CN215829087U

CN215829087U - Full-automatic high-temperature fabric setting machine

Info

Publication number: CN215829087U
Application number: CN202121485210.6U
Authority: CN
Inventors: 吕康康
Original assignee: Dongyang Gaoshan Knitting Co ltd
Current assignee: Dongyang Gaoshan Knitting Co ltd
Priority date: 2021-07-01
Filing date: 2021-07-01
Publication date: 2022-02-15
Anticipated expiration: 2031-07-01

Abstract

The utility model discloses a full-automatic high-temperature fabric setting machine, which comprises a machine body, a housing, an air supply pipe and a fixing device, wherein the housing is provided with a plurality of air supply pipes; a perforated plate is arranged in the housing; the fixing device comprises an intermediate shaft, an embedding groove, a motor, an embedding rod, a supporting plate and a driving piece; a feeding groove is formed in the top of the housing; a plurality of templates for shaping the socks are arranged on the intermediate shaft; a fixing component for fixing the template is arranged on the intermediate shaft; when the multifunctional sock shaping machine is used, hot air is sent between the housing and the porous plate by the air supply pipe and gradually enters the porous plate, so that the hot air is uniformly distributed in the porous plate, and meanwhile, the templates are driven by the motor to coaxially rotate, so that socks on the templates are further uniformly heated, and the shaping effect of the socks is ensured; the lower sealing plate is arranged so that the template can be withdrawn from the housing from the feeding groove to complete the assembly and disassembly of the socks, the interior of the housing is in a closed state, the heat loss is reduced, and the processing efficiency is improved.

Description

Full-automatic high-temperature fabric setting machine

Technical Field

The utility model belongs to the field of sock production and processing, and particularly relates to a full-automatic fabric high-temperature setting machine.

Background

As is well known, socks are necessities of daily life of people, the requirements of people on the quality of the socks are higher and higher along with the improvement of the living standard of people, especially for the shaping of the socks, people often prefer the socks which are not easy to walk, and the socks are generally shaped by utilizing a shaping machine in the processing process.

Sock forming machine generally utilizes high temperature to add fever design to the socks of cover outside the mould, and traditional high temperature sock forming machine generally uses the electric heat piece to generate heat and stereotype socks, it is main to follow the grinding apparatus with the socks of cover outside the mould and fix in airtight box together, then utilize the heating block circular telegram that sets up in the box to generate heat and stereotype socks, because the heating block is when the circular telegram generates heat, there is the socks that keep away from the heating block to be heated the wall and be close to the phenomenon that the heating block socks are heated fewly, this just leads to traditional high temperature sock forming machine to appear that socks are heated inhomogeneous problem and appear.

SUMMERY OF THE UTILITY MODEL

The utility model provides a full-automatic high-temperature fabric setting machine for ensuring the setting quality in order to overcome the defects of the prior art.

The technical scheme provided by the utility model is as follows: a full-automatic fabric high-temperature setting machine comprises a machine body, a housing arranged on the machine body, a plurality of blast pipes arranged at the bottom of the housing, and a fixing device arranged in the housing; a perforated plate is arranged inside the housing; the fixing device comprises an intermediate shaft positioned in the perforated plate, an embedded groove arranged on the rotating shaft, a motor fixed at the bottom of the machine body, an embedded rod connected with the rotating shaft of the motor and inserted into the embedded groove, a supporting plate arranged at the bottom of the intermediate shaft and a driving piece fixed at the bottom of the machine body and used for driving the supporting plate to move up and down; a feeding groove is formed in the top of the housing; a plurality of templates for shaping the socks are arranged on the intermediate shaft; the template can pass through the feed chute; an upper sealing plate is arranged at the top of the intermediate shaft; the upper sealing plate is used for sealing the feeding groove; the lower part of the intermediate shaft is provided with a lower sealing plate; the lower sealing plate is positioned below the template; and the intermediate shaft is provided with a fixing component for fixing the template.

