A disperser for the production of anticorrosive materials

CN224388549UActive Publication Date: 2026-06-23TIANJIN VERISANT TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
TIANJIN VERISANT TECH CO LTD
Filing Date
2025-04-29
Publication Date
2026-06-23

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Abstract

The utility model relates to the technical field of dispersion machine discloses a dispersion machine for anticorrosion material production, including bearing mechanism, the bearing mechanism is slidably connected with the dispersion mechanism of opposite through telescopic mechanism, still include the linkage clamping mechanism for automatic clamping mixing bowl between the dispersion mechanism of opposite and bearing mechanism, the dispersion mechanism of opposite includes installation assembly, sets up the drive assembly on installation assembly, drive assembly is connected with conversion subassembly, and conversion subassembly is connected with first dispersion subassembly and second dispersion subassembly of turning opposite. The utility model has the advantages that: through setting the dispersion mechanism of opposite can form the reverse rotational flow to the liquid in mixing bowl, has improved dispersion effect, through setting linkage clamping mechanism can be beforehand to mixing bowl self -fixing before carrying out dispersion raw material, has dispensed with the separate fixing step, has improved dispersion efficiency.
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Description

Technical Field

[0001] This utility model relates to the technical field of dispersers, specifically to a disperser for the production of anti-corrosion materials. Background Technology

[0002] In the production process of anti-corrosion coatings, various raw materials need to be added into the mixing drum, and then dispersed by a disperser. In the existing technology, the disperser is usually moved to the mixing drum and the disperser head is inserted into the mixing drum to disperse the raw materials. However, due to vibration and other reasons during the dispersion process, the raw material drum needs to be fixed separately, and moving the disperser is also time-consuming and labor-intensive. Moreover, the dispersion mechanism in the existing technology has an unsatisfactory dispersion effect due to its unidirectional rotation. Utility Model Content

[0003] The main inventive concept of this application is as follows: by studying the prior art, a method is provided to pre-fix the mixing cylinder in a linkage manner when dispersing materials in the mixing cylinder, eliminating the need for a separate fixing step. During dispersion, the mixing cylinder is fed to the disperser by a feeding robot or the like. A counter-dispersion component is designed during the dispersing process to improve the dispersion effect.

[0004] Therefore, this application proposes a disperser for the production of anti-corrosion materials, including a carrying mechanism, on which a counter-dispersing mechanism is slidably connected via a telescopic mechanism, and further including a linkage clamping mechanism for automatically clamping a mixing cylinder disposed between the counter-dispersing mechanism and the carrying mechanism.

[0005] The opposing dispersion mechanism includes a mounting component and a drive component mounted on the mounting component. The drive component is driven by a conversion component, and the conversion component is connected to a first dispersion component and a second dispersion component with opposite directions.

[0006] By adopting the above technical solution: the supporting mechanism is used to fix the disperser and to support the mixing cylinder. By setting the opposing dispersion mechanism, the liquid in the mixing cylinder can form a counter-current swirling flow, which improves the dispersion effect. By setting the linkage clamping mechanism, the mixing cylinder can be fixed in advance before the raw materials are dispersed, eliminating the need for a separate fixing step.

[0007] Preferably, the supporting mechanism includes a supporting base plate, on which a hollow cavity plate is provided; the opposing dispersion mechanism is slidably mounted on the cavity plate.

[0008] By adopting the above technical solution: the supporting substrate is used to place the mixing cylinder, and the cavity plate is used to slide and install the above-mentioned opposing dispersion mechanism.

[0009] Preferably, the mounting assembly includes a vertical plate slidably connected within the cavity plate, with a mounting plate connected to the upper end of the vertical plate; the telescopic mechanism is installed between the cavity plate and the vertical plate.

[0010] Preferably, the telescopic mechanism includes a telescopic power component fixed to the cavity plate, and the telescopic shaft of the telescopic power component is connected to the mounting plate.

[0011] By adopting the above technical solution, the telescopic mechanism can drive the upright plate to slide up and down relative to the cavity plate, thereby allowing the mounting plate to move up and down relative to each other.

