阅读说明：本技术 一种织袜机翻转机构 (Hosiery knitter tilting mechanism ) 是由 史璐璐 于 2021-07-09 设计创作，主要内容包括：本发明属于织袜机技术领域,具体的说是一种织袜机翻转机构；包括支撑板；所述支撑板上表面安装有纺织机构；所述支撑板下表面固连有吸管；所述纺织机构空腔内设有翻转机构；所述纺织机构空腔内于纺织机构内壁中固连有两个第一电动伸缩杆；所述翻转机构包括立柱,且立柱上半部分为锥形设计；所述立柱内壁中开设有第一缺槽,且第一缺槽与第一电动伸缩杆相互配合；所述第一电动伸缩杆外表面固连有挡板,且挡板与立柱相互垂直；本发明主要用于解决目前在袜子纺织完成后需要利用专门的机构将袜子引出进行翻面并封口,有些厂家也会人工进行翻面随后封口,上述操作不仅会增大机械成本,同时还会增大人工劳动力。(The invention belongs to the technical field of hosiery machines, and particularly relates to a turnover mechanism of a hosiery machine; comprises a supporting plate; the upper surface of the supporting plate is provided with a spinning mechanism; the lower surface of the supporting plate is fixedly connected with a suction pipe; a turnover mechanism is arranged in the cavity of the spinning mechanism; two first electric telescopic rods are fixedly connected in the inner wall of the spinning mechanism in the cavity of the spinning mechanism; the turnover mechanism comprises an upright post, and the upper half part of the upright post is in a conical design; a first notch is formed in the inner wall of the upright post and is matched with the first electric telescopic rod; the outer surface of the first electric telescopic rod is fixedly connected with a baffle, and the baffle is perpendicular to the upright post; the invention is mainly used for solving the problems that at present, after the socks are woven, special mechanisms are needed to be used for leading out the socks to turn over and seal the socks, and some manufacturers can turn over the socks manually and then seal the socks, so that the mechanical cost and the manual labor are increased due to the operation.)

1. A hosiery machine tilting mechanism which characterized in that: comprises a support plate (1); a spinning mechanism (11) is arranged on the upper surface of the supporting plate (1); the lower surface of the supporting plate (1) is fixedly connected with a suction pipe (12); a turnover mechanism (2) is arranged in a cavity of the spinning mechanism (11); two first electric telescopic rods (21) are fixedly connected in the inner wall of the spinning mechanism (11) in the cavity of the spinning mechanism (11); the turnover mechanism (2) comprises an upright post (22), and the upper half part of the upright post (22) is designed in a conical shape; a first notch (23) is formed in the inner wall of the upright post (22), and the first notch (23) is matched with the first electric telescopic rod (21); the outer surface of the first electric telescopic rod (21) is fixedly connected with a baffle (24), and the baffle (24) is vertical to the upright post (22); a second notch (25) is formed in the inner wall of the baffle (24) on the side opposite to the baffle (24); two second electric telescopic rods (26) are fixedly connected in the inner wall of the upright post (22) at one side opposite to the second notch (25); clamping plates (27) are fixedly connected to the opposite sides of the two second electric telescopic rods (26), and the clamping plates (27) are designed in an L shape and are mutually attached to the second notch grooves (25); uniformly arranged support rods (3) are fixedly connected to the conical surface of the upright post (22), and the support rods (3) are close to each other but are not attached to each other; a sliding groove is formed in the inner wall of each support rod (3), and a top plate (31) is connected in the sliding groove in a sliding manner; the end surface of one side, opposite to each top plate (31), is fixedly connected with tooth blocks (32) which are uniformly arranged; every one side that vaulting pole (3) is relative all is connected with gear (33) through the motor rotation in stand (22) inner wall, and gear (33) all with tooth piece (32) intermeshing.

2. A hosiery knitting machine turning mechanism according to claim 1, wherein: a notch is formed in the inner wall of each top plate (31) at the bottom of each top plate (31), and a roller (34) is rotatably connected in each notch through a rotating shaft; each roller (34) is in unidirectional rotation.

3. A hosiery knitting machine turning mechanism according to claim 2, characterized in that: each outer surface of the roller (34) is fixedly connected with uniformly arranged air bags (35), and air holes are formed in the inner walls of the air bags (35).

