CN220898044U - Automatic production line for operating gowns - Google Patents

Abstract

The utility model belongs to the technical field of surgical gown production, and particularly relates to an automatic production line of surgical gowns, which comprises a surgical gown feeding device, a hand inserting bag welding device, a T-shaped waistband welding device, a straight waistband welding device, a sleeve welding device and a gown welding integrated device, wherein materials are fed through the surgical gown feeding device and sequentially pass through the hand inserting bag welding device, the T-shaped waistband welding device, the straight waistband welding device, the sleeve welding device and the gown welding integrated device, and finally are processed and formed into finished surgical gowns. Therefore, automatic production of the operating gown is realized, no manual work is needed, the production efficiency is effectively improved, and the labor cost is reduced.

Description

Automatic production line for operating gowns

Technical Field

The utility model belongs to the technical field of surgical gown production, and particularly relates to an automatic surgical gown production line.

Background

As is well known, medical staff need to change operating gowns when entering an operating room, on one hand, the operating room is clean and dirt is prevented from entering the operating room; on the other hand, the device is also used for preventing blood or tissue fluid with bacteria from splashing on the body of medical staff to cause cross infection.

The operating gown is used as necessary protective clothing in the operation process, is used for reducing the risk of medical staff contacting pathogenic microorganisms, can also reduce the risk of mutual transmission of pathogenic microorganisms between medical staff and patients, is a safety barrier of an aseptic area in the operation, and needs to suture sleeves and gowns of the operating gown in the production and processing of the operating gown so as to obtain a complete operating gown finished product.

The existing operating gown production and processing can not realize automatic production and needs manual operation, thus leading to high production cost and low production efficiency.

Disclosure of utility model

The utility model aims to provide an automatic production line of surgical gowns, and aims to solve the technical problem that the automatic production cannot be achieved in the production and processing of the surgical gowns in the prior art.

To achieve the above object, an automatic production line for surgical gowns according to an embodiment of the present utility model includes:

the surgical gown feeding device is used for placing a material roll on the surgical gown feeding device and conveying the material to the next station;

The hand inserting bag welding device comprises a hand inserting bag feeding mechanism for feeding the hand inserting bags, a hand inserting bag transplanting mechanism for transplanting the hand inserting bags onto the operating gown, and a hand inserting bag welding mechanism for welding the hand inserting bags onto the operating gown;

The waistband welding equipment is used for feeding the waistband and welding the waistband on the operating coat;

The sleeve welding device comprises a sleeve feeding mechanism for feeding materials, a sleeve cutting mechanism for cutting the materials into sleeves, a sleeve transplanting mechanism for transplanting the cut sleeves onto an operating gown, and a sleeve welding mechanism for welding the sleeves onto the operating gown;

the clothing body welding integrated device comprises a clothing body doubling mechanism for doubling the surgical clothing in half and a clothing body welding mechanism for welding openings at two ends of the doubled clothing body;

Wherein, the material is fed through operating gown loading attachment, in proper order through the hand pocket welding set, waistband welding equipment, sleeve welding set with the clothing body welds integrative device, and the final processing shaping becomes finished operating gown.

Optionally, the waistband welding device comprises a neckline cutting mechanism for cutting a neckline on the operating gown, a first T-shaped waistband welding mechanism for feeding the T-shaped waistband and welding the T-shaped waistband on the upper surface of the operating gown, and a second T-shaped waistband welding mechanism for feeding the T-shaped waistband and welding the T-shaped waistband on the lower surface of the operating gown, which are sequentially arranged along the conveying direction of the operating gown.

Optionally, the collar cutting mechanism comprises a collar cutting bracket, a cutting component for cutting a collar shape on the operating gown and a collar mould frame matched with the cutting component; the cutting assembly is arranged on the collar cutting support, the collar die frame is arranged below the cutting assembly, and the collar die frame is provided with a track groove which is annularly arranged.

Optionally, first T shape waistband welding mechanism with second T shape waistband welding mechanism all is including the blowing dish that is used for the blowing, be used for with the waistband on the blowing dish turns over and turns over the welding assembly that turns over of hem welded, be used for the traction turn over the waistband that welding assembly sent out and will the waistband cuts carry blank subassembly, be used for snatching the one end of waistband turn over and be annular snatch the subassembly, be used for turning over the one end of waistband and be annular back welded and roll over the area welding assembly, be used for being annular one end and pull the traction assembly who removes downwards with the waistband, be used for being annular one end cutting assembly and the T shape waistband that forms with the waistband cutting and weld the welding assembly on the operating gown with the T shape waistband that the cutting formed.