[0012] Preferably, the drive assembly includes a drive motor fixed on a mounting plate, a retainer is provided on the lower side of the mounting plate, a retainer plate is connected to the lower end of the retainer, the shaft of the drive motor is drivenly connected to a conversion assembly mounted on the retainer plate, and the conversion assembly is drivenly connected to a first dispersion assembly and a second dispersion assembly.

[0013] By adopting the above technical solution, the drive motor can deliver power to the conversion component, which can drive the first dispersion component and the second dispersion component to rotate in opposite directions, thereby enabling better dispersion of the raw materials.

[0014] Preferably, the conversion assembly includes a housing connected to a retaining plate, a drive shaft rotatably disposed inside the housing and connected to the drive motor shaft, the lower end of the drive shaft passing through the housing and connected to a first dispersion assembly; the drive shaft is provided with a driving bevel gear, two transmission bevel gears meshing with the driving bevel gear are rotatably connected to both sides inside the housing, a driven bevel gear is rotatably connected to the bottom wall of the housing via a sleeve shaft, the drive shaft passes through the sleeve shaft, and the sleeve shaft extends out of the housing and is connected to a second dispersion assembly.

[0015] By adopting the above technical solution: the transmission shaft can drive the first dispersion component to rotate, for example, clockwise. Through the transmission of the driving bevel gear, the transmission bevel gear and the driven bevel gear, the rotation direction of the sleeve shaft is opposite to that of the transmission shaft, thereby making the rotation direction of the second dispersion component opposite to that of the first dispersion component.

[0016] Preferably, the first dispersion component includes a plurality of first dispersion plates disposed on the drive shaft, and the second dispersion component includes a rotating frame connected to the sleeve shaft, wherein the rotating frame is provided with a plurality of second dispersion plates, and the first dispersion plates and the second dispersion plates are disposed at intervals.

[0017] By adopting the above technical solution, the first dispersion plate and the second dispersion plate rotate in opposite directions, thereby forming a countercurrent dispersion and improving the dispersion effect.

[0018] Preferably, the linkage clamping mechanism includes a clamping component that slides on the support substrate via a spring, and a linkage component disposed between the upright plate and the cavity plate that triggers the clamping component to move.

[0019] By adopting the above technical solution: the clamping component is used to clamp the mixing cylinder, and the linkage component is used to drive the clamping component to move.

[0020] Preferably, the clamping assembly includes clamping plates that are slidably disposed on the support substrate by means of springs. Two clamping plates are disposed opposite each other, and a passive inclined surface is provided on the side of the two clamping plates that is far apart from each other.

[0021] Preferably, the linkage component includes a groove formed in the cavity plate, a connecting rod fixed to the upright plate, the connecting rod being located inside the groove, and an L-shaped actuating rod connected to the connecting rod.

[0022] By adopting the above technical solution: when the mixing cylinder is placed on the supporting substrate, the cylinder opening is aligned with the first and second dispersion components. At this time, the telescopic power component drives the mounting plate to move down, and the first and second dispersion components move down synchronously. During the downward movement, after the L-shaped trigger rod contacts the passive inclined surface, it pushes the two clamping plates closer to each other, thereby clamping and fixing the mixing cylinder. After dispersion is completed, as the telescopic mechanism drives the mounting plate to return to its original position, the L-shaped trigger rod gradually releases contact with the passive inclined surface. Under the pull of the spring, it gradually resets, thus releasing the clamping of the mixing cylinder, making it easy to remove the mixing cylinder and complete the dispersion. The overall action is ingeniously linked, eliminating the need for a separate fixing step.

[0023] The working principle and beneficial effects of this application are as follows:

[0024] 1. The supporting mechanism in this application serves two purposes: firstly, it facilitates the fixing of the disperser, and secondly, it supports the mixing cylinder. By setting the opposing dispersion mechanism, the liquid in the mixing cylinder can form a counter-current swirling flow, which improves the dispersion effect. By setting the linkage clamping mechanism, the mixing cylinder can be pre-fixed before the raw materials are dispersed, eliminating the need for a separate fixing step.

