CN116641194B

CN116641194B - Yarn dyeing device is used in production of fibre protective glove

Info

Publication number: CN116641194B
Application number: CN202310895869.6A
Authority: CN
Inventors: 王鹏; 王咸华; 王双成; 谷志旗; 王景景
Original assignee: Jiangsu Hanvo Safety Product Co ltd
Current assignee: Jiangsu Hanvo Safety Product Co ltd
Priority date: 2023-07-20
Filing date: 2023-07-20
Publication date: 2023-11-07
Anticipated expiration: 2043-07-20
Also published as: CN116641194A

Abstract

The invention discloses a yarn dyeing device for producing fiber protective gloves, which comprises a dyeing box for containing dyeing liquid, wherein a roller for hanging coiled yarns is arranged on the dyeing box; the invention relates to the technical field of yarn dyeing equipment. This yarn dyeing apparatus is used in production of fibre protective glove is through setting up transmission connection structure on the dyeing case for actuating mechanism is at the operation in-process, and the accessible transmission connection structure precursor drives limit structure and extrudees fixedly to the roller, and after fixed, the cooperation of accessible placing a section of thick bamboo and limit structure drives the roller and carries out intermittent type nature rotation, thereby drive the lapping yarn on the roller and carry out intermittent type rotation, change the contact part of yarn and dye solution, evenly dye it, simultaneously because the roller is intermittent type rotation, can prolong the dyeing time that the yarn is arranged in the dye solution, reinforcing dyeing effect, and the yarn after dyeing is accomplished shifts out the dye solution after, the unnecessary dye solution of its surface can drip in the dyeing case.

Description

Yarn dyeing device is used in production of fibre protective glove

Technical Field

The invention relates to the technical field of yarn dyeing equipment, in particular to a yarn dyeing device for producing fiber protective gloves.

Background

In the production and processing process of the fiber protective glove, the manufactured yarns need to be dyed, so that the fiber protective glove with different colors is manufactured. In the existing yarn dyeing process, the yarn is usually wound into a shape of one roll, then the wound yarn is sleeved on a roller, then the roller is placed on the top of a dye vat, and the yarn is supported by the roller or is fully immersed in the dye vat, and the method has certain defects: 1. if the yarn is sleeved on the roller for dyeing, only part of the yarn is in contact with the dyeing liquid, so that after the dyeing time of the part is up, a worker is required to manually rotate the roller, and the part which is not dyed is placed in the dyeing liquid, so that the worker is required to rotate the roller at fixed time, and time and labor are wasted; 2. in either case, after the yarn is dyed, the worker usually directly takes the yarn out of the dye vat and dries it by airing or spin-drying it, which causes the waste of the excess dyeing liquid.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a yarn dyeing device for producing fiber protective gloves, which solves the problems in the prior art.

In order to achieve the above purpose, the invention is realized by the following technical scheme: the utility model provides a yarn dyeing apparatus is used in production of fibre protective glove, includes the dyeing case that is used for splendid attire dyeing liquid, be provided with the roller that is used for hanging lapping yarn on the dyeing case, the surface slip of dyeing case is provided with the link by the locking, be provided with the placement structure of placing the roller on the link, the outside of dyeing case is provided with transmission connection structure, wherein, through actuating mechanism drive transmission connection structure to the roller clamp after, can drive its intermittent type nature rotation, and actuating mechanism still can drive the link after the release locking simultaneously and drive the roller and shift out the dyeing case.

The placing structure comprises a plurality of placing frames which are fixedly arranged at the top of the connecting frame, a connecting plate is fixedly arranged at the top of one side of the connecting frame opposite to the placing frames, a placing cylinder is rotatably arranged in the connecting plate, and a limiting structure for fixing the roller in an extrusion mode is arranged on the placing cylinder.