Optionally, the sleeve cutting mechanism comprises a cutting bedstead, a sleeve conveying structure arranged on the cutting bedstead and used for conveying materials, and two sleeve cutting assemblies used for cutting the materials to form sleeves; the two sleeve cutting components are located at one end of the cutting bed frame, which is close to the sleeve feeding mechanism, and an acute angle is formed between the two sleeve cutting components.

Optionally, the two sleeve cutting assemblies comprise an installation aluminum material arranged on the cutting bed frame, a cutting seat arranged on the installation aluminum material in a sliding manner, a linear driving structure arranged on the installation aluminum material and used for driving the cutting seat to move along the length direction of the installation aluminum material, and a cutting structure arranged on the cutting seat; an acute angle is formed between the two aluminum installation materials.

Optionally, the cutting structure includes the cutting motor that sets up on cutting the seat and with cutting motor transmission connection's cutting knife.

Optionally, the sleeve transplanting mechanism comprises a portal frame, an adsorption component arranged on the portal frame and used for adsorbing the operating gown, and a transplanting component arranged on the portal frame and used for driving the adsorption component to move onto the operating gown.

Optionally, the adsorption component comprises a transplanting bracket connected with the movable end of the transplanting component, a lifting structure arranged on the transplanting bracket, and an adsorption plate arranged at the movable end of the lifting structure; the adsorption plate is provided with a plurality of adsorption holes, and each adsorption hole is connected with a negative pressure structure.

Optionally, the garment body folding mechanism comprises a folding station frame, a grabbing folding assembly for grabbing the surgical gown and folding the surgical gown, and a garment body dragging assembly arranged on the folding station frame and used for dragging the folded surgical gown to the garment body welding mechanism; the grabbing and folding assembly is arranged on the folding station frame.

The one or more technical schemes in the automatic operating coat production line provided by the embodiment of the utility model have at least one of the following technical effects: the operating coat feeding device, the hand inserting bag welding device, the waistband welding device, the sleeve welding device and the coat body welding integrated device are sequentially arranged along the conveying direction of the operating coat. During production, materials of the operating gown are placed on an operating gown feeding device, the operating gown feeding device conveys the materials to a hand inserting bag welding device, meanwhile, a hand inserting bag feeding mechanism feeds the hand inserting bags, a hand inserting bag transplanting mechanism grabs the hand inserting bags and moves the hand inserting bags to the operating gown materials located on the hand inserting bag welding mechanism, and the hand inserting bag welding mechanism welds the hand inserting bags on the operating gown; the surgical gown welded with the handbag is conveyed to the neckline cutting mechanism, the neckline cutting mechanism cuts the surgical gown out of the neckline, then the surgical gown is conveyed to the waistband welding mechanism, the waistband is welded on the surgical gown, and then the surgical gown is conveyed to the sleeve welding mechanism. At the moment, the sleeve feeding mechanism feeds materials to the sleeve cutting mechanism, the sleeve cutting mechanism cuts and forms the sleeve, the sleeve transplanting mechanism moves to the sleeve cutting mechanism to grasp the cut and formed sleeve and moves the sleeve to the surgical gown on the sleeve welding mechanism, and the sleeve is welded to the surgical gown through the sleeve welding mechanism; the surgical gown with the sleeves welded is conveyed to a gown body doubling mechanism, the gown body doubling mechanism folds the surgical gown, the doubled surgical gown is conveyed to a gown body welding mechanism, and openings at two ends of the doubled surgical gown are welded to form the finished surgical gown. Therefore, automatic production of the operating gown is realized, no manual work is needed, the production efficiency is effectively improved, and the labor cost is reduced.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of an automatic operating coat production line according to an embodiment of the present utility model.

Fig. 2 is a schematic structural diagram of a T-shaped waistband welding device according to an embodiment of the present utility model.

Fig. 3 is a schematic structural view of a collar cutting mechanism according to an embodiment of the present utility model.