[0025] 2. When the mixing cylinder is placed on the support base plate, the cylinder opening is aligned with the first and second dispersion components. At this time, the telescopic power component drives the mounting plate to move down, and the first and second dispersion components move down synchronously. During the downward movement, the L-shaped actuating rod contacts the passive inclined surface and pushes the two clamping plates closer to each other, thereby clamping and fixing the mixing cylinder. After dispersion is completed, as the telescopic mechanism drives the mounting plate to return to its original position, the L-shaped actuating rod gradually releases contact with the passive inclined surface and gradually resets under the pull of the spring. At this time, the clamping of the mixing cylinder is released, making it easy to remove the mixing cylinder and complete the dispersion. The overall action is ingeniously linked, eliminating the need for a separate fixing step. Attached Figure Description

[0026] The present application will now be described in further detail with reference to the accompanying drawings and specific embodiments.

[0027] Figure 1 This is a schematic diagram of the overall structure of the front view of an embodiment of this application;

[0028] Figure 2 This is a schematic diagram of the overall structure of a side view of an embodiment of this application;

[0029] Figure 3 Examples of embodiments of this application Figure 1 Enlarged structural diagram at point A in the middle.

[0030] The features in the attached diagram are labeled as follows:

[0031] 100, Supporting mechanism; 110, Supporting base plate; 120, Cavity plate; 200, Telescopic mechanism; 300, Opposing dispersion mechanism; 310, Vertical plate; 320, Mounting plate; 330, Drive motor; 340, Cage; 350, Cage plate; 360, Housing; 361, Drive shaft; 362, Driving bevel gear; 363, Transmission bevel gear; 364, Sleeve shaft; 365, Driven bevel gear; 370, First dispersion plate; 380, Rotating frame; 390, Second dispersion plate; 400, Linkage clamping mechanism; 410, Spring; 420, Clamping plate; 430, Passive inclined surface; 440, Slide groove; 450, Connecting rod; 460, L-shaped actuating rod. Detailed Implementation

[0032] The technical solutions of this utility model will be clearly and completely described below with reference to the embodiments of this utility model. Obviously, the described embodiments are only some embodiments of this utility model, and not all embodiments. Based on the embodiments of this utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the scope of protection of this utility model.

[0033] The main purpose of this embodiment is to provide a method that can pre-fix the mixing cylinder in a linked manner when dispersing materials in the mixing cylinder, eliminating the need for a separate fixing step. During dispersion, the mixing cylinder is fed to the disperser by a feeding robot or other means. The material is dispersed in a counter-current or reverse direction to improve the dispersion effect.

[0034] Reference Figures 1-3Therefore, this embodiment proposes a disperser for the production of anti-corrosion materials, including a supporting mechanism 100, on which a counter-dispersing mechanism 300 is slidably connected via a telescopic mechanism 200, and further including a linkage clamping mechanism 400 for automatically clamping a mixing cylinder disposed between the counter-dispersing mechanism 300 and the supporting mechanism 100; the counter-dispersing mechanism 300 includes a mounting assembly and a driving assembly disposed on the mounting assembly, the driving assembly drivingly connecting a conversion assembly, and the conversion assembly connecting a first dispersing assembly and a second dispersing assembly with opposite directions.

[0035] The basic principle of this embodiment is as follows: The bearing mechanism 100 is used to fix the disperser and to support the mixing cylinder. By setting the opposing dispersion mechanism 300, the liquid in the mixing cylinder can form a counter-current flow, which improves the dispersion effect. By setting the linkage clamping mechanism 400, the mixing cylinder can be fixed in advance before the raw materials are dispersed, eliminating the need for a separate fixing step.

[0036] Reference Figure 1 and Figure 2 The supporting mechanism 100 includes a supporting base plate 110, on which a hollow cavity plate 120 is provided. The supporting base plate 110 and the cavity are arranged perpendicularly and can be made of steel. The opposing dispersion mechanism 300 is slidably mounted on the cavity plate 120. The supporting base plate 110 is used to place the mixing cylinder, and the cavity plate 120 is used to slidably mount the opposing dispersion mechanism 300.

