CN108589133B - Efficient shaping and sock feeding method - Google Patents

Abstract

The invention provides an efficient shaping and sock feeding method, which comprises the following steps: A) sleeving socks: providing a sock plate, and sleeving the sock on the independent sock plate; B) sock inserting plates: providing a sock feeding mechanism and a shaping mechanism, arranging the sock feeding mechanism at a sock inlet of the shaping mechanism, longitudinally inserting the sock plate sleeved with the socks into a clamping block of the sock feeding mechanism, and inserting a pressing rod into the clamping block to press against the lower end of the sock plate; C) overturning sock feeding mechanism: a rotating rod of the sock feeding mechanism rotates to enable the sock plate to be transferred to a shaping area of the shaping mechanism, and a rotating platform where the clamping block is located rotates to enable the sock plate to rotate to be in a horizontal state; D) shaping and separating: after the shaping mechanism clamps the sock plate, the sock feeding mechanism moves back to the direction of the shaping mechanism to separate the sock plate from the clamping block; E) resetting the sock feeding mechanism: the rotating rod and the rotating platform are reversely rotated to reset to an original state so as to insert a new sock plate.

Description

Efficient shaping and sock feeding method

Technical Field

The invention belongs to the technical field of sock production, and relates to an efficient shaping and sock feeding method.

Background

In the coming years, with the improvement of the industrial level, the textile industry in China has been developed at an unprecedented high speed, and part of textile machinery has come out of China and has an important position in the total value of national production and export earning. The development of new products of socks mainly is novel raw materials and the directional development that has special function, just so requires that the hosiery machine has stronger functionality, also puts forward higher requirement to the variety that the hosiery machine was woven, just can constantly adapt to future market demand.

The socks need to be shaped after being knitted so as to ensure that the socks always keep a certain shape after being penetrated and prolong the service life of the socks. The existing sock shaping mainly adopts steam shaping, and cotton threads of the socks are shaped through the steam.

At present, steam shaping is usually carried out in a steam chamber, socks are placed in the steam chamber, and then steam is injected into the steam chamber, a large amount of steam is usually needed by the method, the steam chamber needs to be filled with the steam during shaping, and a large amount of energy is needed for generating the steam, so that high cost needs to be paid on the generation of the steam; because the steam is in a floating state and the sock is in a static state, the effect between the sock and the steam is relatively less, and the condition of insufficient sizing can occur. Secondly, still need carry out the stoving step after finalizing the design through the steam, finalize the design inefficiency. In addition, socks are sleeved on the socks plates during sizing, the socks are conveyed to enter the sizing machine along with the socks plates, and the socks sleeving and taking are both required to depend on manual operation, so that the production efficiency is difficult to improve, which is a problem to be solved by the technical staff urgently.

Disclosure of Invention

The invention aims to provide an efficient shaping and sock feeding method aiming at the problems in the prior art, and aims to solve the problem of low shaping efficiency of socks.

The purpose of the invention can be realized by the following technical scheme:

an efficient sizing sock conveying method comprises the following steps:

A) sleeving socks: providing a sock plate, and sleeving the sock on the independent sock plate;

B) sock inserting plates: providing a sock feeding mechanism and a shaping mechanism, arranging the sock feeding mechanism at a sock inlet of the shaping mechanism, longitudinally inserting a sock plate sleeved with socks into a clamping block of the sock feeding mechanism, and inserting a pressing rod into the clamping block to press against the lower end of the sock plate;

C) overturning sock feeding mechanism: a rotating rod of the sock feeding mechanism rotates to enable the sock plate to be transferred to a shaping area of the shaping mechanism, and a rotating platform where the clamping block is located rotates to enable the sock plate to rotate to be in a horizontal state;

D) shaping and separating: after the sizing mechanism clamps the sock plate, moving the sock feeding mechanism back to the sizing mechanism to separate the sock plate from the clamping block;

E) resetting the sock feeding mechanism: the rotating rod and the rotating platform are reversely rotated to reset to an original state so as to insert a new sock plate.

In the efficient sizing and sock feeding method, the rotating rod and the rotating platform rotate synchronously.

In the efficient shaping and sock feeding method, the range of the rotatable angle of the rotating rod is 0-90 degrees, and the rotatable angle of the rotating platform is 0-180 degrees.

