CN116330670B - Processing method of composite nano heat insulation material - Google Patents

Abstract

The application relates to the technical field of nano material processing, in particular to a processing method of a composite nano heat-insulating material, which is completed by adopting a composite nano heat-insulating material processing device in a matched manner, and comprises a bracket, a supporting plate, a storage mechanism, a picking and placing mechanism and a pushing mechanism; the application solves the problems that the existing composite nano heat insulation material is mainly placed in the processing process, the material is taken out from the upper part through the mechanical arm, the material is added into the material frame in a certain time to avoid the lack of the material to influence the processing, the lower layer material is always unavailable due to the material taking from the upper part, the material backlog deformation is caused, the loading and unloading maintenance cost is higher by using the mechanical arm, the occupied space of the mechanical arm is larger, the use place is limited and the like.

Description

Processing method of composite nano heat insulation material

Technical Field

The application relates to the technical field of nano material processing, in particular to a processing method of a composite nano heat insulation material.

Background

The main processing flow of the composite nano heat-insulating material comprises the steps of mixture preparation, film pressing, cutting of finished nano microporous materials, cross placement, heating fusion forming, nano heat-insulating coating spraying and the like, wherein the cross placement is used for sequentially and cross placement of two materials, namely the cut nano microporous materials and a film layer formed by film pressing with the same thickness, and the heating fusion is carried out after the specified thickness is reached.

When the existing nano microporous material and the film layer are placed in a crossed mode, the materials are sequentially taken out from a material frame through a mechanical arm and placed on a composite device to be stacked, and the materials are heated and fused after the materials are alternately stacked to the required thickness.

However, the following problems mainly exist in the processing process of the current composite nano heat insulation material: 1. the placing of current material is taken out the material through the manipulator from the top, lacks the going on that influences processing for avoiding the material, can add the material in to the material frame at certain time, and gets the material from the top and can lead to the lower floor material can not take all the time to lead to the material backlog to warp.

2. The manipulator is used for loading and unloading, so that the maintenance cost is high, the occupation space of the manipulator is large, and the manipulator has limitation on a use place.

Disclosure of Invention

In view of the above problems, the embodiments of the present application provide a processing method of a composite nano heat insulation material, so as to solve the technical problems of resource waste caused by material backlog damage, high maintenance cost and large occupied space in the related art.

In order to achieve the above object, the embodiment of the present application provides the following technical solutions: the embodiment of the application provides a processing method of a composite nano heat-insulating material, which uses a processing device of the composite nano heat-insulating material, wherein the processing device of the composite nano heat-insulating material comprises a bracket, a supporting plate, a storage mechanism, a picking and placing mechanism and a pushing mechanism, and the processing method of the composite nano heat-insulating material by adopting the processing device of the composite nano heat-insulating material comprises the following steps:

s1, placing materials: manually placing the two materials, namely the nano microporous raw material and the film layer, in two storage mechanisms respectively;

s2, cross feeding: the material taking and placing mechanisms are operated to sequentially and alternately move the materials in the two material storing mechanisms to the pushing mechanism;

s3, stacking materials: the pushing mechanism sequentially pushes the two materials to an external heating area for stacking;

s4, heating and fusing: heating the stacked multi-layer materials to fuse the materials;

s5, spraying finishing: the materials after heating and fusing are sprayed with nano paint and then dried to obtain a finished product;

wherein the upper end surface of the bracket is provided with a supporting plate, the left side of the supporting plate is provided with a material storage mechanism which is used for placing materials and discharging the materials in batches in a front-back symmetrical way, the right side of the supporting plate is provided with a pushing mechanism, and a taking and placing mechanism for alternately conveying the materials in the two storage mechanisms to the pushing mechanism is arranged below the supporting plate;

the picking and placing mechanism comprises a slip ring, the slip ring is rotatably arranged on a supporting plate between the two storage mechanisms, a shaft column is arranged in the middle of the slip ring, the shaft column extends to the upper side and the lower side of the slip ring, a long plate is arranged at the lower part of the shaft column through spline fit, a sucker is arranged on the upper surface of each of the two ends of the long plate, a feeding part for sequentially taking materials from the two storage mechanisms is arranged on the lower end face of the supporting plate, and a driving part for driving the long plate to move up and down and rotate is arranged on the upper end face of the supporting plate.

