Solid raw material dewatering equipment for three-proofing adhesive production
The solid raw material dewatering equipment, with its modular design and mechanical interlocking structure, solves the problems of long downtime and safety hazards in traditional equipment when changing molecular sieve particles, achieving rapid replacement and efficient sealing, and is suitable for the production of conformal adhesives.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- YIDU ZHIREN TECHNOLOGY CO LTD
- Filing Date
- 2025-06-09
- Publication Date
- 2026-06-26
Smart Images

Figure CN224415656U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the technical field of adhesive production, specifically relating to a solid raw material dehydration device for the production of three-proof adhesive. Background Technology
[0002] In the production of conformal adhesives (moisture-proof, mildew-proof, and salt spray-proof), the dehydration of solid raw materials is a crucial step in ensuring stable product performance. Traditional dehydration equipment (such as ovens and vacuum dryers) removes moisture from raw materials through heating or negative pressure, but this suffers from high energy consumption, low efficiency, or damage to the heat sensitivity of the materials. In recent years, with the development of new materials and precision chemicals, new dehydration equipment (such as microwave drying, molecular sieve adsorption, or low-temperature vacuum belt drying) has been gradually applied, achieving precise temperature control, reducing thermal stress, or combining with physical adsorption technology.
[0003] If the replacement of molecular sieve particles cannot be completed quickly, the equipment downtime will be extended, affecting the continuous production rhythm; the adsorption tower may absorb moisture when exposed to air for a long time, reducing the initial efficiency of the new molecular sieve; manual disassembly and assembly may cause particle breakage or dust leakage, which not only pollutes the environment but may also block downstream pipes or valves; if the system is not completely depressurized or cooled during the replacement, the residual high-temperature gas may cause safety hazards. Summary of the Invention
[0004] The purpose of this invention is to provide a solid raw material dehydration device for the production of conformal coatings, aiming 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 solid raw material dehydration device for the production of conformal coatings, comprising,
[0007] The supporting structure includes an adsorption tower, a pipe body fixedly installed on the top of the adsorption tower, and a sealing cover movably installed on the top of the pipe body;
[0008] The mounting mechanism includes a ring, a positioning component disposed on the outside of the ring, and a support column fixedly installed in the inner cavity of the ring.
[0009] The positioning assembly includes a shell fixedly installed on the outside of the ring sleeve, a groove formed on the outside of the shell sleeve, a quick-locking component disposed in the inner cavity of the groove, and a locking block movably locked in the inner cavity of the shell sleeve.
[0010] As a preferred embodiment of the present invention, the installation mechanism further includes a support plate fixedly installed on the top of the support column, and a lifting component disposed in the inner cavity of the housing.
[0011] As a preferred embodiment of the present invention, the positioning component further includes a connecting block fixedly installed on the outside of the card block, a limiting plate fixedly installed on the outside of the connecting block, and a card slot formed on the outside of the card block.
[0012] As a preferred embodiment of this utility model, the quick-release mechanism includes a fixing groove block fixedly installed on the outside of the housing, a return spring fixedly installed in the inner cavity of the fixing groove block, a rotating rod hinged to the inner cavity of the groove, and a locking plate fixedly installed on the outside of the rotating rod.
[0013] As a preferred embodiment of this utility model, one end of the card plate is rounded and is movably engaged in the inner cavity of the card slot.
[0014] As a preferred embodiment of this utility model, the lifting assembly includes a support spring fixedly installed in the inner cavity of the housing, a support plate fixedly installed on the top of the support spring, a limiting groove formed on the outer side of the support plate, and a limiting strip fixedly installed on the inner wall of the housing, wherein the limiting groove is movably engaged on the outer side of the limiting strip.
[0015] As a preferred embodiment of the present invention, the supporting mechanism further includes a box body and a molecular sieve particle plate movably placed in the inner cavity of the box body.