Fig. 4 is a schematic structural diagram of a first T-shaped waistband welding mechanism according to an embodiment of the present utility model.

Fig. 5 is a schematic structural diagram of a welding device for a straight waistband according to an embodiment of the present utility model.

Fig. 6 is a schematic structural diagram of a sleeve cutting mechanism according to an embodiment of the present utility model.

Fig. 7 is a schematic structural diagram of a sleeve transplanting mechanism according to an embodiment of the present utility model.

Fig. 8 is a schematic structural view of a body welding integrated device according to an embodiment of the present utility model.

Wherein, each reference sign in the figure:

10-operating coat feeding device 20-hand inserting bag welding device 30-T-shaped waistband welding device

31-Collar cutting mechanism 32-first T-shaped waistband welding mechanism 33-second T-shaped waistband welding mechanism

40-Straight waistband welding device 41-material placing disc 42-straight waistband welding mechanism

50-Sleeve welding device 51-sleeve feeding mechanism 52-sleeve cutting mechanism

53-Sleeve transplanting mechanism 54-sleeve welding mechanism 60-body welding integrated device

61-Clothing body doubling mechanism 62-clothing body welding mechanism 70-discharging tray

71-A turnover welding assembly 72-a conveying and blanking assembly 73-a grabbing assembly

74-Ribbon-folded welding assembly 75-traction assembly 76-welding assembly

311-Collar cutting support 312-collar mould frame 313-lifting module

314-Drive element 315-slide 316-cutter

317-First template 318-second template 319-resilient cushioning element

421-A turnover welding module 422-a conveying and blanking module 423-a grabbing module

424-Carry-in lifting module 425-cut-in mechanism 426-welding module

501-Mounting aluminum material 502-cutting seat 503-linear driving structure

504-Cutting motor 505-cutting blade 521-cutting bed frame

522-Sleeve conveying structure 523-sleeve cutting assembly 541-portal frame

542-Adsorption component 543-transplanting component 544-transplanting bracket

545-Lifting structure 546-adsorption plate 611-doubling-up station frame

612-A folding component 613-a garment dragging component.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to fig. 1 to 8 are exemplary and intended to illustrate embodiments of the present utility model and should not be construed as limiting the utility model.

In the description of the embodiments of the present utility model, it should be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate description of the embodiments of the present utility model and simplify description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the embodiments of the present utility model, the meaning of "plurality" is two or more, unless explicitly defined otherwise.

In the embodiments of the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured" and the like are to be construed broadly and include, for example, either permanently connected, removably connected, or integrally formed; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the embodiments of the present utility model will be understood by those of ordinary skill in the art according to specific circumstances.

In one embodiment of the present utility model, as shown in fig. 1 to 8, there is provided an automatic operating garment production line including an operating garment loading device 10, a hand pocket welding device 20, a waistband welding device, a sleeve welding device 50, and a body welding integrated device 60. The waistband welding device for feeding and welding a waistband to an operating gown includes a T-shaped waistband welding device 30 and a straight waistband welding device 40.

The roll of material is placed on the surgical gown feeder 10 and the material is transported to the next station by the surgical gown feeder 10. The operating gown feeding device 10 includes an operating gown feeding mechanism for storing operating gown materials, an operating gown stock mechanism for stock, and an operating gown slitting mechanism for cutting the operating gown materials to a fixed length, which are sequentially arranged.

The pocket welding device 20 includes a pocket feeding mechanism for feeding a pocket, a pocket transplanting mechanism for transplanting the pocket to a surgical gown, and a pocket welding mechanism for welding the pocket to the surgical gown. The hand inserting bag welding mechanism receives the operating gown conveyed by the operating gown cutting mechanism, the hand inserting bag feeding mechanism is located at the side of the hand inserting bag welding mechanism, and the hand inserting bag transplanting mechanism is located between the hand inserting bag feeding mechanism and the hand inserting bag welding mechanism. The hand inserting bag feeding mechanism is used for feeding and conveying materials of the hand inserting bag and cutting the materials of the hand inserting bag into the hand inserting bag.

