Carbon molecular sieve shock-absorbing transportation device

By introducing vibration damping and installation mechanisms into the carbon molecular sieve transport device, the problems of particle wear and inconvenience in loading and unloading caused by vibration during the transport of carbon molecular sieves have been solved, achieving the effects of reducing losses and improving loading and unloading efficiency.

CN224324367UActive Publication Date: 2026-06-05JIANGSU KELIXING NEW MATERIALS TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIANGSU KELIXING NEW MATERIALS TECHNOLOGY CO LTD
Filing Date
2025-08-12
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

Existing carbon molecular sieve transport devices are prone to particle collision and friction due to vibration under bumpy road conditions, resulting in wear and performance reduction. At the same time, loading and unloading are inconvenient and inefficient.

Method used

A vibration damping transport device for carbon molecular sieves, including a vibration damping mechanism and an installation mechanism, was designed. The vibration damping mechanism absorbs vibration energy through the cooperation of hinge blocks and springs, while the installation mechanism achieves rapid fixation through the elastic deformation of clamps and springs.

Benefits of technology

It effectively reduces particle loss of carbon molecular sieves during transportation, improves loading and unloading efficiency, shortens loading time, and enhances the overall efficiency of the transportation process.

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Abstract

The utility model discloses a carbon molecular sieve shock attenuation transport device relates to carbon molecular sieve transport technical field, the utility model discloses a base is provided with a plurality of damping mechanism and a plurality of mounting mechanisms on the base, the top of base is provided with a plurality of chute no.
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Description

Technical Field

[0001] This utility model belongs to the field of carbon molecular sieve transportation technology, and in particular relates to a carbon molecular sieve shock-absorbing transportation device. Background Technology

[0002] Carbon molecular sieves are widely used in industrial nitrogen production and other fields, and their transportation is crucial. Currently, common carbon molecular sieve transportation devices have many shortcomings. Traditional containers are mostly simple boxes, which can easily cause carbon molecular sieves to collide and rub against each other under bumpy road conditions, resulting in particle breakage and affecting performance. In addition, existing transportation devices are inconvenient to operate during loading and unloading, inefficient, and consume a lot of manpower and resources. Therefore, it is urgent to develop a transportation device that can effectively protect carbon molecular sieves and facilitate loading and unloading.

[0003] However, existing carbon molecular sieve transport devices are not suitable for vibration damping during transport, which causes the carbon molecular sieves to easily collide and rub against each other due to vibration. This can cause the particles to wear and break, thereby reducing their performance and causing unnecessary losses. Utility Model Content

[0004] The purpose of this utility model is to provide a carbon molecular sieve vibration damping transport device. By setting a vibration damping mechanism, the existing carbon molecular sieve transport device is not convenient to dampen the device during transportation, which causes the carbon molecular sieve to easily collide and rub against each other due to vibration. This causes the particles to wear and break, thereby reducing its performance and causing unnecessary losses.

[0005] To solve the above-mentioned technical problems, this utility model is achieved through the following technical solution:

[0006] This utility model is a carbon molecular sieve shock-absorbing transport device, including a base, on which a plurality of shock-absorbing mechanisms and a plurality of mounting mechanisms are provided;

[0007] The base has several sliding grooves on its top, and each of the sliding grooves has a slider connected to its inner wall. Each slider has a material bucket on its top. The vibration damping mechanism includes two hinge blocks fixedly connected to the bottom of the sliders. Each of the two hinge blocks has a hinge rod hinged to its bottom. The mounting mechanism includes a connecting block fixedly connected to the top of the sliders.

[0008] Furthermore, each of the two hinged rods has a hinged block 2 hinged at its bottom. A bracket is fixedly connected to the bottom inner wall of the slide groove 1. A limit rod 1 is fixedly connected to the inner wall of the bracket. Two sliders 2 are slidably connected to the outer wall of the limit rod 1. The tops of the two sliders 2 are fixedly connected to the two hinged blocks 2 respectively.

[0009] Furthermore, the outer wall of the limiting rod is fitted with two springs, the sides of the two springs that are close to each other are fixedly connected to the two sliders, and the sides of the two springs that are far apart from each other are fixedly connected to the bracket.

[0010] Furthermore, a second sliding groove is provided inside the connecting block, and a third sliding block is slidably connected to the inner wall of the second sliding groove. A clamping plate is fixedly connected to the third sliding block, and the clamping plate is adapted to the material bucket. A handle is fixedly connected to the top of the third sliding block.

[0011] Furthermore, the inner wall of the slide groove 2 is fixedly connected to two limiting rods 2, both of which penetrate the slider 3. The outer walls of both limiting rods 2 are slidably connected to the slider 3. The outer walls of both limiting rods 2 are fitted with springs 2. The side of both springs 2 away from the clamping plate is fixedly connected to the slide groove 2, and the side of both springs 2 near the clamping plate is fixedly connected to the slider 3.