In the efficient sizing sock feeding method, the sock feeding mechanism comprises a moving frame, a rotating rod, a first motor, a fixed table and a rotating table, wherein the rotating rod is rotatably arranged on the moving frame, an output shaft of the first motor is connected with the rotating rod, and the first motor can drive the rotating rod to rotate; the fixed table is fixedly arranged on the rotating rod, the rotating table is rotatably arranged on the fixed table, and a clamping block for clamping the lower end of the sock plate is arranged on the rotating table; a first belt pulley is fixedly arranged below the rotating table, a second belt pulley and a third belt pulley are rotatably arranged on the moving frame and are positioned at two ends of the moving frame, and a belt is sleeved on the second belt pulley and the third belt pulley and is connected with the first belt pulley and can drive the first belt pulley to rotate; a first gear is coaxially and fixedly arranged on an output shaft of the first motor, a second gear is coaxially and fixedly arranged on the third belt pulley, the second gear and the first gear are helical gears, and the second gear is meshed with the first gear.

In the efficient sizing sock conveying method, the sock conveying mechanism further comprises a plurality of push rod motors, output shafts of the push rod motors are horizontally arranged, and the moving frame is fixedly arranged at the end parts of the output shafts of the push rod motors.

In the efficient shaping and sock feeding method, the clamping block is provided with the clamping groove, one end of the clamping block is provided with a plurality of through holes communicated with the clamping groove, the pressing rods penetrate through the through holes and can slide in the through holes, one end of each pressing rod is located in the clamping groove, the end of each pressing rod is provided with the inclined molded surface, and the other end of each pressing rod is connected to the clamping block through the second tension spring.

In the efficient shaping and sock feeding method, the shaping mechanism comprises an upper shaping plate, a lower shaping plate and a first hydraulic cylinder, an output shaft of the first hydraulic cylinder is vertically downward, the upper shaping plate is fixedly arranged at the end part of the output shaft of the first hydraulic cylinder and is vertically opposite to the lower shaping plate, and the upper shaping plate can abut against the lower shaping plate to form a shaping area for shaping socks; the upper shaping plate and the lower shaping plate are internally provided with cavities, and a plurality of heating pipes are uniformly distributed in the cavities.

In the efficient sizing and sock conveying method, heat conduction oil is filled in the cavity, and the heating pipe is immersed in the heat conduction oil.

Compared with the prior art, the technical scheme has the advantages that:

when socks are sleeved, the sock plates are independent, the sock plates and the sock feeding mechanism are in a separated state, and the sock sleeving step is not influenced by the progress of the whole machine; inserting the sock plate sleeved with the socks into the sock feeding mechanism, wherein the sock plate is detachably inserted and is elastically supported by the supporting and pressing rod, so that the subsequent shaping and separating steps are facilitated; the sock plate is turned over and conveyed to the shaping mechanism through the rotation of the sock conveying mechanism, the sock conveying mechanism synchronously realizes the rotation of two positions, and the sock conveying efficiency is improved; the socks board is when receiving to compress tightly the design, and the socks board separates with send socks mechanism, and send socks mechanism to reset and be convenient for insert new socks board for the design step of socks can go on in step with inserting socks board step, thereby has improved the efficiency that socks were stereotyped.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is an enlarged view of a in fig. 1.

FIG. 3 is a schematic view showing the construction of the sock feeding mechanism according to the present invention.

Fig. 4 is a schematic structural view of the clamping mechanism of the present invention.

Fig. 5 is a side view schematic of the present invention.

FIG. 6 is a schematic view of the actuation of the sock feeding mechanism according to the present invention.

Fig. 7 is a schematic view of the structure of the take-out mechanism of the present invention.

FIG. 8 is a schematic flow diagram of the present invention.

In the figure, 1, a frame; 2. shaping box; 3. entering a sock inlet; 4. a sock outlet; 5. an upper shaping plate; 6. a lower shaping plate; 7. a first hydraulic cylinder; 8. a cavity; 9. heating a tube; 10. fixing the rod; 11. a slide bar; 12. a hinged sheet; 13. a slider; 14. a first tension spring; 15. a movable frame; 16. a push rod motor; 17. rotating the rod; 18. a first motor; 19. a fixed table; 20. a rotating table; 21. a first pulley; 22. a second pulley; 23. a third belt pulley; 24. a belt; 25. a first gear; 26. a card slot; 27. a pressing rod; 28. a tension spring II; 29. pushing the plate; 30. a first rotating arm; 31. a second rotating arm; 32. a limiting frame; 33. a second motor; 34. a connecting rod; 35. a limiting surface; 36. a conveyor belt; 37. a fan; 38. a second gear; 39. a chute; 40. a limiting rod; 41. an auxiliary wheel; 42. and (4) clamping the block.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art.