As the preferred scheme, the driving piece include the disc, the backup pad up end sliding ring position install a extension board, the up end and the sliding ring coaxial of a extension board are provided with the disc, the spliced pole passes the disc, and the disc rotates with a extension board and is connected, no. two extension boards are installed to the up end of a extension board, and No. two extension boards are the structure of falling the U, no. two motor is installed to the up end of No. two extension boards, and No. one motor's output shaft is connected with the spliced pole, install a cylinder through No. three extension boards on the disc, two push rods are installed through the connecting plate to the flexible end of a cylinder, the lower extreme of two push rods extends to the below of backup pad and is connected with the longeron.

As the preferred scheme, storage mechanism includes a rectangular hole, a bottom plate is respectively installed to symmetry around the left side of backup pad, and a rectangular hole has been seted up to the up end of bottom plate, and a rectangular hole runs through bottom plate and backup pad, and the up end of bottom plate is provided with a plurality of risers along its center circumference, and the riser be L type structure, and the horizontal segment and the bottom plate sliding connection of riser, the outside of bottom plate is provided with the plastic unit that is used for synchronous movement a plurality of risers on the same bottom plate, and the L template is installed in the bottom plate left side, and the up end and a rectangular hole of L template correspond slidable mounting have the rack, and the clamp plate is installed to the rack lower extreme.

As the preferred scheme, push mechanism include No. two rectangular holes, two rectangular holes have been seted up in the backup pad on right side between the rectangular hole No. one, no. four extension boards are installed to the rectangular hole department No. two of backup pad up end, and No. four extension boards are the U type structure of falling, no. two cylinders are installed to the up end of No. four extension boards, no. two sucking discs are installed to the flexible end of No. two cylinders, and No. two sucking discs and No. two rectangular hole sliding fit, a slide bar is respectively installed to the upper end front-back symmetry of No. two sucking discs, and slide bar and longe-plate sliding fit.

As the preferred scheme, plastic unit include the ring piece, the outside of bottom plate is provided with the concentric ring piece in its center, and the ring piece rotates with the backup pad to be connected, is provided with the regulating part that is used for adjusting the riser and removes between ring piece and the riser, slidable mounting has T type post on the ring piece, installs the extension spring between the horizontal segment of T type post and the ring piece, be provided with two and T type post complex recess along the circumferencial direction of ring piece in the backup pad.

As the preferred scheme, the regulating part include the rectangle and lead to the groove, the circumference inner wall of ring piece evenly has seted up the rectangle along its circumference direction and has led to the groove, and the horizontal segment of riser is kept away from one side of ring piece axle center and is had the T template through No. two extension spring slidable mounting, and T template and rectangle lead to groove sliding fit, the rectangle of ring piece circumference inner wall is led to the groove department and has been seted up the arc chute, and arc chute and riser's horizontal segment sliding fit.

As the preferred scheme, the pay-off piece include the U template, the U template is installed to terminal surface rectangle hole site under the backup pad, and the inside slidable mounting of U template has the slide, and the slide is L type structure, is provided with two material mouths that are used for getting from two storage mechanism on the horizontal segment of slide, and three rectangle holes that are used for the sucking disc to get the material are seted up at the middle part of U template.

The above technical solutions in the embodiments of the present application have at least one of the following technical effects:

1. the picking and placing mechanism provided by the application is convenient for filling in the processing neutral time by alternately picking and placing from below, so that the processing continuity is ensured, meanwhile, the pre-placed materials can be used in advance, and the resource waste caused by backlog damage is avoided.

2. The material storage mechanism provided by the application realizes synchronous movement of a plurality of vertical plates on the same bottom plate through the rotating ring block, thereby facilitating placement of a plurality of stacks of materials in the early processing stage, shortening the preparation work, improving the processing efficiency, and simultaneously shaping and straightening the stacks of materials and improving the quality of later fusion.

3. The feeding piece provided by the application is moved back and forth through the sliding plate, so that the two material openings are alternately communicated with the two rectangular holes, and the materials in the two material storage mechanisms are pushed alternately, so that the alternate superposition of the two materials is ensured.