[0016] Compared with existing technologies, the advantages of this invention are as follows: The box and support plate enable rapid replacement of the molecular sieve particle plates, significantly reducing downtime and preventing production interruptions; the sealing cover and mechanically interlocked positioning components ensure the adsorption tower is sealed during disassembly and assembly, preventing moisture absorption or dust leakage; the spring support and limiting structure of the lifting component assist in a one-button release locking mechanism, reducing manual intervention and avoiding the risk of forced disassembly at high temperatures without pressure relief; and the pre-filled molecular sieve particle plates allow for direct replacement, eliminating particle breakage and pipeline contamination. These designs comprehensively improve replacement efficiency, safety, and sealing, solving the production bottlenecks and hidden dangers of traditional replacement methods. Attached Figure Description
[0017] To more clearly illustrate the technical solutions of the embodiments of this utility model, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort. Among them:
[0018] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0019] Figure 2 This is a partial cross-sectional view of the installation mechanism structure of this utility model;
[0020] Figure 3 This is a partial schematic diagram of the positioning component structure of this utility model;
[0021] Figure 4 This is a cross-sectional view of the card block structure of this utility model;
[0022] Figure 5 This is a cross-sectional view of the lifting component structure of this utility model.
[0023] In the picture:
[0024] 100. Supporting structure; 110. Adsorption tower; 120. Tube body; 130. Sealing cap; 140. Box body; 150. Molecular sieve particle plate;
[0025] 200. Installation mechanism; 210. Ring; 220. Positioning component; 221. Housing; 222. Groove; 223. Quick-release component; 2231. Fixing slot block; 2232. Return spring; 2233. Rotating rod; 2234. Locking plate; 224. Locking block; 225. Connecting block; 226. Limiting plate; 227. Locking groove; 230. Support column; 240. Support plate; 250. Lifting component; 251. Support spring; 252. Support plate; 253. Limiting groove; 254. Limiting strip. Detailed Implementation
[0026] To make the above-mentioned objectives, features and advantages of this utility model more apparent and understandable, the specific embodiments of this utility model will be described in detail below with reference to the accompanying drawings.
[0027] Many specific details are set forth in the following description in order to provide a full understanding of the present invention. However, the present invention may also be implemented in other ways different from those described herein. Those skilled in the art can make similar extensions without departing from the spirit of the present invention. Therefore, the present invention is not limited to the specific embodiments disclosed below.
[0028] Secondly, the term "an embodiment" or "embodiment" as used herein refers to a specific feature, structure, or characteristic that may be included in at least one implementation of the present invention. The phrase "in one embodiment" appearing in different places in this specification does not necessarily refer to the same embodiment, nor is it a single or selective embodiment that excludes other embodiments.
[0029] Example
[0030] Reference Figures 1-5 This embodiment of the present invention provides a solid raw material dehydration device for the production of conformal coatings, comprising:
[0031] The support structure 100 includes an adsorption tower 110, a tube 120 fixedly installed on the top of the adsorption tower 110, and a sealing cover 130 movably installed on the top of the tube 120.
[0032] The mounting mechanism 200 includes a ring 210, a positioning component 220 disposed on the outside of the ring 210, and a support column 230 fixedly installed in the inner cavity of the ring 210.
[0033] The positioning component 220 includes a housing 221 fixedly installed on the outside of the ring 210, a groove 222 opened on the outside of the housing 221, a quick-locking component 223 disposed in the inner cavity of the groove 222, and a locking block 224 movably locked in the inner cavity of the housing 221.
[0034] The modular installation of the adsorption tower 110 and the molecular sieve particle plate 150 is achieved through the coordinated design of the bearing mechanism 100 and the installation mechanism 200, which facilitates quick disassembly and maintenance. The quick-locking component 223 and the locking block 224 in the positioning component 220 form a mechanical interlocking structure to ensure a tight connection between the sealing cover 130 and the pipe body 120, avoid gas leakage, simplify the operation process, and improve the reliability of the equipment.
[0035] Specifically, the installation mechanism 200 also includes a support plate 240 fixedly installed on the top of the support column 230, and a lifting assembly 250 disposed in the inner cavity of the housing 221.
[0036] Among them, the support plate 240 provides stable support for the molecular sieve particle plate 150 to prevent uneven distribution due to airflow impact; the lifting component 250 automatically lifts the locking block 224 inside the shell 221 during disassembly, assisting in the quick release of the locking structure, reducing manual intervention, shortening maintenance time, and is especially suitable for high-frequency replacement of molecular sieve particle plate 150.
[0037] Furthermore, the positioning component 220 also includes a connecting block 225 fixedly installed on the outside of the card block 224, a limiting plate 226 fixedly installed on the outside of the connecting block 225, and a card slot 227 opened on the outside of the card block 224.
