9, a calcium silicate board moving mechanism 2 10, and a sorting platform 11.

[0037] The temporary storage conveyor belt 3 is connected to the incoming material conveyor belt 1. The temporary storage conveyor belt 3 is used to transport the calcium silicate boards to be sorted to the temporary storage conveyor belt 3. The temporary storage conveyor belt 3 is used to temporarily store the calcium silicate boards to be sorted that are transported by the incoming material conveyor belt 1.

[0038] The temporary storage conveyor belt 3, the testing platform 4, and the bidirectional conveyor belt 6 are arranged side by side in sequence. The calcium silicate board moving mechanism 2 spans the temporary storage conveyor belt 3, the testing platform 4, and the bidirectional conveyor belt 6. The calcium silicate board moving mechanism 2 is used to move the calcium silicate boards to be classified stored on the temporary storage conveyor belt 3 to the testing platform 4 and the bidirectional conveyor belt 6 in sequence. The testing platform 4 is used to test and identify the specifications and quality of the calcium silicate boards placed on it.

[0039] The inferior product conveyor belt 5 and the superior product conveyor belt 9 are respectively connected to the two ends of the bidirectional conveyor belt 6. The inferior product conveyor belt 5 is used to transport inferior calcium silicate boards, and the superior product conveyor belt 9 is used to temporarily store superior calcium silicate boards. The bidirectional conveyor belt 6 is used to transport superior and inferior calcium silicate boards to the inferior product conveyor belt 5 and the superior product conveyor belt 9 respectively.

[0040] Multiple sorting platforms 11 are arranged side by side with the premium conveyor belt 9. The calcium silicate board moving mechanism 2 10 spans the sorting platforms 11 and the premium conveyor belt 9. The multiple sorting platforms 11 are used to store calcium silicate boards of different specifications. The calcium silicate board moving mechanism 2 10 is used to transport calcium silicate boards of different specifications from the premium conveyor belt 9 to the corresponding sorting platforms 11.

[0041] The host 8 is used in conjunction with the testing platform 4 to determine the specifications and quality of calcium silicate boards. At the same time, the host 8 is also used to control the above-mentioned equipment to achieve automated production.

[0042] Distribution box 7 is used to supply power to the above-mentioned equipment.

[0043] The calcium silicate board moving mechanism 12 consists of a beam frame 12, a track 13, a pneumatic suction cup lifting device 19, a lifting device crossbeam 16, an electric telescopic rod 15, and an electric railcar 123. The track 13 is fixed below the crossbeam of the beam frame 12. The electric railcar 123 is installed on the track 13. The bottom of the electric railcar 123 is fixedly connected to the lifting device crossbeam 16 through the electric telescopic rod 15. A pneumatic suction cup lifting device 19 is fixed at each end of the lifting device crossbeam 16.

[0044] The calcium silicate board moving mechanism 210 consists of a beam frame 24, a track 25, an electric telescopic rod 15, a pneumatic suction cup lifting device 19, and an electric railcar 27. The track 25 is fixed below the crossbeam of the beam frame 24. The electric railcar 27 is installed on the track 25. The bottom of the electric railcar 27 is fixedly connected to a pneumatic suction cup lifting device 19 through the electric telescopic rod 15.

[0045] The pneumatic suction cup hanger 19 consists of a pneumatic suction cup mounting frame 17, a pneumatic suction cup 20, a top plate 18, a spring 21, and a connecting screw 22. The pneumatic suction cup mounting frame 17 is I-shaped, with a pneumatic suction cup 20 installed at each of the four corners and the middle of the bottom of the pneumatic suction cup mounting frame 17. The top plate 18 is located above the pneumatic suction cup mounting frame 17, and the top plate 18 is connected to the pneumatic suction cup mounting frame 17 by two connecting screws 22. The spring 21 is sleeved on the connecting screw 22 and is located between the top plate 18 and the pneumatic suction cup mounting frame 17.

