A conveying module

By combining the pin-shaft limiting part with the snap-on sealing part, the problems of unstable limiting of connecting parts and inconvenient disassembly and assembly of sealing parts in the conveying module are solved, realizing a stable connection between module units and convenient maintenance, and improving the overall reliability and conveying accuracy of the conveying equipment.

CN224376796UActive Publication Date: 2026-06-19SHANDONG DONGLONG TRANSMISSION EQUIP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANDONG DONGLONG TRANSMISSION EQUIP CO LTD
Filing Date
2025-08-25
Publication Date
2026-06-19

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  • Figure CN224376796U_ABST
    Figure CN224376796U_ABST
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Abstract

The utility model relates to conveying equipment technical field especially, it relates to a conveying module. Including a plurality of along vertical and horizontal direction array splicing's module unit, the front and back of module unit form the spacing convexly arranged connecting block and recessed connecting groove, the connecting block of module unit can embed the connecting groove of adjacent module unit before and after, be equipped with the through hole of the connecting piece through setting on the connecting block, the detachable connection is realized through the connecting piece of through setting between module unit, the side of module unit forms the pin shaft limiting portion, the pin shaft limiting portion is detachably equipped with the obturator, after setting in the through hole, the pin shaft is sealed and positioned through the installation obturator. The problem that the connecting piece location is not stable, the obturator is inconvenient to dismount, the poor problem of conveying module limiting effect is solved.
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Description

Technical Field

[0001] This utility model relates to the field of conveying equipment technology, and in particular to a conveying module. Background Technology

[0002] In the field of conveying equipment, conveying modules, as core components for efficient material transfer, directly affect conveying efficiency, stability, and ease of maintenance through their structural design. Existing conveying modules have several structural design shortcomings. First, the connecting parts between module units, such as pins, lack reliable limiting and sealing structures after insertion, leading to easy loosening or detachment. Second, the disassembly process of some modules is cumbersome, requiring complex tools or damage to parts of the structure, greatly increasing the difficulty of later maintenance and replacement. Third, the limiting structure design of some modules is simple, making it difficult to form a limiting effect when combined with the track, leading to easy deviation during conveying, especially when carrying heavy or large materials, which affects conveying accuracy and safety.

[0003] Therefore, it is necessary to solve the problems of unstable limiting of connecting parts, inconvenient disassembly and assembly of sealing parts, and poor limiting effect of conveying modules in order to meet the material conveying needs. Utility Model Content

[0004] To address the problems of unstable limiting of connectors, inconvenient disassembly and assembly of sealing components, and poor limiting effect of conveying modules, this utility model provides a conveying module.

[0005] This utility model provides a conveying module, comprising several module units arrayed and spliced ​​along the longitudinal and transverse directions. Each module unit has a connecting block with a gap between its front and back, and a connecting groove with a recess. The connecting block of the module unit can be embedded in the connecting groove of the adjacent module unit. The connecting block has a through hole for a connector to pass through. The module units are detachably connected by the connectors that pass through. A pin limiting part is formed on one side of each module unit. A sealing part is detachably provided on the pin limiting part. After the connector is placed in the through hole, the pin is blocked and limited by installing the sealing part.

[0006] Furthermore, a sealing block is protruding on the pin limiting part. The sealing block and the connecting block are arranged in the same direction and at the same interval. An installation hole is formed on the sealing block. A sealing member is detachably provided on the pin limiting part. After the connecting member passes through the installation hole and is placed in the through hole, the sealing member seals the installation hole.

[0007] Furthermore, the width of the sealing block is half the width of the connecting block, and the side wall of the module unit away from the pin limiting part forms a splicing part. The splicing part is a structure that protrudes from the side wall of the module unit, and the length of the splicing part protruding from the side wall of the module unit is half the width of the connecting groove.

[0008] Furthermore, a recessed groove is formed on the upper surface of the pin limiting part, and the sealing member is inserted into the recessed groove to seal the mounting hole.

[0009] Furthermore, the outer edge of the recessed groove extends toward the connecting block to form two symmetrical strip-shaped mounting grooves. The strip-shaped mounting grooves connect the recessed groove and the through hole of the sealing block. The sealing component includes a sealing cover plate that mates with the recessed groove and a sealing wing that is embedded in the strip-shaped mounting groove. The sealing wing extends into the through hole.