4. A hosiery knitting machine turning mechanism according to claim 1, wherein: the end surface of one side of each top plate (31) opposite to the other side is hinged with a push block (36) through a rotating shaft; a transmission belt (37) is rotatably connected in the inner wall of the support rod (3) at the side of each sliding groove back to the back through a rotating shaft, and the transmission belt (37) is attached to the push block (36); one side of the transmission belt (37) far away from the push block (36) is mutually attached to the outer surface of the support rod (3).

5. A hosiery knitting machine turning mechanism according to claim 2, characterized in that: the outer surface of the transmission belt (37) is fixedly connected with uniformly arranged rubber bags (38).

6. A hosiery knitting machine turning mechanism according to claim 5, characterized in that: air grooves (39) are formed in the inner walls of the support rods (3) on the upper side and the lower side of each transmission belt (37), and sliding blocks (391) are connected in the air grooves (39) in a sliding mode through springs; through holes (392) which are uniformly distributed are formed in the opposite sides of the air grooves (39), guide rods (393) are fixedly connected to one side, close to the transmission belt (37), of each sliding block (391), the guide rods (393) extend out of the air grooves (39) and are close to and not attached to the transmission belt (37), and the guide rods (393) are in arc-shaped design on one side, close to the transmission belt (37).

Technical Field

The invention belongs to the technical field of hosiery machines, and particularly relates to a turnover mechanism of a hosiery machine.

Background

The hosiery knitter is a textile device which adopts crochet to knit out the formed hosiery piece and produce hosiery articles, the hosiery knitter can knit out leg, high heel, foot (including sole and surface of sock), and the sections of reinforcing ring and toe, etc. compared with the artificial hosiery knitter, the hosiery knitter greatly improves the efficiency of hosiery. The hosiery machine wire guiding mechanism is installed in the hosiery machine, and thereby hosiery machine wire guiding mechanism is used for drawing the winding frame that knits the line to the leg of a hosiery knitter and weaving, nevertheless current hosiery machine still has certain problem, specifically includes following aspect:

among the prior art, need utilize special mechanism to draw socks out behind the weaving of socks and turn over and seal, some producers also can artifically turn over and seal afterwards, and above-mentioned operation not only can increase mechanical cost, still can increase the hand labor simultaneously.

In view of the above, in order to overcome the above technical problems, the present invention provides a turnover mechanism of a hosiery knitting machine, which solves the above technical problems.

Disclosure of Invention

In order to make up for the defects of the prior art, the invention provides a turnover mechanism of a hosiery machine, which is mainly used for solving the problems that at present, after the weaving of the socks is finished, the socks need to be led out by a special mechanism to be turned over and sealed, and some manufacturers can turn over and seal the socks manually, so that the operation not only increases the mechanical cost, but also increases the manual labor force.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to a turnover mechanism of a hosiery machine, which comprises a supporting plate; the upper surface of the supporting plate is provided with a spinning mechanism; the lower surface of the supporting plate is fixedly connected with a suction pipe; a turnover mechanism is arranged in the cavity of the spinning mechanism; two first electric telescopic rods are fixedly connected in the inner wall of the spinning mechanism in the cavity of the spinning mechanism; the turnover mechanism comprises an upright post, and the upper half part of the upright post is in a conical design; a first notch is formed in the inner wall of the upright post and is matched with the first electric telescopic rod; the outer surface of the first electric telescopic rod is fixedly connected with a baffle, and the baffle is perpendicular to the upright post; a second notch is formed in the inner wall of the baffle plate on one side opposite to the baffle plate; two second electric telescopic rods are fixedly connected in the inner wall of the upright post at one side opposite to the second notch; clamping plates are fixedly connected to the opposite sides of the two second electric telescopic rods, are in L-shaped design and are mutually attached to the second notches; uniformly arranged support rods are fixedly connected to the conical surface of the upright post, and the support rods are close to each other but are not attached to each other; a sliding groove is formed in the inner wall of each support rod, and a top plate is connected in each sliding groove in a sliding manner; the end face of one side, opposite to each top plate, of each top plate is fixedly connected with tooth blocks which are uniformly arranged; a gear is rotatably connected in the inner wall of the upright post at one side opposite to each support rod through a motor, and the gears are meshed with the tooth blocks;