[0046] Two triggers 14 are installed on the crossbeam of beam frame 12. The triggers 14 correspond to the positions of temporary storage conveyor belt 3 and detection platform 4, respectively. A trigger plate 35 that cooperates with the triggers 14 is fixed on electric railcar 23.

[0047] The crossbeam of beam frame 24 is equipped with triggers 14 in the same number as the sorting platform 11 and the premium conveyor belt 9. The triggers 14 correspond to the positions of the sorting platform 11 and the premium conveyor belt 9, respectively. The electric railcar 27 is fixed with trigger plates 35 that cooperate with the triggers 14.

[0048] The trigger 14 consists of a grating transmitter 33, a grating receiver 34, and a grating mount 32. Both the grating transmitter 33 and the grating receiver 34 are mounted on the grating mount 32, and the grating transmitter 33 and the grating receiver 34 correspond to each other.

[0049] The sorting platform 11 consists of an electric flatbed cart 28, a scissor lift 29, and a calcium silicate board pallet 30. The scissor lift 29 is installed on the top of the electric flatbed cart 28, and the calcium silicate board pallet 30 is installed on the top of the scissor lift 29. The calcium silicate board pallet 30 has a groove 31 that cooperates with the forklift arm of the forklift.

[0050] On the crossbeam of beam frame 24, there are classification platform position detection devices 26, which are equal in number and correspond one-to-one with the classification platforms 11. The classification platform position detection device 26 consists of a camera and a camera mounting bracket, with the camera installed at the end of the camera mounting bracket.

[0051] The desktop of the testing platform 4 is made of transparent tempered glass. A calcium silicate board testing device 37 is installed on the side of the testing platform 4. The calcium silicate board testing device 37 consists of a CCD camera 36 and a camera mounting bracket 38. A CCD camera 36 is installed at the top and bottom of the camera mounting bracket 38. The two CCD cameras 36 are located above and below the desktop of the testing platform 4, respectively.

[0052] The working principle and usage process of this utility model: This utility model can perform specification testing and quality judgment on calcium silicate boards to be classified. At the same time, it can distinguish between high-quality and low-quality calcium silicate boards, and can classify and place high-quality calcium silicate boards according to different specifications. The calcium silicate boards are transported by calcium silicate board moving mechanism 12 and calcium silicate board moving mechanism 20. The gripping force on the calcium silicate boards is more controllable, and the calcium silicate boards are not easy to break.

[0053] Both the calcium silicate board moving mechanism 12 and the calcium silicate board moving mechanism 210 use pneumatic suction cup lifting devices 19 to grab the calcium silicate boards, and the corresponding electric railcars transport them, resulting in higher and more stable transport efficiency.

[0054] The calcium silicate board moving mechanism 12 is equipped with two pneumatic suction cups 19, and the two pneumatic suction cups 19 operate simultaneously. This allows the calcium silicate board moving mechanism 12 to move the calcium silicate board on the temporary storage conveyor belt 3 to the testing platform 4, while simultaneously moving the calcium silicate board on the testing platform 4 to the bidirectional conveyor belt 6. This can effectively increase the efficiency of calcium silicate board specification testing and quality judgment.

[0055] The pneumatic suction cup hanger 19 of this utility model has a spring 21 between the pneumatic suction cup mounting frame 17 and the top plate 18. This spring 21 provides a certain buffering effect when the electric telescopic rod 15 drives the pneumatic suction cup hanger 19 to grab the calcium silicate board, thereby avoiding excessive impact force during grabbing and causing the calcium silicate board to break.

[0056] Both the calcium silicate board moving mechanism 12 and the calcium silicate board moving mechanism 210 are equipped with triggers 14, and the triggers 14 correspond to their respective different positions. The triggers 14 can determine the position of the electric railcar, thereby making the operation of the electric railcar more controllable and the operation accuracy higher.

[0057] The sorting platform 11 is used to store calcium silicate boards of different specifications. The sorting platform 11 consists of an electric flatbed cart 28, a scissor-type electric lifting frame 29, and a calcium silicate board pallet 30. The scissor-type electric lifting frame 29 is used to lift the calcium silicate board pallet 30, thereby compensating for the problem of the effective extension length of the electric telescopic rod 15. The electric flatbed cart 28 can realize the automatic handling of calcium silicate boards.