When the device works, the driving piece pulls the supporting plate to move downwards, so that the intermediate shaft and the template move downwards to the inside of the pore plate, the upper sealing plate seals the feeding groove, and the inside of the housing is in a closed state; an external air source supplies air to the air supply pipe, hot air firstly enters the middle area between the housing and the pore plate and then enters the pore plate from the small holes on the surface of the pore plate, so that the hot air is fully diffused around the template; meanwhile, the motor drives the intermediate shaft to rotate, the template rotates along with the intermediate shaft, and the socks on the template are further fully contacted with hot air, so that the shaping effect of the socks is ensured; accomplish the back driving piece that stereotypes and drive the template and move out the housing from the feed chute, lower shrouding seals the feed chute afterwards, protects the inside steam of housing, reduces the steam trumpet, and then makes the socks that get into in the housing next design rapider, has promoted production efficiency.

Further, a cross slide block is arranged on the surface of the middle shaft; the lower sealing plate comprises a first flat plate arranged on the intermediate shaft, a plurality of short columns arranged on the first flat plate, a plurality of first springs arranged on the first flat plate, and a vent plate fixed at the bottoms of the first springs; the vent plate is provided with air holes which are in one-to-one correspondence with the short columns; the middle part of the vent plate is provided with a cross sliding chute; the aeration plate is positioned below the template; the cross sliding block can slide up and down along the cross sliding groove.

In the shaping process of the socks, the short columns are positioned below the air holes, and the air entering the bottom of the first flat plate from the pore plate moves upwards from the air holes to ensure that hot air at all positions around the template is uniformly distributed; after finishing the design, along with shifting up of jackshaft, the aeration board contacts the feed chute bottom surface, and in the air hole was inserted to the short column, the circulation of air about blocking the aeration board, and then inside the closed housing to keep warm to the housing is inside.

Further, a mounting seat is arranged at the center of the top of the middle shaft; the middle part of the mounting seat is provided with a spacer ring; the upper sealing plate comprises a supporting column inserted in the mounting seat, a second flat plate rotatably connected to the top of the supporting column and a first tension spring arranged at the bottom of the supporting column; a first magnetic ring is fixed on the support column; the second plate is positioned above the feeding groove; the first tension spring is positioned between the support column and the mounting seat; the bottom of the support column is positioned below the spacer ring; and in the process of placing the template into the housing, the second flat plate gradually contacts the top surface of the feeding groove, and the second flat plate is tightly attached to the top surface of the feeding groove under the action of the tension of the first tension spring, so that the top of the housing is sealed.

Furthermore, one end of the template is provided with a slot; the slots are provided with triangular blocks; the middle shaft is provided with vertical grooves corresponding to the templates one by one; square grooves are arranged on the lateral sides of the vertical grooves; two sides of the top of the square groove are respectively provided with a through groove; the fixing assembly comprises a trapezoidal block connected in the mounting groove in a sliding manner, a second spring arranged between the trapezoidal block and the square groove, rectangular blocks inserted between the through groove and the square groove, circular plates used for connecting the rectangular blocks and hollow columns arranged at the bottoms of the circular plates; the template is inserted into the vertical groove; the trapezoidal blocks are inserted in the slots; the triangular block is attached to one side of the trapezoidal block; the bottom of the rectangular block is contacted with one end of the rectangular block; a second tension spring is sleeved outside the hollow column; a second magnetic ring is fixed at the bottom of the hollow column; the hollow column is inserted into the mounting seat and is positioned above the spacer ring; the second tension spring is positioned between the hollow column and the mounting seat; the support columns are inserted into the hollow columns; the second magnetic ring and the first magnetic ring attract each other.

