CN111807773A

CN111807773A - Preparation process of heat insulation material

Info

Publication number: CN111807773A
Application number: CN202010702920.3A
Authority: CN
Inventors: 查焰林
Original assignee: Hangzhou Zhonglu New Material Co ltd
Current assignee: Hangzhou Zhonglu New Material Co ltd
Priority date: 2020-07-18
Filing date: 2020-07-18
Publication date: 2020-10-23

Abstract

The invention discloses a preparation process of a heat insulation material, which is characterized by comprising the following steps: the method comprises the following steps: a. crushing: crushing rice hulls, corncob cores, volcanic rock residues and calcium carbonate: b. sieving: sieving after crushing the material; c. bamboo fiber: making bamboo chips into bamboo fibers; d. stirring: stirring the mixture according to the parts by weight to obtain a mixture; e. molding: injecting the mixture into a mold, and demolding after molding; f. packaging: and cutting the heat-insulating material, and packaging. According to the invention, the rice hull, the corncob core, the volcanic rock ballast, the calcium carbonate and the bamboo fiber are used as raw materials for stirring and injection molding, so that the thermal insulation material is more environment-friendly, and the prepared thermal insulation material has high strength and good performance.

Description

Preparation process of heat insulation material

Technical Field

The invention belongs to the technical field of new materials, and particularly relates to a preparation process of a heat-insulating material.

Background

The building heat-insulating material mainly reduces the indoor heat of the building to be dissipated outdoors by taking measures for the outer protective structure of the building, thereby keeping the indoor temperature of the building. Most of building heat-insulating materials on the market are made of foam foaming, and have the advantages of low compressive strength, easy aging and low durability.

Disclosure of Invention

The invention provides a preparation process of a high-quality and anti-aging heat insulation material in order to overcome the defects of the prior art.

A preparation process of a heat insulation material comprises the following steps:

a. crushing: crushing rice hulls, corncobs, volcanic rock residues and calcium carbonate:

b. sieving: sieving rice hull, corncob core, volcanic rock slag and calcium carbonate;

c. preparing bamboo fiber: making bamboo chips into bamboo fibers;

d. stirring: in parts by weight of

25-35 of rice husk

Corncob cores 26-34

Volcanic rock slag 10-15

3-5 parts of calcium carbonate

Bamboo fiber 0.5-1

Adhesive 20-26

Stirring uniformly to obtain a mixture;

e. molding: injecting the mixture into a mold, and demolding after molding;

f. packaging: and cutting the formed heat-insulating material, and then packaging and warehousing.

In the process e, before injection molding, a release agent is firstly coated in a mold; then injecting the mixture into a mould to form the mixture; curing at 5-35 deg.c for 12-30 hr and demolding; the step enables the heat-insulating material to have higher stability after being molded, no crack is formed, and the quality of the heat-insulating material is improved.

The step f, the packaging machine comprises a main body, a cutting frame arranged on the main body, a cutting knife arranged on the cutting frame, a conveying device arranged on the main body, a packaging table arranged on the side edge of the main body and a packaging device arranged at the left end of the main body; the packing device comprises an aligning mechanism arranged on the main body, a rotating stick arranged on the main body, a first spring arranged on the rotating stick, and a packing frame arranged on the main body.

The cutting of the heat-insulating material to be packaged is realized through the arrangement of the cutting knife, so that the heat-insulating material can adapt to the size of the packaging bag; on the other hand, the treatment of the heat-insulating material is improved, and the quality of the heat-insulating material is improved; the intermittent conveying of the heat-insulating material is realized through the arrangement of the conveying device, and the treatment efficiency of the heat-insulating material is improved; on the other hand, the stability of the heat insulation material is improved; the automatic packaging of the cut heat-insulating materials is realized through the arrangement of the packaging device, and the heat-insulating material processing efficiency is improved; on the other hand, because automatic packing is realized, the damage to the heat-insulating material is avoided, and the quality of the finished heat-insulating material is improved; the alignment mechanism is arranged to align a plurality of heat-insulating materials before packaging, so that the heat-insulating materials can smoothly enter the packaging frame, and the stability is improved; on the other hand, because each piece of heat insulation material is arranged in order, the packed heat insulation material is more complete and can not be scratched, and the quality of the heat insulation material is improved; the rolling friction of the heat-insulating material is realized through the arrangement of the rotating roller, and the heat-insulating material is prevented from moving on the packing table and affecting the packing effect; the automatic packing of the heat-insulating material is realized through the arrangement of the packing frame, so that each surface of the heat-insulating material can be sealed by a packing bag, and missing low grades are prevented; the aging resistance of the thermal insulation material is improved.