[0037] Reference Figure 1 and Figure 2 The mounting components include a vertical plate 310 slidably connected within the cavity plate 120, with a mounting plate 320 connected to the upper end of the vertical plate 310; the telescopic mechanism 200 is installed between the cavity plate 120 and the vertical plate 310.

[0038] Reference Figure 1 and Figure 2 The telescopic mechanism 200 includes a telescopic power component fixed on the cavity plate 120, such as a cylinder, electric cylinder or hydraulic cylinder. The telescopic shaft of the telescopic power component is connected to the mounting plate 320. The telescopic mechanism 200 can drive the upright plate 310 to slide up and down relative to the cavity plate 120, thereby allowing the mounting plate 320 to move up and down relative to the cavity plate 120.

[0039] Reference Figure 1 and Figure 2The driving component includes a drive motor 330 fixed on a mounting plate 320. A retainer 340 is provided on the lower side of the mounting plate 320, and a retaining plate 350 is connected to the lower end of the retainer 340. The shaft of the drive motor 330 is drivenly connected to a conversion component mounted on the retaining plate 350. The conversion component drives a first dispersion component and a second dispersion component. The drive motor 330 can deliver power to the conversion component, which can drive the first and second dispersion components to rotate in opposite directions, thereby achieving better dispersion of the raw materials.

[0040] Reference Figure 3 The conversion assembly includes a housing 360 connected to a retaining plate 350. Inside the housing 360, a drive shaft 361 is rotatably connected to the shaft of a drive motor 330. The lower end of the drive shaft 361 extends out of the housing 360 and connects to a first dispersion assembly. A driving bevel gear 362 is mounted on the drive shaft 361. Two transmission bevel gears 363, meshing with the driving bevel gear 362, are rotatably connected to both sides of the housing 360. A driven bevel gear 365 is rotatably connected to the bottom wall of the housing 360 via a sleeve shaft 364. The drive shaft 361 passes through the sleeve shaft 364, which extends out of the housing 360 and connects to a second dispersion assembly. The drive shaft 361 can drive the first dispersion assembly to rotate, for example, clockwise. Through the transmission of the driving bevel gear 362, transmission bevel gear 363, and driven bevel gear 365, the sleeve shaft 364 rotates in the opposite direction to the drive shaft 361, thereby causing the second dispersion assembly to rotate in the opposite direction to the first dispersion assembly.

[0041] The first dispersion component includes a plurality of first dispersion plates 370 disposed on a drive shaft 361, and the second dispersion component includes a rotating frame 380 connected to a sleeve shaft 364, wherein the rotating frame 380 is provided with a plurality of second dispersion plates 390, and the first dispersion plates 370 and the second dispersion plates 390 are spaced apart. The first dispersion plates 370 and the second dispersion plates 390 rotate in opposite directions, thereby forming a counter-current dispersion and improving the dispersion effect.

[0042] Reference Figure 1 and Figure 2 In this embodiment, the linkage clamping mechanism 400 includes a clamping assembly that slides on the support substrate 110 via a spring 410, and a linkage assembly disposed between the upright plate 310 and the cavity plate 120 to actuate the clamping assembly. The clamping assembly is used to clamp the mixing cylinder, and the linkage assembly is used to drive the clamping assembly to move.

[0043] Specifically, the clamping assembly includes a clamping plate 420 slidably disposed on the support substrate 110 by a spring 410. Two clamping plates 420 are disposed opposite each other, and a passive inclined surface 430 is provided on the side of the two clamping plates 420 that is far apart from each other.

[0044] Specifically, the linkage component includes a slide groove 440 formed on the cavity plate 120 and a connecting rod 450 fixed on the upright plate 310. The connecting rod 450 is located inside the slide groove 440 and an L-shaped actuating rod 460 is connected to the connecting rod 450.

[0045] When the mixing cylinder is placed on the support base plate 110, the cylinder opening is aligned with the first and second dispersion components. At this time, the telescopic power component drives the mounting plate 320 to move downward, and the first and second dispersion components move downward synchronously. During the downward movement, the L-shaped actuating rod 460 contacts the passive inclined surface 430 and pushes the two clamping plates 420 closer together, thereby clamping and fixing the mixing cylinder. After dispersion is completed, as the telescopic mechanism 200 drives the mounting plate 320 to return to its original position, the L-shaped actuating rod 460 gradually releases contact with the passive inclined surface 430 and gradually resets under the pull of the spring 410. At this time, the clamping of the mixing cylinder is released, making it easy to remove the mixing cylinder and complete the dispersion. The overall action is ingeniously linked, eliminating the need for a separate fixing step.