When the template is used, the template is inserted into the vertical groove, and the trapezoidal block is inserted into the slot, so that one end of the template is fixed in the vertical groove; in the process of moving the socks to the inner part of the pore plate, the first magnetic ring is gradually close to the second magnetic ring, so that the circular plate moves downwards, the rectangular blocks are respectively inserted into the square grooves below the rectangular blocks and contact the end surfaces of the trapezoidal blocks, the template is completely fixed on the intermediate shaft, the socks are prevented from loosening and deforming due to the shaking of the template, the template is prevented from falling off from the intermediate shaft due to the loosening of the trapezoidal blocks in the process of rotating the template along with the intermediate shaft, and the smooth shaping work is ensured; after the shaping is completed, the supporting column moves downwards relative to the hollow column under the action of the first tension spring along with the upward movement of the intermediate shaft, the first magnetic ring and the second magnetic ring are mutually far away, the second tension spring pulls the circular plate to move upwards, the rectangular block moves back into the through groove, the template can be taken out from the vertical groove by pulling the template at the moment, and a user can conveniently replace the template.

Further, a T-shaped groove is formed in the bottom of the vertical groove; the fixing assembly further comprises a first fixing piece inserted in the upper part of the vertical groove and a second fixing piece inserted in the T-shaped groove; the first fixing piece comprises a first rotating rod, a pressing block and a first contact point, wherein the middle part of the first rotating rod is rotatably connected in the vertical groove; the second fixing piece comprises a second rotating rod rotatably connected in the T-shaped groove, a second contact point arranged at one end of the second rotating rod, a balancing weight arranged below the second contact point, and an inclined block which is positioned above the other end of the second rotating rod and can move up and down along the T-shaped groove; the bottom of the first rotating rod contacts the template; the top of the pressing block contacts the circular plate; the first contact point is hollow inside, and the bottom of the first contact point is in contact with the top of the socks sleeved on the template; the top of the inclined block is contacted with the template; the second contact point is hollow inside, and the top of the second contact point is in contact with the bottom of the sock sleeved on the template.

In the process that the template is inserted into the vertical groove, the first rotating rod on the top part rotates to enable the second contact point to be in contact with the socks on the template, meanwhile, the bottom part of the template is in contact with the inclined block and pushes the inclined block to move downwards, so that the second rotating rod rotates, and the second contact point is in contact with the socks; the first contact point and the second contact point are hollow, and the socks are deformed after being contacted to be tightly attached to the socks and further fixed, so that the socks are prevented from loosening in the qualitative process to interfere with the shaping effect; and in the shaping process, the bottom of the disc is in contact with the pressing block, the bottom of the template is in contact with the top of the inclined block, the first rotating rod and the second rotating rod are further limited, and the first contact point and the second contact point are prevented from loosening.

In conclusion, when the multifunctional sock shaping machine is used, the air supply pipe supplies hot air between the housing and the porous plate and gradually enters the porous plate, so that the hot air is uniformly distributed in the porous plate, and meanwhile, the templates are driven by the motor to coaxially rotate, so that socks on the templates are further uniformly heated, and the shaping effect of the socks is ensured; the lower sealing plate is arranged so that the template can be withdrawn from the housing from the feeding groove to complete the assembly and disassembly of the socks, the interior of the housing is in a closed state, the heat loss is reduced, and the processing efficiency is improved.

Drawings

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

Fig. 2 is a schematic cross-sectional structure of the present invention.

Fig. 3 is an exploded view of a portion of the structure of the fastening device of fig. 1.

Fig. 4 is a schematic sectional view of the intermediate shaft of fig. 3.

Fig. 5 is a partially enlarged view of a portion a in fig. 1.

Fig. 6 is a partially enlarged view of a portion B in fig. 1.

Fig. 7 is a partially enlarged view of a portion C in fig. 2.

Fig. 8 is a sectional view of a portion of the structure of the fixing assembly of fig. 5.

Fig. 9 is an exploded view of the lower closure plate of fig. 1.

Detailed Description

In order to make the technical solutions of the present invention better understood, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention.