Preferably, the limit structure comprises a mounting plate fixedly arranged on the placing frame, a limit rod is arranged on the internal thread of the mounting plate, one end of the limit rod penetrates through the placing cylinder and is fixedly provided with a limit disc, and the outer surface of the limit rod is fixedly provided with a limit spring, wherein one end of the limit spring is fixed with the mounting plate.

Preferably, the inside of link runs through the slip and is provided with the locking piece, locking piece and the lateral wall joint of dyeing case lock the position of link.

Preferably, the transmission connection structure comprises a rack plate, one side of the connecting frame is rotatably provided with a transmission gear, the transmission gear is in transmission connection with the placing cylinder through a first transmission structure, the bottom of the rack plate is fixedly provided with a connecting rod, and the end part of the connecting rod is fixedly provided with a sliding rod in sliding connection with the dyeing box.

Preferably, the lateral wall of the dyeing box is provided with a connecting groove, a guide block is fixedly arranged in the connecting groove, and the end part of the sliding rod extends into the connecting groove and is positioned between the lateral wall of the connecting groove and the guide block.

Preferably, the surface fixing of dyeing case is provided with the braced frame, the inside slip of braced frame is provided with the bracing piece, the connecting rod runs through the bracing piece and rather than internal surface sliding connection, fixedly be provided with supporting spring between the inner wall of bracing piece and braced frame.

Preferably, the driving mechanism comprises a driving motor which is fixedly arranged on the outer surface of the dyeing box and is on the same side as the rack plate, a driving rod is fixedly arranged on an output shaft of the driving motor through a coupler, a push rod is rotatably arranged at the end part of the driving rod, and the end part of the push rod is rotatably connected with the rack plate.

Preferably, the side wall of the adjacent rack board of the dyeing box is rotatably provided with a lifting screw, the outer surface thread of the lifting screw is provided with a lifting block, the top of the lifting block is rotatably provided with a lifting rod, wherein the end part of the lifting rod is rotatably connected with the connecting frame, the outer side of the dyeing box is provided with a transmission assembly, and the transmission assembly is started by a driving motor to drive the lifting screw to rotate.

Preferably, the transmission assembly comprises a first transmission fluted disc arranged on the outer surface of the lifting screw in a sliding manner, a reset spring is arranged on the outer surface of the lifting screw in a fixed manner, one end of the reset spring is fixedly connected with the first transmission fluted disc, a transmission shaft is rotatably arranged on the outer surface of the dyeing box, a second transmission fluted disc is arranged on the outer surface of the transmission shaft in a fixed manner, the second transmission fluted disc is meshed with the first transmission fluted disc, and the transmission shaft is in transmission connection with an output shaft of the driving motor through a second transmission structure.

Advantageous effects

The invention provides a yarn dyeing device for producing fiber protective gloves. Compared with the prior art, the method has the following beneficial effects:

(1) According to the yarn dyeing device for producing the fiber protective glove, the connecting frame with the adjustable locking state is arranged on the dyeing box, so that the driving mechanism can normally operate when the connecting frame is in the state, and the position of the connecting frame is unchanged; when the locking state of the connecting frame is released, the driving mechanism can drive the connecting frame to move upwards, so that coiled yarns on the roller are driven to move out of the dyeing liquid and are dried, redundant dyeing liquid on the yarns can drop into the dyeing box to be collected, waste is prevented, and workers can conveniently take the dried yarns.

(2) This yarn dyeing apparatus is used in fiber protective glove production is through setting up transmission connection structure on the dyeing case for actuating mechanism is at the operation in-process, and the accessible transmission connection structure precursor drives limit structure and extrudees fixedly to the roller, and after fixed, the cooperation of accessible place a section of thick bamboo and limit structure drives the roller and carries out intermittent type nature rotation, thereby drive the lapping yarn on the roller and carry out intermittent type rotation, change the contact part of yarn and dye solution, evenly dye it, simultaneously because the roller is intermittent type rotation, can prolong the dyeing time that the yarn is arranged in the dye solution, reinforcing dyeing effect, and the yarn after dyeing is accomplished shifts out the dye solution in its surperficial unnecessary dye solution can drip to the dyeing case, prevent extravagant, resources are saved.

