A gluing and water removing mechanism

By using the coordinated movement of the transposition and clamping components on the suspension conveyor, the problem of difficult drying of rubber sheets in the suspended position is solved, achieving full drying of rubber sheets and improving processing stability and product quality.

CN224327497UActive Publication Date: 2026-06-05SAARGUMMI CHINA INVESTMENT CO LTD +2

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SAARGUMMI CHINA INVESTMENT CO LTD
Filing Date
2025-05-09
Publication Date
2026-06-05

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  • Figure CN224327497U_ABST
    Figure CN224327497U_ABST
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Abstract

The utility model relates to a kind of glue hanging water removal mechanism, install in suspension rod conveyor, the suspension rod conveyor has multiple for suspending rubber sheet body suspension rod, the glue hanging water removal mechanism includes: transposition component, slidingly set on the rack;Two clamping components, oppositely set on the transposition component, to clamp the two sides of rubber sheet body on one of suspension rod, and under the action of the transposition component, to realize the up-and-down alternate motion of two clamping components.The glue hanging water removal mechanism of the utility model, by the up-and-down alternate motion of clamping component, the part of rubber sheet body that is in contact with suspension rod is constantly changed, so that the part that is originally in contact with suspension rod is separated from contact area, exposed under air cooling airflow, to facilitate comprehensive blow-drying, avoid partial moisture residue, to ensure the stability of subsequent processing technology.
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Description

Technical Field

[0001] This utility model relates to the technical field of rubber processing equipment, specifically to a rubber coating and water removal mechanism. Background Technology

[0002] Sealing strips are sealing elements commonly used in automobiles, doors and windows, and machinery. They are typically made of rubber to ensure good sealing performance and flexibility. The raw material for sealing strips is usually rubber sheet, which undergoes extrusion molding, cooling, dehydration, and cutting processes during production. In existing technology, after extrusion molding, the rubber sheet is usually fixed to a suspension conveyor by a hanging method, relying on the continuous conveyor and a matching air-cooling device to dry and cool the rubber sheet.

[0003] However, since the rubber sheet is suspended on the suspension rod of the suspension conveyor, the part of the rubber sheet in contact with the suspension rod is difficult to be directly blown by the air-cooled airflow. As a result, the moisture in these parts cannot be effectively removed, and local residual moisture is likely to occur, which in turn affects the subsequent processing technology and the quality of the sealing strip product. Summary of the Invention

[0004] In view of the shortcomings of the existing technology, the purpose of this utility model is to provide a rubber coating and water removal mechanism to solve the problem that in the related technology, the part of the rubber sheet suspended on the suspension rod of the suspension conveyor is difficult to be directly blown by the air-cooled airflow, which easily leads to local residual moisture.

[0005] To achieve the above objectives, the present invention adopts the following technical solution:

[0006] A rubber-coated dewatering mechanism is installed on a suspension conveyor, the suspension conveyor having multiple suspension rods for suspending the rubber sheet body, including:

[0007] The transposition assembly is slidably mounted on the frame of the suspension conveyor;

[0008] Two clamping components are disposed opposite to the shifting component to clamp the two sides of the rubber sheet body on one of the suspension rods, and under the action of the shifting component, the two clamping components can move up and down alternately.

[0009] Compared with the prior art, the present invention has the following beneficial effects:

[0010] 1. Through the alternating up and down movement of the clamping components, the contact area between the rubber sheet body and the suspension rod is constantly changed, causing the part that was originally in contact with the suspension rod to detach from the contact area and be exposed to the air-cooled airflow, so as to facilitate thorough drying, avoid local moisture residue, and thus ensure the stability of its subsequent processing.

[0011] 2. This mechanism is applicable to rubber sheet bodies of different specifications and thicknesses, and the structure of the transposition component and clamping component is flexible. The parameters can be adjusted according to actual production needs, and it has good versatility and applicability.