[0058] The platform position detection device 26 on beam frame 24 captures the position image of the corresponding sorting platform 11 and the stacking image of calcium silicate boards on the sorting platform 11 through a camera. The host 8 analyzes the position image information and controls the movement of the sorting platform 11 accordingly, so that the stopping position and stopping angle of the sorting platform 11 meet the stacking requirements of the calcium silicate boards (the host 8 and the sorting platform 11 are connected wirelessly). The host 8 analyzes the stacking image and controls the sorting platform 11 to move the boards after the stacking height reaches a certain level.

[0059] The desktop of the testing platform 4 is made of transparent tempered glass, which makes it convenient for the two CCD cameras 36 on the calcium silicate board testing device 37 to capture images of the top and bottom of the calcium silicate board. The host 8 analyzes the images to determine the specifications of the calcium silicate board and whether there are obvious defects on the surface of the calcium silicate board.

[0060] It should be noted that, in this document, terms such as "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such a process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one..." does not exclude the presence of other identical elements in the process, method, article, or apparatus that includes said element.

[0061] Although embodiments of the present 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 present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. An intelligent sorting device suitable for sorting calcium silicate boards of multiple specifications, characterized in that: It includes an incoming material conveyor belt (1), a calcium silicate board moving mechanism one (2), a temporary storage conveyor belt (3), a testing platform (4), a defective product conveyor belt (5), a bidirectional conveyor belt (6), a power distribution box (7), a main unit (8), a superior product conveyor belt (9), a calcium silicate board moving mechanism two (10), and a sorting platform (11). The temporary storage conveyor belt (3) is connected to the incoming material conveyor belt (1). The temporary storage conveyor belt (3) is used to transport the calcium silicate boards to be sorted to the temporary storage conveyor belt (3). The temporary storage conveyor belt (3) is used to temporarily store the calcium silicate boards to be sorted that are transported by the incoming material conveyor belt (1). The temporary storage conveyor belt (3), the testing platform (4) and the bidirectional conveyor belt (6) are arranged side by side in sequence. The calcium silicate board moving mechanism (2) spans the temporary storage conveyor belt (3), the testing platform (4) and the bidirectional conveyor belt (6). The calcium silicate board moving mechanism (2) is used to move the calcium silicate boards to be classified stored on the temporary storage conveyor belt (3) to the testing platform (4) and the bidirectional conveyor belt (6) in sequence. The testing platform (4) is used to test and identify the specifications and quality of the calcium silicate boards placed on it. The inferior product conveyor belt (5) and the superior product conveyor belt (9) are respectively connected to the two ends of the bidirectional conveyor belt (6). The inferior product conveyor belt (5) is used to transport inferior calcium silicate boards, and the superior product conveyor belt (9) is used to temporarily store superior calcium silicate boards. The bidirectional conveyor belt (6) is used to transport superior and inferior calcium silicate boards to the inferior product conveyor belt (5) and the superior product conveyor belt (9) respectively. The sorting platform (11) is provided in multiple ways and is arranged in parallel with the premium product conveyor belt (9). The second calcium silicate board moving mechanism (10) spans the sorting platform (11) and the premium product conveyor belt (9). The multiple sorting platforms (11) are used to store calcium silicate boards of different specifications. The second calcium silicate board moving mechanism (10) is used to transport calcium silicate boards of different specifications on the premium product conveyor belt (9) to the corresponding sorting platform (11).

2. The intelligent sorting device for sorting multiple specifications of calcium silicate boards according to claim 1, characterized in that: The calcium silicate board moving mechanism 1 (2) consists of a beam frame 1 (12), a track 1 (13), a pneumatic suction cup lifting device (19), a lifting device crossbeam (16), an electric telescopic rod (15), and an electric railcar 1 (23). The track 1 (13) is fixed below the crossbeam of the beam frame 1 (12). The electric railcar 1 (23) is installed on the track 1 (13). The bottom of the electric railcar 1 (23) is fixedly connected to the lifting device crossbeam (16) through the electric telescopic rod (15). A pneumatic suction cup lifting device (19) is fixed at each end of the lifting device crossbeam (16).

