Material transport device for refractory production
By using symmetrical guide plates and adjustment components in refractory material production, the problem of offset during billet transportation was solved, achieving stable conveying and efficient adaptation, and reducing equipment replacement costs and manpower requirements.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DANYANG QIXU THERMAL INSULATION PROD CO LTD
- Filing Date
- 2025-08-29
- Publication Date
- 2026-06-26
AI Technical Summary
In the traditional refractory material production process, the billets are prone to lateral displacement or tilting due to vibration and deviation during transportation, resulting in billet damage and production discontinuity.
The conveyor mounting plates and guide plates are symmetrically arranged. Combined with the adjustment components, the spacing of the guide plates can be adjusted by adjusting the screws and threads, forming a symmetrical guiding structure to ensure the stable conveying of the billet on the belt conveyor.
It effectively avoids billet displacement and collision, ensures billet integrity, adapts to the needs of billets of different specifications, reduces equipment replacement costs, and improves transportation efficiency and process continuity.
Smart Images

Figure CN224410434U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to a material transport device for the production of refractory materials. Background Technology
[0002] In the production of refractory materials, the transportation of billets has a significant impact on production efficiency and product quality. Currently, refractory billets are typically transported using belt conveyors. The billets are generally placed on supporting plates and move along the conveyor belt with the plates.
[0003] Traditional transport devices lack effective guiding structures. When the plates carrying the billets move on the belt conveyor, they are prone to lateral displacement or tilting due to factors such as conveyor belt vibration and billet placement deviation. This can cause the billets to collide with the conveyor frame or be squeezed against each other, resulting in damage or falling off of the billets, which affects product quality and production continuity. In view of this, this utility model proposes a material transport device for refractory material production to solve the above problems. Utility Model Content
[0004] The purpose of this invention is to provide a material transport device for refractory material production, so as to solve the problems mentioned in the background art.
[0005] To achieve the above objectives, this utility model provides the following technical solution:
[0006] A material conveying device for refractory material production includes:
[0007] Belt conveyor;
[0008] Two sets of conveyor mounting plates; the two sets of conveyor mounting plates are symmetrically arranged on the belt conveyor;
[0009] Four sets of guide plates; each pair of guide plates is respectively installed on two sets of conveyor mounting plates;
[0010] Four sets of adjustment components; each pair of adjustment components is respectively installed on two sets of conveyor mounting plates; the adjustment components are matched with the guide plates in position;
[0011] The guide plate is connected to the adjustment assembly, which drives the change in the distance between the guide plate and the conveyor mounting plate.
[0012] As an improvement to the above technical solution, the adjustment assembly includes two sets of adjustment sleeves, and the two sets of adjustment sleeves are connected to the guide plate;
[0013] An adjusting screw is provided inside the adjusting sleeve, and the adjusting screw is disposed in the adjusting sleeve so that the adjusting sleeve is displaced along the axis of the adjusting screw.
[0014] As an improvement to the above technical solution, a fixing plate is provided on the adjusting screw, the adjusting screw is rotatably mounted on the fixing plate, and the fixing plate is fixedly connected to the conveyor mounting plate.
[0015] As an improvement to the above technical solution, an adjustment block is provided inside the adjustment sleeve, and a threaded hole is provided on the adjustment block;
[0016] The adjusting screw is disposed in the threaded hole, and the adjusting screw is threadedly engaged with the threaded hole.
[0017] As an improvement to the above technical solution, the adjusting sleeve is provided with an installation through groove, and the adjusting block is provided with an installation hole, the installation hole and the installation through groove being matched in position;
[0018] Mounting bolts are provided between the mounting holes and the mounting slots.
[0019] As an improvement to the above technical solution, an adjustment handwheel is provided on the adjustment screw, and the adjustment block is slidably disposed in the inner cavity of the adjustment sleeve.
[0020] As an improvement to the above technical solution, a guide side plate is provided on the guide plate;
[0021] The guide plate is provided with a guide bend, and the guide side plate is provided with a side plate bend. The side plate bend is positioned to match the guide bend, and the guide bend and the side plate bend are bent toward the direction away from the conveyor mounting plate.
[0022] As an improvement to the above technical solution, a baffle plate is provided between the two sets of conveyor mounting plates, and the baffle plate is located at the end point of the belt conveyor.
[0023] The barrier plate is connected to the conveyor mounting plate by bolts.
[0024] Compared with the prior art, the beneficial effects of this utility model are:
[0025] With two sets of symmetrically arranged conveyor mounting plates and four sets of guide plates on them forming a symmetrical guiding structure, when the plate carrying the refractory billet moves on the belt conveyor, the guide plates on both sides can simultaneously guide and correct the plate in both directions, effectively preventing the plate from shifting or tilting during transportation, ensuring that the billet is always transported stably along the preset path, reducing the risk of billet collision and falling due to shift, and ensuring the integrity of the billet.