[0012] Furthermore, the shifting assembly includes two shifting cylinders slidably disposed on the frame along the Y-axis direction, and each shifting cylinder has a connecting plate at its telescopic end, with the two clamping assemblies respectively disposed on the two connecting plates.

[0013] Furthermore, the clamping assembly includes a clamping cylinder disposed on the connecting plate, and a moving clamping plate is provided at the telescopic end of the clamping cylinder; a fixed clamping plate corresponding to the moving clamping plate is provided at the end of the connecting plate away from the clamping cylinder; the clamping cylinder is perpendicular to the shifting cylinder.

[0014] Furthermore, it also includes a drive assembly, which is mounted on the frame and connected to the shifting assembly, to drive the shifting assembly to slide along the Y-axis direction, so as to enable the two clamping assemblies to move closer to or further away from the rubber sheet body.

[0015] Furthermore, the drive assembly includes a mounting plate disposed on the frame and a drive cylinder disposed on the mounting plate. The extension and retraction end of the drive cylinder is provided with a fixed plate, and the shifting assembly is disposed on the fixed plate. The drive cylinder is perpendicular to the shifting cylinder.

[0016] Furthermore, the adhesive coating and water removal mechanism consists of two sets, which are installed on two opposite surfaces of the frame.

[0017] Furthermore, the frame is equipped with a first air-cooling device and a second air-cooling device. The first air-cooling device is used to dry the outer side of the rubber sheet body, and the second air-cooling device is used to dry the inner side of the rubber sheet body.

[0018] Furthermore, the second air-cooling device is located on both sides of the adhesive-coating and dehydration mechanism. Attached Figure Description

[0019] Appendix Figure 1 This embodiment shows a three-dimensional structural diagram of the adhesive coating and water removal mechanism installed on the suspension conveyor.

[0020] Appendix Figure 2 This embodiment shows a side view of the adhesive coating and water removal mechanism installed on the suspension conveyor.

[0021] Appendix Figure 3 This embodiment presents a schematic diagram of the structure in which the adhesive coating and water removal mechanism works in conjunction with the rubber sheet body.

[0022] Appendix Figure 4 Schematic diagram of the adhesive coating and water removal mechanism in this embodiment Figure 1 ;

[0023] Appendix Figure 5 Schematic diagram of the adhesive coating and water removal mechanism in this embodiment Figure 2 ;

[0024] Explanation of icon numbers:

[0025] 10. Suspension conveyor; 11. Frame; 12. Suspension rod; 13. First air-cooling unit; 14. Second air-cooling unit

[0026] 20. Transposition assembly; 21. Transposition cylinder; 22. Connecting plate;

[0027] 30. Clamping assembly; 31. Clamping cylinder; 32. Moving clamping plate; 33. Fixed clamping plate;

[0028] 40. Drive assembly; 41. Mounting plate; 42. Drive cylinder; 43. Fixing plate;

[0029] 50. Rubber sheet body.

[0030] The realization of the purpose, functional features and advantages of this utility model will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation

[0031] To make the objectives, technical solutions, and beneficial effects of this utility model clearer, the technical solutions of this utility model are further described below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of this utility model and are not intended to limit it.

[0032] In the description of this utility model, it should be noted that the structures, proportions, sizes, etc., illustrated in the accompanying drawings are only for illustrative purposes to aid those skilled in the art and to facilitate understanding and reading. They are not intended to limit the implementation conditions of this utility model and therefore have no substantial technical significance. Any modifications to the structure, changes in proportions, or adjustments to the size, without affecting the effects and objectives of this utility model, should still fall within the scope of the technical content disclosed in this utility model. Furthermore, the terms such as "upper," "lower," "left," "right," "middle," and "one" used in this specification are merely for clarity and not intended to limit the scope of implementation of this utility model. Changes or adjustments to their relative relationships, without substantially altering the technical content, should also be considered within the scope of implementation of this utility model.