Drawings

FIG. 1 is a first perspective view of an external structure of the present invention;

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

FIG. 3 is a perspective view of a placement structure of the present invention;

FIG. 4 is a partially disassembled schematic illustration of the structure of FIG. 3 in accordance with the present invention;

FIG. 5 is a schematic cross-sectional view of an arrangement of the present invention;

FIG. 6 is a schematic diagram of the connection of the drive connection structure to the placement structure of the present invention;

FIG. 7 is a partially disassembled schematic illustration of the structure of FIG. 6 in accordance with the present invention;

FIG. 8 is a schematic diagram of a connection between a driving mechanism and a transmission connection structure according to the present invention;

FIG. 9 is a schematic cross-sectional view of the partial structure of FIG. 6 in accordance with the present invention;

FIG. 10 is a schematic diagram of the connection of the transmission assembly to the driving mechanism according to the present invention;

FIG. 11 is a schematic view of the partial structure of FIG. 10 according to the present invention;

fig. 12 is a perspective view of a transmission assembly of the present invention.

In the figure: 1-dyeing box, 2-roller, 3-connecting frame, 301-locking block, 4-placing structure, 401-placing frame, 402-connecting plate, 403-placing cylinder, 404-mounting plate, 405-limit rod, 406-limit disk, 407-limit spring, 5-transmission connecting structure, 501-rack plate, 502-transmission gear, 503-first transmission structure, 504-connecting rod, 505-sliding rod, 506-connecting groove, 507-guide block, 6-driving mechanism, 601-driving motor, 602-driving rod, 603-push rod, 7-supporting frame, 701-supporting rod, 702-supporting spring, 8-lifting screw, 801-lifting block, 802-lifting rod, 9-transmission assembly, 901-first transmission fluted disc, 902-return spring, 903-transmission shaft, 904-second transmission fluted disc, 10-second transmission structure.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-12, the present invention provides a technical solution: the yarn dyeing device for producing the fiber protective glove comprises a dyeing box 1 for containing dyeing liquid, wherein one side of the dyeing box 1 is communicated with a water outlet pipe (not shown in the figure) so as to be convenient for replacing the dyeing liquid. The dyeing box 1 is provided with a roller 2 for hanging coiled yarns, the outer surface of the dyeing box 1 is slidably provided with a locked connecting frame 3, the inside of the connecting frame 3 is penetratingly slidably provided with a locking block 301, the locking block 301 is clamped with the side wall of the dyeing box 1 to lock the position of the connecting frame 3, and the locking state of the connecting frame 3 can be released by pulling out the locking block 301, so that the dyeing box can move in the vertical direction. The connecting frame 3 is provided with a placing structure 4 for placing the roller 2, the outer side of the dyeing box 1 is provided with a transmission connecting structure 5, wherein the transmission connecting structure 5 is driven by the driving mechanism 6 to drive the roller 2 to intermittently rotate after being clamped, and meanwhile, the connecting frame 3 after the locking is released can be driven by the driving mechanism 6 to drive the roller 2 to move out of the dyeing box 1.

Wherein, with regard to the design scheme of placing structure 4, placing structure 4 includes that a plurality of is fixed to be set up the rack 401 in link 3 top one side, and the top of rack 401 is one side and is open-ended arc design, the better contact with roller 2's surface of being convenient for when roller 2 places unfixed, stable effect is better. The connecting plate 402 is fixedly arranged on the connecting frame 3 at the top of one side of the connecting plate opposite to the placing frame 401, the placing barrel 403 is rotatably arranged in the connecting plate 402, the inside of the placing barrel 403 is hollow, one side of the connecting plate opposite to the placing frame 401 is provided with an opening, and the distance between the placing barrel 403 and the placing frame 401 is slightly smaller than the length of the roller 2. In the setting, one end of the roll 2 is inserted into the setting cylinder 403, and the other end is set on the setting frame 401. The placing cylinder 403 is provided with a limiting structure for fixing the roller 2 in an extrusion mode, so that stability of the roller 2 is improved, and meanwhile the placing cylinder 403 is convenient to drive the roller to rotate.