in the prior art, after the socks are woven, special mechanisms are needed to lead out the socks to turn over and seal the socks, and some manufacturers can turn over the socks manually and then seal the socks, so that the mechanical cost and the manual labor force are increased by the operation;

the turnover mechanism can turn over the socks which are being woven, so that the socks can be turned over without manual work through a machine, the mechanical or labor cost is reduced, and meanwhile, the socks can be prevented from being influenced by the rotation of a textile mechanism in the turnover process of the socks, so that the socks are wound to influence the weaving;

when the invention is used, when socks are woven in the weaving mechanism, the turnover mechanism is fixedly connected through the first electric telescopic rod, so that the turnover mechanism can rotate along with the weaving mechanism, as the socks are longer and longer to be woven, the unsealed parts of the socks can be sleeved on the uniformly arranged support rods due to the mutual approach of the support rods, when the socks are gradually lengthened, the socks can slide downwards on the uniformly arranged support rods, when the socks slide to one side of the second electric telescopic rod, the controller controls the second electric telescopic rod to stretch at the moment, the clamping plate can be pushed to stretch the socks in the stretching process of the second electric telescopic rod, when the socks are stretched, the socks cloth placed below the clamping plate deviates to the opposite side of the clamping plate due to certain elasticity of the socks, and the controller controls the second electric telescopic rod to rapidly contract at the moment, in the process, socks can be clamped on the surface of the stand column through the clamping plates, the turning mechanism rotates along with the spinning mechanism, the stand column can drive the socks to rotate along with the spinning mechanism, the situation that the socks are wound by the spinning mechanism in the rotating process can be prevented, then the controller controls the motor to rotate slowly, as the gears are meshed with the toothed blocks on the top plate, the top plate can be driven to slowly slide out of the sliding grooves of the supporting rods in the rotating process of the motor, the socks can be extruded in the process that the top plate slowly extends out of the sliding grooves, the socks are slowly sleeved on the outer surface of the stand column, the socks can be gradually turned over, the socks after the completion of spinning can be prevented from being turned over by related machinery or manpower in the process, the mechanical and labor cost is reduced, when the socks are spun and separated from the spinning mechanism, the top plate can extrude the socks, when the socks are separated from the top plate, the top plate slides to the limit position, meanwhile, the socks are turned over and are placed below the support rods, the controller controls the second electric telescopic rods to stretch, when the second electric telescopic rod is stretched, the clamping plate can release the clamping of the socks, the socks can be separated from the upright post and fall on the stretching shaft of the first electric telescopic rod, the second electric telescopic rod continues to stretch and is clamped into the second notch of the baffle, and then the controller controls the first electric telescopic rod to contract, when the first electric telescopic rod finishes the contraction, the turned socks fall into the suction pipe and are sucked out by the suction pipe, the first electric telescopic rod and the second electric telescopic rod are matched with each other to prevent the turnover mechanism from falling, after the socks are drawn out, the first electric telescopic rod stretches and is clamped into the first notch, and the second electric telescopic rod restores to the initial position.

Preferably, the bottom of each top plate is provided with a notch in the inner wall of the top plate, and the notches are rotatably connected with rollers through rotating shafts; each roller rotates in one direction;

the during operation, because all rotate in the roof inner wall and be connected with one-way pivoted roller, when the roof moves down, the roller can rotate on socks face, can reduce the frictional force of roof to socks at this in-process to prevent that the roof from scraping the yarn on socks absolutely, prevent simultaneously that socks card from on the roof.

Preferably, the outer surface of each roller is fixedly connected with uniformly arranged air bags, and air holes are formed in the inner walls of the air bags;

the during operation, because the roller surface links firmly the gasbag of evenly arranging, can extrude the gasbag at roller pivoted in-process socks, after the gasbag back extrusion, gas in the gasbag can pass through the gas pocket blowout, can blow socks at this in-process to can blow off the yarn that is stained with on the socks, simultaneously because the existence of gasbag can make socks and roller present the point contact, thereby further reduce the friction of socks.