The conveying device comprises two cross beams arranged on the right side of the main body, first conveying belts arranged on two sides of the cross beams, a lifting mechanism arranged on the first conveying belts, a second conveying belt arranged on the left side of the cross beams, conveying springs arranged in the second conveying belts, and telescopic blocks arranged on the conveying springs.

On one hand, the strength of the heat insulation material can be improved when the heat insulation material is cut through the arrangement of the cross beam, and the heat insulation material is prevented from deforming when the heat insulation material is cut; on the other hand, the heat insulation material can be stably cut into different sizes, so that the stability of the heat insulation material is improved; the protection of the first conveyor belt during cutting is realized through the arrangement of the lifting mechanism, and the influence of pressure on the first conveyor belt during cutting is prevented; the packing effect is further improved; the second conveying belt is arranged to realize secondary conveying of the heat insulation material, so that the cut heat insulation material can be separated, and the treatment effect is improved; on the other hand, the packed heat-insulating material is prevented from breaking the packaging bag due to the influence of friction force during packing, so that the quality of the heat-insulating material is not influenced; the heat-insulating material can be pushed to the packaging table smoothly by the aid of the telescopic blocks, and accordingly the heat-insulating material processing effect is improved.

The lifting mechanism comprises a lifting plate arranged on the first conveying belt, a lifting spring arranged below the lifting plate, a gear arranged on the lifting plate, a rack arranged on the main body, a pressing plate arranged on the inner side of the cutting frame, a clamping groove arranged on the pressing plate, a supporting block arranged on the lifting plate, a second spring arranged on the supporting block, an arc-shaped groove arranged on the supporting block and a limiting assembly arranged on the lifting plate.

The lifting treatment of the first conveyor belt is realized through the arrangement of the lifting plate, so that the first conveyor belt can move to the position below the upper end face of the cross beam during cutting; the heat insulation material can be placed on the cross beam for cutting, so that the quality of the cut heat insulation material is improved; the lifting plate is buffered through the arrangement of the lifting spring, so that the first conveying belt is prevented from being damaged due to the fact that the lifting plate moves too fast, and the treatment of the heat insulation material is prevented from being influenced; the lifting plate is stably conveyed by the arrangement of the mutual meshing of the gear and the rack, so that the lifting plate is prevented from being blocked due to excessive lifting motion; the treatment effect of the heat-insulating material is improved; the arrangement of the clamping groove and the abutting block realizes that the lifting plate is driven to move when the cutting knife is in contact with the heat insulation material, so that the lifting plate can not move downwards at any time; the protection to the heat-insulating material is improved, thereby improving the quality of the heat-insulating material.

The limiting assembly comprises a buckle arranged on the main body, a clamping hole arranged on the lifting plate, a third spring arranged on the buckle, a chute arranged on the buckle, a limiting block arranged on the side edge of the buckle, a fourth spring arranged on the limiting block and a driving groove arranged on the pressing plate.

The limit of the lifting plate is realized through the arrangement of the buckle and the clamping hole, the lifting plate is prevented from moving upwards under the action of the lifting spring, and the heat-insulating material is prevented from being influenced by the upward movement of the first conveyor belt; by the mechanism, the lifting plate can continuously move downwards under the condition that the pressing plate can ensure that the lifting plate is not reset after the lifting plate is driven to move; the cutting effect on the heat-insulating material is improved, and the quality of the heat-insulating material is further improved.

In the step f, after the heat insulation material is cut, the heat insulation material needs to be adjusted and arranged, and then the heat insulation material is packaged.

By the steps, the uniformity of the heat-insulating material can be improved, and the quality of the packed heat-insulating material is further improved.

The aligning mechanism comprises an aligning rod arranged on two sides of the packing table, an aligning spring arranged on the aligning rod, a wave groove arranged on the packing table, a plum blossom groove arranged on the aligning rod, a telescopic rod arranged at the bottom of the aligning rod, a reset spring arranged on the telescopic rod, a pressing rod arranged on the side edge of the packing table, a motor arranged on the pressing rod and a fifth spring arranged on the pressing rod.