[0010] Furthermore, the recessed groove has a stepped structure, and the sealing cover plate has a stepped portion on the side facing the recessed groove that matches the stepped structure of the recessed groove. The sealing member covers the recessed groove, and the sealing member and the recessed groove on the module unit form a detachable snap-fit ​​connection. The sealing wing can be inserted along the strip mounting groove and snap-fit ​​with the groove wall.

[0011] Furthermore, the sealing wing partially or completely seals the mounting hole to restrict the axial movement of the connector.

[0012] Furthermore, the lower surface of the pin limiting part is provided with a disassembly through hole corresponding to the recessed groove. The disassembly through hole extends into the recessed groove, and the sealing part can be pushed out of the recessed groove by inserting a tool through the disassembly through hole.

[0013] Furthermore, the bottom surface of the module unit is provided with a limiting part for cooperating with the track. The limiting part includes two mutually parallel limiting plates. The limiting plates protrude from the bottom of the module unit and are perpendicular to the horizontal transport plane of the module unit. The outline of the limiting plates matches the guide groove of the track.

[0014] Furthermore, the upper side of the module unit is a continuous support surface, and the lower side of the module unit is a rib structure formed on the lower side of the support surface.

[0015] In summary, this utility model has the following beneficial technical effects:

[0016] 1. The present invention proposes a conveying module, which, through the cooperation structure of the pin limiting part and the snap-on sealing part, allows the sealing wings of the sealing part to penetrate into the through hole to effectively limit the connecting parts. At the same time, the snap-fit ​​design of the sealing wings and the strip mounting groove further restricts the axial movement of the connecting parts, solving the problem of easy loosening and falling off of the connecting parts in traditional conveying modules, significantly enhancing the stability of the connection between module units, and ensuring the overall reliability of the conveying process.

[0017] 2. This utility model enables convenient assembly and disassembly of the sealing component. The stepped engagement structure between the sealing component and the recessed groove, as well as the design of the disassembly through hole, allow the sealing component to be quickly embedded and positioned during installation via the sealing wing. During disassembly, the sealing component can be pushed out by simply inserting a tool through the disassembly through hole without complicated operations or structural damage. This significantly reduces the difficulty of subsequent maintenance, repair, and replacement, and improves operation and maintenance efficiency.

[0018] 3. The modular unit of this utility model achieves longitudinal and transverse array splicing through the cooperation of connecting blocks and connecting grooves. The size matching design of the sealing block and the splicing part effectively reduces splicing gaps and misalignment, ensuring the continuity and flatness of the conveying surface. At the same time, the modular splicing method can flexibly adapt to conveying scenarios of different lengths and widths, improving the versatility of the equipment.

[0019] 4. The limiting part on the bottom surface of the module unit of this utility model is precisely matched with the track guide groove, which can form a reliable guide during the transportation process and effectively prevent the module from deviating. The convex rib structure on the lower side reduces the overall weight while enhancing the structural strength of the supporting surface through the distribution of ribs, thus achieving a balance between strength and lightweight. Attached Figure Description

[0020] Figure 1 This is a schematic diagram of the structure of a conveying module according to an embodiment of the present utility model.

[0021] Figure 2 This is a partially enlarged view of the pin limiting part according to an embodiment of the present utility model.

[0022] Figure 3 This is a schematic diagram of the back structure of a conveying module according to an embodiment of the present invention.

[0023] Figure 4 This is a schematic diagram of the sealing component according to an embodiment of the present invention.

[0024] Figure 5 This is a schematic diagram of the sealing principle of an embodiment of this utility model.

[0025] Figure 6 This is a schematic diagram showing the dimensional relationship between the splicing part, the connecting block, and the sealing block in an embodiment of this utility model.

[0026] Figure 7 This is a schematic diagram of the assembled structure of a conveying module according to an embodiment of the present invention.

[0027] Figure 8 This is an embodiment of the present utility model. Figure 7 A magnified view of part A in the image.

