Heat-resistant conveyor belt with stable structure
By adopting structures such as trough-shaped steel rails, ceramic rollers, and support baffles on the conveyor belt, the problem of easy damage to heat-resistant conveyor belts in high-temperature environments has been solved, achieving stable conveying of high-temperature materials and convenient installation.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIAOZUO XIANGYUAN RUBBER PROD CO LTD
- Filing Date
- 2025-06-23
- Publication Date
- 2026-06-23
Smart Images

Figure CN224393690U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of heat-resistant conveyor belt technology, specifically a heat-resistant conveyor belt with stable structure. Background Technology
[0002] Conveyor belts are mechanized equipment in material handling systems, widely used in industries such as mining, metallurgy, chemical, building materials, food, and grain. They are used to transport various block, granular, and powdery materials as well as packaged goods. In high-temperature transportation, high-temperature resistant conveyor belts are required to transport high-temperature items. For example, in the brick production process, high-temperature resistant conveyor belts are needed to transport bricks that are to be cooled, ensuring that the high-temperature bricks are accurately delivered to the receiving area.
[0003] Heat-resistant conveyor belts on the market are generally made of high-temperature resistant rubber, with a maximum temperature resistance of 400-600 degrees Celsius. On some high-temperature production conveyor lines, the temperature may exceed the limit of the conveyor belt, causing irreversible damage and reducing its service life. Furthermore, heat-resistant conveyor belts are difficult to install when monitoring or marking equipment, causing trouble for users. Therefore, we propose a heat-resistant conveyor belt with a stable structure. Utility Model Content
[0004] The purpose of this invention is to provide a structurally stable heat-resistant conveyor belt to solve the problems mentioned in the background art.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a structurally stable heat-resistant conveyor belt, comprising a channel steel rail, a connecting plate, an upper mounting plate, and rollers. Several rollers are movably connected to the inner wall of the channel steel rail, and ceramic rollers are interference-fitted to the outer wall of the rollers. A connecting shaft is keyed to the inner wall of the rollers, and bearings are interference-fitted to the outer walls of both ends of the connecting shaft. Several supporting baffles are bolted to one side of the inner wall of the channel steel rail, and these supporting baffles are evenly distributed at equal intervals on the inner wall of the channel steel rail. A column is clamped to the middle of the channel steel rail near one side of its outer wall, and an upper mounting plate is mounted on the upper end of the column. A top cover is mounted on the top of the upper mounting plate, and an mounting groove is formed in the middle of the inner wall of the upper mounting plate.
[0006] Preferably, a plurality of connecting plates are mounted on the top of the upper end of the channel rail, and locking screws are threadedly connected to the connection points of the connecting plates and the channel rail. Tightening holes are provided at the connection points of the connecting plates and the locking screws, and limit rods are welded to the ends of the plurality of connecting plates.
[0007] Preferably, the limiting rods are distributed in a "bow" shape, and the limiting rods are symmetrically distributed along the center line of the roller shaft.
[0008] Preferably, the connecting shaft is movably connected to the inner wall of the channel rail via a bearing, and the channel rail is interference-fitted to the outer ring of the bearing.
[0009] Preferably, an industrial camera or an industrial labeling machine is mounted on the inner wall of the mounting slot.
[0010] Preferably, the upper mounting plate has several side holes around the mounting groove, and the upper mounting plate is fixed with internal studs along the inner wall side of the top cover.
[0011] Preferably, the internal studs are threaded to the column, and the internal studs are distributed along the four corners of the upper mounting plate. The upper mounting plate is interference-fitted to the top cover via the internal studs.
[0012] Preferably, a lower clamping plate is connected to the lower end surface of the column, and a locking screw is threadedly connected to the connection between the lower clamping plate and the channel steel rail. An upper clamping plate is connected to the upper end surface of the column, and a pad is fixed to one side of the upper clamping plate, and the pad is in contact with one corner of the upper mounting plate.
[0013] Preferably, the column, lower clamping plate, locking screw, upper clamping plate and pad block form a support structure, and the support structure is provided with four parts distributed at the four corners along the upper mounting plate.