Preferably, the end surface of one side of each top plate, which is opposite to the other side, is hinged with a push block through a rotating shaft; a driving belt is rotatably connected in the inner wall of the support rod through a rotating shaft at one side of each sliding chute, which is opposite to the side of each sliding chute, and the driving belt is attached to the pushing block; one side of the transmission belt, which is far away from the push block, is mutually attached to the outer surface of the support rod;

the during operation, because articulated ejector pad and drive belt laminate each other, when the socks of weaving contact with the vaulting pole of evenly arranging gradually, the reverse slow rotation of controller control motor this moment, can drive the roof through the ejector pad at motor antiport in-process and shift up, the in-process that shifts up at the roof can promote the drive belt and slowly rotate, can slowly drive the socks downstream of cover on the vaulting pole at drive belt pivoted in-process, thereby prevent to make socks fix on the vaulting pole because the frictional force between socks and the vaulting pole, when the roof moves down, the ejector pad can take place to rotate, thereby can not drive the drive belt and rotate.

Preferably, the outer surface of the transmission belt is fixedly connected with uniformly arranged rubber bags;

the during operation, because the drive belt surface links firmly the rubber bag of evenly arranging, when the drive belt rotated, the rubber bag can increase the pressure between drive belt and the socks to drive socks downstream that can be better, the rubber bag of evenly arranging simultaneously can prop up socks, and the better messenger socks are followed textile mechanism and are rotated, prevent that the winding condition from appearing in socks.

Preferably, the upper side and the lower side of each driving belt are respectively provided with an air groove in the inner wall of the stay bar, and the air grooves are respectively connected with a sliding block in a sliding manner through springs; through holes which are uniformly distributed are formed in the opposite sides of each air groove; one side of each sliding block, which is close to the transmission belt, is fixedly connected with a guide rod, and the guide rods extend to form air outlet grooves which are close to the transmission belt and are not attached to the transmission belt; the guide rod is in arc design at one side close to the transmission belt;

the during operation, because the guide arm extends to drive belt one side, when the drive belt rotates, the extrusion guide arm that the rubber bag can be interrupted, can extrude the slider and slide in the air duct after the guide arm receives the extrusion, thereby can extrude the gas in the air duct through the through-hole, can blow socks after gas blowout, thereby can further blow off the dust that is stained with on the socks, simultaneously because the slider passes through spring and air duct sliding connection, when the rubber bag passes through the guide arm, the slider resumes to initial condition under the effect of spring this moment, can adsorb external gas through the through-hole when the slider resumes, can adsorb socks to vaulting pole surface at the inspiratory in-process of through-hole, thereby make better and the drive belt contact and remove of socks.

The invention has the following beneficial effects:

1. the turnover mechanism can turn over the socks which are being woven, so that the socks do not need to be turned over manually by a machine, the mechanical or labor cost is reduced, and meanwhile, the socks can be prevented from being influenced by the rotation of the textile mechanism in the turnover process of the socks, so that the socks are wound to influence the weaving.

2. Because the guide arm extends to drive belt one side, when the drive belt rotates, the extrusion guide arm that the rubber bag can be interrupted, can extrude the slider and slide in the air pocket after the guide arm receives the extrusion, thereby can extrude the gas in the air pocket through the through-hole, can blow socks after gas blowout, thereby can further blow off the dust that is stained with on the socks, simultaneously because the slider passes through spring and air pocket sliding connection, when the rubber bag passes through the guide arm, the slider resumes to initial condition under the effect of spring this moment, can adsorb external gas through the through-hole when the slider resumes, can adsorb socks to vaulting pole surface at the in-process that the through-hole was breathed in, thereby make better and the drive belt contact of socks and remove.

Drawings

The invention will be further explained with reference to the drawings.

FIG. 1 is a body diagram of the present invention;

FIG. 2 is a perspective view of the present invention;

FIG. 3 is a cross-sectional view of the present invention;

FIG. 4 is an enlarged view of a portion of FIG. 3 at A;

FIG. 5 is a partial enlarged view of FIG. 4 at B;

in the figure: the device comprises a supporting plate 1, a textile mechanism 11, a suction pipe 12, a turnover mechanism 2, a first electric telescopic rod 21, an upright post 22, a first notch 23, a baffle 24, a second notch 25, a second electric telescopic rod 26, a clamping plate 27, a support rod 3, a top plate 31, a toothed block 32, a gear 33, a roller 34, an air bag 35, a push block 36, a transmission belt 37, a rubber bag 38, an air groove 39, a sliding block 391, a through hole 392 and a guide rod 393;

Detailed Description

A turnover mechanism of a hosiery knitting machine according to the invention will be described below with reference to fig. 1-5.