[0026] With the cooperation of four sets of adjustment components and guide plates, the distance between the guide plates and the conveyor mounting plate can be adjusted by adjusting the components, so that the device can be adapted to different specifications of bearing plates, meet the transportation needs of different types and sizes of refractory billets, expand the application range of the device, and reduce the cost of replacing transportation equipment due to changes in billet specifications.
[0027] The adjustment of the component settings makes the adjustment of the guide spacing convenient, and the adaptation adjustment can be completed without complicated disassembly or modification, which shortens the preparation time for switching between different specifications of billets. At the same time, the automatic correction function of the guide plate reduces the manual intervention for alignment, reduces labor costs, and improves the continuity and efficiency of the overall transportation process. Attached Figure Description
[0028] Figure 1 This is a schematic diagram of the structure of this utility model;
[0029] Figure 2 This utility model Figure 1 Enlarged structural diagram at point A;
[0030] Figure 3 This is a schematic diagram showing the positions of the guide plate and adjustment components of this utility model;
[0031] Figure 4 This is a schematic diagram of the structure of the guide plate of this utility model;
[0032] Figure 5 This is a schematic diagram of the guide plate of this utility model from another angle;
[0033] Figure 6 This utility model Figure 5 Enlarged structural diagram at point B;
[0034] Figure 7 This is a schematic diagram of the structure of the adjustment block of this utility model;
[0035] Figure 8 This is a schematic diagram of the adjusting screw of this utility model.
[0036] In the diagram: 10. Belt conveyor; 11. Conveyor mounting plate; 20. Guide plate; 21. Guide bend; 30. Baffle plate; 40. Adjustment assembly; 41. Adjustment handwheel; 42. Adjustment screw; 43. Mounting hole; 44. Adjustment block; 45. Mounting slot; 46. Adjustment sleeve; 47. Threaded hole; 48. Fixing plate; 50. Guide side plate; 51. Side plate bend; 60. Mounting bolt. Detailed Implementation
[0037] 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.
[0038] Example:
[0039] like Figure 1-8 As shown, this embodiment proposes a material transport device for refractory material production, comprising:
[0040] Belt conveyor 10;
[0041] Two sets of conveyor mounting plates 11; the two sets of conveyor mounting plates 11 are symmetrically arranged on the belt conveyor 10;
[0042] Four sets of guide plates 20; each pair of guide plates 20 is respectively installed on two sets of conveyor mounting plates 11;
[0043] Four sets of adjustment components 40; each pair of adjustment components 40 is respectively installed on two sets of conveyor mounting plates 11; the adjustment components 40 are matched with the guide plates 20 in position;
[0044] The guide plate 20 is connected to the adjustment assembly 40, which drives the change in the distance between the guide plate 20 and the conveyor mounting plate 11.
[0045] In this embodiment, when transporting refractory material billets, the billets are placed on plates, and the plates are placed on belt conveyors 10. The belt conveyors 10 drive the plates to move, thereby driving the billets to move. Before conveying, the guide plates 20 are adjusted by adjusting the assembly 40 until the distance between the guide plates 20 and the conveyor mounting plate 11 is adapted to the plates. That is, when the plates pass between the two sets of guide plates 20, the guide plates 20 guide and correct the plates.
[0046] Of course, when correcting the plate, two sets of guide plates 20 are symmetrically arranged on the belt conveyor 10, that is, when the plate moves on the belt conveyor 10, the guide plates 20 on both sides can simultaneously guide the plate.
[0047] With two sets of conveyor mounting plates 11 symmetrically arranged, and four sets of guide plates 20 on them forming a symmetrical guiding structure, when the plate carrying the refractory billet moves on the belt conveyor 10, the guide plates 20 on both sides can simultaneously guide and correct the plate in both directions, effectively preventing the plate from shifting or tilting during transportation, ensuring that the billet is always transported stably along the preset path, reducing the risk of billet collision and falling due to shift, and ensuring the integrity of the billet;
[0048] With the cooperation of four sets of adjustment components 40 and guide plate 20, the distance between guide plate 20 and conveyor mounting plate 11 can be driven by adjusting components 40, so that the device can be adapted to different specifications of bearing plates, meet the transportation needs of different types and sizes of refractory billets, expand the application range of the device, and reduce the cost of replacing transportation equipment due to changes in billet specifications.
[0049] The adjustment of component 40 makes the adjustment of guide spacing convenient, and the adaptation adjustment can be completed without complicated disassembly or modification, which shortens the preparation time for switching between different specifications of billets. At the same time, the automatic correction function of guide plate 20 reduces the manual intervention for alignment, reduces labor costs, and improves the continuity and efficiency of the overall transportation process.