As shown in fig. 1-9, a full-automatic fabric high-temperature setting machine comprises a machine body 1, a housing 2 arranged on the machine body 1, a plurality of blast pipes 3 arranged at the bottom of the housing 2, and a fixing device 4 arranged inside the housing 2; a perforated plate 5 is arranged in the housing 2; the fixing device 4 comprises an intermediate shaft 41 positioned in the perforated plate, a tabling groove 411 arranged on the rotating shaft, a motor 42 fixed at the bottom of the machine body 1, a tabling rod 43 connected with the rotating shaft of the motor 42 and inserted into the tabling groove 411, a supporting plate 44 arranged at the bottom of the intermediate shaft 41, and a driving piece 45 fixed at the bottom of the machine body 1 and used for driving the supporting plate 44 to move up and down; a feeding groove 21 is formed in the top of the housing 2; a plurality of templates 46 for shaping socks are arranged on the intermediate shaft 41; the die plate 46 can pass through the feed chute 21; the top of the intermediate shaft 41 is provided with an upper sealing plate 47; the upper sealing plate 47 is used for sealing the feeding groove 21; a lower sealing plate 48 is arranged at the lower part of the intermediate shaft 41; the lower closure plate 48 is positioned below the template 46; a fixing assembly 49 for fixing the template 46 is mounted on the intermediate shaft 41.

The blast pipe 3 is connected with the existing external hot air source and is used for conveying hot air between the housing 2 and the pore plate; the intermediate shaft 41 is positioned in the middle area of the inner side of the orifice plate, and the templates 46 are circumferentially distributed around the intermediate shaft 41; the support plate 44 is rotatably connected to the bottom of the intermediate shaft 41, and the driving member 45 is preferably a commercially available air cylinder for driving the support plate 44 to move up and down so that the intermediate shaft 41 can be inserted into or removed from the inside of the sealing plate; the engaging rod 43 is inserted into the engaging groove 411 from the bottom of the engaging groove 411 and can slide up and down along the engaging groove 411, so that when the motor 42 drives the engaging rod 43 to rotate, the intermediate shaft 41 can rotate along with the engaging rod, and the driving member 45 drives the intermediate shaft 41 to move up and is always connected with the engaging rod 43; feed chute 21 corresponds to die plate 46 one-to-one and the width of the chute is greater than the thickness of die plate 46 so that die plate 46 can normally pass through feed chute 21.

Further, a cross sliding block 412 is arranged on the surface of the intermediate shaft 41; the lower sealing plate 48 includes a first flat plate 481 provided on the intermediate shaft 41, a plurality of stubs 482 provided on the first flat plate 481, a plurality of first springs 483 provided on the first flat plate 481, and a vent plate 484 fixed to the bottom of the plurality of first springs 483; the vent plate 484 is provided with air holes 485 corresponding to the short columns 482 one by one; a cross sliding chute 486 is arranged in the middle of the ventilating plate 484; the aeration panel 484 is positioned below the template 46; the cross sliding block 412 can slide up and down along the cross sliding groove 486.

The first plate 481 is fixed to the intermediate shaft 41, and the stub 482 is fitted with a commercially available seal ring, which is not shown in the drawings of the specification, so as to completely close the air hole 485 when the stub 482 is inserted into the air hole 485; the cross sliding block 412 is inserted into the cross sliding groove 486, and the ventilation plate 484 and the first flat plate 481 synchronously rotate in the rotation process of the intermediate shaft 41, so that the short columns 482 can be correctly inserted into the air holes 485; the first spring 483 is used to support the vent plate 484 with the first plate 481 after the template 46 is inserted inside the orifice plate.

