CN220123356U - Anti-electromagnetic interference nano composite wave-absorbing material lamination equipment - Google Patents

Abstract

The utility model relates to the field of nano wave-absorbing materials, in particular to an anti-electromagnetic interference nano composite wave-absorbing material laminating device, which comprises: the device comprises a material placing rack and a material placing table, wherein the material placing rack is arranged at the upper end of the material placing table; the alignment mechanism is arranged between the material placing rack and the material placing table and extends to the inside of the material placing table; wherein the alignment mechanism includes an alignment assembly for assisting in alignment; through setting up alignment mechanism, to need place lay material carry out supplementary alignment operation, the device has reached when contact through material rack and limit for the height pole will drive the movable plate with the material rack and carry out synchronous movement, and then has ensured when laying bed charge and the stacked material that the material rack drove of movable plate upper end lay, and then supplementary time that has improved subsequent alignment put has improved work efficiency.

Description

Anti-electromagnetic interference nano composite wave-absorbing material lamination equipment

Technical Field

The utility model relates to the field of nano wave-absorbing materials, in particular to an anti-electromagnetic interference nano composite wave-absorbing material laminating device.

Background

The wave-absorbing material is crystallized into various soft magnetic alloys by using high-permeability and high-loss metal in the ultra-micro molecule, and laminated with layer-by-layer ribbon films, so that the microwave noise generated by the electronic device, module and surface current can be absorbed in a wide band with high efficiency; wherein the lamination device is dedicated to thin film lamination. The thin materials are divided into laminate, coating and structure, and the laminate is generally matched with laminating equipment to laminate multiple materials to form the required functions of composite wave absorption and the like, but in the material lamination process, the alignment, placement and calibration of different materials are slow when the equipment is laminated due to the fact that the processing chamber needs to calibrate the position of the processing chamber for multiple times, so that the working efficiency of lamination processing is affected.

Accordingly, an electromagnetic interference resistant nanocomposite wave absorbing material laminating apparatus has been proposed to solve the above-described problems.

Disclosure of Invention

The utility model aims to solve the problems and provide the anti-electromagnetic interference nanocomposite wave-absorbing material laminating equipment, which solves the problems that in the material laminating process, the alignment and the calibration of different materials are slow when the equipment is laminated due to the fact that the position of the processing chamber needs to be calibrated for a plurality of times, and the working efficiency of laminating processing is affected.

The utility model realizes the aim through the following technical scheme, and the anti-electromagnetic interference nano composite wave-absorbing material lamination equipment comprises: the device comprises a material placing rack and a material placing table, wherein the material placing rack is arranged at the upper end of the material placing table; the alignment mechanism is arranged between the material placing rack and the material placing table and extends to the inside of the material placing table; the aligning mechanism comprises an aligning component used for assisting in aligning, the aligning component is arranged at the upper end of the material placing table, a reset component is arranged at the lower end of the aligning component, and the reset component is used for assisting in resetting and moving of the aligning component.

Preferably, the alignment assembly comprises two groups of grooved wheels rotatably connected to the upper end of the material placing table, the two groups of grooved wheels are arranged in parallel, a movable plate is arranged between the two groups of grooved wheels, the surface of the movable plate is in contact with the surface of the grooved wheels, the upper end of the movable plate is fixedly connected with a plurality of height limiting rods, materials needing to be subjected to stacking operation are placed through the material placing frame, the material placing frame generally places stacked materials above the movable plate through structures such as suckers, when the stacked materials are placed for the first time, when the stacked materials of the same type are placed subsequently, only the height of the suckers of the material placing frame is required to be adjusted, so that the lower end of the material placing frame can abut against different height limiting rods each time when the materials are paved, the effect of placing the materials required by different positions can be achieved, because the height limiting rods are two groups, when the material is placed for the first time, the height of the lowest end of the material placing frame is set between the height limiting rods of the first height and the second height, when the material is placed, the material is driven by the material placing frame, the surface of the material placing frame is contacted with the surface of the highest height limiting rod, the moving plate is driven by the highest height limiting rod to move, the bottom material is paved at the upper end of the moving plate, the preliminary alignment operation is further finished, when the material is paved and placed for each time, only the height interval between the height limiting rods of different heights is needed to be adjusted, and when the material placing frame is contacted with the height limiting rods, the height limiting rods are driven by the material placing frame to move synchronously, and then ensured the lamination material that lays bed charge and material rack on the movable plate upper end when laying, can align more conveniently, supplementary time that has improved subsequent alignment and put has improved work efficiency.