The arrangement of the alignment roller realizes the alignment of the side edge of the heat-insulating material, and improves the integrity of the heat-insulating material; the heat insulation material can be neatly packed, and the quality of the heat insulation material is improved; the wave groove is arranged to realize the alignment of the alignment roller, so that the end part of the heat insulation material can be abutted against the alignment roller, and the stability is improved; the heat insulation material is abutted through the arrangement of the return spring, so that the integrity of the heat insulation material is further improved, the heat insulation material can be more delicate after being packaged, and the quality of the heat insulation material is improved; the friction is increased through the arrangement of the plum spline, so that the movement of the heat insulation material is ensured; on the other hand, the end part of the heat insulation material can be abutted against the side of the plum spline, so that the aligning roller can smoothly rotate; the pressing driving of the side edge of the heat-insulating material is realized through the arrangement of the pressing roller, so that the heat-insulating material can move smoothly at the packing platform.

The packaging frame comprises a fixing frame arranged on the packaging table, a movable plate arranged on the fixing frame, a first cloth spreading rod arranged on the movable plate, a sixth spring arranged on the movable plate, a hot melting device arranged on the movable plate, a second cloth spreading rod arranged on the side edge of the fixing frame, a seventh spring arranged on the second cloth spreading rod, packaging bags arranged on four sides of the fixing frame and a focusing device arranged on the fixing frame.

The upper end face of the heat-insulating material is pressed through the arrangement of the moving plate, so that the packaging bag can be tightly attached to the upper end face of the heat-insulating material; on the other hand, air between the heat insulation materials is squeezed, so that the packaging is more sealed, and the quality of the heat insulation materials is improved; the arrangement of the waterfall roller realizes that the packaging bag can be tightly attached to the upper end surface of the heat-insulating material, improves the sealing property of the packaging and further improves the quality of the heat-insulating material; the hot melting device is arranged to seal immediately after the packaging bag is laid, so that the packaging belt can be attached to the heat-insulating material, and the sealing property is improved; the arrangement of the second cloth spreading roller realizes the pressing of the side edge of the heat insulation material, and the sealing performance of the package is improved.

The focusing device comprises a focusing plate arranged on the fixed frame, a focusing spring arranged on the focusing plate and a hot-melting roller 93 arranged on the focusing plate; after the surface of the heat-insulating material is paved with a packaging bag, the heat-insulating material is abutted against the focusing plate; at this time, the hot melting roller 93 is embedded with the edge box of the heat insulation material to perform hot melting sealing on the packaging bag.

The arrangement of the mechanism realizes the hot melting of the edges of the heat-insulating material, so that the packaging bag can be tightly attached to the heat-insulating material; the sealing performance of the heat insulation material is improved, and the influence on quality caused by dampness in the transportation process is prevented.

In conclusion, the invention has the following advantages: the rice hull, the corncob core, the volcanic rock ballast, the calcium carbonate and the bamboo fiber are used as raw materials to be stirred and injected, so that the heat-insulating material is more environment-friendly, and the prepared heat-insulating material is high in strength and good in performance; the volcanic rock ballast is added, so that the compression resistance and the ageing resistance of the heat-insulating material are well improved, and the fireproof performance is good.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a left side view of the present invention.

Fig. 3 is a front view of the present invention.

Fig. 4 is a cross-sectional perspective view along a-a of fig. 2 of the present invention.

Fig. 5 is a first cross-sectional view along a-a of fig. 2 of the present invention.

Fig. 6 is a second cross-sectional view along a-a of fig. 2 of the present invention.

Fig. 7 is a cross-sectional view taken along C-C of fig. 3 of the present invention.

Fig. 8 is a cross-sectional view taken along B-B of fig. 3 of the present invention.

Fig. 9 is a partial view of fig. 4 taken at a in accordance with the present invention.

Fig. 10 is a partial view of the invention at D in fig. 5.

FIG. 11 is a partial view taken at B of FIG. 5 in accordance with the present invention.

Fig. 12 is a partial view of the invention at E of fig. 7.

Fig. 13 is a partial enlarged view at F in fig. 12 of the present invention.

Fig. 14 is a partial view at H of fig. 8 of the present invention.

Fig. 15 is a partial view of the invention at G in fig. 8.

Fig. 16 is a partial view of the invention at C of fig. 5.

Fig. 17 is a partial view of the invention at J of fig. 6.

FIG. 18 is a partial view taken at K of FIG. 6 in accordance with the present invention.

