A conveying device for medical carbon crystal plate production
By designing a conveyor system for the support frame, transport components, adhesive spraying components, and film application components for medical carbon crystal plates, the problem of easy damage to the film during transportation was solved, thus protecting the wear resistance and corrosion resistance of the carbon crystal plates and extending their service life.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHANXI HENGSHENG CHENLONG NEW MATERIALS CO LTD
- Filing Date
- 2025-03-06
- Publication Date
- 2026-07-03
AI Technical Summary
During the production of medical carbon crystal panels, the coating is easily scratched during subsequent transportation, affecting its wear resistance and corrosion resistance, resulting in a reduced service life.
Design a conveying device that includes a support frame, a transport component, an adhesive spraying component, and a film application component. The transport component transports the medical carbon crystal plate to the adhesive spraying component for adhesive spraying, and then transports it to the film application component to cover it with a plastic film to protect the film surface from damage.
This effectively avoids damage to the coating of medical carbon crystal plates during transportation, improves their wear resistance and corrosion resistance, and thus extends their service life.
Smart Images

Figure CN224446928U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of sheet material transportation, and in particular to a conveying device for the production of medical carbon crystal sheets. Background Technology
[0002] Medical carbon crystal plates are a high-tech material commonly used in the manufacture of high-end electronic products and optical equipment. They are composed of carbon fiber and resin composites, offering advantages such as lightweight, high strength, and corrosion resistance. Carbon crystal plates possess excellent thermal and electrical conductivity, enabling effective heat dissipation, and also exhibit high mechanical strength, allowing them to be manufactured in various shapes and sizes.
[0003] In existing technologies, medical carbon crystal plates undergo a coating process during production. This coating is intended to enhance the wear resistance and corrosion resistance of the medical carbon crystal plates. However, during subsequent transportation on the production line or during inspection, the plates may be stacked due to space constraints or the coated surface may be scratched during transportation, which affects the wear resistance and corrosion resistance of the medical carbon crystal plates, thereby reducing their service life.
[0004] Therefore, there is a need in the current environment to design a conveying device for the production of medical carbon crystal plates in order to solve the technical problems mentioned in the background. Utility Model Content
[0005] This invention provides a conveying device for the production of medical carbon crystal plates to solve the technical problems mentioned in the background art.
[0006] This utility model provides a conveying device for the production of medical carbon crystal plates. The conveying device includes: a support frame, which is vertically installed on the ground; a transport component for transporting the medical carbon crystal plates, which is installed at the bottom end of the support frame; a glue spraying component for spraying adhesive onto the surface of the formed medical carbon crystal plate, which is installed on one side of the top end of the support frame; and a film-applying component for covering the adhesive-coated surface of the medical carbon crystal plate with a plastic film, which is installed on the side of the top end of the support frame away from the glue spraying component.
[0007] Optionally, the transport assembly includes a transport motor, multiple transport drive shafts, a transport drive wheel, a transport driven wheel, and a transport belt. The transport motor is mounted at the bottom end of the support frame. The multiple transport drive shafts are respectively mounted on the side of the support frame near the glue spraying assembly and the side near the film application assembly. The transport drive wheel is mounted at the output end of the transport motor. The transport driven wheel is mounted on the transport drive shaft on the side near the glue spraying assembly. The transport belt is mounted on the multiple transport drive shafts.
[0008] Optionally, the glue spraying assembly includes a glue spraying support frame, a storage cylinder, multiple nozzles, a first sensor, and a first receiver. The glue spraying support frame is installed on one side of the top of the support frame, the storage cylinder passes through the top of the glue spraying support frame, the multiple nozzles are installed at the bottom of the storage cylinder, the first sensor is installed on one side of the inner wall of the glue spraying support frame, and the first receiver is installed on the top of the glue spraying support frame and is electrically connected to the storage cylinder.
[0009] Optionally, the film application assembly includes a film application support frame, a storage hopper, and a drive unit for adsorbing and moving the plastic film for application. The film application support frame is installed on the top of the support frame away from the adhesive spraying assembly, and the film application support frame is divided into a middle layer and a top layer. The storage hopper is installed at the top of the middle layer of the film application support frame, and the drive unit is installed at the top of the top layer of the film application support frame.
[0010] Optionally, the driving component includes multiple threaded rods, a drive motor, a movable slide, a cylinder, a rubber plate, an electrostatic generator, a second receiver, a second sensor, and a third sensor. The multiple threaded rods pass through both ends of the top layer of the film-applying support frame. The drive motor is connected to any one of the threaded rods. The movable slide is slidably mounted on the multiple threaded rods. The cylinder passes through the top of the movable slide. The rubber plate is connected to the output end of the cylinder. The electrostatic generator is mounted on the top of the movable slide and electrically connected to the rubber plate. The second receiver is mounted on one side of the cylinder and electrically connected to the cylinder. The second sensor is mounted on the top layer of the film-applying support frame near the drive motor and electrically connected to the second receiver. The third sensor is mounted on the top layer of the film-applying support frame away from the drive motor and electrically connected to the second receiver.