Preferably, the reset component comprises a middle groove formed in the upper end of the material placement table, the inner wall of the middle groove is fixedly connected with a cylinder body, the inner wall of the cylinder body is slidably connected with a piston, one side of the piston is fixedly connected with a connecting rod, the other end of the connecting rod penetrates through the outside of the cylinder body and is fixedly connected with a connecting block, the connecting block is fixedly connected with the lower end of a moving plate, the moving plate can drive the connecting block to move along with the moving plate when moving, and at the moment, the connecting block can move in the middle groove through the connecting rod in a synchronous manner when the connecting block moves in the inner wall of the cylinder body.

Preferably, the alignment assembly further comprises a bottom groove formed in the upper end of the material placement table, the rollers are arranged on the left and right sides of the inner wall of the bottom groove, the lower end of the moving plate is fixedly connected with a sliding rail, the inner top wall of the sliding rail is in contact with the surface of the rollers, when the moving plate moves, the effect of evaluating the movement of the moving plate is kept through two rows of grooved wheels, and meanwhile the moving plate moves more stably by being matched with the rollers and the sliding rail.

Preferably, the opposite side fixedly connected with reset spring of piston, reset spring's the other end fixedly connected with inner wall in the cylinder body, when the piston is moving, will make the piston remove extrusion reset spring, when the movable plate does not receive external influence, will be through reset spring's reset effect, auxiliary piston resets at the inner wall of cylinder body.

Preferably, one end of the cylinder body penetrates through the outside of the material placement table, a vent hole is formed in one end of the cylinder body, when the piston moves on the inner wall of the cylinder body, gas in the cylinder body can be discharged to the outside through the vent hole quickly, and the moving speed of the piston in the cylinder body is relieved due to the small diameter of the vent hole, so that the moving speed of the piston in the cylinder body is relatively mild.

The beneficial effects of the utility model are as follows:

1. through setting up alignment mechanism, can be under alignment mechanism's effect, the auxiliary alignment operation is carried out to the material of laying that needs to place, in the material range upon range of in-process for traditional device, because carry out the processing room and need carry out calibration many times to the place, when leading to equipment to carry out range upon range of, different materials align to put the calibration slowly, influence the work efficiency of range upon range of processing, the device has reached when contacting through material rack and limit for the limit for height pole will drive the movable plate and carry out synchronous movement along with the material rack, and then the laminating material that has guaranteed laying bed charge and material rack drive of movable plate upper end can not change when laying, thereby make the alignment operation of material of laying, and then supplementary time of having improved subsequent alignment put, work efficiency has been improved.

2. Through setting up reset assembly, can be under reset assembly's effect, reset the operation to driving the movable plate, the device has reached when removing through the movable plate, will drive the connecting block and follow and remove, will make the connecting block at the middle part inslot portion when removing this moment, will move in step at the inner wall of cylinder body through the connecting rod butt moving piston. At the moment, the piston moves to squeeze the reset spring, and the auxiliary piston resets on the inner wall of the cylinder body through the reset effect of the reset spring.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of the alignment assembly of the present utility model;

FIG. 3 is an exploded view of the alignment mechanism of the present utility model;

FIG. 4 is a schematic view of the cylinder position of the present utility model;

fig. 5 is a schematic view of the internal structure of the cylinder body of the present utility model.