Further, a mounting seat 413 is arranged at the center of the top of the middle shaft 41; a spacer ring 414 is arranged in the middle of the mounting seat 413; the upper sealing plate 47 comprises a supporting column 471 inserted in the mounting seat 413, a second flat plate 472 rotatably connected to the top of the supporting column 471, and a first tension spring 473 arranged at the bottom of the supporting column 471; a first magnetic ring 474 is fixed on the supporting column 471; the second flat plate 472 is positioned above the feed chute 21; the first tension spring 473 is located between the support column 471 and the mounting seat 413; the bottom of the supporting column 471 is positioned below the spacer ring 414; one end of the template 46 is provided with a slot 461; a triangular block 462 is arranged on the slot; the middle shaft 41 is provided with vertical grooves 415 corresponding to the templates 46 one by one; a square groove 416 is arranged on the side of each vertical groove 415; two sides of the top of the square groove 416 are respectively provided with a through groove 417; the fixing assembly 49 comprises a trapezoidal block 491 slidably connected in the mounting groove, a second spring 492 arranged between the trapezoidal block 491 and the square groove 416, a rectangular block 493 inserted between the through groove 417 and the square groove 416, a circular plate 494 used for connecting each rectangular block 493, and a hollow column 495 arranged at the bottom of the circular plate 494; the template 46 is inserted into the vertical slot 415; the trapezoidal blocks 491 are inserted into the slots 461; the triangular block 462 is attached to one side of the trapezoidal block 491; the bottom of the rectangular block 493 is in contact with one end of the rectangular block 493; a second tension spring 496 is sleeved outside the hollow column 495; a second magnetic ring 497 is fixed at the bottom of the hollow column 495; the hollow column 495 is inserted into the mounting seat 413 and is located above the spacer ring 414; the second tension spring 496 is positioned between the hollow column 495 and the mounting seat 413; the supporting columns 471 are inserted into the hollow columns 495; the second magnetic ring 497 and the first magnetic ring 474 attract each other.

When the template 46 is inserted into the vertical groove 415, the end part of the template 46 contacts one end of the trapezoidal block 491 with the inclined plane, the trapezoidal block 491 is pushed to retreat into the square groove 416 until the square groove 416 is opposite to the slot 461, the trapezoidal block 491 is inserted into the slot 461 under the action of the second spring 492, the triangular block 462 is attached to the inclined plane end of the trapezoidal block 491, and the installation of the template 46 on the intermediate shaft 41 is completed; the second flat plate 472 is rotatably connected with the support column 471, so that the bottom surface of the second flat plate 472 is prevented from being abraded due to the rotation of the intermediate shaft 41 in the shaping process, and the sealing effect of the second flat plate 472 on the feed chute 21 is ensured; the first magnetic ring 474 and the second magnetic ring 497 have opposite magnetism so that they can attract each other, so that the circular plate 494 can be driven to move downwards along with the upward movement of the supporting column 471 after the second plate 472 contacts the top surface of the feeding chute 21; when the circular plate 494 moves downwards, the rectangular block 493 moves downwards from the through groove 417 to the vertical groove 415, and contacts one end of the trapezoidal block 491 provided with the second spring 492 to prevent the trapezoidal block 491 from shaking; after the template 46 is removed from the orifice plate, the block 493 moves upward and retracts into the slot 417, whereupon pulling the template 46, the cam 462 pushes the trapezoidal block 491 to retract into the square slot 416 until the template 46 is removed from the vertical slot 415 and the trapezoidal block 491 is reset by the second spring 492.

Further, a T-shaped groove 418 is arranged at the bottom of the vertical groove 415; the fixing assembly 49 further comprises a first fixing member 498 inserted in the upper portion of the vertical groove 415, and a second fixing member 499 inserted in the T-shaped groove 418; the first fixing member 498 includes a first rotating rod 4981 rotatably connected to the middle of the vertical slot 415, a pressing block 4982 disposed at the top of the first rotating rod 4981, and a first contact point 4983 disposed at one end of the first rotating rod 4981; the second fixing member 499 comprises a second rotating rod 4991 rotatably connected in the T-shaped slot 418, a second contact point 4992 provided at one end of the second rotating rod 4991, a counter weight 4993 provided below the second contact point 4992, and a ramp 4994 located above the other end of the second rotating rod 4991 and capable of moving up and down along the T-shaped slot 418; the bottom of first stem 4981 contacts template 46; the top of the pressure block 4982 contacts a circular plate 494; the first contact point 4983 is hollow inside and the bottom of the first contact point contacts the top of the sock sleeved on the template 46; the top of ramp 4994 contacts template 46; the second contact point 4992 is hollow and has a top contacting the bottom of the sock sleeved on the template 46.