As shown in fig. 1 to 7, the present invention provides a hot-press type setting machine, which comprises a frame 1, wherein a plurality of setting boxes 2 are fixedly arranged on the frame 1, setting mechanisms for setting socks are arranged in the setting boxes 2, a sock inlet 3 is arranged at the front side of each setting box 2, a sock outlet 4 is arranged at the rear side of each setting box 2, a sock feeding mechanism for feeding socks into the setting boxes 2 is arranged on the frame 1, and the sock feeding mechanism is positioned at the sock inlet 3; the frame 1 is provided with a plurality of taking-out mechanisms for taking out socks in the shaping mechanism, the taking-out mechanisms correspond to the shaping boxes 2 one by one and are positioned at sock outlets 4 of the shaping boxes 2; the frame 1 is also provided with a conveying mechanism for conveying the taken socks to the next station; the shaping box 2 is fixedly provided with a sliding chute 39, the sliding chute 39 is positioned on one side of the sock outlet 4, the lower end of the sliding chute 39 is positioned right above the conveying mechanism, and the sock plate slides to the conveying mechanism along the sliding chute 39.

Specifically, the design mechanism includes stereotype 5, stereotype 6 down, first pneumatic cylinder 7, and first pneumatic cylinder 7 sets firmly in frame 1 and the output shaft is vertical downwards, and in the output shaft of first pneumatic cylinder 7 penetrated stereotype case 2 from the upper plate of stereotype case 2, goes up stereotype 5 and sets firmly at the output shaft tip of first pneumatic cylinder 7, and stereotype 6 is connected in frame 1 through a plurality of elastic construction down, and in this embodiment case, the quantity of elastic construction is four.

The upper shaping plate 5 can abut against the lower shaping plate 6 and form a shaping area for shaping socks; go up the stereotype 5 and all seted up cavity 8 in the stereotype 6 down, the equipartition is arranged in cavity 8 and is equipped with a plurality of heating pipes 9 and clamp spare, and the clamp spare is contradicted in the inner wall of cavity 8, and the heating pipe 9 closely wears to establish the clamp spare and forms the clearance with the inner wall of cavity 8, and has irritated the conduction oil in the cavity 8, and the heating pipe 9 submergence is in the conduction oil.

The elastic structure comprises a fixed rod 10, a sliding rod 11, a plurality of hinged sheets 12 and a plurality of sliding blocks 13, wherein in the embodiment, the number of the hinged sheets 12 is two, and the number of the sliding blocks 13 is two; the sliding rod 11 is fixedly arranged on the rack 1, a sliding hole is formed in the sliding block, and the sliding block is sleeved on two ends of the sliding rod 11 through the sliding hole; the hinged sheets 12 are respectively hinged on the sliding blocks at the two ends of the sliding rod 11, one end of the fixed rod 10 is hinged on the hinged sheets 12, and the other end of the fixed rod 10 is fixedly arranged on the lower plate surface of the lower shaping plate 6; a first tension spring 14 is sleeved on the sliding rod 11, and two ends of the first tension spring 14 are respectively connected with sliding blocks on two ends of the sliding rod 11.

When the socks board entered into down stereotype 6, go up stereotype 5 pushes down, go up stereotype 5 can lean on and form a design district that is used for stereotyped socks with stereotype 6 counterbalance down, the socks board is in design district, stereotype 6 down is connected in frame 1 through a plurality of elastic construction, when last stereotype 5 presses down stereotype 6, prevent to go up stereotype 5 and stereotype 6 rigid contact down, socks compress tightly each other in upper and lower stereotype 6 through heating, the setting that socks can be quick.