Detailed Description

Example 1:

a preparation process of a heat insulation material is characterized by comprising the following steps: the method comprises the following steps:

c. preparing bamboo fiber: making bamboo chips into bamboo fibers;

d. stirring: in parts by weight of

Rice husk 25

Corncob core 26

Volcanic rock ballast 10

Calcium carbonate 3

Bamboo fiber 0.5

Adhesive 20

Stirring uniformly to obtain a mixture;

e. molding: injecting the mixture into a mold, and demolding after molding;

f. packaging: cutting the formed heat-insulating material, and then packaging and warehousing;

wherein, as shown in fig. 1-18, the packaging machine in step f comprises a main body 1, a cutting frame 2, a cutting knife 3, a conveying device 4, a packaging table 5 and a packaging device 6; the packing device 6 comprises an aligning mechanism 61, a rotating roller 62, a first spring 64 and a packing frame 63; the cutting frame 2 is fixedly arranged on the main body 1; the cutting knife 3 can be embedded in the cutting frame 2 in a way of moving up and down, and the cutting knife 3 is a cutting knife directly available in the market; the conveying device 4 is arranged in the main body 1; the packing table 5 is arranged on the side edge of the main body 1; the packing device 6 is arranged on the packing table 5; the aligning mechanism 61 is arranged on the main body 1 and is positioned at the front end of the packing table 5; the rotating roller 62 is embedded on the plane of the packing table 5 and can rotate and move up and down; the first spring 64 connects the rotary roller 62 and the packing table 5; the packing frame 63 is arranged on the packing table 5 and is positioned in the middle of the packing table 5.

And in the step b, the rice hulls, the corncobs, the volcanic rock residues and the calcium carbonate are sieved, and the mesh number is 60-120 meshes.

In the process e, before injection molding, a release agent is firstly coated in a mold; then injecting the mixture into a mould to form the mixture; curing at 5-35 deg.c for 12-30 hr and demolding.

As shown in fig. 4 and 9, the conveying device 4 includes a cross beam 41, a first conveyor belt 42, a lifting mechanism 7, a second conveyor belt 43, a conveying spring 44, and a telescopic block 45; the number of the cross beams 41 is 2, and the cross beams are fixedly arranged at the bottom of the main body 1; the height of the beam 41 is 3mm lower than the upper surface of the main body 1; the first conveyor belts 42 are 2 groups and are respectively arranged on two sides of the cross beam 41; the second conveyor belt 43 is arranged between the 2 cross beams 41, and the second conveyor belt 43 is positioned at the left side of the first conveyor belt 41; the telescopic block 45 can be embedded on the surface of the second conveyor belt 43 in a way of moving up and down; the conveying spring 44 connects the telescopic block 45 and the second conveying belt 43; the lifting mechanism 7 is disposed at a side of the first conveyor belt 42.

As shown in fig. 10-13, the lifting mechanism 7 includes a lifting plate 71, a lifting spring 72, a gear 73, a rack 74, a pressing plate 75, a slot 76, a pressing block 77, a second spring 78, an arc-shaped groove 79, and a limit component 8; the lifting plate 71 can be embedded on the inner side wall of the main body 1 in a vertically movable manner; the lifting spring 72 is connected with the lifting plate 75 and the main body 1; the gear 73 is rotatably embedded on the lifting plate 71; the rack 74 is fixedly arranged on the main body 1 and meshed with the gear 73; the low pressure plate 75 can be embedded on the inner side wall of the cutting frame 2 in a vertically moving way, and the pressing plate 75 is fixedly connected with the cutting knife 3; the clamping groove 76 is formed in the low pressure plate 75; the resisting block 77 is movably embedded on the lifting plate 77, and the longitudinal section of the resisting block 77 is rhombic; the second spring 78 connects the resisting block 77 and the lifting plate 75; the arc groove 78 is arranged on the abutting block 77, and the arc groove 78 can abut against the clamping groove 76; the limiting assembly 8 is arranged on the lifting plate 71.

As shown in fig. 14, the limiting component 8 includes a buckle 81, a buckle hole 82, a third spring 83, an inclined groove 84, a limiting block 85, a fourth spring 86, and a driving groove 87; the buckle 81 is movably embedded in the main body 1; the clamping hole 82 is formed in the lifting plate 71, and the clamping hole 82 can be embedded with the buckle 81; the third spring 83 connects the buckle 81 and the main body 1; the chute 84 is arranged on the buckle 81; the limiting block 85 is movably embedded on the lifting plate 71, and the limiting block 85 can abut against the chute 84; the fourth spring 86 is connected with the limit block 85 and the lifting plate 71; the driving groove 87 is opened at the side of the lifting groove 71, and the driving groove 87 can abut against the limit block 85.