[0014] Compared with the prior art, the beneficial effects of this utility model are as follows: the stable heat-resistant conveyor belt is equipped with support baffles, which are evenly distributed along the inner wall of the channel steel rail. Through the constraint and protection of the support baffles, the possibility of deformation of the channel steel rail under load is reduced, and the stability of the overall structure is improved. Furthermore, the heat-resistant conveyor belt uses rollers and ceramic rollers as moving parts. Their excellent hardness, wear resistance, high temperature resistance and corrosion resistance can meet the requirements of high-temperature conveying, making it convenient for users.
[0015] The upper mounting structure consists of an upper mounting plate, a top cover, a mounting groove, internal studs, and side holes. The inner wall of the mounting groove is equipped with some detection and marking equipment such as industrial cameras or industrial labeling machines to ensure that the detection and marking equipment can effectively detect and mark the workpiece when it is transported along the conveyor belt. Attached Figure Description
[0016] Figure 1 This is a three-dimensional structural diagram of the present invention;
[0017] Figure 2 This is a schematic diagram of the heat-resistant conveyor belt structure of this utility model;
[0018] Figure 3 This is a schematic diagram of the internal structure of the mounting plate of this utility model;
[0019] Figure 4 This is a schematic diagram of the connecting plate structure of this utility model;
[0020] Figure 5 This is a schematic diagram of the support structure of this utility model;
[0021] Figure 6 This is a schematic diagram of the roller structure of this utility model.
[0022] In the diagram: 1. Channel rail; 2. Connecting plate; 21. Connecting bolt; 22. Tightening hole; 23. Limiting rod; 3. Support baffle; 4. Column; 41. Lower clamping plate; 42. Locking screw; 43. Upper clamping plate; 44. Pad; 5. Upper mounting plate; 51. Top cover; 52. Mounting groove; 53. Internal stud; 54. Side hole; 6. Roller; 61. Ceramic roller; 62. Connecting shaft; 63. Bearing. Detailed Implementation
[0023] 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.
[0024] Please see Figure 1-6This utility model provides a technical solution: a structurally stable heat-resistant conveyor belt, including a trough-shaped steel rail 1, a connecting plate 2, an upper mounting plate 5, and rollers 6. Several rollers 6 are movably connected to the inner wall of the trough-shaped steel rail 1, and ceramic rollers 61 are interference-fitted to the outer wall of the rollers 6. A connecting shaft 62 is keyed to the inner wall of the rollers 6, and bearings 63 are interference-fitted to the outer walls of both ends of the connecting shaft 62. Several support baffles 3 are bolted to one side of the inner wall of the trough-shaped steel rail 1, and these support baffles 3 are evenly distributed at equal intervals on the inner wall of the trough-shaped steel rail 1. A column 4 is clamped to the middle of the trough-shaped steel rail 1 near one side of its outer wall, and an upper mounting plate 5 is mounted on the upper end of the column 4. A top cover 51 is mounted on the top of the upper end of the upper mounting plate 5, and an mounting groove 52 is formed in the middle of the inner wall of the upper mounting plate 5. Several connecting plates 2 are mounted on the top of the upper end of the trough-shaped steel rail 1, and these connecting plates 2 are connected to the trough-shaped steel rail 1. The connection point is threaded with a locking screw 42. A waist-tightening hole 22 is provided at the connection point between the connecting plate 2 and the locking screw 42. Several connecting plates 2 have limit rods 23 welded to their ends. The limit rods 23 are distributed in an "arch" shape and are symmetrically distributed along the center line of the roller shaft 6. The connecting plate 2, connecting bolt 21, waist-tightening hole 22 and limit rod 23 form a guiding component to limit and guide the conveyed workpiece, ensuring that the workpiece can be guided and conveyed along the middle position of the conveyor belt to meet the conveying requirements of the workpiece. At the same time, the guiding component has a certain anti-flow function to reduce the workpiece from flowing out along one side of the channel steel rail 1 and ensure accurate conveying of the workpiece. Furthermore, the guiding component uses the waist-tightening hole 22 as the mounting hole. Through the adjustable gap of the waist-tightening hole 22, the position of the guiding component can be adjusted within a small range to meet the user's needs for appropriate adjustment according to the size of the workpiece, making it convenient for the user.