4. The application completes the cross placement of two materials through a simple mechanical structure, reduces the manufacturing and maintenance cost of equipment, and simultaneously, the taking and placing mechanism is mainly arranged inside the bracket, thereby improving the space utilization, reducing the occupied space and improving the safety of the equipment during operation.

Additional aspects and advantages of the application will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the application.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are required to be used in the embodiments or the description of the prior art will be briefly described below, and it is obvious that the drawings in the following description are only embodiments of the present application, and that other drawings can be obtained according to the provided drawings without inventive effort for a person skilled in the art.

FIG. 1 is a process flow diagram of the present application.

Fig. 2 is a schematic view of a first view angle structure of a processing device for composite nano heat insulation materials provided by the application.

Fig. 3 is a schematic view of a second view angle structure of the composite nano heat insulation material processing device according to the present application.

Fig. 4 is a schematic top perspective view of fig. 2 (with L-shaped plates, racks, and platens hidden).

Fig. 5 is a cross-sectional view of a portion of the structure of the adjuster of fig. 4.

Fig. 6 is a schematic perspective view of the bottom view of fig. 2.

Fig. 7 is a schematic view of the structure of the shaft post and the long plate in fig. 6.

Fig. 8 is a cross-sectional view of the feed member of fig. 3.

Reference numerals: 1. a bracket; 2. a support plate; 3. a picking and placing mechanism; 30. a slip ring; 31. a shaft post; 32. a long plate; 33. a first sucker; 34. a driving member; 340. a disc; 341. a motor I; 342. a first air cylinder; 343. a push rod; 35. a feeding member; 350. a U-shaped plate; 351. a slide plate; 352. a material port; 353. a third rectangular hole; 4. a storage mechanism; 40. a rectangular hole I; 41. a vertical plate; 42. a rack; 43. a pressing plate; 7. a shaping unit; 70. a ring block; 71. a T-shaped column; 72. a groove; 73. an adjusting member; 730. rectangular through grooves; 731. t-shaped plates; 732. an arc chute; 5. a pushing mechanism; 50. a second rectangular hole; 51. a second cylinder; 52. a second sucker; 53. and a slide bar.

Detailed Description

In order that the above objects, features and advantages of the application will be readily understood, a more particular description of the application will be rendered by reference to the appended drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application. The present application may be embodied in many other forms than described herein and similarly modified by those skilled in the art without departing from the spirit of the application, whereby the application is not limited to the specific embodiments disclosed below.

As shown in fig. 1, 2, 3 and 4, a method for processing a composite nano heat-insulating material uses a composite nano heat-insulating material processing device, wherein the composite nano heat-insulating material processing device comprises a bracket 1, a supporting plate 2, a material storage mechanism 4, a picking and placing mechanism 3 and a pushing mechanism 5, and when the composite nano heat-insulating material processing device is used for processing the composite nano heat-insulating material, the method comprises the following steps: s1, placing materials: the ring block 70 is manually rotated to enable the vertical plate 41 to be far away from the axis of the ring block 70, and then two materials, namely the stacked nano microporous raw materials and the film layer, are separately placed in the two storage mechanisms 4.

S2, cross feeding: the taking and placing mechanism 3 drives the long plate 32 to move up and down through the expansion and contraction of the first air cylinder 342 to take and place materials, and drives the shaft column 31 to rotate positively and negatively through the first motor 341, so that the long plate 32 alternately moves the materials in the two material storage mechanisms 4 to the pushing mechanism 5.

S3, stacking materials: the pushing mechanism 5 sequentially pushes the two materials alternately sent by the taking and placing mechanism 3 to an external heating area for stacking.

S4, heating and fusing: and heating the stacked multi-layer materials to fuse the multi-layer materials.

S5, spraying finishing: and spraying the nano paint on the heated and fused material, and drying to obtain a finished product.

Wherein, backup pad 2 is installed to the up end of support 1, and the left side front and back symmetry of backup pad 2 respectively is provided with one and is used for placing the material and the storage mechanism 4 of batch ejection of compact, and the right side of backup pad 2 is provided with push mechanism 5, and the below of backup pad 2 is provided with the mechanism 3 of getting that is used for sending the material in two storage mechanisms 4 to push mechanism 5 in turn.