[0028] Among them, 1. Module unit; 101. Connecting block; 102. Connecting groove; 103. Through hole; 105. Limiting plate; 106. Supporting surface; 107. Rib structure; 2. Pin limiting part; 201. Sealing block; 202. Mounting hole; 203. Recessed groove; 204. Strip mounting groove; 205. Disassembly through hole; 3. Splicing part; 4. Sealing component; 401. Sealing cover plate; 402. Sealing wing; 403. Stepped part; 5. Connecting component. Detailed Implementation

[0029] The present invention will be further described in detail below with reference to the accompanying drawings.

[0030] Example 1

[0031] Reference Figure 1 , Figure 7 and Figure 8 This embodiment of a conveying module includes several module units 1 arrayed and spliced ​​along the longitudinal and transverse directions. Each module unit 1 has a connecting block 101 protruding at intervals and a connecting groove 102 recessed at intervals. The connecting block 101 of the module unit 1 can be embedded into the connecting groove 102 of adjacent module units 1. The shapes of the connecting block 101 and the connecting groove 102 are adapted to each other. After splicing, the relative displacement of adjacent module units 1 in the direction perpendicular to the conveying direction can be restricted, enhancing longitudinal connection stability. The connecting block 101 is provided with a through hole 103 for a connector 5 to pass through. The axis of the through hole 103 is consistent with the splicing direction of the module unit 1, which can ensure that the connector 5 forms an effective connection between adjacent module units 1 after it is inserted. The module units 1 are detachably connected through the through connector 5. A pin limit part 2 is formed on one side of the module unit 1. The pin limit part 2 provides a limiting space for the end of the connector 5 and provides an installation reference for the sealing part 4. The sealing part 4 is detachably provided on the pin limit part 2. After the connector 5 is set in the through hole 103, the pin is blocked and limited by installing the sealing part 4.

[0032] Reference Figure 2 and Figure 4 The pin limiting part 2 has a protruding sealing block 201. The sealing block 201 cooperates with the connecting block 101 to guide the insertion path of the connector 5, ensuring that the connector 5 is accurately inserted into the through hole 103. The sealing block 201 and the connecting block 101 are arranged in the same direction and at the same interval. The sealing block 201 has a mounting hole 202, which is coaxial with the through hole 103, ensuring that the connector 5 can be smoothly inserted and the force is even. The pin limiting part 2 is detachably provided with a sealing member 4. After the connector 5 passes through the mounting hole 202 and is placed in the through hole 103, the sealing member 4 seals the mounting hole 202. The connector 5 can be a plastic pin and can be cut to a suitable length according to actual use.

[0033] Reference Figure 6 L represents the length. The width of the sealing block 201 is half that of the connecting block 101. The side wall of the module unit 1 away from the pin limiting part 2 forms a splicing part 3. The splicing part 3 is a structure that protrudes from the side wall of the module unit 1. The splicing part 3 can form a complementary splicing with the side wall of the adjacent module unit 1. The length of the splicing part 3 protruding from the side wall of the module unit 1 is half the width of the connecting groove 102. This size design allows the splicing part 3 to form a tight fit with the connecting groove 102 when multiple module units 1 are spliced ​​laterally, improving the overall integrity of the lateral connection.

[0034] Reference Figure 2 The upper surface of the pin limiting part 2 has a recessed groove 203. The recessed groove 203 is mainly used for installing the sealing part 4. It can pre-position the sealing part 4 and prevent the sealing part 4 from shifting during installation. The sealing part 4 is inserted into the recessed groove 203 to seal the mounting hole 202.

[0035] Reference Figure 2 The outer edge of the recessed groove 203 extends toward the connecting block 101 to form two symmetrical strip-shaped mounting grooves 204. The strip-shaped mounting grooves 204 can guide and constrain the sealing wings 402 of the sealing member 4, ensuring that the sealing wings 402 are accurately embedded. The strip-shaped mounting grooves 204 connect the recessed groove 203 and the through hole 103 of the sealing block 201. The sealing member 4 includes a sealing cover plate 401 that is installed in conjunction with the recessed groove 203 and a sealing wing 402 embedded in the strip-shaped mounting groove 204. The sealing wing 402 extends into the through hole 103 and can directly contact the connecting member 5 and form a limit to prevent the connecting member 5 from moving axially.