[0011] The beneficial effects of this utility model are as follows:
[0012] This conveying device for the production of medical carbon crystal plates includes a support frame, a transport component for transporting the medical carbon crystal plates, a spraying component for spraying adhesive onto the surface of the molded medical carbon crystal plates, and a film-applying component for covering the adhesive-coated surface of the medical carbon crystal plates with plastic film. The support frame is vertically installed on the ground, the transport component is installed at the bottom of the support frame, the spraying component is installed on one side of the top of the support frame, and the film-applying component is installed on the side of the top of the support frame away from the spraying component. Through the arrangement of these structures, after the medical carbon crystal plates are produced, the transport component first transports the medical carbon crystal plates to the spraying component, where adhesive is applied to the film-coated surface of the medical carbon crystal plates. Then, the transport component transports the medical carbon crystal plates to the film-applying component, where plastic film is applied to the adhesive-coated surface of the medical carbon crystal plates. This avoids surface abrasion of the medical carbon crystal plates during subsequent transportation, thereby greatly improving the service life of the medical carbon crystal plates. Attached Figure Description
[0013] To more clearly illustrate the technical solutions in 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.
[0014] Figure 1 This is a first-view structural schematic diagram of a conveying device for the production of medical carbon crystal plates provided by this utility model;
[0015] Figure 2 This is a second-view structural schematic diagram of a conveying device for the production of medical carbon crystal plates provided by this utility model;
[0016] Figure 3 This is a third-view schematic diagram of a conveying device for the production of medical carbon crystal plates provided by this utility model;
[0017] Explanation of reference numerals in the attached drawings: 100, support frame; 200, transport assembly; 210, transport motor; 220, transport drive shaft; 230, transport drive wheel; 240, transport driven wheel; 250, conveyor belt; 300, glue spraying assembly; 310, glue spraying support frame; 320, storage cylinder; 330, nozzle; 340, first sensor; 350, first receiver; 400, film application assembly; 410, film application support frame; 420, storage hopper; 430, drive component; 431, threaded rod; 432, drive motor; 433, moving slide; 434, cylinder; 435, rubber plate; 436, electrostatic generator; 437, second receiver; 438, second sensor; 439, third sensor. Detailed Implementation
[0018] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. It should be understood that the specific embodiments described herein are only for explaining the present utility model and not for limiting it. Furthermore, it should be noted that, for ease of description, only the parts related to the present utility model are shown in the drawings, not all of the structures. All other embodiments obtained by those skilled in the art based on the embodiments of the present utility model without creative effort are within the scope of protection of the present utility model.
[0019] In this document, the term "embodiment" means that a particular feature, structure, or characteristic described in connection with an embodiment may be included in at least one embodiment of the present invention. The appearance of this phrase in various places throughout the specification does not necessarily refer to the same embodiment, nor is it a separate or alternative embodiment mutually exclusive with other embodiments. It will be explicitly and implicitly understood by those skilled in the art that the embodiments described herein can be combined with other embodiments.
[0020] Please see Figures 1 to 3 The present invention provides a conveying device for the production of medical carbon crystal plates, comprising a support frame 100, a transport component 200, a glue spraying component 300, and a film application component 400.
[0021] The support frame 100 is vertically installed on the ground, the transport component 200 is installed at the bottom of the support frame 100, the glue spraying component 300 is installed on one side of the top of the support frame 100, and the film application component 400 is installed on the side of the top of the support frame 100 away from the glue spraying component 300.
[0022] Among them, the support frame 100 plays a supporting role, ensuring that the conveying device for the production of medical carbon crystal plates provides a stable working platform during operation;
[0023] Meanwhile, after the medical carbon crystal plate completes the coating process, it is conveyed into the transport component 200. First, the transport component 200 transports the medical carbon crystal plate to the bottom of the adhesive spraying component 300. At this time, the adhesive spraying component 300 will evenly spray the prepared adhesive onto the surface of the medical carbon crystal plate. Then, the transport component 200 transports the medical carbon crystal plate with adhesive on its surface to the bottom of the film application component 400. The film application component 400 then applies a plastic film to the surface of the medical carbon crystal plate, thereby protecting the coated surface of the medical carbon crystal plate from damage and greatly improving its service life.