[0050] Specifically, the adjustment assembly 40 includes two sets of adjustment sleeves 46, and the two sets of adjustment sleeves 46 are connected to the guide plate 20;
[0051] An adjusting screw 42 is provided inside the adjusting sleeve 46. The adjusting screw 42 is disposed in the adjusting sleeve 46, so that the adjusting sleeve 46 is displaced along the axis of the adjusting screw 42, thereby causing the adjusting sleeve 46 to move.
[0052] In this embodiment, the adjustment sleeve 46 and the adjustment screw 42 in the adjustment assembly 40 cooperate to drive the adjustment sleeve 46 to move stably along its axis by rotating the adjustment screw 42, thereby driving the guide plate 20 to move synchronously. This enables precise control of the distance between the guide plate 20 and the conveyor mounting plate 11, ensuring that the distance is compatible with the specifications and height of the bearing plate, and improving the accuracy of guidance correction.
[0053] The structural design of the adjusting sleeve 46 displacing along the axis of the adjusting screw 42 limits the movement trajectory of the guide plate 20, preventing the guide plate 20 from tilting or shaking during the adjustment process, and ensuring that the guide plate 20 always maintains the preset guiding posture, thus guaranteeing the stability of the adjustment operation and the structural reliability of the device during operation.
[0054] Specifically, a fixing plate 48 is provided on the adjusting screw 42, the adjusting screw 42 is rotatably mounted on the fixing plate 48, and the fixing plate 48 is fixedly connected to the conveyor mounting plate 11.
[0055] In this embodiment, when adjusting the adjusting sleeve 46, rotating the adjusting screw 42 can facilitate the displacement adjustment of the adjusting sleeve 46. Of course, the fixing plate 48 can improve the stability of the adjusting screw 42, thereby improving the stability of the guide.
[0056] Specifically, an adjustment block 44 is provided inside the adjustment sleeve 46, and a threaded hole 47 is provided on the adjustment block 44;
[0057] The adjusting screw 42 is disposed in the threaded hole 47, and the adjusting screw 42 is threadedly engaged with the threaded hole 47.
[0058] In this embodiment, the threaded hole 47 on the adjusting block 44 and the adjusting screw 42 form a threaded engagement structure. By rotating the adjusting screw 42, the adjusting block 44 can be driven to drive the adjusting sleeve 46 and the guide plate 20 to generate a stable displacement along the axial direction of the adjusting screw 42. Utilizing the high precision characteristics of the threaded transmission, the spacing of the guide plate 20 can be adjusted slightly and precisely to ensure that the spacing and the specifications of the bearing plate are matched with high precision, thereby improving the reliability of the guide correction.
[0059] The threaded fit has a natural self-locking function. When adjusted to the preset spacing, there will be no relative displacement between the adjusting block 44 and the adjusting screw 42 without external force driving the adjusting screw 42. This allows the guide plate 20 to remain in the set position, preventing spacing deviation due to vibration and other factors during transportation and ensuring the stability of the guide structure.
[0060] Specifically, the adjusting sleeve 46 is provided with a mounting slot 45, and the adjusting block 44 is provided with a mounting hole 43, the mounting hole 43 and the mounting slot 45 are matched in position;
[0061] A mounting bolt 60 is provided between the mounting hole 43 and the mounting through groove 45.
[0062] In this embodiment, by using the mounting slot 45, mounting hole 43 and mounting bolt 60, the adjusting block 44 and adjusting sleeve 46 can be quickly assembled and fixed. The connection structure is stable and reliable, and can effectively transmit the driving force generated when the adjusting screw 42 drives the adjusting block 44, ensuring that the adjusting sleeve 46 moves synchronously with the adjusting block 44, and ensuring the continuity and stability of the adjustment process of the guide plate 20.
[0063] The detachable structure with bolted connection allows for quick replacement or repair of damaged parts when the adjusting block 44 or adjusting sleeve 46 is worn or damaged, by removing the mounting bolts 60 without disassembling the entire adjusting assembly 40. This reduces maintenance difficulty, minimizes equipment downtime, and improves the efficiency of the device.
[0064] Specifically, the adjusting screw 42 is provided with an adjusting handwheel 41, and the adjusting block 44 is slidably disposed in the inner cavity of the adjusting sleeve 46.
[0065] In this embodiment, the adjustment handwheel 41 provided on the adjustment screw 42 provides the operator with a convenient force application component. By rotating the adjustment handwheel 41, the adjustment screw 42 can be driven to rotate. Compared with directly rotating the adjustment screw 42, the required operating force is effectively reduced, making the adjustment of the guide plate 20 spacing more effortless and convenient, facilitating quick spacing adjustment and improving operating efficiency.