As shown in fig. 15-16, the aligning mechanism 61 includes an aligning roller 611, an aligning spring 612, a wave groove 613, a telescopic rod 617, a return spring 618, a plum blossom groove 614, a pressing roller 615, a motor 616, and a fifth spring 617; the aligning rods 611 are provided with 2 rods which are rotatably embedded at two sides of the packing table 5 and are positioned at the front end of the packing table 5; the aligning spring 612 is connected with the aligning roller 611 and the bottom of the packing table 5; the wave groove 613 is arranged on the packing table 5 and is positioned below the aligning roller 611; the telescopic rod 617 is arranged at the bottom of the aligning stick 611, and the telescopic rod 617 can be abutted against the wave groove 613; the return spring 618 is connected with the telescopic rod 617 and the aligning roller 611; the plum blossom groove 614 is arranged on the surface of the aligning stick 611; the low-pressure rollers 615 are provided with a plurality of rollers which can rotate and are movably embedded at the side of the packing table 5; the motor 616 is connected with the pressing roller 615, and the motor 616 is directly purchased from the market; the fifth spring 617 connects the low-pressure roller 615 and the packing table 5.

As shown in fig. 4, 6 and 17, the packing frame 63 includes a fixing frame 631, a moving plate 632, a first cloth spreading roller 633, a sixth spring 634, a hot melting device 635, a second cloth spreading roller 636, a seventh spring 637, a packing bag 638 and a focusing device 9; the fixing frame 631 is provided with both sides of the packing table 5; the moving plate 632 can be embedded on the fixed frame 631 to move up and down; the first cloth spreading roller 633 is provided with a plurality of rotatable cloth spreading rollers embedded on the moving plate 632; the sixth spring 634 connects the moving plate 632 and the fixed frame 631; the hot melting device 635 is arranged on the moving plate 632, and the hot melting device 635 is directly purchased from the market; the second cloth spreading roller 636 is rotatably embedded at the side of the fixed frame 631; the seventh spring 637 is connected with the second cloth spreading stick 636 and the fixed frame 631; the packaging bag 638 is provided with 4 groups which are respectively positioned on four sides of the fixing frame 631; the number of the focalizers 9 is 4, and the focalizers are arranged on four sides of the fixing frame 631.

As shown in fig. 18, the focusing unit 9 includes a focusing plate 91, a focusing spring 92, and a fusing roller 93; the focusing plates 91 are movably embedded on four edges of the fixed frame 631; the focusing spring 92 connects the focusing plate 91 and the fixing frame 631; the hot-melt roller 93 is rotatably embedded on the inner side of the focusing plate 91.

Example 2

c. preparing bamboo fiber: making bamboo chips into bamboo fibers;

d. stirring: in parts by weight of

Rice husk 35

Corncob core 34

Volcanic rock ballast 15

Calcium carbonate 5

Bamboo fiber 1

Adhesive 26

Stirring uniformly to obtain a mixture;

e. molding: injecting the mixture into a mold, and demolding after molding;

example 3

c. preparing bamboo fiber: making bamboo chips into bamboo fibers;

d. stirring: in parts by weight of

Rice husk 30

Corncob core 29

Volcanic rock slag 13

Calcium carbonate 4

Bamboo fiber 0.8

Adhesive 23

Stirring uniformly to obtain a mixture;

e. molding: injecting the mixture into a mold, and demolding after molding;

the specific working process is as follows: firstly, placing a molded heat insulation material on a conveying device 4; then starting the conveying device 4 to convey the heat-insulating material to the lower part of the cutting frame 2; at the moment, the cutting knife 3 is started to cut the heat insulation material; then, the heat-insulating material is conveyed continuously, and meanwhile, the heat-insulating material is slowly separated on the conveying device 4; the heat insulation material conveyed by the conveying device 4 is contacted with the rotating roller 62, and the rotating roller 62 is driven to move downwards under the influence of the self gravity of the heat insulation material; then, under the pushing of the conveying device 4, the heat-insulating material moves on the rotating roller 62; the heat-insulating material is contacted with the rotating rod 62 and the aligning mechanism 61 at the same time, so that the heat-insulating material is aligned; at the moment, the heat insulation material enters the packing frame 63, and the heat insulation plate is automatically packed.