Wherein, regarding limit structure's design, limit structure is including fixed mounting panel 404 that sets up on rack 401, and the internal thread of mounting panel 404 is provided with gag lever post 405, and the surface of gag lever post 405 is provided with local screw thread, and with mounting panel 404's internal surface threaded connection. One end of the limiting rod 405 penetrates through the placing cylinder 403 and is fixedly provided with a limiting disc 406, the outer surface of the limiting rod 405 is in sliding connection with the inner surface of the placing cylinder 403, and the outer surface of the limiting disc 406 is in sliding connection with the inner surface of the placing cylinder 403, so that the limiting rod 405 is effectively limited and prevented from rotating. The outer surface of the limiting rod 405 is fixedly provided with a limiting spring 407, and the elastic coefficient of the limiting spring 407 can be set according to requirements. Wherein one end of the limit spring 407 is fixed to the mounting plate 404. When the placing cylinder 403 rotates, the limiting rod 405 is driven to rotate, as the limiting rod 405 is partially in threaded connection with the mounting plate 404, the limiting rod 405 moves to one side close to the dyeing box 1 while rotating, so as to drive the limiting disc 406 to move, when the limiting disc 406 extrudes the roller 2 and the other end of the roller 2 is tightly abutted with the placing frame 401, the position of the roller 2 is fixed, meanwhile, the threaded part on the limiting rod 405 is separated from the mounting plate 404, the smooth part of the threaded part is connected with the mounting plate 404, at the moment, the limiting rod 405 still rotates along with the placing cylinder 403, but the position of the threaded part is not moved, at the moment, the limiting spring 407 is stretched, so that the threaded part on the surface of the limiting rod 405 can be connected with the mounting plate 404 when the limiting rod 405 is reversed, and is convenient to move to one side far away from the dyeing box 1, and the fixation of the roller 2 is released.

With regard to the design of the drive connection 5, the drive connection 5 comprises a toothed plate 501, wherein the toothed plate 501 is provided with a plurality of sections of toothed sections, which are respectively engaged with the drive gear 502. One side of the connecting frame 3 is rotatably provided with a transmission gear 502, the transmission gear 502 is in transmission connection with the placing cylinder 403 through a first transmission structure 503, the first transmission structure 503 is composed of a belt pulley and a belt, the belt pulley is fixedly arranged on one side of the transmission gear 502, which is close to the dyeing box 1, and the outer surface of the placing cylinder 403, and the belt transmission is arranged between the outer surfaces of the two belt pulleys, so that the transmission gear 502 can drive the placing cylinder 403 to rotate through the first transmission structure 503 when rotating, thereby driving the roller 2 to rotate, changing the contact part of the yarn and the dyeing liquid, and facilitating the whole dyeing of the yarn. The bottom of rack plate 501 is fixedly provided with a connecting rod 504, and the end of connecting rod 504 is fixedly provided with a sliding rod 505 in sliding connection with dye box 1.

As a further technical scheme, the side wall of the dyeing box 1 is provided with a connecting groove 506, the inside of the connecting groove 506 is fixedly provided with a guide block 507, the guide block 507 is in a parallelogram shape, the rack plate 501 can be driven to move up and down through the matching of the guide block 507 and the connecting groove 506 and is meshed with the transmission gear 502 intermittently, and the roller 2 is driven to rotate intermittently through the transmission gear 502, so that the soaking time of spinning in dyeing liquid is prolonged. The end of the slide bar 505 extends into the connection groove 506 and is located between the side wall of the connection groove 506 and the guide block 507.