[0033] like Figure 1-5As shown in the figure, this utility model embodiment proposes a glue-coating and dewatering mechanism, which is installed on a suspension conveyor 10. The suspension conveyor 10 has multiple suspension rods 12 for suspending rubber sheet bodies 50. The glue-coating and dewatering mechanism includes a shifting component 20 and two clamping components 30. The shifting component 20 is slidably disposed on the frame 11 of the suspension conveyor 10. The two clamping components 30 are disposed opposite to the shifting component 20 to clamp the two sides of the rubber sheet body 50 on one of the suspension rods 12, and under the action of the shifting component 20, the two clamping components 30 move up and down alternately. It should be understood that the above-mentioned suspension conveyor 10 is a conventional device in the art, such as a so-called rod-type conveyor structure, in which multiple suspension rods 12 are driven by chains to drive sprockets intermittently to achieve sequential conveying. Since this utility model does not make any improvements to it, its specific structure and working method will not be described in detail here.

[0034] In this embodiment of the invention, during operation, after the rubber sheet body 50 moves with the suspension conveyor 10 to the glue-coating and dehydration mechanism, two clamping components 30 mounted on the switching component 20 respectively clamp the two sides of the rubber sheet body 50 on the suspension rod 12 at that position. Then, driven by the switching component 20, the two clamping components 30 alternately move up and down in the vertical direction. When one clamping component 30 moves upward, the other clamping component 30 moves downward, thereby causing the corresponding positions on both sides of the rubber sheet body 50 to move accordingly. Through the alternating up and down movement of the clamping components 30, the contact area between the rubber sheet body 50 and the suspension rod 12 continuously changes, causing the part that was originally in contact with the suspension rod 12 to separate from the contact area and be exposed to the air-cooled airflow, facilitating thorough drying and avoiding local moisture residue, thereby ensuring the stability of its subsequent processing. Finally, after the switching and dehydration action is completed, the clamping components 30 are released, and the rubber sheet body 50 continues to move.

[0035] Specifically, such as Figure 4-5 As shown in the present invention, the shifting component 20 includes two shifting cylinders 21 slidably disposed on the frame 11 along the Y-axis direction. Each shifting cylinder 21 has a connecting plate 22 at its telescopic end. The two clamping components 30 are respectively disposed on the two connecting plates 22.

[0036] During operation, driven by the shifting assembly 20, the two shifting cylinders 21 alternately extend and retract, driving their respective connecting plates 22 to move up and down along the Y-axis. Thus, the movement of the connecting plates 22 causes the clamping assembly 30 located on them to move up and down synchronously. The clamping assembly 30 clamps both sides of the rubber sheet body 50 and partially shifts the rubber sheet body 50, causing the contact position between the rubber sheet body 50 and the suspension rod 12 to continuously change. This avoids the problem of uneven drying caused by prolonged contact between certain parts and the suspension rod 12.

[0037] Specifically, after the clamping assembly 30 clamps the rubber sheet, the shifting cylinder 21 moves up and down, causing the clamping assembly 30 to move up and down alternately, thus changing the contact area between the rubber sheet body 50 and the suspension rod 12. This local shifting process ensures that every area of ​​the rubber sheet body 50 can be thoroughly dried by the air-cooling device, thereby avoiding drying dead spots caused by the suspension rod 12 and ensuring uniform drying and dehydration of the outer and inner surfaces of the rubber sheet body 50.

[0038] Through this repositioning process, all areas of the rubber sheet body 50 surface are effectively exposed to the air-cooling device. Whether it is the side closer to the suspension rod 12 or the side farther away from the suspension rod 12, the consistency and thoroughness of the drying effect are ensured, ultimately achieving complete drying and dehydration of the rubber sheet body 50. This process not only improves drying efficiency but also effectively avoids residue in localized damp areas, contributing to improved product quality.