[0024] In this embodiment, the transport motor 210 is installed at the bottom of the support frame 100, and a plurality of transport drive shafts 220 are respectively installed on the side of the support frame 100 near the glue spraying assembly 300 and the side near the film application assembly 400. The transport drive wheel 230 is installed at the output end of the transport motor 210, the transport driven wheel 240 is installed on the transport drive shaft 220 near the glue spraying assembly 400, and the transport belt 250 is installed on the plurality of transport drive shafts 220.
[0025] When the medical carbon crystal plate is transported to the conveyor belt 250, the output end of the transport motor 210 starts to rotate. The transport drive wheel 230 installed on the output end of the transport motor 210 rotates accordingly. Then, the transport drive wheel 230 drives the transport driven wheel 240 to rotate through the belt drive. The transport driven wheel 240 then drives the transport drive shaft 220 near the glue spraying assembly 300 to rotate. Finally, the transport drive shaft 220 near the glue spraying assembly 300 drives another transport drive shaft 220 to start rotating through the transport belt 250, thereby realizing the transport of the medical carbon crystal plate.
[0026] In this embodiment, the glue spraying support frame 310 is installed on one side of the top of the support frame 100, the storage cylinder 320 passes through the top of the glue spraying support frame 310, a plurality of spray nozzles 330 are installed at the bottom of the storage cylinder 320, the first sensor 340 is installed on one side of the inner wall of the glue spraying support frame 310, and the first receiver 350 is installed on the top of the glue spraying support frame 310 and is electrically connected to the storage cylinder 320.
[0027] Among them, the glue spraying support frame 310 plays a supporting role and provides a stable working platform during the operation of the glue spraying assembly 300;
[0028] Meanwhile, when the medical carbon crystal plate is transported to the adhesive spraying assembly 300, the first sensor 340 transmits a signal to the first receiver 350, and the first receiver 350 transmits the working signal to the storage cylinder 320. At this time, the storage cylinder 320 opens its opening, and the stored adhesive flows into the interior of multiple nozzles 330. The multiple nozzles 330 spray the adhesive evenly onto the surface of the medical carbon crystal plate, thereby completing the work of spraying adhesive onto the surface of the medical carbon crystal plate.
[0029] In this embodiment, the film-applying support frame 410 is installed on the side of the support frame 100 away from the adhesive spraying assembly 300, and the film-applying support frame 410 is divided into a middle layer and a top layer. The storage hopper 420 is installed at the top of the middle layer of the film-applying support frame 410, and the driving member 430 is installed at the top of the top layer of the film-applying support frame 410.
[0030] When the medical carbon crystal plate with the adhesive on its surface is transported to the film-applying assembly 400, the drive unit 430 first adsorbs the plastic film stored in the storage hopper 420, and then applies the plastic film to the surface of the medical carbon crystal plate with the adhesive, so that the plastic film adheres to the surface of the medical carbon crystal plate without being damaged, further improving its wear resistance and corrosion resistance, and greatly increasing its service life.
[0031] In this embodiment, multiple threaded rods 431 are inserted through both ends of the top layer of the film-applying support frame 100. The drive motor 432 is connected to any one of the threaded rods 431. The movable slide 433 is slidably disposed on the multiple threaded rods 431. The cylinder 434 is inserted through the top end of the movable slide 433. The rubber plate 435 is connected to the output end of the cylinder 434. The electrostatic generator 436 is installed on the top end of the movable slide 433 and is electrically connected to the rubber plate 435. The second receiver 437 is installed on one side of the cylinder 434 and is electrically connected to the cylinder 434. The second sensor 438 is installed on the top layer of the film-applying support frame 410 near the drive motor 430 and is electrically connected to the second receiver 437. The third sensor 439 is installed on the top layer of the film-applying support frame 410 away from the drive motor 432 and is electrically connected to the second receiver 437.
[0032] Among them, the electrostatic generator 436 generates electrostatic charge and transfers the electrostatic charge to the rubber plate 435. At this time, the rubber plate 435 carries electrostatic charge and can attract the plastic film.
[0033] Meanwhile, when the medical carbon crystal plate is transported to the film-applying assembly 400, the second sensor 438 transmits a working signal to the second receiver 437. At this time, the second receiver 437 transmits a working signal to the cylinder 434, and the cylinder 434 begins to push the rubber plate 435. The rubber plate 435 begins to move down until it stops at the storage hopper 420. Since the rubber plate 435 carries electrostatic charge, it can adsorb the plastic film when it is close to the storage hopper 420. After the plastic film is adsorbed, the cylinder 434 retracts it. This process is repeated to achieve the adsorption of the plastic film.