The T-shaped waistband welding device 30 includes a neckline cutting mechanism 31 for cutting a neckline on the operating gown, a first T-shaped waistband welding mechanism 32 for feeding the T-shaped waistband and welding the T-shaped waistband to the upper surface of the operating gown, and a second T-shaped waistband welding mechanism 33 for feeding the T-shaped waistband and welding the T-shaped waistband to the lower surface of the operating gown, which are sequentially provided in the conveying direction of the operating gown. The collar cutting mechanism 31 receives the surgical gown conveyed by the pocket welding mechanism.

The straight waistband welding device 40 comprises a material placing disc 41 for feeding the straight waistband and a straight waistband welding mechanism 42 for welding the straight waistband on an operating coat. The straight waistband welding mechanism 42 receives the surgical gown conveyed by the second T-shaped waistband welding mechanism 33.

The sleeve welding device 50 includes a sleeve feeding mechanism 51 for feeding a material, a sleeve cutting mechanism 52 for cutting the material into sleeves, a sleeve transplanting mechanism 53 for transplanting the cut sleeves onto an operating garment, and a sleeve welding mechanism 54 for welding the sleeves onto the operating garment. The sleeve welding mechanism 54 receives the surgical gown conveyed by the straight waistband welding mechanism 42, the sleeve feeding mechanism 51 is positioned beside the sleeve welding mechanism 54, and the sleeve transplanting mechanism 53 is positioned between the sleeve welding mechanism 54 and the sleeve cutting mechanism 52.

The body welding integrated device 60 includes a body folding mechanism 61 for folding the surgical gown in half and a body welding mechanism 62 for welding both end openings of the folded body. The body folding mechanism 61 receives the surgical gown fed by the sleeve welding mechanism 54.

Wherein, the material is fed by the operating gown feeding device 10, sequentially passes through the hand inserting bag welding device 20, the T-shaped waistband welding device 30, the straight waistband welding device 40, the sleeve welding device 50 and the gown body welding integrated device 60, and finally is processed and formed into the finished operating gown.

The operating gown feeding device 10, the hand pocket welding device 20, the T-shaped waistband welding device 30, the straight waistband welding device 40, the sleeve welding device 50 and the body welding integrated device 60 are sequentially arranged along the conveying direction of the operating gown. During production, materials of the operating gown are placed on the operating gown feeding device 10, the operating gown feeding device 10 conveys the materials to the hand inserting bag welding device 20, meanwhile, the hand inserting bag feeding mechanism feeds the hand inserting bags, the hand inserting bag transplanting mechanism grabs the hand inserting bags and moves the hand inserting bags to the operating gown materials located on the hand inserting bag welding mechanism, and the hand inserting bag welding mechanism welds the hand inserting bags on the operating gown; the surgical gown welded with the handbag is conveyed to a neckline cutting mechanism 31, the neckline cutting mechanism cuts the surgical gown out of a neckline, then the surgical gown is sequentially conveyed to a first T-shaped waistband welding mechanism 32 and a second T-shaped waistband welding mechanism 33, the first T-shaped waistband welding mechanism 32 is used for welding a T-shaped waistband on the upper surface of the surgical gown, and the second T-shaped waistband welding mechanism 33 is used for welding the T-shaped waistband on the lower surface of the surgical gown; the surgical gown welded with the T-shaped waistband is conveyed to the straight waistband welding device 40, the straight waistband is fed to the surgical gown by the feeding tray 41, the straight waistband is welded to the surgical gown through the straight waistband welding mechanism 42, and then the surgical gown is conveyed to the sleeve welding mechanism 54. At this time, the sleeve feeding mechanism 51 feeds the material to the sleeve cutting mechanism 52, and cuts and forms the material by the sleeve cutting mechanism 52, the sleeve transplanting mechanism 53 moves to the sleeve cutting mechanism 52 to grasp the cut and formed sleeve and move the sleeve to the surgical gown on the sleeve welding mechanism 54, and the sleeve is welded to the surgical gown by the sleeve welding mechanism 54; the surgical gown with the sleeves welded is conveyed to a gown body doubling mechanism 61, the gown body doubling mechanism 61 folds the surgical gown, the folded surgical gown is conveyed to a gown body welding mechanism 62, and openings at two ends of the folded surgical gown are welded to form a finished surgical gown. Therefore, automatic production of the operating gown is realized, no manual work is needed, the production efficiency is effectively improved, and the labor cost is reduced.