[0046] The above are merely preferred embodiments of the present utility model and are not intended to limit the present utility model. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model shall be included within the protection scope of the present utility model.

Claims

1. A disperser for the production of anti-corrosion materials, characterized in that, It includes a carrying mechanism (100), on which a counter-dispersing mechanism (300) is slidably connected via a telescopic mechanism (200), and also includes a linkage clamping mechanism (400) disposed between the counter-dispersing mechanism (300) and the carrying mechanism (100) for automatically clamping the mixing cylinder. The opposing dispersion mechanism (300) includes a mounting component and a drive component disposed on the mounting component. The drive component is driven to connect to a conversion component, and the conversion component is connected to a first dispersion component and a second dispersion component with opposite directions. The support mechanism (100) includes a support substrate (110), on which a hollow cavity plate (120) is provided. The opposing dispersion mechanism (300) is slidably mounted on the cavity plate (120); The mounting assembly includes a vertical plate (310) slidably connected within the cavity plate (120), and an mounting plate (320) is connected to the upper end of the vertical plate (310); the telescopic mechanism (200) is installed between the cavity plate (120) and the vertical plate (310); The linkage clamping mechanism (400) includes a clamping assembly that slides on the support base plate (110) via a spring (410), and a linkage assembly disposed between the upright plate (310) and the cavity plate (120) that triggers the clamping assembly to move. The clamping assembly includes a clamping plate (420) slidably disposed on a support substrate (110) by a spring (410). Two clamping plates (420) are arranged opposite each other, and a passive inclined surface (430) is provided on the side of the two clamping plates (420) that is far away from each other. The linkage component includes a groove (440) formed on the cavity plate (120) and a connecting rod (450) fixed on the upright plate (310). The connecting rod (450) is located inside the groove (440) and an L-shaped actuating rod (460) is connected to the connecting rod (450).

2. A disperser for producing anti-corrosion materials according to claim 1, characterized in that, The telescopic mechanism (200) includes a telescopic power component fixed on the cavity plate (120), and the telescopic shaft of the telescopic power component is connected to the mounting plate (320).

3. A disperser for producing anti-corrosion materials according to claim 1, characterized in that, The drive assembly includes a drive motor (330) fixed on a mounting plate (320). A retainer (340) is provided on the lower side of the mounting plate (320). A retainer plate (350) is connected to the lower end of the retainer (340). The shaft of the drive motor (330) is driven to connect with a conversion assembly mounted on the retainer plate (350). The conversion assembly is driven to connect a first dispersion assembly and a second dispersion assembly.

4. A disperser for producing anti-corrosion materials according to claim 3, characterized in that, The conversion assembly includes a housing (360) connected to a retaining plate (350). Inside the housing (360), a drive shaft (361) connected to the shaft of a drive motor (330) is rotatably disposed. The lower end of the drive shaft (361) extends out of the housing (360) and is connected to a first dispersion assembly. The drive shaft (361) is provided with a driving bevel gear (362). Two drive bevel gears (363) that mesh with the driving bevel gear (362) are rotatably connected to both sides inside the housing (360). A driven bevel gear (365) is rotatably connected to the bottom wall of the housing (360) via a sleeve shaft (364). The drive shaft (361) passes through the sleeve shaft (364). The sleeve shaft (364) extends out of the housing (360) and is connected to a second dispersion assembly.

5. A disperser for producing anti-corrosion materials according to claim 4, characterized in that, The first dispersion component includes a plurality of first dispersion plates (370) disposed on a drive shaft (361), and the second dispersion component includes a rotating frame (380) connected to a sleeve shaft (364). The rotating frame (380) is provided with a plurality of second dispersion plates (390), and the first dispersion plates (370) and the second dispersion plates (390) are spaced apart.