The heat transfer oil inside the cavity 8 can keep the temperature within a stable range. When the lower shaping plate 6 is pressed downwards by the upper shaping plate 5, the fixed rod 10 is pressed downwards, the sliding blocks 13 slide towards two ends on the sliding rod 11, and the first tension spring 14 connects the two sliding blocks 13 on the sliding rod 11. In this way, the lower shaped plate 6 has a certain deformability, so that the socks in the shaped areas are subjected to the same pressure. When the upper shaping plate 5 is lifted, the first tension spring 14 contracts to enable the two sliding blocks 13 to slide relatively to drive the lower shaping plate 6 to reset upwards.

Specifically, the sock feeding mechanism comprises a moving frame 15, a plurality of push rod motors 16, a rotating rod 17, a first motor 18, a plurality of fixed tables 19 and a plurality of rotating tables 20, wherein the push rod motors 16 are fixedly arranged on the frame 1, output shafts of the push rod motors are horizontally arranged, the moving frame 15 is fixedly arranged at the end parts of the output shafts of the push rod motors 16, the moving frame 15 is driven by the push rod motors 16 to stretch, the rotating rod 17 is rotatably arranged on the moving frame 15, the first motor 18 is fixedly arranged on the frame 1, the output shafts of the first motor 18 are connected with the rotating rod 17, the first motor 18 can drive the rotating rod 17 to rotate, and in the embodiment, the rotating angle range of the rotating rod 17 is 0; the fixed table 19 is fixed on the rotating rod 17, the rotating table 20 is rotatably arranged on the fixed table 19, and in the embodiment, the rotating angle of the rotating table 20 on the fixed table 19 is 0-180 degrees.

Furthermore, a clamping mechanism for clamping the lower end of the sock plate is arranged on the rotating table 20, a first belt pulley 21 is fixedly arranged below the rotating table 20, a second belt pulley 22 and a third belt pulley 23 are rotatably arranged on the moving frame 15, the second belt pulley 22 and the third belt pulley 23 are respectively positioned at two ends of the moving frame 15, a belt 24 is sleeved on the second belt pulley 22 and the third belt pulley 23, and the belt 24 is connected with the first belt pulley 21 and can drive the first belt pulley to rotate; a first gear 25 is coaxially and fixedly arranged on an output shaft of the first motor 18, a second gear 38 is coaxially and fixedly arranged on the third belt pulley 23, the second gear 38 and the first gear 25 are helical gears, and the second gear 38 is meshed with the first gear 25.

The clamping mechanism comprises a clamping block 42, a clamping groove 26 is formed in the clamping block 42, one end of the clamping block 42 is provided with a plurality of through holes communicated with the clamping groove 26, a pressing rod 27 penetrates through the through holes and can slide in the through holes, one end of the pressing rod 27 is located in the clamping groove 26, an inclined molded surface is arranged on the end of the pressing rod 27, and the other end of the pressing rod 27 is connected to the clamping block 42 through a second tension spring 28.

Insert the grip block 42 on the rotation platform 20 with the socks, at this moment, draw-in groove 26 on the grip block 42 is the vertical state with dwang 17, the socks are perpendicular to down stereotype 6 and the socks are not in the design district, when first motor 18 rotates, first motor 18 drives dwang 17 and rotates, drive first gear 25 simultaneously and rotate, fixed station 19 that sets firmly on the dwang 17 also rotates along with dwang 17, until the socks rotate to the design district in, and first gear 25 drives third belt pulley 23 and rotates, third belt pulley 23 drives second belt pulley 22 and rotates and the belt 24 that the cover was established on third belt pulley 23 and second belt pulley 22 and rotates, belt 24 drives first belt pulley 21 and rotates, first belt pulley 21 drives rotation platform 20 and rotates, make the socks rotate to be parallel with lower stereotype 6. The rotation of the rotating table 20 and the rotation of the rotating lever 17 are synchronized. When the sock is inserted into the slot 26, the lower end of the sock is inserted from the inclined surface of the pressing rod 27, and the pressing rod 27 presses against the sock.

The fixed table 19 is provided with a limiting rod 40, the limiting rod 40 is provided with an auxiliary wheel 41, the auxiliary wheel 41 is positioned on one side of the first belt pulley 21, and the belt 24 passes through the space between the auxiliary wheel 41 and the first belt pulley 21 and is pressed on the first belt pulley 21 through the auxiliary wheel 41.