In this embodiment, as shown in fig. 2 to 3, the collar cutting mechanism 31 includes a collar cutting bracket 311, a cutting member for cutting out a collar shape on the surgical gown, and a collar mold frame 312 engaged with the cutting member; the excision subassembly sets up on collarband excision support 311, and collarband die carrier 312 is located the below of excision subassembly and is equipped with the track groove that the annular set up on the collarband die carrier 312. Specifically, a lifting module 313 for driving the cutting assembly to lift is disposed on the collar cutting bracket 311, a moving end of the lifting module 313 is connected with the cutting assembly, and the lifting module 313 may be a cylinder, an oil cylinder, an electric cylinder, etc. When the operating gown is conveyed to the collar die carrier 312, the operating gown is positioned between the collar die carrier 312 and the cutting assembly, the lifting module 313 drives the cutting assembly to move downwards, the cutting assembly is matched with the collar die carrier 312, and the cutting knife 316 of the cutting assembly cuts along the track groove, so that the collar is cut and formed.

In this embodiment, as shown in fig. 3, the cutting assembly includes a driving element 314 disposed on the collar cutting bracket 311, a sliding rail 315 connected to an output end of the driving element 314, a cutter 316 slidably connected to the sliding rail 315, and a track module connected to the collar cutting bracket 311; the track module is provided with an annular groove matched with the track groove, and the cutter 316 penetrates through the annular groove and is in sliding connection with the track module. Specifically, the driving element 314 is configured to drive the sliding rail 315 to rotate, one end of the cutter 316 is provided with a connection block slidably connected to the sliding rail 315, and the connection block can slide along the sliding rail 315 on the sliding rail 315. The annular groove is the same shape as the track groove and is disposed opposite, and the cutter 316 is disposed within the annular groove. When the collar is cut, the lifting module 313 drives the cutting assembly to move downwards, the cutting edge of the cutter 316 penetrates through the operating gown and stretches into the track groove, the driving element 314 drives the sliding rail 315 to rotate, the sliding rail 315 drives the connecting block to rotate, the connecting block drives the cutter 316 to move, the connecting block slides on the sliding rail 315 while the cutter 316 moves in the annular groove in the shape of the collar, and meanwhile, the cutter 316 cuts the operating gown out of the collar along the track of the track groove.

In this embodiment, as shown in fig. 3, the track module includes a first template 317 and a second template 318 which are sequentially arranged downward in the vertical direction, the first template 317 and the second template 318 are arranged at intervals, and annular grooves are provided in each of them; a plurality of engaging teeth are provided in the annular groove of the first die plate 317, and gears engaged with the respective engaging teeth are provided on the cutter 316. Specifically, a plurality of elastic buffer members 319 are disposed between the first template 317 and the second template 318, the elastic buffer members 319 are connected with the first template 317 and the second template 318, the elastic buffer members 319 comprise a guide rod and a spring, the spring is sleeved outside the guide rod, one end of the guide rod is fixedly connected with the second template 318, the other end of the guide rod is slidably connected with the first template 317, and two ends of the spring are respectively connected with the first template 317 and the second template 318. The driving element 314 drives the sliding rail 315 to rotate, the sliding rail 315 drives the connecting block to rotate, the connecting block drives the cutter 316 to move, and the cutter 316 moves along the annular groove under the driving of the driving element 314 due to the fact that the gear is arranged on the cutter 316 and meshed with the meshing teeth.