[0025] The connecting shaft 62 is movably connected to the inner wall of the channel rail 1 via the bearing 63, and the channel rail 1 is interference-fitted to the outer ring of the bearing 63. The roller 6, ceramic roller 61, connecting shaft 62, and bearing 63 form a complete conveyor belt roller. Multiple conveyor belt rollers cooperate to form a complete conveyor belt. The surface of the roller 6 is made of ceramic roller 61 as a high-temperature resistant material, which can improve the high-temperature resistance of the roller 6 and meet the conveying requirements of some high-temperature workpieces. The ceramic roller 61 is made of high-quality ceramic raw materials, such as alumina ceramic, and is carefully proportioned and mixed to ensure that the roller has good hardness and wear resistance. During high-temperature processing, it can withstand the impact of high temperature, high pressure, and corrosive substances, ensuring the continuous operation of the production line. The connecting shaft 62, as the drive shaft of the roller 6, can be directly connected to the transmission system to meet the power conveying requirements of the conveyor belt. In order to reduce the friction coefficient between the conveyor belt and the channel rail 1, a bearing 63 is provided at the connection to ensure the effective operation of the entire equipment.
[0026] An industrial camera or industrial labeling machine is mounted on the inner wall of the mounting slot 52. The upper mounting plate 5 has several side holes 54 around the mounting slot 52, and the upper mounting plate 5 is fixed with internal studs 53 along the inner wall of the top cover 51. The internal studs 53 are threaded to the column 4, and the internal studs 53 are distributed at the four corners of the upper mounting plate 5. The upper mounting plate 5 is connected to the top cover 51 by the internal studs 53 through an interference fit. The top cover 51 serves as the upper protective component of the upper mounting plate 5. The top cover 51 is tightly connected to the multiple internal studs 53 by an interference fit. This connection method is simple to disassemble, convenient and practical, and convenient for users to maintain. At the same time, the four side holes 54 of the mounting slot 52 facilitate the connection and installation of subsequent equipment with the upper mounting plate 5.
[0027] The lower end surface of the column 4 is connected to a lower clamping plate 41, and a locking screw 42 is threadedly connected to the connection between the lower clamping plate 41 and the channel rail 1. The upper end surface of the column 4 is connected to an upper clamping plate 43, and a pad 44 is fixed to one side of the upper clamping plate 43. The pad 44 fits against one corner of the upper mounting plate 5. The column 4, lower clamping plate 41, locking screw 42, upper clamping plate 43, and pad 44 form a support structure, and four supports are provided along the four corners of the upper mounting plate 5. This support structure serves as the support for the upper mounting structure. The support connector has a lower clamping plate 41 and an upper clamping plate 43 installed at its upper and lower ends, respectively. By adjusting the size of the conveyed workpiece, the distance between the lower clamping plate 41 and the upper clamping plate 43 and the column 4 can be adjusted to adjust the placement height of the upper installation structure, thus ensuring the stable operation of the subsequent upper installation structure's inspection and marking equipment. The pad 44, as a contact part with the upper installation plate 5, can increase the contact area between the support structure and the upper installation plate 5, improve the stability of the overall structure, and ensure the stable use of the entire equipment.