As shown in fig. 1-5, the turnover mechanism of the hosiery knitting machine according to the invention comprises a supporting plate 1; the upper surface of the supporting plate 1 is provided with a spinning mechanism 11; the lower surface of the supporting plate 1 is fixedly connected with a suction pipe 12; a turnover mechanism 2 is arranged in a cavity of the spinning mechanism 11; two first electric telescopic rods 21 are fixedly connected in the inner wall of the spinning mechanism 11 in the cavity of the spinning mechanism 11; the turnover mechanism 2 comprises a vertical column 22, and the upper half part of the vertical column 22 is in a conical design; a first notch 23 is formed in the inner wall of the upright post 22, and the first notch 23 is matched with the first electric telescopic rod 21; the outer surface of the first electric telescopic rod 21 is fixedly connected with a baffle 24, and the baffle 24 is vertical to the upright column 22; a second notch 25 is formed in the inner wall of the baffle 24 at the opposite side of the baffle 24; two second electric telescopic rods 26 are fixedly connected in the inner wall of the upright post 22 at one side opposite to the second notch 25; clamping plates 27 are fixedly connected to the opposite sides of the two second electric telescopic rods 26, and the clamping plates 27 are in an L-shaped design and are mutually attached to the second notch 25; uniformly arranged support rods 3 are fixedly connected to the conical surface of the upright post 22, and the support rods 3 are close to each other but are not attached to each other; a sliding groove is formed in the inner wall of each support rod 3, and a top plate 31 is connected in the sliding groove in a sliding manner; the end face of one side, opposite to each top plate 31, is fixedly connected with uniformly arranged tooth blocks 32; a gear 33 is rotatably connected in the inner wall of the upright post 22 at one side of each support rod 3 opposite to the upright post through a motor, and the gears 33 are mutually meshed with the gear blocks 32;

in the prior art, after the socks are woven, special mechanisms are needed to lead out the socks to turn over and seal the socks, and some manufacturers can turn over the socks manually and then seal the socks, so that the mechanical cost and the manual labor force are increased by the operation;

the turnover mechanism 2 can turn over the socks which are being woven, so that the socks can be turned over without manual work through a machine, the mechanical or labor cost is reduced, and meanwhile, the socks can be prevented from being influenced by the rotation of the textile mechanism 11 in the turnover process of the socks, so that the socks are wound to influence the weaving;

when the invention is used, when socks are woven in the weaving mechanism 11, the overturning mechanism 2 is fixedly connected through the first electric telescopic rod 21, so that the overturning mechanism 2 can rotate along with the weaving mechanism 11, as the socks are woven to be longer and longer, the unsealed parts of the socks can be sleeved on the uniformly arranged support rods 3 due to the mutual approach of the support rods 3, when the socks are gradually lengthened, the socks can slide downwards on the uniformly arranged support rods 3, when the socks slide to one side of the second electric telescopic rod 26, the controller controls the second electric telescopic rod 26 to stretch at the moment, the clamping plate 27 can be pushed to stretch the socks in the stretching process of the second electric telescopic rod 26, when the socks are stretched, the socks placed below the clamping plate 27 are stretched, and the socks placed below the clamping plate 27 can deviate to the opposite side of the clamping plate 27 due to certain elasticity of the socks, and the controller controls the second electric telescopic rod 26 to rapidly contract at the moment, in the process, socks can be clamped on the surface of the stand column 22 through the clamping plate 27, the turnover mechanism 2 rotates along with the textile mechanism 11, at the moment, the stand column 22 can drive the socks to rotate along with the textile mechanism 11, the situation that the socks are wound by the textile mechanism 11 in the rotating process can be prevented in the process, then the controller controls the motor to rotate slowly, as the gear 33 is meshed with the tooth block 32 on the top plate 31, in the rotating process of the motor, the top plate 31 can be driven to slide out of the sliding groove of the supporting rod 3 slowly, the socks can be extruded in the process that the top plate 31 slowly extends out of the sliding groove, the socks are sleeved on the outer surface of the stand column 22 slowly, the socks can be overturned gradually, in the process, the socks after finishing textile can be prevented from being overturned by related machinery or manpower, the mechanical and labor costs are reduced, when the socks finish textile and are separated from the textile mechanism 11, at the moment, the top plate 31 still extrudes the socks, after the socks are separated from the top plate 31, the top plate 31 slides to the limit position, meanwhile, the socks are overturned and are placed below the supporting rod 3, at the moment, the controller controls the second electric telescopic rod 26 to stretch, in the process of stretching the second electric telescopic rod 26, the clamping plate 27 releases the clamping of the socks, at the moment, the socks are separated from the upright post 22 and fall on the stretching shaft of the first electric telescopic rod 21, at the moment, the second electric telescopic rod 26 continues to stretch and is clamped into the second notch 25 of the baffle plate 24, then, the controller controls the first electric telescopic rod 21 to contract, after the first electric telescopic rod 21 contracts, the overturned socks fall into the suction pipe 12 and are sucked out by the suction pipe 12, the falling of the socks overturning mechanism 2 can be prevented through the mutual matching of the first electric telescopic rod 21 and the second electric telescopic rod 26, and after the socks are drawn out, the first electric telescopic rod 21 is stretched and clamped into the first notch 23, and the second electric telescopic rod 26 is restored to the initial position.