[0036] Reference Figure 2 The recessed groove 203 has a stepped structure. The sealing cover plate 401 has a stepped portion 403 on the side facing the recessed groove 203 that matches the stepped structure of the recessed groove 203. The stepped structure increases the contact area between the sealing member 4 and the pin limiting part 2, improving the engagement stability and preventing the sealing member 4 from being over-embedded. The sealing member 4 covers the recessed groove 203, and the sealing member 4 and the recessed groove 203 on the module unit 1 form a detachable engaging connection. The sealing wing 402 can be inserted along the strip mounting groove 204 and engage with the groove wall. The close contact between the sealing wing 402 and the groove wall generates friction, further preventing the sealing member 4 from loosening. Several module units 1 are spliced ​​to form a conveyor belt. The recessed groove 203 on the conveyor module in the middle of the conveyor belt can be covered with a cover plate that matches the recessed groove 203, or it can be left uncovered.

[0037] Reference Figure 5 The sealing wing 402 partially or completely blocks the mounting hole 202 to restrict the axial movement of the connector 5.

[0038] Reference Figure 3 The lower surface of the pin limiting part 2 is provided with a disassembly through hole 205 corresponding to the recessed groove 203. The disassembly through hole 205 extends into the recessed groove 203. By inserting a tool through the disassembly through hole 205, the sealing member 4 can be pushed out of the recessed groove 203. The disassembly through hole 205 eliminates the need for top force to disassemble the sealing member 4, thus avoiding interference with the material on the conveying surface. The sealing member 4 can be fitted into the recessed groove 203 by an interference fit.

[0039] Reference Figure 3 The bottom surface of the module unit 1 is provided with a limiting part for cooperating with the track. The limiting part includes two parallel limiting plates 105. The limiting plates 105 protrude from the bottom of the module unit 1 and are perpendicular to the horizontal transport plane of the module unit 1. The outline of the limiting plates 105 matches the guide groove of the track, which can guide the module unit 1 to move stably along the track during the transport process and limit its horizontal deviation to a certain extent.

[0040] Reference Figure 2 and Figure 7 The upper side of the module unit 1 is a continuous support surface 106. The support surface 106 is designed without holes to avoid material jamming or dirt accumulation, ensuring a clean conveying environment. The lower side of the module unit 1 is a rib structure 107 formed on the lower side of the support surface 106. The rib structure 107 can reduce the weight of the module unit 1 while enhancing the structural strength of the support surface 106 and improving its load-bearing capacity.

[0041] Workflow and operating steps:

[0042] Module unit 1 splicing preparation: Arrange several module units 1 in a preset array direction, so that the connecting block 101 of adjacent module units 1 is aligned with the connecting groove 102, and the splicing part 3 is aligned with the splicing part 3 of adjacent module units 1.

[0043] Lateral splicing and positioning: Push the module unit 1 so that the connecting block 101 is embedded into the connecting groove 102 of the adjacent module unit 1, and the splicing part 3 is embedded into one side of the connecting groove 102 of the adjacent module unit 1, thus completing the initial positioning.

[0044] Installation of connector 5: Insert connector 5, such as a pin, through the mounting hole 202 of one side module unit 1, and sequentially through the mounting hole 202 of the sealing block 201 and the through hole 103 of the connector 101, until the end of connector 5 extends into the strip mounting groove 204 of the other side module unit 1.

[0045] Installation of sealing component 4: Align the sealing wing 402 of the sealing component 4 with the strip mounting groove 204 and insert it along the groove so that the stepped portion 403 of the sealing cover plate 401 fits against the stepped structure of the recessed groove 203 until the sealing wing 402 engages with the wall of the strip mounting groove 204, thus completing the limiting of the connector 5.

[0046] Overall assembly complete: All module units 1 are spliced ​​together in both directions to form a complete conveying surface. At this time, the limiting plate 105 on the bottom surface of module unit 1 is aligned with the track guide groove.

[0047] Track alignment: Place the assembled conveying module on the track, so that the limiting plate 105 is embedded in the track guide groove to achieve limiting and guiding during the conveying process.

[0048] Disassembly and maintenance of sealing component 4: When it is necessary to disassemble the connecting component 5, insert the tool into the disassembly through hole 205 on the lower surface of the pin limit part 2, push the sealing cover plate 401 of the sealing component 4, so that the sealing wing 402 is disengaged from the strip mounting groove 204, and the connecting component 5 can be pulled out after the sealing component 4 is removed.