In the figure: 1. a material placing rack; 2. a material placement table; 3. an alignment mechanism; 31. an alignment assembly; 311. a moving plate; 312. a sheave; 313. a height limiting rod; 314. a bottom groove; 315. a slide rail; 316. a roller; 32. a reset assembly; 321. a middle groove; 322. a cylinder; 323. a piston; 324. a connecting rod; 325. a connecting block; 326. a vent hole; 327. and a return spring.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The specific implementation method comprises the following steps: as shown in fig. 1-5, an electromagnetic interference resistant nanocomposite wave-absorbing material laminating apparatus includes: the material placing rack 1 and the material placing table 2, wherein the material placing rack 1 is arranged at the upper end of the material placing table 2; the alignment mechanism 3 is arranged between the material placing rack 1 and the material placing table 2, and the alignment mechanism 3 extends to the inside of the material placing table 2; the aligning mechanism 3 comprises an aligning component 31 for assisting in alignment, the aligning component 31 is arranged at the upper end of the material placing table 2, a reset component 32 is arranged at the lower end of the aligning component 31, and the reset component 32 is used for assisting in resetting movement of the aligning component 31;

as shown in fig. 1, fig. 2 and fig. 3, the alignment assembly 31 comprises two groups of sheaves 312 rotatably connected to the upper end of the material placing table 2, the two groups of sheaves 312 are arranged in parallel, a moving plate 311 is arranged between the two groups of sheaves 312, the surface of the moving plate 311 is contacted with the surface of the sheaves 312, a plurality of height limiting rods 313 are fixedly connected to the upper end of the moving plate 311, the alignment assembly 31 further comprises a bottom groove 314 formed in the upper end of the material placing table 2, rollers 316 are arranged on the left and right of the inner walls of the bottom groove 314, a sliding rail 315 is fixedly connected to the lower end of the moving plate 311, the inner top wall of the sliding rail 315 is contacted with the surface of the rollers 316, when the material placing frame 1 is contacted with the height limiting rods 313, the height limiting rods 313 can drive the moving plate 311 to synchronously move along with the material placing frame 1, and further ensure that when the moving plate 311 moves, the two rows of sheaves 312 keep the effect of evaluating the moving plate 311, and the inner walls of the moving plate 311 are matched with the sliding rail 315 to enable the moving plate 311 to move smoothly, thereby improving the alignment efficiency and the subsequent alignment to be more convenient;

as shown in fig. 3, fig. 4 and fig. 5, the reset assembly 32 includes a middle groove 321 opened at the upper end of the material placing table 2, the inner wall of the middle groove 321 is fixedly connected with a cylinder 322, the inner wall of the cylinder 322 is slidably connected with a piston 323, one side of the piston 323 is fixedly connected with a connecting rod 324, the other end of the connecting rod 324 penetrates through the outside of the cylinder 322 and is fixedly connected with a connecting block 325, the connecting block 325 is fixedly connected with the lower end of the moving plate 311, the other side of the piston 323 is fixedly connected with a reset spring 327, the other end of the reset spring 327 is fixedly connected with the inner wall of the cylinder 322, one end of the cylinder 322 penetrates through the outside of the material placing table 2, one end of the cylinder 322 is provided with a vent 326, the moving plate 311 drives the connecting block 325 to move, at this moment, when the connecting block 325 moves inside the middle groove 321, the piston 323 moves synchronously through the connecting rod 324, at this moment, the piston 323 moves to squeeze the reset spring 327, the reset effect of the reset piston 323 is achieved on the inner wall of the cylinder 322, when the piston 323 moves on the inner wall of the cylinder 322, the air 326 is discharged from the inside of the cylinder 322 through the vent 326, and the diameter of the piston 323 is relatively small inside the cylinder 322 is relaxed.