As an embodiment of the present invention, a notch is formed in the inner wall of the top plate 31 at the bottom of each top plate 31, and a roller 34 is rotatably connected in each notch through a rotating shaft; each roller 34 rotates in one direction;

the during operation, because all rotate in the roof 31 inner wall and be connected with unidirectional rotation's roller 34, when roof 31 downstream, roller 34 can rotate on the socks face, can reduce the frictional force of roof 31 to socks at this in-process to prevent that roof 31 from scraping the yarn on the socks absolutely, prevent simultaneously that socks card is on roof 31.

As an embodiment of the present invention, the outer surface of each roller 34 is fixedly connected with an air bag 35 which is uniformly arranged, and the inner wall of the air bag 35 is provided with air holes;

during operation, because roller 34 surface links firmly the gasbag 35 of even arrangement, can extrude gasbag 35 at roller 34 pivoted in-process socks, and after gasbag 35 back of the body extrudees, the gas in the gasbag 35 can be through the gas pocket blowout, can blow socks at this in-process to can blow the yarn that is stained with on the socks, simultaneously because the existence of gasbag 35 can make socks and roller 34 present the point contact, thereby further reduce the friction of socks.

As an embodiment of the present invention, an end surface of each of the top plates 31 opposite to each other is hinged to a push block 36 through a rotating shaft; a transmission belt 37 is rotatably connected in the inner wall of the support rod 3 at the side of each sliding groove back to the back through a rotating shaft, and the transmission belt 37 is attached to the push block 36; one side of the transmission belt 37, which is far away from the push block 36, is mutually attached to the outer surface of the support rod 3;

in operation, because articulated ejector pad 36 and drive belt 37 are laminated each other, when the socks of weaving contact with the vaulting pole 3 of evenly arranging gradually, the reverse slow rotation of controller control motor this moment, can drive roof 31 through ejector pad 36 in the process of motor antiport and shift up, the in-process that shifts up at roof 31 can promote drive belt 37 slow rotation, the socks rebound on vaulting pole 3 of drive belt 37 pivoted in-process drive cover that can be slow, thereby prevent that the socks from fixing on vaulting pole 3 because the frictional force between socks and the vaulting pole 3, when roof 31 rebound, ejector pad 36 can take place to rotate, thereby can not drive belt 37 and rotate.

In one embodiment of the present invention, the outer surface of the transmission belt 37 is fixedly connected with uniformly arranged rubber bags 38;

the during operation, because drive belt 37 surface links firmly the rubber bag 38 of evenly arranging, when drive belt 37 rotated, rubber bag 38 can increase the pressure between drive belt 37 and the socks to drive socks downstream that can be better, the rubber bag 38 of evenly arranging simultaneously can prop up socks, and the better messenger socks are followed textile mechanism 11 and are rotated, prevent that the winding condition from appearing in socks.