[0028] Working principle: For this type of structurally stable heat-resistant conveyor belt, the height of the upper mounting plate 5 is first adjusted according to the size of the conveyed workpiece. The user only needs to loosen the locking screw 42 at the upper clamping plate 43, which increases the diameter of the hole at the upper clamping plate 43. The upper clamping plate 43 slides and rises along the surface of the column 4. After adjusting to the appropriate position, the locking screw 42 at the upper clamping plate 43 is tightened. At this time, the user aligns the lower clamping plate 41 with the surface of the channel steel rail 1, and its clamping hole connects with the channel steel rail 1. The locking screw 42 is then tightened, and the lower clamping plate... 41 is fastened to the channel steel rail 1. Repeat the above operation to install four support structures. Then, according to the requirements, the upper mounting plate 5 is covered along the four support structures. Its inner stud 53 is threaded to the column 4. The pad 44 is attached to the four corners of the upper mounting plate 5. Finally, the user takes out the finished product and rolls it along the roller 6. Its ceramic roller 61 is attached to the finished product. When the finished product slides along the roller 6, the friction force drives the roller 6 to move along the inner wall of the bearing 63. When the finished product rolls along the conveyor belt without any abnormalities, the workpiece can be transported.
Claims
1. A structurally stable heat-resistant conveyor belt, comprising a trough-shaped steel rail (1), a connecting plate (2), an upper mounting plate (5), and a roller (6), characterized in that: The inner wall of the channel rail (1) is movably connected with several rollers (6), and the outer wall of the rollers (6) is interference-fitted with ceramic rollers (61). The inner wall of the rollers (6) is keyed with a connecting shaft (62), and the outer walls of the two ends of the connecting shaft (62) are interference-fitted with bearings (63). The inner wall of one side of the channel rail (1) is bolted with several support baffles (3), and the several support baffles (3) are evenly distributed at equal intervals on the inner wall of the channel rail (1). The middle part of the channel rail (1) is clamped with a column (4) near one side of the outer wall, and the upper end of the column (4) is supported by an upper mounting plate (5). The top of the upper end of the upper mounting plate (5) is supported by a top cover (51), and the middle part of the inner wall of the upper mounting plate (5) is provided with an installation groove (52).
2. The structurally stable heat-resistant conveyor belt according to claim 1, characterized in that: The upper end of the channel rail (1) is provided with several connecting plates (2), and the connection between the connecting plates (2) and the channel rail (1) is threaded with locking screws (42). The connection between the connecting plates (2) and the locking screws (42) is provided with waist tightening holes (22), and the ends of the connecting plates (2) are welded with limit rods (23).
3. The structurally stable heat-resistant conveyor belt according to claim 2, characterized in that: The limiting rods (23) are distributed in a "bow" shape, and the limiting rods (23) are symmetrically distributed along the center line of the roller shaft (6).
4. The structurally stable heat-resistant conveyor belt according to claim 1, characterized in that: The connecting shaft (62) is movably connected to the inner wall of the channel rail (1) through the bearing (63), and the channel rail (1) and the outer ring of the bearing (63) are interference-fitted.
5. A structurally stable heat-resistant conveyor belt according to claim 1, characterized in that: An industrial camera or an industrial labeling machine is mounted on the inner wall of the mounting slot (52).
6. A structurally stable heat-resistant conveyor belt according to claim 5, characterized in that: The upper mounting plate (5) has several side holes (54) around the mounting groove (52), and the upper mounting plate (5) is fixed with an inner stud (53) along the inner wall of the top cover (51).
7. A structurally stable heat-resistant conveyor belt according to claim 6, characterized in that: The internal stud (53) is threaded to the column (4), and the internal stud (53) is distributed along the four corners of the upper mounting plate (5). The upper mounting plate (5) is interference-fitted to the top cover (51) through the internal stud (53).
8. A structurally stable heat-resistant conveyor belt according to claim 1, characterized in that: The lower end surface of the column (4) is connected to a lower clamping plate (41), and the lower clamping plate (41) is threadedly connected to the channel rail (1) with a locking screw (42). The upper end surface of the column (4) is connected to an upper clamping plate (43), and a pad (44) is fixed on one side of the upper clamping plate (43), and the pad (44) is in contact with the upper mounting plate (5).
9. A structurally stable heat-resistant conveyor belt according to claim 8, characterized in that: The column (4), lower clamping plate (41), locking screw (42), upper clamping plate (43) and pad (44) form a support structure, and there are four support structures, which are distributed along the four corners of the upper mounting plate (5).