As shown in fig. 2, fig. 3 and fig. 4, the material storage mechanism 4 includes a rectangular hole 40, a bottom plate is respectively installed in front and back symmetry on the left side of the supporting plate 2, a rectangular hole 40 is provided on the up end of the bottom plate, and the rectangular hole 40 runs through the bottom plate and the supporting plate 2, a plurality of risers 41 are provided on the up end of the bottom plate along its center circumference, the riser 41 is in an L-shaped structure, and the horizontal section of riser 41 is in sliding connection with the bottom plate, the shaping unit 7 for synchronously moving a plurality of risers 41 on the same bottom plate is provided on the outside of the bottom plate, an L-shaped plate is installed on the left side of the bottom plate, a rack 42 is installed on the up end of the L-shaped plate corresponding to the rectangular hole 40 in sliding manner, and a pressing plate 43 is installed on the lower end of the rack 42.

As shown in fig. 3 and 4, the shaping unit 7 includes a ring block 70, a ring block 70 concentric with the center of the bottom plate is provided at the outside of the bottom plate, the ring block 70 is rotatably connected with the support plate 2, an adjusting member 73 for adjusting the movement of the vertical plate 41 is provided between the ring block 70 and the vertical plate 41, a T-shaped column 71 is slidably mounted on the ring block 70, a first tension spring is mounted between the horizontal section of the T-shaped column 71 and the ring block 70, and two grooves 72 matched with the T-shaped column 71 are provided on the support plate 2 along the circumferential direction of the ring block 70.

As shown in fig. 4 and 5, the adjusting member 73 includes a rectangular through groove 730, the circumferential inner wall of the ring block 70 is uniformly provided with the rectangular through groove 730 along the circumferential direction thereof, one side of the horizontal section of the vertical plate 41 away from the axis of the ring block 70 is slidably provided with a T-shaped plate 731 by a second tension spring, the T-shaped plate 731 is slidably matched with the rectangular through groove 730, the rectangular through groove 730 on the circumferential inner wall of the ring block 70 is provided with an arc-shaped chute 732, and the arc-shaped chute 732 is slidably matched with the horizontal section of the vertical plate 41.

In specific work, after the T-shaped column 71 is pulled upwards manually, the T-shaped column 71 is separated from the current groove 72, then the ring block 70 is rotated, the arc chute 732 is far away from the vertical plate 41 in the rotating process of the ring block 70, at the moment, the vertical plate 41 is pulled away from the axle center of the ring block 70 under the action of the second tension spring, so that a plurality of stacks of materials can be conveniently placed on the bottom plate in the earlier stage of equipment use, after the materials are placed, the ring block 70 is rotated reversely manually, the arc chute 732 approaches and props against the vertical plate 41, the vertical plate 41 is pushed to move the materials while the second tension spring is stretched, so that the stacked materials are pushed and shaped, the ring block 70 is aligned, then the T-shaped column 71 is released, the T-shaped column 71 is downwards moved and inserted into the current groove 72 under the action of the first tension spring, the ring block 70 is fixed, then the taking and placing mechanism 3 takes materials from the two material storing mechanisms 4 alternately from the lower part, an external motor is arranged on the upper end face of the L-shaped plate and drives the rack 42 to move up and down through an external gear, after taking materials each time, the external motor drives the rack 42 to move down through the external gear, the rack 42 drives the pressing plate 43 to move down by one unit, materials below reach the taking range, the materials taken down by the taking and placing mechanism 3 can be connected to a heating device pushed to the outside through the pushing mechanism 5 for heating and fusing, when the materials in the material storing mechanism 4 are insufficient, the taking and placing mechanism 3 is in an empty stage in the heating and fusing processing process, and the materials can be added by moving out of the pressing plate 43, so that the continuous processing is ensured.