Specifically, the taking-out mechanism comprises a push plate 29, a first rotating arm 30, a second rotating arm 31, a limiting frame 32 and a second motor 33, the limiting frame 32 is fixedly arranged on the rack 1, the second motor 33 is fixedly arranged on the rack 1, an output shaft of the second motor 33 is horizontally arranged, the first rotating arm 30 is fixedly arranged on an output shaft of the second motor 33, the second rotating arm 31 is rotatably arranged on the limiting frame 32, two ends of the push plate 29 are fixedly arranged on a connecting rod 34, a limiting surface 35 is arranged on the connecting rod 34, limiting rods parallel to each other are arranged on the limiting frame 32, a push rod is rotatably arranged on the first rotating arm 30 and the second rotating arm 31 through the connecting rod 34, the first rotating arm 30 and the second rotating arm 31 are respectively provided with a telescopic structure, the push plate 29 can be perpendicular to the upper plane of the lower shaping plate 6 when the limiting surface 35 is in contact with the limiting rods, and the push plate 29 can push out the sock.

The second motor 33 drives the first rotating arm 30 to rotate, the first rotating arm 30 drives the second rotating arm 31 to rotate, the push plate 29 rotates around an output shaft of the second motor 33, the limiting surface 35 on the connecting rod 34 of the push plate 29 is in contact with the limiting rod on the limiting frame 32, the push plate 29 is perpendicular to the lower sizing plate 6, the second motor 33 continues to rotate, and the push plate 29 moves along the limiting rod through the telescopic structures of the first rotating arm 30 and the second rotating arm 31 and pushes the sock plate out of the lower sizing plate 6. The telescopic structure comprises a big rod, a small rod and a pressure spring, a channel is arranged in the big rod, and the small rod is arranged in the channel of the big rod in a penetrating way and is connected with the big rod through the pressure spring.

Specifically, conveying mechanism includes conveyer belt 36, first roller, second roller, fan 37, and first roller rotates parallel arrangement in frame 1 with the second roller, and conveyer belt 36 cover is established at first roller and second roller, and conveyer belt 36 is chain conveyor 36, and fan 37 sets firmly on frame 1, and fan 37 is located the below of conveyer belt 36, and fan 37 can blow upwards.

When the socks board fell on conveyer belt 36, carry out quick cooling to socks through fan 37, improve the design effect.

The working principle of the invention is as follows: the sock is sleeved on the sock plate and the sock plate is inserted into the sock feeding mechanism, the sock plate enters the shaping mechanism from the sock inlet 3 and is rapidly shaped through the shaping mechanism, the shaping mechanism adopts a hot-pressing shaping mode, a drying step is not needed, the sock shaping time is short, and the effect is good; after finalizing the design, release the socks board from the forming mechanism through taking out mechanism to on sending into conveying mechanism, carry out the socks board through conveying mechanism, when the socks are finalized the design, insert new socks board into send socks mechanism, a plurality of steps go on simultaneously, improve work efficiency.

As shown in fig. 8, the present invention also provides an efficient method for shaping and delivering socks, which comprises the following steps:

A) sleeving socks: providing a sock plate, and sleeving the sock on the independent sock plate;

B) sock inserting plates: providing a sock feeding mechanism and a shaping mechanism, arranging the sock feeding mechanism at a sock inlet of the shaping mechanism, longitudinally inserting the sock plate sleeved with the sock into a clamping block 42 of the sock feeding mechanism, and inserting a pressing rod 27 into the clamping block 42 to press the lower end of the sock plate;

C) overturning sock feeding mechanism: the rotating rod 17 of the sock feeding mechanism rotates to enable the sock plate to be transferred to the shaping area of the shaping mechanism, and the rotating platform 20 where the clamping block 42 is located rotates to enable the sock plate to rotate to be in a horizontal state; the rotating rod 17 and the rotating platform 20 rotate synchronously;

D) shaping and separating: after the sizing mechanism clamps the sock plate, the sock feeding mechanism moves back to the sizing mechanism to separate the sock plate from the clamping block 42;

E) resetting the sock feeding mechanism: the turning rod 17 and the turning table 20 are both turned reversely to be restored to the original state for inserting a new sock plate.