[0049] The above are all preferred embodiments of this utility model, and are not intended to limit the scope of protection of this utility model. Therefore, all equivalent changes made to the structure, shape and principle of this utility model should be covered within the scope of protection of this utility model.

Claims

1. A conveying module, comprising a plurality of module units (1) arranged in a longitudinal and transverse array, wherein each module unit (1) has a connecting block (101) protruding at intervals and a connecting groove (102) recessed at intervals, the connecting block (101) of the module unit (1) being able to be embedded in the connecting groove (102) of adjacent module units (1), the connecting block (101) having a through hole (103) for a connector (5) to pass through, and the module units (1) being detachably connected to each other through the connector (5), characterized in that, A pin limiting part (2) is formed on one side of the module unit (1). A sealing part (4) is detachably provided on the pin limiting part (2). After the connecting part (5) is placed in the through hole (103), the pin is sealed and limited by installing the sealing part (4).

2. The conveying module according to claim 1, characterized in that, A sealing block (201) is protruding on the pin limiting part (2). The sealing block (201) and the connecting block (101) are arranged in the same direction and at the same interval. An installation hole (202) is formed on the sealing block (201). A sealing member (4) is detachably provided on the pin limiting part (2). After the connecting member (5) passes through the installation hole (202) and is placed in the through hole (103), the sealing member (4) seals the installation hole (202).

3. The conveying module according to claim 2, characterized in that, The width of the sealing block (201) is half the width of the connecting block (101). The side wall of the module unit (1) away from the pin limiting part (2) forms a splicing part (3). The splicing part (3) is a structure that protrudes from the side wall of the module unit (1). The length of the splicing part (3) protruding from the side wall of the module unit (1) is half the width of the connecting groove (102).

4. The conveying module according to claim 3, characterized in that, The upper surface of the pin limiting part (2) is formed with a recessed groove (203), and the sealing member (4) is inserted into the recessed groove (203) to seal the mounting hole (202).

5. The conveying module according to claim 4, characterized in that, The outer edge of the recessed groove (203) extends toward the connecting block (101) to form two symmetrical strip-shaped mounting grooves (204). The strip-shaped mounting grooves (204) connect the recessed groove (203) and the through hole (103) of the sealing block (201). The sealing component (4) includes a sealing cover plate (401) that is fitted with the recessed groove (203) and a sealing wing (402) that is embedded in the strip-shaped mounting groove (204). The sealing wing (402) extends into the through hole (103).

6. The conveying module according to claim 5, characterized in that, The recessed groove (203) has a stepped structure. The sealing cover plate (401) has a stepped portion (403) on the side facing the recessed groove (203) that matches the stepped structure of the recessed groove (203). The sealing member (4) covers the recessed groove (203). The sealing member (4) and the recessed groove (203) on the module unit (1) form a detachable snap-fit ​​connection. The sealing wing (402) can be inserted along the strip mounting groove (204) and snap-fit ​​with the groove wall.

7. The conveying module according to claim 6, characterized in that, The sealing wing (402) partially or completely seals the mounting hole (202) to restrict the axial movement of the connector (5).

8. The conveying module according to claim 7, characterized in that, The lower surface of the pin limiting part (2) is provided with a disassembly through hole (205) corresponding to the recessed groove (203). The disassembly through hole (205) extends through the recessed groove (203). By inserting a tool through the disassembly through hole (205), the sealing part (4) can be pushed out of the recessed groove (203).

9. The conveying module according to claim 8, characterized in that, The bottom surface of the module unit (1) is provided with a limiting part for cooperating with the track. The limiting part includes two mutually parallel limiting plates (105). The limiting plates (105) protrude from the bottom of the module unit (1). The limiting plates (105) are perpendicular to the transport horizontal plane of the module unit (1). The outline of the limiting plates (105) matches the guide groove of the track.

10. The conveying module according to claim 9, characterized in that, The upper side of the module unit (1) is a continuous support surface (106), and the lower side of the module unit (1) is a rib structure (107) formed on the lower side of the support surface (106).