As shown in fig. 3, fig. 4, fig. 6 and fig. 7, the picking and placing mechanism 3 comprises a slip ring 30, the slip ring 30 is rotatably mounted on the support plate 2 between the two storage mechanisms 4, a shaft column 31 is mounted in the middle of the slip ring 30, the shaft column 31 extends to the upper side and the lower side of the slip ring 30, a long plate 32 is mounted on the lower portion of the shaft column 31 through spline fit, a first sucker 33 is mounted on the upper surface of each of two ends of the long plate 32, a feeding part 35 for sequentially picking materials from the two storage mechanisms 4 is arranged on the lower end face of the support plate 2, and a driving part 34 for driving the long plate 32 to move up and down is arranged on the upper end face of the support plate 2.

As shown in fig. 4, the driving member 34 includes a disc 340, a first support plate is mounted on the upper end surface of the support plate 2 at the slip ring 30, the disc 340 is coaxially disposed on the upper end surface of the first support plate and the slip ring 30, the shaft post 31 passes through the disc 340, the disc 340 is rotationally connected with the first support plate, a second support plate is mounted on the upper end surface of the first support plate, the second support plate is in an inverted-U structure, a first motor 341 is mounted on the upper end surface of the second support plate, an output shaft of the first motor 341 is connected with the shaft post 31, a first cylinder 342 is mounted on the disc 340 through a third support plate, the first cylinder 342 is located in the second support plate, two push rods 343 are mounted on the telescopic ends of the first cylinder 342 through a connecting plate, and the lower ends of the two push rods 343 extend to the lower portion of the support plate 2 and are connected with the long plate 32.

Specifically during operation, the first air cylinder 342 pulls the long plate 32 to move upwards, wherein the first suction disc 33 located at the position of the material storage mechanism 4 sucks air to fix materials sent to the feeding mechanism, the first suction disc 33 located at the position of the pushing mechanism 5 discharges air, the pushing mechanism 5 fixes the materials on the long plate 32, the first air cylinder 342 pushes the long plate 32 away from the supporting plate 2, then the first motor 341 drives the shaft column 31 to rotate, the long plate 32 can slide on the shaft column 31 due to the fact that the shaft column 31 and the long plate 32 are matched with each other through splines, the long plate 32 can rotate along with the shaft column 31, the first suction disc 33 absorbing materials can rotate to the pushing mechanism 5, the other first suction disc 33 rotates to the position of the feeding piece 35 to take materials, then the first air cylinder 342 pushes the elongated plate 32 to match with the suction and discharge of the first suction disc 33 to realize material taking and discharging, and then the first motor 341 drives the shaft column 31 to rotate reversely to perform material taking and discharging so as to avoid winding of external connecting wires, so that the circulation work can realize alternate material taking and discharging of two materials.

As shown in fig. 3, 6 and 8, the feeding member 35 includes a u-shaped plate 350, the u-shaped plate 350 is mounted at the position of the first rectangular hole 40 on the lower end surface of the support plate 2, a sliding plate 351 is slidably mounted inside the u-shaped plate 350, the sliding plate 351 has an L-shaped structure, two material openings 352 for taking materials from the two material storage mechanisms 4 are provided on the horizontal section of the sliding plate 351, and a third rectangular hole 353 for taking materials from the first suction cup 33 is provided in the middle of the u-shaped plate 350.

During specific work, the front side of the external cylinder mounting bracket 1 is connected with the vertical section of the sliding plate 351, the material in the rear storage mechanism 4 moves to the material opening 352 under the pushing of the rear rack 42, then the external cylinder pulls the sliding plate 351 to move forward, the material opening 352 at the rear side moves to the position of the third rectangular hole 353, meanwhile the first sucker 33 moves upwards to take materials, after the material taking is completed, the material at the rear side moves to the material opening 352 at the front side under the pushing of the rack 42 at the front side, then the external cylinder pushes the sliding plate 351 to move backward, and the material at the front side is conveyed to the third rectangular hole 353 to be fed, so that alternate feeding stacking is realized.