The pressing block 4982 is located at one end of the first rotating rod 4981 far from the first contact point 4983, so that when the template 46 is not inserted into the vertical slot 415, the end of the rotating rod provided with the pressing block 4982 is obliquely and downwards arranged in the vertical slot 415 when the gravity difference between the two ends of the first rotating rod 4981 is poor, and the template 46 can be ensured to be inserted into the vertical slot 415 to drive the first rotating rod 4981 to rotate; a weight 4993 is provided at the bottom of the second contact point 4992, and after the die plate 46 exits the vertical slot 415, the end of the second lever 4991 having the weight 4993 is disposed obliquely downward in the T-shaped slot 418 and pushes the top of the oblique block 4994 to insert into the vertical slot 415.

When the sock rack is used specifically, socks are sleeved on the templates 46 one by one, one end of each template 46 is inserted into the vertical groove 415 until the trapezoidal blocks 491 are inserted into the slots 461, the first rotating rod 4981 and the second rotating rod 4991 rotate along with the trapezoidal blocks, and the first contact point 4983 and the second contact point 4992 are respectively abutted against the upper end and the lower end of each sock to complete the installation of the templates 46; then the driving piece 45 drives the middle shaft 41 to move downwards, the template 46 enters the interior of the pore plate from the feeding groove 21, the second flat plate 472 seals the feeding groove 21, the first magnetic ring 474 and the second magnetic ring 497 are mutually attracted, the circular plate 494 moves downwards, the rectangular block 493 is inserted into the square groove 416 and contacts with the trapezoidal block 491, and the trapezoidal block 491 is locked; an external hot air source supplies air to the air supply pipe 3, hot air enters between the housing 2 and the pore plate and is diffused to the periphery of the template 46 from the small holes on the surface of the pore plate and the air holes 485 on the ventilation plate 484, the motor 42 drives the embedded rod 43 to rotate, the intermediate shaft 41 rotates along with the rotation of the embedded rod, and socks are shaped on the inner side of the pore plate; then the motor 42 stops working, the driving piece 45 drives the intermediate shaft 41 to move upwards, and the template 46 is withdrawn out of the housing 2; the first tension spring 473 drives the second flat plate 472 to move downwards to reset relative to the hollow column 495, the second tension spring 496 drives the circular plate 494 to move upwards to reset, the rectangular block 493 retracts into the through groove 417, and the template 46 and the socks can be taken down by pulling the template 46; when the intermediate shaft 41 moves upward, the air-vent plate 484 contacts the bottom surface of the feed chute 21, the first spring 483 contracts, and the stubs 482 are inserted into the air holes 485, closing the feed chute 21 to insulate the inside of the housing 2.

Claims

1. A full-automatic fabric high-temperature setting machine comprises a machine body (1), a housing (2) arranged on the machine body (1), a plurality of blast pipes (3) arranged at the bottom of the housing (2), and a fixing device (4) arranged inside the housing (2); the method is characterized in that: a perforated plate (5) is arranged in the housing (2); the fixing device (4) comprises an intermediate shaft (41) positioned in the perforated plate, a tabling groove (411) arranged on the rotating shaft, a motor (42) fixed at the bottom of the machine body (1), a tabling rod (43) connected with the rotating shaft of the motor (42) and inserted into the tabling groove (411), a supporting plate (44) arranged at the bottom of the intermediate shaft (41), and a driving piece (45) fixed at the bottom of the machine body (1) and used for driving the supporting plate (44) to move up and down; a feeding groove (21) is formed in the top of the housing (2); a plurality of templates (46) for shaping socks are arranged on the intermediate shaft (41); the template (46) can pass through the feed chute (21); an upper sealing plate (47) is arranged at the top of the middle shaft (41); the upper closing plate (47) is used for closing the feeding groove (21); a lower sealing plate (48) is arranged at the lower part of the middle shaft (41); the lower sealing plate (48) is positioned below the template (46); and a fixing assembly (49) for fixing the template (46) is arranged on the intermediate shaft (41).