Claims

1. A preparation process of a heat insulation material is characterized by comprising the following steps: the method comprises the following steps:

crushing: crushing rice hulls, corncobs, volcanic rock residues and calcium carbonate:

sieving: sieving rice hull, corncob core, volcanic rock slag and calcium carbonate;

preparing bamboo fiber: making bamboo chips into bamboo fibers;

stirring: in parts by weight of

25-35 of rice husk

Corncob cores 26-34

Volcanic rock slag 10-15

3-5 parts of calcium carbonate

Bamboo fiber 0.5-1

Adhesive 20-26

Stirring uniformly to obtain a mixture;

molding: injecting the mixture into a mold, and demolding after molding;

packaging: and cutting the formed heat-insulating material, and then packaging and warehousing.

2. The preparation process of the heat insulation material according to claim 1, characterized in that: in the process e, before injection molding, a release agent is firstly coated in a mold; then injecting the mixture into a mould to form the mixture; curing at 5-35 deg.c for 12-30 hr and demolding.

3. The preparation process of the heat insulation material according to claim 1, characterized in that: the step f, the packing machine comprises a main body (1), a cutting frame (2) arranged on the main body (1), a cutting knife (3) arranged on the cutting frame (2), a conveying device (4) arranged on the main body (1), a packing table (5) arranged on the side edge of the main body (1) and a packing device (6) arranged at the left end of the main body (1); the packing device (6) comprises an aligning mechanism (61) arranged on the main body (1), a rotating stick (62) arranged on the main body (1), a first spring (64) arranged on the rotating stick (62), and a packing frame (63) arranged on the main body (1); firstly, placing the formed heat-insulating material on a conveying device (4); then starting a conveying device (4) to convey the heat-insulating material to the lower part of the cutting frame (2); at the moment, the cutting knife (3) is started to cut the heat-insulating material; then, the heat-insulating material is conveyed continuously, and meanwhile, the heat-insulating material is slowly separated on the conveying device (4); the heat insulation material is conveyed by the conveying device (4) to be contacted with the rotating roller (62), and the rotating roller (62) is driven to move downwards under the influence of the self gravity of the heat insulation material; then under the pushing of the conveying device (4), the heat insulation material moves on the rotating stick (62); the heat-insulating material is contacted with the aligning mechanism (61) while being contacted with the rotating stick (62), so that the heat-insulating material is aligned; at the moment, the heat insulation material enters the packaging frame (63) and automatically packages the heat insulation plate.

4. The preparation process of the heat insulation material according to claim 3, characterized in that: the conveying device (4) comprises two cross beams (41) arranged on the right side of the main body (1), first conveying belts (42) arranged on two sides of the cross beams (41), a lifting mechanism (7) arranged on the first conveying belts (42), second conveying belts (43) arranged on the left side of the cross beams (41), conveying springs (44) arranged in the second conveying belts (43), and telescopic blocks (45) arranged on the conveying springs (44); placing the insulation material on a first conveyor belt (42) to start conveying; when the heat insulation material is conveyed to the position below the cutting frame (2), the cutting knife (3) is started to move downwards; at the moment, when the cutting knife (3) moves downwards, the lifting mechanism (7) is driven to start; then the first conveyor belt (42) starts to move downwards, and the heat insulation material on the first conveyor belt (42) falls on the cross beam (41); then cutting off the heat insulation material by a cutting knife (3); then conveying the cut heat-insulating material to a second conveyor belt (43) through a first conveyor belt (42); at the moment, the telescopic block (45) moves downwards under the self gravity of the heat insulation material, and the heat insulation material is pushed into the packing device (6) through the second conveying belt (43).

5. The preparation process of the heat insulation material according to claim 4, characterized in that: the lifting mechanism (7) comprises a lifting plate (71) arranged on the first conveying belt (42), a lifting spring (72) arranged below the lifting plate (71), a gear (73) arranged on the lifting plate (71), a rack (74) arranged on the main body (1), a pressing plate (75) arranged on the inner side of the cutting frame (2), a clamping groove (76) arranged on the pressing plate (75), a pressing block (77) arranged on the lifting plate (75), a second spring (78) arranged on the pressing block (77), an arc-shaped groove (79) arranged on the pressing block (77), and a limiting assembly (8) arranged on the lifting plate (71); when the cutting knife (3) moves downwards, the pressing plate (75) is driven to move downwards; then the clamping groove (76) on the pressing plate (75) is pressed against the pressing block (77), and the clamping groove (76) is in contact with the arc groove (79); the lifting plate (71) is driven to move downwards, and the gear (73) starts to rotate on the rack (74); at the moment, the limiting assembly (8) starts to drive, so that the lifting plate (71) is kept stable and motionless.