As an embodiment of the present invention, air grooves 39 are formed in the inner walls of the supporting rods 3 on the upper and lower sides of each driving belt 37, and sliders 391 are slidably connected to the air grooves 39 through springs; through holes 392 are uniformly distributed on the opposite side of each air groove 39; one side of each sliding block 391, which is close to the transmission belt 37, is fixedly connected with a guide rod 393, and the guide rods 393 extend to form air outlet grooves 39 which are close to and not attached to the transmission belt 37; the guide rod 393 is in an arc design at one side close to the transmission belt 37;

during operation, because guide arm 393 extends to drive belt 37 one side, when drive belt 37 rotates, rubber bag 38 extrusion guide arm 393 that can be interrupted, can extrude slider 391 and slide in air duct 39 after guide arm 393 receives the extrusion, thereby can extrude the gas in air duct 39 through-hole 392, can blow socks after the gas blowout, thereby can further blow off the dust that is stained with on the socks, simultaneously because slider 391 passes through spring and air duct 39 sliding connection, when rubber bag 38 passes through guide arm 393, slider 391 resumes to initial condition under the effect of spring this moment, can adsorb outside gas through-hole 392 when slider 391 resumes, can adsorb socks to vaulting pole 3 surface at the inspiratory in-process of through-hole 392, thereby make better contact with drive belt 37 and remove of socks.

The specific working process is as follows:

when the sock unfolding device is used, when a sock is woven in the weaving mechanism 11, the overturning mechanism 2 is fixedly connected through the first electric telescopic rod 21, so that the overturning mechanism 2 can rotate along with the weaving mechanism 11, as the sock is woven to be longer and longer, the sock can be sleeved on the uniformly arranged supporting rods 3 at the unsealed positions due to the mutual approach of the supporting rods 3, when the sock is gradually lengthened, the sock can slide downwards on the uniformly arranged supporting rods 3, when the sock slides to one side of the second electric telescopic rod 26, the controller controls the second electric telescopic rod 26 to stretch at the moment, the clamping plate 27 can be pushed to stretch the sock in the stretching process of the second electric telescopic rod 26, the sock cloth placed below the clamping plate 27 is stretched after the sock is stretched, and the sock cloth placed below the clamping plate 27 can deviate to the opposite side of the clamping plate 27 due to certain elasticity of the sock, at the moment, the controller controls the second electric telescopic rod 26 to contract rapidly, socks can be clamped on the surface of the upright post 22 through the clamping plate 27 in the process, the overturning mechanism 2 rotates along with the textile mechanism 11, the upright post 22 can drive the socks to rotate along with the textile mechanism 11 at the moment, the situation that the socks are wound by the textile mechanism 11 in the rotating process can be prevented, then the controller controls the motor to rotate slowly, the gear 33 is meshed with the tooth blocks 32 on the top plate 31, the top plate 31 can be driven to slide out of the sliding grooves of the supporting rods 3 slowly in the rotating process of the motor, the socks can be extruded in the process that the top plate 31 slowly extends out of the sliding grooves, the socks are sleeved on the outer surface of the upright post 22 slowly, the socks can be overturned gradually, and the socks after finishing textile can be prevented from being overturned by related machinery or manpower in the process, thereby reducing the mechanical and labor costs, when the socks are completely woven and separated from the weaving mechanism 11, the top plate 31 extrudes the socks, when the socks are separated from the top plate 31, the top plate 31 slides to the limit position, meanwhile, the socks are completely turned and placed below the supporting rod 3, the controller controls the second electric telescopic rod 26 to stretch, in the stretching process of the second electric telescopic rod 26, the clamping plate 27 releases the clamping of the socks, the socks are separated from the upright post 22 and fall on the stretching shaft of the first electric telescopic rod 21, the second electric telescopic rod 26 continues to stretch and is clamped in the second notch 25 of the baffle plate 24, then the controller controls the first electric telescopic rod 21 to contract, when the first electric telescopic rod 21 contracts, the turned socks fall in the suction pipe 12 and are sucked out by the suction pipe 12, the falling of the turnover mechanism 2 can be prevented through the mutual matching of the first electric telescopic rod 21 and the second electric telescopic rod 26, when the sock is pulled out, the first electric telescopic rod 21 is stretched and clamped into the first notch 23, and the second electric telescopic rod 26 is restored to the initial position.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.