When the utility model is used, when the material placing frame 1 is contacted with the height limiting rod 313, the height limiting rod 313 drives the movable plate 311 to synchronously move along with the material placing frame 1, so that the layered materials driven by the material placing frame 1 and the laying bed material at the upper end of the movable plate 311 are ensured to be laid, when the movable plate 311 moves, the movement of the movable plate 311 is kept to be evaluated through the two rows of grooved wheels 312, meanwhile, the movable plate 311 is enabled to move more stably by matching with the rollers 316 and the sliding rails 315, the movable plate 311 drives the connecting block 325 to move along with the movement when the movable plate 311 moves, at the moment, the connecting block 325 moves in the middle groove 321, the piston 323 is enabled to synchronously move on the inner wall of the cylinder 322 through the connecting rod 324, at the moment, the piston 323 moves to squeeze the reset spring 327, the auxiliary piston 323 resets on the inner wall of the cylinder 322 through the reset effect of the reset spring 327, and when the piston 323 moves on the inner wall of the cylinder 322, the gas inside the cylinder 322 is enabled to be discharged to the outside through the vent holes 326, the diameter of the vent holes 326 is smaller, the movement of the piston 322 is relieved, the movement speed of the piston 322 inside the cylinder 322 is enabled to be aligned, and the operation efficiency of the piston 322 is enabled to be further improved, and the operation is further improved.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (8)

1. An electromagnetic interference resistant nanocomposite wave absorbing material laminating apparatus, comprising:

the device comprises a material placing rack (1) and a material placing table (2), wherein the material placing rack (1) is arranged at the upper end of the material placing table (2);

the alignment mechanism (3) is arranged between the material placing rack (1) and the material placing table (2), and the alignment mechanism (3) extends to the inside of the material placing table (2);

the aligning mechanism (3) comprises an aligning component (31) for assisting in aligning, the aligning component (31) is arranged at the upper end of the material placing table (2), a reset component (32) is arranged at the lower end of the aligning component (31), and the reset component (32) is used for assisting in resetting and moving the aligning component (31).

2. The electromagnetic interference resistant nanocomposite wave absorbing material laminating apparatus according to claim 1, wherein: the alignment assembly (31) comprises two groups of grooved wheels (312) which are rotationally connected to the upper end of the material placing table (2), the two groups of grooved wheels (312) are arranged in parallel, a movable plate (311) is arranged between the two groups of grooved wheels (312), the surface of the movable plate (311) is in contact with the surface of the grooved wheels (312), and a plurality of height limiting rods (313) are fixedly connected to the upper end of the movable plate (311).

3. The electromagnetic interference resistant nanocomposite wave absorbing material laminating apparatus according to claim 2, wherein: the reset assembly (32) comprises a middle groove (321) formed in the upper end of the material placing table (2), a cylinder body (322) is fixedly connected to the inner wall of the middle groove (321), and a piston (323) is slidably connected to the inner wall of the cylinder body (322).

4. The electromagnetic interference resistant nanocomposite wave absorbing material laminating apparatus according to claim 3, wherein: one side of the piston (323) is fixedly connected with a connecting rod (324), the other end of the connecting rod (324) penetrates to the outside of the cylinder body (322) and is fixedly connected with a connecting block (325), and the connecting block (325) is fixedly connected to the lower end of the movable plate (311).

5. The electromagnetic interference resistant nanocomposite wave absorbing material laminating apparatus according to claim 4, wherein: the alignment assembly (31) further comprises a bottom groove (314) formed in the upper end of the material placing table (2), and left and right rollers (316) are arranged on the inner wall of the bottom groove (314).

6. The electromagnetic interference resistant nanocomposite wave absorbing material laminating apparatus according to claim 5, wherein: the lower extreme fixedly connected with slide rail (315) of movable plate (311), the interior roof of slide rail (315) and the surface contact of gyro wheel (316).

7. The electromagnetic interference resistant nanocomposite wave absorbing material laminating apparatus according to claim 4, wherein: the other side of the piston (323) is fixedly connected with a return spring (327), and the other end of the return spring (327) is fixedly connected with the inner wall of the cylinder body (322).

8. The electromagnetic interference resistant nanocomposite wave absorbing material laminating apparatus according to claim 3, wherein: one end of the cylinder body (322) penetrates through the outside of the material placing table (2), and a vent hole (326) is formed in one end of the cylinder body (322).