[0066] Specifically, the guide plate 20 is provided with a guide side plate 50;
[0067] The guide plate 20 is provided with a guide bending part 21, and the guide side plate 50 is provided with a side plate bending part 51. The side plate bending part 51 and the guide bending part 21 are matched in position, and the guide bending part 21 and the side plate bending part 51 are bent in a direction away from the conveyor mounting plate 11.
[0068] In this embodiment, the guide bend 21 of the guide plate 20 and the side plate bend 51 of the guide side plate 50 bend toward the direction away from the conveyor mounting plate 11 to form an outwardly expanding guide inlet structure. When the plate carrying the refractory billet enters the guide area, the outwardly expanding structure can play a pre-guiding role for the plate, reduce the collision risk when the plate initially contacts the guide plate 20 and the guide side plate 50, and enable the plate to enter the guide correction zone smoothly and smoothly, reducing the damage to the plate or billet caused by impact.
[0069] The guide bend 21 and the side plate bend 51 are matched in position, and the two work together to form a continuous guide profile. During the transportation of the plate, a guiding force can be applied from different sides of the plate (such as the edge and side) to achieve multi-directional constraint and correction of the plate, avoid lateral deviation or torsion of the plate during transportation, ensure that the plate always moves stably along the preset path, and improve the comprehensiveness and reliability of the guide correction.
[0070] Specifically, a baffle plate 30 is provided between the two sets of conveyor mounting plates 11, and the baffle plate 30 is located at the end position of the belt conveyor 10.
[0071] The barrier plate 30 is connected to the conveyor mounting plate 11 by bolts.
[0072] In this embodiment, the baffle plate 30 is set at the end position of the belt conveyor 10, which can effectively block the load-bearing plates and refractory material blanks conveyed to the end position by the belt conveyor 10, prevent the plates from continuing to move due to inertia and detaching from the belt conveyor 10, ensure that the materials stop accurately at the preset end position, facilitate the precise docking of subsequent processes such as transfer and processing, and improve the continuity of the production process.
[0073] 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. A material conveying device for refractory material production, characterized in that: include: Belt conveyor (10); Two sets of conveyor mounting plates (11); the two sets of conveyor mounting plates (11) are symmetrically arranged on the belt conveyor (10); Four sets of guide plates (20); each pair of guide plates (20) is respectively installed on two sets of conveyor mounting plates (11); Four sets of adjustment components (40); each pair of adjustment components (40) is respectively installed on two sets of conveyor mounting plates (11); the adjustment components (40) are matched with the guide plates (20) in position; The guide plate (20) is connected to the adjustment assembly (40) to drive the change in the distance between the guide plate (20) and the conveyor mounting plate (11).
2. The material conveying device for refractory material production according to claim 1, characterized in that: The adjustment assembly (40) includes two sets of adjustment sleeves (46), which are connected to the guide plate (20); An adjusting screw (42) is provided inside the adjusting sleeve (46). The adjusting screw (42) is disposed in the adjusting sleeve (46), so that the adjusting sleeve (46) moves along the axis of the adjusting screw (42) to drive the adjusting sleeve (46) to move.
3. A material conveying device for refractory material production according to claim 2, characterized in that: A fixing plate (48) is provided on the adjusting screw (42). The adjusting screw (42) is rotatably mounted on the fixing plate (48). The fixing plate (48) is fixedly connected to the conveyor mounting plate (11).
4. A material conveying device for refractory material production according to claim 3, characterized in that: An adjustment block (44) is provided inside the adjustment sleeve (46), and a threaded hole (47) is provided on the adjustment block (44). The adjusting screw (42) is disposed in the threaded hole (47), and the adjusting screw (42) is threadedly engaged with the threaded hole (47).
5. A material conveying device for refractory material production according to claim 4, characterized in that: The adjusting sleeve (46) is provided with an installation through groove (45), and the adjusting block (44) is provided with an installation hole (43), the installation hole (43) and the installation through groove (45) are matched in position; A mounting bolt (60) is provided between the mounting hole (43) and the mounting through groove (45).
6. A material conveying device for refractory material production according to claim 5, characterized in that: An adjustment handwheel (41) is provided on the adjustment screw (42), and the adjustment block (44) is slidably disposed in the inner cavity of the adjustment sleeve (46).
7. A material conveying device for refractory material production according to claim 1, characterized in that: The guide plate (20) is provided with a guide side plate (50); The guide plate (20) is provided with a guide bending part (21), and the guide side plate (50) is provided with a side plate bending part (51). The side plate bending part (51) and the guide bending part (21) are matched in position. The guide bending part (21) and the side plate bending part (51) are bent in a direction away from the conveyor mounting plate (11).
8. A material conveying device for refractory material production according to claim 1, characterized in that: A baffle plate (30) is provided between the two sets of conveyor mounting plates (11), and the baffle plate (30) is located at the end position of the belt conveyor (10); The barrier plate (30) and the conveyor mounting plate (11) are connected by bolts.