[0039] Specifically, such as Figure 4-5 As shown in the present invention embodiment, the clamping assembly 30 includes a clamping cylinder 31 disposed on the connecting plate 22, and a moving clamping plate 32 is provided at the telescopic end of the clamping cylinder 31; a fixed clamping plate 33 corresponding to the moving clamping plate 32 is provided at one end of the connecting plate 22 away from the clamping cylinder 31; the clamping cylinder 31 is perpendicular to the shifting cylinder 21.

[0040] During operation, driven by the clamping cylinder 31, the telescopic end drives the moving clamping plate 32 to move along the X-axis. The moving clamping plate 32 is arranged opposite to the fixed clamping plate 33. Through the operation of the clamping cylinder 31, both sides of the rubber sheet body 50 on the suspension rod 12 can be effectively clamped. In this way, the clamping assembly 30 can realize the clamping and releasing functions on both sides of the rubber sheet body 50, ensuring that the rubber sheet body 50 does not slip or loosen during the repositioning process, thereby providing a stable repositioning process.

[0041] After clamping the rubber sheet body 50, the shifting cylinder 21 drives the clamping assembly 30 to move alternately up and down along the Y-axis with the connecting plate 22. In this way, the clamping assembly 30 moves the two sides of the rubber sheet body 50, gradually changing the contact area between the rubber sheet body 50 and the suspension rod 12, completing a partial shift. Through this shifting process, the area that was originally in contact with the suspension rod 12 is exposed, ensuring that this area can be dried by the air-cooling device.

[0042] Based on the above solutions, such as Figure 2 As shown in this embodiment of the present invention, the adhesive coating and water removal mechanism further includes a drive component 40, which is mounted on the frame 11 and connected to the shifting component 20. The drive component 40 drives the shifting component 20 to slide along the Y-axis, thereby allowing the two clamping components 30 to move closer to or further away from the rubber sheet body 50. In the clamped state, the drive component 40 drives the shifting component 20 to move up and down alternately along the Y-axis, thereby changing the contact position between the rubber sheet body 50 and the suspension rod 12. The drive component 40 can be a conventional linear drive mechanism such as a hydraulic cylinder, pneumatic cylinder, electric push rod, or lead screw, which can drive the shifting component 20 to move up and down along the Y-axis as needed.

[0043] Specifically, in this embodiment of the present invention, the drive assembly 40 includes a mounting plate 41 disposed on the frame 11 and a drive cylinder 42 disposed on the mounting plate 41. The extension end of the drive cylinder 42 is provided with a fixing plate 43, and the shifting assembly 20 is disposed on the fixing plate 43. The drive cylinder 42 is perpendicular to the shifting cylinder 21.

[0044] During operation, the extension end of the drive cylinder 42 drives the fixed plate 43 to move along the Y-axis. Simultaneously, the shifting component 20 installed on the fixed plate 43 also moves linearly, thereby realizing the action of the clamping component 30 moving closer to or further away from the rubber sheet body 50 along the Y-axis. That is, the shifting cylinder 21 controls the clamping component 30 to clamp or release the rubber sheet body 50. Through the cooperation of the two, the contact position between the rubber sheet body 50 and the suspension rod 12 is effectively changed, ensuring that the surface of the rubber sheet body 50 is completely dried.

[0045] like Figure 2-3 As shown, in one embodiment of this utility model, the adhesive coating and water removal mechanism consists of two sets, which are installed on two opposite surfaces of the frame 11. This allows the suspension conveyor 10 to simultaneously transport two sets of rubber sheet bodies 50, resulting in higher processing efficiency.