[0034] Furthermore, the drive motor 432 is in operation, driving the threaded rod 431 connected to it to rotate. At this time, the movable slide 433 slides on the threaded rod 431. When the cylinder 434 and the rubber plate 435 complete the adsorption and recycling action of the plastic film, the movable slide 433 moves towards the third sensor 439. When the movable slide 433 moves to the third sensor 439, the third sensor 439 transmits a working signal to the second receiver 437, and the second receiver 437 transmits a working signal to the cylinder 434. At this time, the cylinder 434, in conjunction with the rubber plate 435, moves down to the medical... On the surface of the medical carbon crystal plate, adhesive has been evenly applied. Then, a plastic film can be adhered to the surface of the medical carbon crystal plate. Since the electrostatic charge on the rubber plate 435 is less than the tensile force generated by the adhesive, when the cylinder 434 is retracted, the plastic film will not be retracted along with the cylinder 434 and the rubber plate 435, but will stick to the surface of the medical carbon crystal plate. This process is repeated to achieve the work of adhering the plastic film to the surface of the medical carbon crystal plate, thereby avoiding scratches on the surface of the medical carbon crystal plate, protecting its wear resistance and corrosion resistance, and greatly improving its service life.
[0035] In summary, the conveying device for the production of medical carbon crystal plates provided by this utility model, through the arrangement of various structures, after the medical carbon crystal plate is produced, firstly, the conveying component 200 transports the carbon crystal plate to the adhesive spraying component 300, where the adhesive is attached to the film-coated surface of the carbon crystal plate. Then, the conveying component 200 transports the carbon crystal plate to the film-applying component 400, where a plastic film is applied to the adhesive-coated surface of the carbon crystal plate. This avoids the phenomenon of the carbon crystal plate being scratched during subsequent transportation, thereby greatly improving the service life of the carbon crystal plate.
[0036] The above description is merely an embodiment of this utility model and does not limit the patent scope of this utility model. Any equivalent structural or procedural transformations made based on the description and drawings of this utility model, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of this utility model.
Claims
1. A conveying device for medical carbon crystal plate production, characterized by, include A support frame, which is vertically installed on the ground; A transport assembly for transporting medical carbon crystal plates, the transport assembly being mounted at the bottom end of the support frame; A spraying assembly for spraying colloid onto the surface of a molded medical carbon crystal plate, the spraying assembly being mounted on one side of the top of the support frame; A film-applying assembly for applying a plastic film to the surface of an adhesive-coated medical carbon crystal plate, the film-applying assembly being mounted on the top of the support frame on the side away from the adhesive spraying assembly; The film application assembly includes a film application support frame, a storage hopper, and a drive unit for adsorbing and moving the plastic film for application. The film application support frame is installed on the top of the support frame away from the adhesive spraying assembly, and the film application support frame is divided into a middle layer and a top layer. The storage hopper is installed at the top of the middle layer of the film application support frame, and the drive unit is installed at the top of the top layer of the film application support frame.
2. The conveying device for the production of medical carbon crystal plates according to claim 1, characterized in that The transport assembly includes a transport motor, multiple transport drive shafts, a transport drive wheel, a transport driven wheel, and a transport belt. The transport motor is mounted at the bottom end of the support frame. The multiple transport drive shafts are respectively mounted on the side of the support frame near the glue spraying assembly and the side near the film application assembly. The transport drive wheel is mounted at the output end of the transport motor. The transport driven wheel is mounted on the transport drive shaft on the side near the glue spraying assembly. The transport belt is mounted on the multiple transport drive shafts.
3. The conveying device for the production of medical carbon crystal plates according to claim 1, characterized in that, The glue spraying assembly includes a glue spraying support frame, a storage cylinder, multiple nozzles, a first sensor, and a first receiver. The glue spraying support frame is installed on one side of the top of the support frame. The storage cylinder passes through the top of the glue spraying support frame. The multiple nozzles are installed at the bottom of the storage cylinder. The first sensor is installed on one side of the inner wall of the glue spraying support frame. The first receiver is installed on the top of the glue spraying support frame and is electrically connected to the storage cylinder.
4. The conveying device for the production of medical carbon crystal plates according to claim 1, characterized in that, The driving component includes multiple threaded rods, a drive motor, a movable slide, a cylinder, a rubber plate, an electrostatic generator, a second receiver, a second sensor, and a third sensor. The multiple threaded rods pass through both ends of the top layer of the film-applying support frame. The drive motor is connected to any one of the threaded rods. The movable slide is slidably mounted on the multiple threaded rods. The cylinder passes through the top of the movable slide. The rubber plate is connected to the output end of the cylinder. The electrostatic generator is mounted on the top of the movable slide and electrically connected to the rubber plate. The second receiver is mounted on one side of the cylinder and electrically connected to the cylinder. The second sensor is mounted on the top layer of the film-applying support frame near the drive motor and electrically connected to the second receiver. The third sensor is mounted on the top layer of the film-applying support frame away from the drive motor and electrically connected to the second receiver.