[0012] This utility model has the following beneficial effects:

[0013] 1. By setting up a vibration damping mechanism, when encountering bumps or other vibrations during transportation, slider one will slide in slide groove one under this vibration. At this time, slider one will drive slider two to slide on limit rod one through the interaction between hinge block one, hinge rod and hinge block two. At this time, slider two will compress or stretch spring one, thereby causing it to undergo elastic deformation and generate elastic force. Under the action of this elastic force, the vibration will be canceled, so that the device can be damped during transportation, avoiding the carbon molecular sieve from colliding and rubbing against each other due to vibration during transportation, which would cause the performance of its particles to deteriorate, thereby reducing the loss of carbon molecular sieve during transportation;

[0014] 2. By setting up an installation mechanism, during installation, the carbon molecular sieve is loaded into the material bucket, and then the handle is pulled, causing the clamping plate to slide via slider three. Two installation mechanisms are set on the top of slider one. After the two clamping plates are moved to their farthest distance from each other, the material bucket can be placed between the two clamping plates. While slider three is sliding, it will also apply pressure to spring two, causing it to undergo elastic deformation and generate elastic force. After the material bucket is placed, the handle can be released. At this time, under the action of the elastic force of spring two, the material bucket will be clamped, which allows the packaging box of carbon molecular sieve to be quickly fixed to the device. This eliminates the need for workers to spend a lot of time fixing it, thereby shortening the loading time and the overall transportation process.

[0015] Of course, any product implementing this utility model does not necessarily need to achieve all of the advantages described above at the same time. Attached Figure Description

[0016] To more clearly illustrate the technical solutions of the embodiments of this utility model, the accompanying 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.

[0017] Figure 1 This is a partial cross-sectional view of the slider of this utility model;

[0018] Figure 2 This is a schematic diagram of the overall structure of the vibration reduction mechanism of this utility model;

[0019] Figure 3 This is a partial cross-sectional view of the installation mechanism of this utility model;

[0020] Figure 4 This utility model Figure 3 A magnified structural diagram of A in the middle;

[0021] Figure 5 This is a schematic diagram of the overall structure of this utility model.

[0022] The attached diagram lists the components represented by each number as follows:

[0023] 1. Base; 101. Slide 1; 102. Slider 1; 103. Material bucket; 2. Vibration damping mechanism; 201. Hinge block 1; 202. Hinge rod; 203. Hinge block 2; 204. Bracket; 205. Limiting rod 1; 206. Slider 2; 207. Spring 1; 3. Installation mechanism; 301. Connecting block; 302. Slide 2; 303. Slider 3; 304. Clamping plate; 305. Handle; 306. Limiting rod 2; 307. Spring 2. Detailed Implementation

[0024] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0025] Please see Figure 1-5As shown, this utility model is a carbon molecular sieve vibration damping and transportation device, including a base 1, on which a plurality of vibration damping mechanisms 2 and a plurality of mounting mechanisms 3 are arranged. A plurality of sliding grooves 101 are formed on the top of the base 1. Sliding blocks 102 are slidably connected to the inner walls of each sliding groove 101. A material bucket 103 is provided on the top of each sliding block 102. The vibration damping mechanism 2 includes two hinge blocks 201 fixedly connected to the bottom of each sliding block 102. A hinge rod 202 is hinged to the bottom of each of the two hinge blocks 201. A hinge block 203 is hinged to the bottom of each of the two hinge rods 202. A bracket 204 is fixedly connected to the inner wall of the bottom of each sliding groove 101. The inner wall of the 4 is fixedly connected to a limiting rod 205. The outer wall of the limiting rod 205 is slidably connected to two sliders 206. The tops of the two sliders 206 are fixedly connected to two hinge blocks 203 respectively. The outer wall of the limiting rod 205 is fitted with two springs 207. The side of the two springs 207 that are close to each other is fixedly connected to the two sliders 206 respectively. The side of the two springs 207 that are far apart from each other is fixedly connected to the bracket 204. By setting the vibration damping mechanism 2, the device can be vibration damped during transportation, so as to avoid the carbon molecular sieve from colliding and rubbing against each other due to vibration during transportation, which would cause the performance of the particles to deteriorate, thereby reducing the loss of carbon molecular sieve during transportation.

[0026] The mounting mechanism 3 includes a connecting block 301 fixedly connected to the top of slider 102. A second sliding groove 302 is formed inside the connecting block 301. A third slider 303 is slidably connected to the inner wall of the second sliding groove 302. A clamping plate 304 is fixedly connected to the third slider 303, and the clamping plate 304 is adapted to the material bucket 103. A handle 305 is fixedly connected to the top of the third slider 303. Two limiting rods 306 are fixedly connected to the inner wall of the second sliding groove 302, and both limiting rods 306 penetrate the third slider 303. The outer walls of the two limiting rods 306... All are slidably connected to slider 303. The outer walls of the two limiting rods 306 are fitted with springs 307. The side of the two springs 307 away from the clamping plate 304 is fixedly connected to the slide groove 302. The side of the two springs 307 near the clamping plate 304 is fixedly connected to slider 303. By setting the installation mechanism 3, the packaging box of carbon molecular sieve can be quickly fixed to the device without the need for staff to spend a lot of time fixing it, thereby shortening the loading time and the overall transportation process.