[0038] The connecting block 225 and the limiting plate 226 form a linkage mechanism to ensure that the movement trajectory of the card block 224 is controllable; the card slot 227 and the quick-release card 223 cooperate precisely to avoid locking failure caused by misoperation through mechanical limiting, thereby enhancing the stability of equipment operation.
[0039] Preferably, the quick-release component 223 includes a fixing slot 2231 fixedly installed on the outside of the housing 221, a return spring 2232 fixedly installed in the cavity of the fixing slot 2231, a rotating rod 2233 hinged in the cavity of the groove 222, and a locking plate 2234 fixedly installed on the outside of the rotating rod 2233. One end of the locking plate 2234 is rounded and is movably locked in the cavity of the locking groove 227.
[0040] Among them, the return spring 2232 drives the rotating rod 2233 to automatically reset, so that the locking plate 2234 always fits against the slot 227 to achieve one-way locking; the hinged rotating rod 2233 structure reduces the wear of the locking plate 2234 and extends its service life, while the rounded corner design reduces the risk of jamming. The rounded corner end of the locking plate 2234 is smoothly guided into the slot 227 when locked, avoiding structural deformation caused by hard collision; the movable locking method allows for micro-adjustment, adapts to manufacturing tolerances, and ensures that the sealing performance is not affected.
[0041] Furthermore, the lifting assembly 250 includes a support spring 251 fixedly installed in the inner cavity of the housing 221, a support plate 252 fixedly installed on the top of the support spring 251, a limiting groove 253 opened on the outer side of the support plate 252, and a limiting strip 254 fixedly installed on the inner wall of the housing 221, wherein the limiting groove 253 is movably engaged on the outer side of the limiting strip 254.
[0042] Among them, the support spring 251 and the support plate 252 work together to lift the locking block 224 out of the locked state during disassembly; the sliding cooperation between the limiting groove 253 and the limiting strip 254 prevents the support plate 252 from tilting, ensuring the verticality and stability of the lifting action, and further improving maintenance efficiency.
[0043] The support mechanism 100 also includes a box 140 and a molecular sieve particle plate 150 that is movably placed inside the box 140.
[0044] The box 140 serves as an independent container for the molecular sieve particle plate 150, facilitating overall removal and replacement and preventing particle spillage that could contaminate the equipment. The modular design supports pre-filling of the molecular sieve particle plate 150, reducing downtime and making it suitable for continuous production needs.
[0045] In use, the box 140 pre-loaded with molecular sieve particle plates 150 is placed into the support plate 240. The sealing cover 130 is connected to the adsorption tower 110 through the pipe 120. When the sealing cover 130 is pressed down, the locking block 224 is pre-lifted by the support spring 251 of the lifting component 250. The locking plate 2234 of the quick-locking component 223 is automatically locked into the slot 227 under the action of the reset spring 2232, completing the mechanical locking and ensuring the seal. Moisture enters the adsorption tower 110 from the pipe 120, is adsorbed and dehydrated by the molecular sieve particle plates 150 and then discharged. The support plate 240 keeps the molecular sieve particle plates 150 stable and avoids uneven distribution caused by airflow impact.
[0046] During disassembly, press the rotating rod 2233 to release the locking plate 2234. The support spring 251 pushes the support plate 252 to lift the locking block 224, allowing the sealing cover 130 to quickly detach. The box body 140 can be removed as a whole to replace the new molecular sieve particle plate 150. The limiting groove 253 and the limiting strip 254 ensure that there is no deviation during the lifting process. No complicated tools are required throughout the process, which greatly improves maintenance efficiency.
[0047] In summary, the modular design of the bearing mechanism 100 and the installation mechanism 200 enables rapid replacement and maintenance of the molecular sieve particle plate 150. The mechanical interlocking structure of the positioning component 220 ensures sealing and prevents gas leakage. The lifting component 250, together with the support plate 240, provides stable support and prevents airflow disturbance from affecting dewatering efficiency. The independent container design of the box body 140 simplifies the replacement process of the molecular sieve particle plate 150 and reduces downtime. Meanwhile, detailed structures such as the reset spring 2232 and the limit groove 253 improve the smoothness of operation and equipment reliability, making it particularly suitable for continuous production scenarios requiring high-frequency maintenance.