As shown in fig. 2 and fig. 4, the pushing mechanism 5 includes a second rectangular hole 50, two second rectangular holes 50 are formed in the support plate 2 on the right side between the first rectangular holes 40, a fourth support plate is installed at the second rectangular hole 50 on the upper end surface of the support plate 2, the fourth support plate is in an inverted-u structure, a second air cylinder 51 is installed on the upper end surface of the fourth support plate, a second suction cup 52 is installed at the telescopic end of the second air cylinder 51, the second suction cup 52 is in sliding fit with the second rectangular hole 50, a sliding rod 53 is installed in front of and behind the upper end surface of the second suction cup 52, and the sliding rod 53 is in sliding fit with the long plate 32.

During specific work, the material moving to the pushing mechanism 5 through the taking and placing mechanism 3 moves upwards along with the taking and placing mechanism 3, so that the material is attached to the second sucker 52, the first sucker 33 is deflated, the second sucker 52 is deflated to fix the material, the long plate 32 is rotated to be far away from the second rectangular hole 50, and then the second cylinder 51 pushes the material to move downwards, so that the material is pushed into an external heating device to be stacked and then heated and fused.

In the description of the present application, it should be understood that the azimuth or positional relationships indicated by the azimuth terms such as "front, rear, upper, lower, left, right", "lateral, vertical, horizontal", and "top, bottom", etc., are generally based on the azimuth or positional relationships shown in the drawings, merely to facilitate description of the present application and simplify the description, and these azimuth terms do not indicate and imply that the apparatus or elements referred to must have a specific azimuth or be constructed and operated in a specific azimuth, and thus should not be construed as limiting the scope of protection of the present application; the orientation word "inner and outer" refers to inner and outer relative to the contour of the respective component itself.

Furthermore, the terms "first," "second," "first," and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "first", "second", "first", "second" may include at least one such feature, either explicitly or implicitly. In the description of the present application, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

In the description of the present application, it should also be noted that, unless explicitly specified and limited otherwise, the terms "disposed," "connected," "mounted," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present application will be understood in specific cases by those of ordinary skill in the art.

The embodiments of the present application are all preferred embodiments of the present application, and are not intended to limit the scope of the present application; all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (4)

1. The utility model provides a processing method of compound nanometer insulating material, its has used a compound nanometer insulating material processingequipment, and this compound nanometer insulating material processingequipment includes support (1), backup pad (2), storage mechanism (4), gets put mechanism (3) and pushing equipment (5), its characterized in that: the processing of the composite nano heat insulation material by adopting the processing device for the composite nano heat insulation material comprises the following steps:

s1, placing materials: manually placing two materials, namely a nano microporous raw material and a film layer, in two storage mechanisms (4) respectively;

s2, cross feeding: the taking and placing mechanisms (3) are operated to sequentially and crosswise move the materials in the two storage mechanisms (4) to the pushing mechanism (5);

s3, stacking materials: the pushing mechanism (5) sequentially pushes the two materials to an external heating area for stacking;

s4, heating and fusing: heating the stacked multi-layer materials to fuse the materials;

s5, spraying finishing: the materials after heating and fusing are sprayed with nano paint and then dried to obtain a finished product;

the material feeding device comprises a support plate (2) arranged on the upper end face of the support (1), material storage mechanisms (4) for placing materials and discharging the materials in batches are symmetrically arranged on the left side, the right side of the support plate (2) is provided with a pushing mechanism (5), and a taking and placing mechanism (3) for alternately conveying the materials in the two material storage mechanisms (4) to the pushing mechanism (5) is arranged below the support plate (2);

the picking and placing mechanism (3) comprises a slip ring (30), the slip ring (30) is rotatably installed on a supporting plate (2) between two storage mechanisms (4), a shaft column (31) is installed in the middle of the slip ring (30), the shaft column (31) extends to the upper side and the lower side of the slip ring (30), a long plate (32) is installed at the lower portion of the shaft column (31) through spline fit, a first sucker (33) is installed on the upper surface of each of the two ends of the long plate (32), feeding parts (35) for sequentially taking materials from the two storage mechanisms (4) are arranged on the lower end face of the supporting plate (2), and driving parts (34) for driving the long plate (32) to move up and down are arranged on the upper end face of the supporting plate (2);