6. The preparation process of the heat insulation material according to claim 5, characterized in that: the limiting assembly (8) comprises a buckle (81) arranged on the main body (1), a clamping hole (82) arranged on the lifting plate (71), a third spring (83) arranged on the buckle (81), a chute (84) formed on the buckle (81), a limiting block (85) arranged on the side edge of the buckle (81), a fourth spring (86) arranged on the limiting block (85), and a driving groove (87) formed on the pressing plate (75); when the pressing plate (75) drives the lifting plate (71) to move downwards, the pressing block (77) is separated from the clamping groove (76) and continuously moves downwards; at the moment, the limiting block (85) is abutted against the driving groove (87) to drive the limiting block (85) to transversely move; then the limiting block (85) is abutted against the chute (84) to drive the buckle (81) to move and is embedded with the clamping hole (82) to lock the lifting plate (71).

7. The preparation process of the heat insulation material according to claim 3, wherein in the step f, the heat insulation material is required to be adjusted and finished after being cut, and then is packaged.

8. The preparation process of the heat insulation material according to claim 3, characterized in that: the aligning mechanism (61) comprises an aligning roller (611) arranged on two sides of the packing table (5), an aligning spring (612) arranged on the aligning roller (611), a wave groove (613) arranged on the packing table (5), a quincunx groove (614) arranged on the aligning roller (611), an expansion rod (617) arranged at the bottom of the aligning roller (611), a return spring (618) arranged on the expansion rod (617), a pressing roller (615) arranged on the side edge of the packing table (5), a motor (616) arranged on the pressing roller (615), and a fifth spring (617) arranged on the pressing roller (615); when the second conveyor belt (43) pushes the heat-insulating material to just enter the packing table (5), firstly, two side edges of the front end of the heat-insulating material are abutted against the plum blossom groove (614); the aligning roller (611) is driven to rotate, and the aligning roller (611) is moved transversely under the action of the aligning spring (612); meanwhile, under the influence of force interaction, the side edges of the heat insulation material are integrated; the heat insulation material is pressed against the pressing roller (615) along with the pushing of the second conveyor belt (43); the motor (616) is started, so that the pressing roller (615) starts to drive the heat-insulating material to move continuously into the packing frame (63).

9. The preparation process of the heat insulation material according to claim 3, characterized in that: the packing frame (63) comprises a fixing frame (631) arranged on the packing table (5), a moving plate (632) arranged on the fixing frame (631), a first cloth spreading stick (633) arranged on the moving plate (632), a sixth spring (634) arranged on the moving plate (632), a hot melting device (635) arranged on the moving plate (632), a second cloth spreading stick (636) arranged on the side of the fixing frame (631), a seventh spring (637) arranged on the second cloth spreading stick (636), packing bags (638) arranged on four sides of the fixing frame (631), and a focusing device (9) arranged on the fixing frame (631); when the heat insulation material enters the fixing frame (631), the end part of the heat insulation material is abutted against the packaging bag (638); pulling the bag (638) to lay flat on each side of the insulation as the insulation moves; at the moment, the packaging bag is tightly attached to the surface of the heat-insulating material under the pressing of a first cloth spreading roller (633) and a second cloth spreading roller (636); along with the movement of the heat insulation material, the edge of the heat insulation material is abutted against the focusing device (9); at the moment, the packaging bags (638) are fused together, and meanwhile, the hot-melting device (635) is started to perform hot-melting sealing on the packaging bags.

10. The preparation process of the heat insulation material according to claim 9, characterized in that: the focusing device (9) comprises a focusing plate (91) arranged on the fixing frame (631), a focusing spring (92) arranged on the focusing plate (91), and a hot-melting roller (93) arranged on the focusing plate (91); after the surface of the heat insulation material is paved with a packaging bag, the heat insulation material is abutted against a focusing plate (91); at the moment, the hot melting roller (93) is embedded with the edge box of the heat insulation material, and the packaging bag (638) is subjected to hot melting sealing.