2. The full-automatic high-temperature fabric setting machine according to claim 1, characterized in that: the surface of the intermediate shaft (41) is provided with a cross sliding block (412); the lower sealing plate (48) comprises a first flat plate (481) arranged on the middle shaft (41), a plurality of short columns (482) arranged on the first flat plate (481), a plurality of first springs (483) arranged on the first flat plate (481), and a vent plate (484) fixed at the bottoms of the first springs (483); the vent plate (484) is provided with air holes (485) which are in one-to-one correspondence with the short columns (482); a cross sliding chute (486) is arranged in the middle of the ventilating plate (484); the aeration panel (484) is located below the template (46); the cross sliding block (412) can slide up and down along the cross sliding groove (486).

3. The full-automatic high-temperature fabric setting machine according to claim 1, characterized in that: the center of the top of the middle shaft (41) is provided with a mounting seat (413); a spacer ring (414) is arranged in the middle of the mounting seat (413); the upper sealing plate (47) comprises a supporting column (471) inserted in the mounting seat (413), a second flat plate (472) rotatably connected to the top of the supporting column (471), and a first tension spring (473) arranged at the bottom of the supporting column (471); a first magnetic ring (474) is fixed on the supporting column (471); the second plate (472) is positioned above the feed chute (21); the first tension spring (473) is positioned between the support column (471) and the mounting seat (413); the bottom of the support column (471) is positioned below the spacer ring (414).

4. The full-automatic high-temperature fabric setting machine according to claim 3, characterized in that: one end of the template (46) is provided with a slot (461); a triangular block (462) is arranged on the slot; the middle shaft (41) is provided with vertical grooves (415) which correspond to the templates (46) one by one; a square groove (416) is arranged on the side of each vertical groove (415); two sides of the top of the square groove (416) are respectively provided with a through groove (417); the fixing assembly (49) comprises a trapezoidal block (491) which is connected in the mounting groove in a sliding manner, a second spring (492) which is arranged between the trapezoidal block (491) and the square groove (416), a rectangular block (493) which is inserted between the through groove (417) and the square groove (416), a circular plate (494) which is used for connecting each rectangular block (493), and a hollow column (495) which is arranged at the bottom of the circular plate (494); the template (46) is inserted into the vertical groove (415); the trapezoidal blocks (491) are inserted in the slots (461); the triangular block (462) is attached to one side of the trapezoidal block (491); the bottom of the rectangular block (493) is contacted with one end of the rectangular block (493); a second tension spring (496) is sleeved outside the hollow column (495); a second magnetic ring (497) is fixed at the bottom of the hollow column (495); the hollow column (495) is inserted into the mounting seat (413) and is positioned above the spacer ring (414); the second tension spring (496) is positioned between the hollow column (495) and the mounting seat (413); the supporting columns (471) are inserted in the hollow columns (495); the second magnetic ring (497) and the first magnetic ring (474) attract each other.

5. The full-automatic fabric high-temperature setting machine according to claim 4, characterized in that: the bottom of the vertical groove (415) is provided with a T-shaped groove (418); the fixing assembly (49) further comprises a first fixing piece (498) inserted in the upper part of the vertical groove (415) and a second fixing piece (499) inserted in the T-shaped groove (418); the first fixing part (498) comprises a first rotating rod (4981) with the middle part rotatably connected in the vertical groove (415), a pressing block (4982) arranged at the top of the first rotating rod (4981), and a first contact point (4983) arranged at one end of the first rotating rod (4981); the second fixing part (499) comprises a second rotating rod (4991) rotatably connected in the T-shaped groove (418), a second contact point (4992) arranged at one end of the second rotating rod (4991), a balancing weight (4993) arranged below the second contact point (4992), and an inclined block (4994) which is positioned above the other end of the second rotating rod (4991) and can move up and down along the T-shaped groove (418); the bottom of the first rotating rod (4981) contacts the template (46); the top of the pressure block (4982) contacts a circular plate (494); the first contact point (4983) is hollow inside and the bottom of the first contact point contacts the top of the sock sleeved on the template (46); the top of the sloping block (4994) is in contact with the template (46); the second contact point (4992) is hollow inside and the top of the second contact point contacts the bottom of the sock sleeved on the template (46).