the driving piece (34) comprises a disc (340), a first support plate is arranged at the position of a slip ring (30) on the upper end surface of the supporting plate (2), the disc (340) is coaxially arranged on the upper end surface of the first support plate and the slip ring (30), a shaft post (31) penetrates through the disc (340), the disc (340) is rotationally connected with the first support plate, a second support plate is arranged on the upper end surface of the first support plate, the second support plate is of an inverted U-shaped structure, a first motor (341) is arranged on the upper end surface of the second support plate, an output shaft of the first motor (341) is connected with the shaft post (31), a first air cylinder (342) is arranged on the disc (340) through a third support plate, two push rods (343) are arranged at the telescopic ends of the first air cylinder (342) through connecting plates, and the lower ends of the two push rods (343) extend to the lower parts of the supporting plate (2) and are connected with the long plate (32).

The feeding piece (35) comprises a U-shaped plate (350), the U-shaped plate (350) is arranged at the position of a first rectangular hole (40) on the lower end surface of the supporting plate (2), a sliding plate (351) is slidably arranged in the U-shaped plate (350), the sliding plate (351) is of an L-shaped structure, two material holes (352) for taking materials from two material storage mechanisms (4) are formed in the horizontal section of the sliding plate (351), and a third rectangular hole (353) for taking materials from a first sucker (33) is formed in the middle of the U-shaped plate (350);

the storage mechanism (4) comprises a number one rectangular hole (40), a bottom plate is respectively installed on the left side of the supporting plate (2) in a front-back symmetrical mode, a number one rectangular hole (40) is formed in the upper end face of the bottom plate, the number one rectangular hole (40) penetrates through the bottom plate and the supporting plate (2), a plurality of vertical plates (41) are arranged on the upper end face of the bottom plate along the circumferential direction of the center of the upper end face of the bottom plate, the vertical plates (41) are of an L-shaped structure, the horizontal sections of the vertical plates (41) are in sliding connection with the bottom plate, shaping units (7) for synchronously moving the plurality of vertical plates (41) on the same bottom plate are arranged on the outer portion of the bottom plate, an L-shaped plate is installed on the left side of the bottom plate, racks (42) are correspondingly and slidably installed on the upper end faces of the L-shaped plates and the number one rectangular holes (40), and pressing plates (43) are installed at the lower ends of the racks (42).

2. The method for processing the composite nano heat insulation material according to claim 1, wherein the method comprises the following steps: push mechanism (5) include No. two rectangular hole (50), two offer No. two rectangular hole (50) on backup pad (2) on the right side between No. one rectangular hole (40), no. two rectangular hole (50) departments of backup pad (2) up end install No. four extension boards, and No. four extension boards are the structure of falling the U, no. two cylinder (51) are installed to No. four extension boards's up end, no. two sucking disc (52) are installed to No. two telescopic ends of cylinder (51), and No. two sucking disc (52) and No. two rectangular hole (50) sliding fit, a slide bar (53) is respectively installed to the upper end front and back symmetry of No. two sucking disc (52), and slide bar (53) and longe-plate (32) sliding fit.

3. The method for processing the composite nano heat insulation material according to claim 1, wherein the method comprises the following steps: the shaping unit (7) comprises a ring block (70), the ring block (70) concentric with the center of the bottom plate is arranged outside the bottom plate, the ring block (70) is rotationally connected with the supporting plate (2), an adjusting piece (73) for adjusting the vertical plate (41) to move is arranged between the ring block (70) and the vertical plate (41), a T-shaped column (71) is slidably arranged on the ring block (70), a first tension spring is arranged between the horizontal section of the T-shaped column (71) and the ring block (70), and two grooves (72) matched with the T-shaped column (71) are formed in the supporting plate (2) along the circumferential direction of the ring block (70).

4. A method of processing a composite nano-insulation material according to claim 3, wherein: the adjusting piece (73) include rectangle through groove (730), rectangle through groove (730) have evenly been seted up along its circumference direction to the circumference inner wall of ring piece (70), the horizontal segment of riser (41) is kept away from one side of ring piece (70) axle center and is had T template (731) through No. two extension spring slidable mounting, and T template (731) and rectangle through groove (730) sliding fit, arc chute (732) have been seted up in rectangle through groove (730) department of ring piece (70) circumference inner wall, and arc chute (732) and the horizontal segment sliding fit of riser (41).