[0048] It is important to note that the constructions and arrangements of this application shown in several different exemplary embodiments are merely illustrative. Although only a few embodiments are described in detail in this disclosure, those who consult this disclosure will readily understand that many modifications are possible (e.g., changes in the size, dimensions, structure, shape and proportion of various elements, as well as parameter values (e.g., temperature, pressure, etc.), mounting arrangements, use of materials, color, orientation, etc.) without substantially departing from the novel teachings and advantages of the subject matter described in this application). For example, an element shown as integrally formed may be composed of multiple parts or elements, the position of elements may be inverted or otherwise altered, and the nature or number or position of discrete elements may be changed or altered. Therefore, all such modifications are intended to be included within the scope of this utility model. The order or sequence of any process or method steps may be changed or reordered according to alternative embodiments. In the claims, any "device plus function" clause is intended to cover the structure described herein that performs the function, and not only structural equivalents but also equivalent structures. Without departing from the scope of this invention, other substitutions, modifications, alterations, and omissions may be made in the design, operation, and arrangement of the exemplary embodiments. Therefore, this invention is not limited to the specific embodiments, but extends to various modifications that still fall within the scope of the appended claims.
[0049] Furthermore, in order to provide a concise description of exemplary embodiments, not all features of actual embodiments (i.e., those features that are not relevant to the best mode of carrying out the present invention as currently considered, or those features that are not relevant to implementing the present invention) may be omitted.
[0050] It should be understood that numerous specific implementation decisions can be made during the development of any practical implementation, such as in any engineering or design project. Such development efforts may be complex and time-consuming, but for those skilled in the art who benefit from this disclosure, the development effort will be a routine work of design, manufacturing, and production without requiring much experimentation.
[0051] It should be noted that the above embodiments are only used to illustrate the technical solution 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 solution of this utility model without departing from the spirit and scope of the technical solution 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 solid raw material dehydration device for the production of conformal coatings, characterized in that: include, The support structure (100) includes an adsorption tower (110), a tube (120) fixedly installed on the top of the adsorption tower (110), and a sealing cap (130) movably installed on the top of the tube (120). The mounting mechanism (200) includes a ring (210), a positioning component (220) disposed on the outside of the ring (210), and a support (230) fixedly installed in the inner cavity of the ring (210). The positioning component (220) includes a housing (221) fixedly installed on the outside of the ring (210), a groove (222) opened on the outside of the housing (221), a quick-locking component (223) disposed in the inner cavity of the groove (222), and a locking block (224) movably locked in the inner cavity of the housing (221).
2. The solid raw material dehydration equipment for producing conformal coatings according to claim 1, characterized in that: The mounting mechanism (200) also includes a support plate (240) fixedly mounted on the top of the support column (230) and a lifting assembly (250) disposed in the inner cavity of the housing (221).
3. The solid raw material dehydration equipment for producing conformal coatings according to claim 2, characterized in that: The positioning component (220) further includes a connecting block (225) fixedly installed on the outside of the card block (224), a limiting plate (226) fixedly installed on the outside of the connecting block (225), and a card slot (227) opened on the outside of the card block (224).
4. The solid raw material dehydration equipment for producing conformal coatings according to claim 3, characterized in that: The quick-release component (223) includes a fixed groove block (2231) fixedly installed on the outside of the housing (221), a return spring (2232) fixedly installed in the cavity of the fixed groove block (2231), a rotating rod (2233) hinged in the cavity of the groove (222), and a locking plate (2234) fixedly installed on the outside of the rotating rod (2233).
5. The solid raw material dehydration equipment for producing conformal coatings according to claim 4, characterized in that: One end of the card plate (2234) is rounded and is movably engaged in the inner cavity of the card slot (227).
6. The solid raw material dehydration equipment for producing conformal coatings according to claim 5, characterized in that: The lifting assembly (250) includes a support spring (251) fixedly installed in the inner cavity of the housing (221), a support plate (252) fixedly installed on the top of the support spring (251), a limiting groove (253) opened on the outside of the support plate (252), and a limiting strip (254) fixedly installed on the inner wall of the housing (221). The limiting groove (253) is movably engaged on the outside of the limiting strip (254).
7. A solid raw material dehydration device for producing conformal coatings according to claim 6, characterized in that: The support mechanism (100) also includes a box (140) and a molecular sieve particle plate (150) movably placed inside the box (140).