[0046] Specifically, such as Figure 2-3As shown in this embodiment of the invention, the frame 11 is equipped with a first air-cooling device 13 and a second air-cooling device 14. The first air-cooling device 13 is used to dry the outer side of the rubber sheet body 50, and the second air-cooling device 14 is used to dry the inner side of the rubber sheet body 50. The second air-cooling device 14 is located on both sides of the adhesive coating and dehydration mechanism. The first air-cooling device 13 and the second air-cooling device 14 are conventional air-cooling devices, such as fan devices, so their structures will not be described in detail here. By having the first air-cooling device 13 and the second air-cooling device 14 act on the inner and outer sides of the rubber sheet body 50 respectively, uneven drying caused by hanging obstruction is avoided. At the same time, the second air-cooling device 14 is located on both sides of the adhesive coating and dehydration mechanism, specifically drying the inner side of the rubber sheet body 50 (i.e., the side near the suspension rod 12). With the help of the adhesive coating and dehydration mechanism, the rubber sheet body 50 is partially repositioned, exposing the area that was originally in contact with the suspension rod 12, and effectively drying the inner side in conjunction with the second air-cooling device 14.

[0047] Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of this utility model and are not intended to limit it. Although this utility model has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solutions of this utility model without departing from the spirit and scope of the technical solutions of this utility model, and all such modifications or substitutions should be covered within the scope of the claims of this utility model.

Claims

1. A rubber-coating dewatering mechanism, installed on a suspension conveyor (10), the suspension conveyor (10) having a plurality of suspension rods (12) for suspending a rubber sheet body (50), characterized in that, include: The transposition assembly (20) is slidably mounted on the frame (11) of the suspension conveyor (10); Two clamping components (30) are disposed opposite to the shifting component (20) to clamp the two sides of the rubber sheet body (50) on one of the suspension rods (12), and under the action of the shifting component (20), the two clamping components (30) move up and down alternately.

2. The adhesive-coating and water-removing mechanism according to claim 1, characterized in that, The shifting assembly (20) includes two shifting cylinders (21) that are slidably disposed on the frame (11) along the Y-axis direction. Each shifting cylinder (21) has a connecting plate (22) at its telescopic end. The two clamping assemblies (30) are respectively disposed on the two connecting plates (22).

3. The adhesive-coating and water-removing mechanism according to claim 2, characterized in that, The clamping assembly (30) includes a clamping cylinder (31) disposed on the connecting plate (22), and a moving clamping plate (32) is provided at the telescopic end of the clamping cylinder (31); a fixed clamping plate (33) corresponding to the moving clamping plate (32) is provided at one end of the connecting plate (22) away from the clamping cylinder (31); the clamping cylinder (31) is perpendicular to the shifting cylinder (21).

4. A glue-coating and water-removing mechanism according to any one of claims 2-3, characterized in that, It also includes a drive assembly (40), which is mounted on the frame (11) and connected to the shifting assembly (20) to drive the shifting assembly (20) to slide along the Y-axis direction so that the two clamping assemblies (30) can move closer to or further away from the rubber sheet body (50).

5. The adhesive-coating and water-removing mechanism according to claim 4, characterized in that, The drive assembly (40) includes a mounting plate (41) disposed on the frame (11) and a drive cylinder (42) disposed on the mounting plate (41). The extension end of the drive cylinder (42) is provided with a fixing plate (43). The shifting assembly (20) is disposed on the fixing plate (43). The drive cylinder (42) is perpendicular to the shifting cylinder (21).

6. The adhesive-coating and water-removing mechanism according to claim 5, characterized in that, The adhesive-coating and water-removing mechanism consists of two sets, which are installed on two opposite surfaces of the frame (11).

7. The adhesive-coating and water-removing mechanism according to claim 1, characterized in that, The frame (11) is provided with a first air-cooling device (13) and a second air-cooling device (14). The first air-cooling device (13) is used to dry the outer side of the rubber sheet body (50), and the second air-cooling device (14) is used to dry the inner side of the rubber sheet body (50).

8. The adhesive coating and water removal mechanism according to claim 7, characterized in that, The second air-cooling device (14) is located on both sides of the adhesive-coated water removal mechanism.