According to the sizing sock feeding method provided by the invention, the sock plates are independent when socks are sleeved, the sock plates and the sock feeding mechanism are in a separated state, and the sock sleeving step is not influenced by the progress of the whole machine; inserting the sock plate sleeved with the socks into the sock feeding mechanism, wherein the sock plate is detachably inserted and is elastically supported by the supporting and pressing rod, so that the subsequent shaping and separating steps are facilitated; the sock plate is turned over and conveyed to the shaping mechanism through the rotation of the sock conveying mechanism, the sock conveying mechanism synchronously realizes the rotation of two positions, and the sock conveying efficiency is improved; the socks board is when receiving to compress tightly the design, and the socks board separates with send socks mechanism, and send socks mechanism to reset and be convenient for insert new socks board for the design step of socks can go on in step with inserting socks board step, thereby has improved the efficiency that socks were stereotyped.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the spirit or ambit of the invention as defined in the appended claims.

Claims (6)

1. An efficient sizing sock conveying method is characterized by comprising the following steps:

A) sleeving socks: providing a sock plate, and sleeving the sock on the independent sock plate;

B) sock inserting plates: providing a sock feeding mechanism and a shaping mechanism, arranging the sock feeding mechanism at a sock inlet of the shaping mechanism, longitudinally inserting the sock plate sleeved with the socks into a clamping block of the sock feeding mechanism, and inserting a pressing rod into the clamping block to press the lower end of the sock plate;

C) overturning sock feeding mechanism: a rotating rod of the sock feeding mechanism rotates to enable the sock plate to be transferred to a shaping area of the shaping mechanism, and a rotating platform where the clamping block is located rotates to enable the sock plate to rotate to be in a horizontal state;

D) shaping and separating: after the shaping mechanism clamps the sock plate, the sock feeding mechanism moves back to the direction of the shaping mechanism to separate the sock plate from the clamping block;

E) resetting the sock feeding mechanism: the rotating rod and the rotating platform both rotate reversely and reset to the original state for inserting a new sock plate; the sock feeding mechanism comprises a moving frame, a rotating rod, a first motor, a fixed table and a rotating table, wherein the rotating rod is rotatably arranged on the moving frame, an output shaft of the first motor is connected with the rotating rod, and the first motor can drive the rotating rod to rotate; the fixed table is fixedly arranged on the rotating rod, the rotating table is rotatably arranged on the fixed table, and a clamping block for clamping the lower end of the sock plate is arranged on the rotating table; a first belt pulley is fixedly arranged below the rotating table, a second belt pulley and a third belt pulley are rotatably arranged on the moving frame and are positioned at two ends of the moving frame, and a belt is sleeved on the second belt pulley and the third belt pulley and is connected with the first belt pulley and can drive the first belt pulley to rotate; a first gear is coaxially and fixedly arranged on an output shaft of the first motor, a second gear is coaxially and fixedly arranged on the third belt pulley, the second gear and the first gear are helical gears, and the second gear is meshed with the first gear; the clamping groove has been seted up on the grip block, grip block one end set up a plurality of through-holes that are linked together with the draw-in groove, all wear to be equipped with in the through-hole and support the depression bar and can slide in the through-hole, the one end that supports the depression bar is located the draw-in groove and should serve and have oblique profile, the other end that supports the depression bar connect on the grip block through extension spring two.

2. An efficient method for sizing and delivering socks according to claim 1, wherein the rotating rod and the rotating table rotate synchronously.

3. An efficient method for sizing and delivering socks according to claim 1, wherein the rotation angle of the rotation rod ranges from 0 to 90 ° and the rotation angle of the rotation table ranges from 0 to 180 °.

4. The efficient sizing sock feeding method according to claim 1, wherein the sock feeding mechanism further comprises a plurality of push rod motors, output shafts of the push rod motors are horizontally arranged, and the moving frame is fixedly arranged at end portions of the output shafts of the push rod motors.

5. The efficient method for sizing and delivering socks according to claim 1, wherein the sizing mechanism comprises an upper sizing plate, a lower sizing plate and a first hydraulic cylinder, an output shaft of the first hydraulic cylinder faces vertically downwards, the upper sizing plate is fixedly arranged at an end part of the output shaft of the first hydraulic cylinder and is opposite to the lower sizing plate up and down, and the upper sizing plate can abut against the lower sizing plate and form a sizing area for sizing socks; the upper shaping plate and the lower shaping plate are internally provided with cavities, and a plurality of heating pipes are uniformly distributed in the cavities.

6. The efficient shaping and sock feeding method according to claim 5, wherein heat conducting oil is filled in the cavity, and the heating pipe is immersed in the heat conducting oil.

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