In this embodiment, as shown in fig. 2 and 4, the first T-shaped waistband welding mechanism 32 and the second T-shaped waistband welding mechanism 33 each include a discharging tray 70 for discharging, a folding welding assembly 71 for folding and welding the waistband on the discharging tray 70, a conveying and blanking assembly 72 for pulling the waistband sent out by the folding welding assembly 71 and cutting the waistband, a grabbing assembly 73 for grabbing one end of the waistband, a folding strap welding assembly 74 for folding one end of the waistband into a ring shape and then welding, a pulling assembly 75 for pulling and moving one end of the waistband downwards, a cutting assembly for cutting one end of the waistband into a ring shape and forming a T-shaped waistband, and a welding assembly 76 for welding the T-shaped waistband formed by cutting onto a surgical garment. Specifically, during the surgical gown setup, the surgical gown sequentially passes through the first T-lap welding mechanism 32 and the second T-lap welding mechanism 33. When passing through the first T-shaped waistband welding mechanism, one end of waistband material placed on the discharging tray 70 is pulled to the folding welding assembly 71, the waistband is folded in half along the length direction by the folding welding assembly 71, and the folded edges of the waistband are welded. Then, the folded and welded waistband is transported to the folded band welding component 74 by being pulled by the transport blanking component 72, the grabbing component 73 is moved between the transport blanking component 72 and the folded band welding component 74, and grabs the waistband to move towards the direction close to the traction component 75, so that the waistband is folded, when the folded band welding component 74 reaches the welding point of the folded band welding component 74, one end of the waistband is welded to be annular by the folded band welding component 74, the waistband is transported to the traction component 75 by the grabbing component 73, and then the waistband is transversely cut off along the width by the cutting component according to the length of the set waistband. One end of the traction assembly 75 is inserted into a hole formed at one annular end of the waistband and drives the waistband downward. Until the cutting assembly cuts the waistband, one end of the waistband, which is annular, is cut and a T-shaped waistband is formed, one end of the T-shaped waistband is contacted with the operating gown, and then the welding assembly 76 welds the T-shaped waistband on the upper end surface of the operating gown.

Then, the operating gown is conveyed to the second T-shaped waistband welding mechanism 33, one end of the waistband material placed on the discharging tray 70 is pulled to the folding welding assembly 71, the waistband is folded in half along the length direction thereof by the folding welding assembly 71, and the folds of the waistband are welded. Then, the folded and welded waistband is transported to the folded band welding component 74 by being pulled by the transport blanking component 72, the grabbing component 73 is moved between the transport blanking component 72 and the folded band welding component 74, and grabs the waistband to move towards the direction close to the traction component 75, so that the waistband is folded, when the folded band welding component 74 reaches the welding point of the folded band welding component 74, one end of the waistband is welded to be annular by the folded band welding component 74, the waistband is transported to the traction component 75 by the grabbing component 73, and then the waistband is transversely cut off along the width by the cutting component according to the length of the set waistband. One end of the traction assembly 75 is inserted into a hole formed at one annular end of the waistband and drives the waistband downward. Until the cutting assembly cuts the waistband, the annular end of the waistband is cut and forms a T-shaped waistband, one end of the T-shaped waistband is contacted with the operating gown, and then the welding assembly 76 welds the T-shaped waistband to the lower end face of the operation.

In this embodiment, as shown in fig. 5, the straight waistband welding mechanism 42 includes a folding welding module 421 for folding and welding the folds, a conveying and blanking module 422 located beside the folding welding mechanism, a grabbing module 423 for grabbing the waistband for moving, a clamping and lifting module 424 for clamping the waistband and lifting the middle part of the waistband, a band cutting mechanism 425 for cutting the lifted waistband to form two waistbands, and a welding module 426 for welding the two waistbands on the operating gown. Specifically, when the waistband on the material placing tray 41 is conveyed to the folding welding module 421 in use, the folding welding module 421 folds the waistband in half along the length direction thereof, and folds and welds the folds of the waistband; then, the girdle after hemming and welding passes through the conveying and blanking module 422, the grabbing module 423 moves to one end of the conveying and blanking module 422 away from the turnover welding module 421, and the grabbing girdle moves towards a direction close to the entrainment and lifting module 424. The grabbing module 423 grabs the waistband to pass through the entrainment lifting module 424, then the entrainment lifting module 424 clamps one end of the waistband, then the entrainment lifting module 424 lifts the middle part of the waistband upwards, the entrainment lifting module 424 clamps the other end of the waistband, then the conveying and blanking module 422 cuts off the waistband, meanwhile the grabbing module 423 loosens the waistband, the welding module 426 respectively welds the clamped two ends of the waistband on the operating gown, and finally the band cutting module cuts off the lifted waistband to form two waistbands. Thus, the same equipment is realized, the two waistbands are welded on the operating gown at the same station, no manual work is needed, and the welding efficiency is high.