[0027] A specific application of this embodiment is as follows: First, move each component of the device to its corresponding position. Then, load the carbon molecular sieve into the material bucket 103. Next, pull the handle 305, causing it to slide via the slider 303, which in turn drives the clamping plate 304 to slide. Two mounting mechanisms 3 are provided on the top of the slider 102. After the two clamping plates 304 are moved to their furthest distance from each other, the material bucket 103 can be placed between the two clamping plates 304. Simultaneously, as the slider 303 slides, it applies pressure to the spring 307, causing it to undergo elastic deformation and generate elastic force, thus placing the material bucket 103 between them. After placement, handle 305 can be released. At this time, the material bucket 103 will be clamped under the action of the elastic force of spring 307. When encountering bumps or vibrations during transportation, slider 102 will slide in the slide groove 101 under this vibration. At this time, slider 102 will drive slider 206 to slide on limit rod 205 through the interaction between hinge block 201, hinge rod 202 and hinge block 203. At this time, slider 206 will compress or stretch spring 207, thereby causing it to undergo elastic deformation and generate elastic force. Under the action of this elastic force, the vibration will be canceled.

[0028] In the description of this specification, references to terms such as "an embodiment," "example," "specific example," etc., indicate that a specific feature, structure, material, or characteristic described in connection with that embodiment or example is included in at least one embodiment or example of the present invention. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples.

[0029] The preferred embodiments of this utility model disclosed above are merely illustrative of the present utility model. These preferred embodiments do not exhaustively describe all details, nor do they limit the utility model to the specific implementations described. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of this utility model, thereby enabling those skilled in the art to better understand and utilize it. This utility model is limited only by the claims and their full scope and equivalents.

Claims

1. A carbon molecular sieve shock-absorbing transport device, characterized in that: Includes a base (1), on which a plurality of vibration damping mechanisms (2) and a plurality of mounting mechanisms (3) are provided; The base (1) has several sliding grooves (101) on its top. The inner walls of the several sliding grooves (101) are slidably connected to sliders (102). The tops of the several sliders (102) are provided with material buckets (103). The vibration damping mechanism (2) includes two hinge blocks (201) fixedly connected to the bottom of the sliders (102). The bottoms of the two hinge blocks (201) are hinged with hinge rods (202). The installation mechanism (3) includes a connecting block (301) fixedly connected to the top of the sliders (102).

2. The carbon molecular sieve shock-absorbing transport device according to claim 1, characterized in that, The bottom of each of the two hinge rods (202) is hinged with a second hinge block (203), and the bottom inner wall of the first slide groove (101) is fixedly connected with a bracket (204).

3. The carbon molecular sieve shock-absorbing transport device according to claim 2, characterized in that, The inner wall of the bracket (204) is fixedly connected to a limiting rod (205), and the outer wall of the limiting rod (205) is slidably connected to two sliders (206). The tops of the two sliders (206) are respectively fixedly connected to two hinge blocks (203).

4. The carbon molecular sieve shock-absorbing transport device according to claim 3, characterized in that, The outer wall of the limiting rod (205) is fitted with two springs (207). The two springs (207) are fixedly connected to the two sliders (206) on the side that is close to each other, and the two springs (207) are fixedly connected to the bracket (204) on the side that is far away from each other.

5. A carbon molecular sieve shock-absorbing transport device according to claim 4, characterized in that, The connecting block (301) has a sliding groove (302) inside, and a slider (303) is slidably connected to the inner wall of the sliding groove (302).

6. The carbon molecular sieve shock-absorbing transport device according to claim 5, characterized in that, A clamping plate (304) is fixedly connected to the slider three (303), the clamping plate (304) is adapted to the material bucket (103), and a handle (305) is fixedly connected to the top of the slider three (303).

7. A carbon molecular sieve shock-absorbing transport device according to claim 6, characterized in that, The inner wall of the slide groove 2 (302) is fixedly connected to two limiting rods 2 (306), both limiting rods 2 (306) penetrate the slider 3 (303), the outer walls of the two limiting rods 2 (306) are slidably connected to the slider 3 (303), the outer walls of the two limiting rods 2 (306) are fitted with springs 2 (307), the side of the two springs 2 (307) away from the clamping plate (304) is fixedly connected to the slide groove 2 (302), and the side of the two springs 2 (307) near the clamping plate (304) is fixedly connected to the slider 3 (303).