3. The intelligent sorting device for sorting multiple specifications of calcium silicate boards according to claim 1, characterized in that: The calcium silicate board moving mechanism 2 (10) consists of beam frame 2 (24), track 2 (25), electric telescopic rod (15), pneumatic suction cup lifting device (19) and electric railcar 2 (27). The track 2 (25) is fixed below the crossbeam of beam frame 2 (24). The electric railcar 2 (27) is installed on track 2 (25). The bottom of the electric railcar 2 (27) is fixedly connected to a pneumatic suction cup lifting device (19) through electric telescopic rod (15).

4. An intelligent sorting device for sorting multiple specifications of calcium silicate boards according to claim 2 or 3, characterized in that: The pneumatic suction cup lifting device (19) consists of a pneumatic suction cup mounting frame (17), a pneumatic suction cup (20), a top plate (18), a spring (21), and a connecting screw (22). The pneumatic suction cup mounting frame (17) is I-shaped. A pneumatic suction cup (20) is installed at each of the four corners and the middle of the bottom of the pneumatic suction cup mounting frame (17). The top plate (18) is located above the pneumatic suction cup mounting frame (17). The top plate (18) and the pneumatic suction cup mounting frame (17) are connected by two connecting screws (22). The spring (21) is sleeved on the connecting screw (22) and is located between the top plate (18) and the pneumatic suction cup mounting frame (17).

5. The intelligent sorting device for sorting multiple specifications of calcium silicate boards according to claim 2, characterized in that: Two triggers (14) are installed on the crossbeam of the beam frame (12). The triggers (14) correspond to the position of the temporary storage conveyor belt (3) and the position of the detection platform (4), respectively. The electric railcar (23) is fixed with a trigger plate (35) that cooperates with the triggers (14).

6. The intelligent sorting device for sorting multiple specifications of calcium silicate boards according to claim 3, characterized in that: The beam of the second beam (24) is equipped with triggers (14) in the same number as the sorting platform (11) and the premium conveyor belt (9). The triggers (14) correspond to the positions of the sorting platform (11) and the premium conveyor belt (9), respectively. The electric railcar (27) is fixed with a trigger plate (35) that cooperates with the triggers (14).

7. An intelligent sorting device for sorting multiple specifications of calcium silicate boards according to claim 5 or 6, characterized in that: The trigger (14) consists of a grating transmitter (33), a grating receiver (34) and a grating mount (32). The grating transmitter (33) and the grating receiver (34) are both mounted on the grating mount (32) and correspond to each other.

8. The intelligent sorting device for sorting multiple specifications of calcium silicate boards according to claim 1, characterized in that: The sorting platform (11) consists of an electric flatbed cart (28), a scissor lift (29), and a calcium silicate board tray (30). The scissor lift (29) is installed on the top of the electric flatbed cart (28), and the calcium silicate board tray (30) is installed on the top of the scissor lift (29).

9. The intelligent sorting device for sorting multiple specifications of calcium silicate boards according to claim 3, characterized in that: The beam of the second beam (24) is equipped with a classification platform position detection device (26) that is equal in number to and corresponds one-to-one with the classification platform (11). The classification platform position detection device (26) consists of a camera and a camera mounting bracket, with the camera installed at the end of the camera mounting bracket.

10. The intelligent sorting device for sorting multiple specifications of calcium silicate boards according to claim 1, characterized in that: The desktop of the testing platform (4) is made of transparent tempered glass. A calcium silicate board testing device (37) is installed on the side of the testing platform (4). The calcium silicate board testing device (37) consists of a CCD camera (36) and a camera mounting bracket (38). A CCD camera (36) is installed at the top and bottom of the camera mounting bracket (38). The two CCD cameras (36) are located above and below the desktop of the testing platform (4), respectively.