In this embodiment, the material carrying module 424 includes a lifting assembly, a clamping assembly connected to a moving end of the lifting assembly, and a material carrying assembly connected to the clamping assembly; the clamping assembly is provided with two clamping ends, the lifting assembly is positioned above the clamping assembly, and the lifting assembly is provided with a lifting belt mandrel for lifting materials. Specifically, the lifting structure is used for driving the clamping assembly to reciprocate along the vertical direction, so as to avoid the space grabbing module 423 and drive the waistband to move downwards, so that the waistband is matched with the welding module 426 to realize welding. The clamping assembly is provided with two clamping ends and is used for clamping the waistband, after the grabbing module 423 grabs the waistband and passes through the two clamping ends of the clamping assembly, the clamping assembly is close to one end of the grabbing module 423 to clamp the waistband, the other end of the clamping assembly is kept open, the lifting assembly upwards drives the waistband between the two clamping ends to move to a set height, the clamping assembly is close to one end of the conveying blanking module 422 to clamp the waistband, the conveying blanking module 422 cuts off the waistband, and the clamping assembly loosens the clamping of the waistband.

In this embodiment, as shown in fig. 6 to 7, the sleeve cutting mechanism 52 includes a cutting frame 521, a sleeve conveying structure 522 provided on the cutting frame 521 for conveying materials, and two sets of sleeve cutting components 523 for cutting the materials to form sleeves; the two sleeve cutting components 523 are located at one end of the cutting bed frame 521, which is close to the sleeve feeding mechanism 51, and an acute angle is formed between the two sleeve cutting components 523. Specifically, the two sleeve cutting assemblies 523 are splayed to cut the material into a trapezoid. The two sleeve cutting assemblies 523 comprise an installation aluminum material 501 arranged on a cutting bedstead 521, a cutting seat 502 arranged on the installation aluminum material 501 in a sliding manner, a linear driving structure 503 arranged on the installation aluminum material 501 and used for driving the cutting seat 502 to move along the length direction of the installation aluminum material 501, and a cutting structure arranged on the cutting seat 502; the cutting structure comprises a cutting motor 504 arranged on a cutting seat 502 and a cutting knife 505 in transmission connection with the cutting motor 504; an acute angle is formed between the two mounting aluminum materials 501.

In this embodiment, as shown in fig. 7, the sleeve transplanting mechanism 53 includes a gantry 541, an adsorption assembly 542 provided to the gantry 541 and used for adsorbing the surgical gown, and a transplanting assembly 543 provided to the gantry 541 and used for driving the adsorption assembly 542 to move onto the surgical gown. Specifically, the adsorption assembly 542 includes a transplanting bracket 544 connected to the moving end of the transplanting assembly 543, a lifting structure 545 provided on the transplanting bracket 544, and an adsorption plate 546 provided at the moving end of the lifting structure 545; the adsorption plate 546 is provided with a plurality of adsorption holes, and each adsorption hole is connected with the negative pressure structure. The cut sleeves are adsorbed by negative pressure, and are moved to the upper part of the operating gown by the transplanting assembly 543, the lifting structure 545 drives the transplanting support 544 downwards, and the sleeves are placed on the operating gown.

In this embodiment, as shown in fig. 8, the body folding mechanism 61 includes a folding station frame 611, a grabbing and folding assembly 612 for grabbing and folding the surgical gown, and a body dragging assembly 613 provided on the folding station frame 611 for dragging the folded surgical gown to the body welding mechanism 62; the grabbing and folding assembly 612 is disposed on the folding station frame 611. Specifically, the grabbing and folding assembly 612 grabs one end of the operating gown and moves towards the body welding mechanism 62, after the grabbing and folding assembly 612 moves to the set position, the operating gown is loosened, folding of the operating gown is completed, and then the body dragging assembly 613 moves the folded operating gown to the body welding mechanism 62 for welding.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (10)

1. An operating gown automated production line, characterized by comprising:

the surgical gown feeding device is used for placing a material roll on the surgical gown feeding device and conveying the material to the next station;

The hand inserting bag welding device comprises a hand inserting bag feeding mechanism for feeding the hand inserting bags, a hand inserting bag transplanting mechanism for transplanting the hand inserting bags onto the operating gown, and a hand inserting bag welding mechanism for welding the hand inserting bags onto the operating gown;

The waistband welding equipment is used for feeding the waistband and welding the waistband on the operating coat;

The sleeve welding device comprises a sleeve feeding mechanism for feeding materials, a sleeve cutting mechanism for cutting the materials into sleeves, a sleeve transplanting mechanism for transplanting the cut sleeves onto an operating gown, and a sleeve welding mechanism for welding the sleeves onto the operating gown;

the clothing body welding integrated device comprises a clothing body doubling mechanism for doubling the surgical clothing in half and a clothing body welding mechanism for welding openings at two ends of the doubled clothing body;

Wherein, the material is fed through operating gown loading attachment, in proper order through the hand pocket welding set, waistband welding equipment, sleeve welding set with the clothing body welds integrative device, and the final processing shaping becomes finished operating gown.

2. The surgical gown automation line of claim 1, wherein: the waistband welding equipment comprises a neckline cutting mechanism for cutting a neckline on the operating gown, a first T-shaped waistband welding mechanism for feeding the T-shaped waistband and welding the T-shaped waistband on the upper surface of the operating gown, and a second T-shaped waistband welding mechanism for feeding the T-shaped waistband and welding the T-shaped waistband on the lower surface of the operating gown, which are sequentially arranged along the conveying direction of the operating gown.

3. The surgical gown automation line of claim 2, wherein: the collarband cutting mechanism comprises a collarband cutting bracket, a cutting assembly for cutting out the shape of a collarband on the operating gown and a collarband die carrier matched with the cutting assembly; the cutting assembly is arranged on the collar cutting support, the collar die frame is arranged below the cutting assembly, and the collar die frame is provided with a track groove which is annularly arranged.

4. The surgical gown automation line of claim 2, wherein: the first T-shaped waistband welding mechanism and the second T-shaped waistband welding mechanism comprise a discharging disc used for discharging, a waistband folding welding assembly used for folding and welding folds on the discharging disc, a waistband conveying and blanking assembly used for pulling the waistband sent out by the folding welding assembly and cutting the waistband, a grabbing assembly used for grabbing one end of the waistband to fold and form an annular shape, a waistband folding welding assembly used for folding one end of the waistband and forming an annular shape and then welding the annular shape, a traction assembly used for downwards pulling and moving one end of the waistband, a cutting assembly used for cutting one end of the waistband into an annular shape and forming a T-shaped waistband, and a welding assembly used for welding the T-shaped waistband formed by cutting on an operating coat.

5. The surgical gown automation line of any one of claims 1 to 4, wherein: the sleeve cutting mechanism comprises a cutting bedstead, a sleeve conveying structure arranged on the cutting bedstead and used for conveying materials, and two sleeve cutting assemblies used for cutting the materials to form sleeves; the two sleeve cutting components are located at one end of the cutting bed frame, which is close to the sleeve feeding mechanism, and an acute angle is formed between the two sleeve cutting components.

6. The surgical gown automated production line of claim 5, wherein: the two sleeve cutting assemblies comprise an installation aluminum material arranged on the cutting bedstead, a cutting seat arranged on the installation aluminum material in a sliding manner, a linear driving structure arranged on the installation aluminum material and used for driving the cutting seat to move along the length direction of the installation aluminum material, and a cutting structure arranged on the cutting seat; an acute angle is formed between the two aluminum installation materials.

7. The surgical gown automated production line of claim 6, wherein: the cutting structure comprises a cutting motor arranged on the cutting seat and a cutting knife in transmission connection with the cutting motor.

8. The surgical gown automation line of any one of claims 1 to 4, wherein: the sleeve transplanting mechanism comprises a portal frame, an adsorption component which is arranged on the portal frame and used for adsorbing surgical gowns, and a transplanting component which is arranged on the portal frame and used for driving the adsorption component to move onto the surgical gowns.

9. The surgical gown automated production line of claim 8, wherein: the adsorption assembly comprises a transplanting support connected with the movable end of the transplanting assembly, a lifting structure arranged on the transplanting support and an adsorption plate arranged at the movable end of the lifting structure; the adsorption plate is provided with a plurality of adsorption holes, and each adsorption hole is connected with a negative pressure structure.

10. The surgical gown automation line of any one of claims 1 to 4, wherein: the garment body doubling-up mechanism comprises a doubling-up station frame, a grabbing doubling-up assembly used for grabbing the surgical gown and doubling up the surgical gown, and a garment body dragging assembly arranged on the doubling-up station frame and used for dragging the doubled-up surgical gown to the garment body welding mechanism; the grabbing and folding assembly is arranged on the folding station frame.