As a further technical scheme, the outer surface of the dyeing box 1 is fixedly provided with a supporting frame 7, the inside of the supporting frame 7 is slidably provided with a supporting rod 701, a connecting rod 504 penetrates through the supporting rod 701 and is slidably connected with the inner surface of the supporting rod 701, a supporting spring 702 is fixedly arranged between the supporting rod 701 and the inner wall of the supporting frame 7, and the elasticity coefficient of the supporting spring 702 can be set according to requirements. In the initial state, the sliding rod 505 is positioned on the horizontal center line of the guide block 507 such that the connecting rod 504 moves to the lowest side of the connecting groove 506 along the right side surface of the guide block 507 when moving to the side close to the driving motor 601, and the supporting spring 702 is compressed; when moving to one side of the connecting groove 506 closest to the driving motor 601, under the reset action of the supporting spring 702, the supporting rod 701 drives the connecting rod 504 to move upwards, so that the sliding rod 505 is positioned on the horizontal central line of the guide block 507, and when moving to one side far away from the driving motor 601, the connecting rod 504 can be driven to move upwards, so as to drive the rack plate 501 to be meshed with the transmission gear 502, and when the rack plate 501 continues to move in the horizontal direction, the transmission gear 502 is driven to rotate, so that the roller 2 is driven to rotate by the placement structure 4, and the roller 2 drives yarns to intermittently rotate in the dyeing liquid.

Regarding the design scheme of the driving mechanism 6, the driving mechanism 6 comprises a driving motor 601 fixedly arranged on the outer surface of the dyeing tank 1 and on the same side of the rack plate 501, and the driving motor 601 is electrically connected with an external power supply. An output shaft of the driving motor 601 is fixedly provided with a driving rod 602 through a coupler, the end part of the driving rod 602 is rotatably provided with a push rod 603, and the end part of the push rod 603 is rotatably connected with the rack plate 501. By starting the driving motor 601 to drive the driving rod 602 to rotate, when the sliding rod 505 is located at the leftmost end of the connecting slot 506, the driving rod 602 can drive the rack plate 501 to move rightwards through the push rod 603, and when the rack plate 501 moves to the rightmost end of the connecting slot 506, the driving rod 602 can drive the rack plate 506 to start to move leftwards through the push rod 603.

Wherein, regarding the technical scheme that drive link 3 moved up, rotate on the lateral wall of the adjacent rack board 501 of dyeing case 1 and be provided with lift screw 8, the surface screw thread of lift screw 8 is provided with lifter block 801, and the fixed sliding block that is provided with in one side of lifter block 801, the sliding tray has been seted up to the surface of dyeing case 1, sliding block and sliding tray sliding connection, effectively prevent lifter block 801 along with lifter screw 8 rotation, improved the stability of lifter block 801 removal in-process. The top rotation of elevating block 801 is provided with lifter 802, and wherein, the tip and the link 3 rotation of lifter 802 are connected, and the outside of dyeing case 1 is provided with drive assembly 9, starts drive assembly 9 through driving motor 601 and drives lift screw 8 rotation. When the lifting screw 8 rotates, the lifting block 801 in threaded connection with the lifting screw is driven to move to one side far away from the driving motor 601, the lifting block 801 pushes the connecting frame 3 to move upwards through the lifting rod 802, and the connecting frame 3 drives the roller 2 to move upwards through the placing structure 4, so that the dyed yarn is dried, dyeing liquid on the yarn can drop into the dyeing box 1, and dyeing liquid waste is prevented.

With respect to the design scheme of the transmission assembly 9, the transmission assembly 9 comprises a first transmission fluted disc 901 which is slidably arranged on the outer surface of the lifting screw rod 8, a reset spring 902 is fixedly arranged on the outer surface of the lifting screw rod 8, and the elastic coefficient of the reset spring 902 can be set according to requirements. Wherein, reset spring 902's one end and first transmission fluted disc 901 fixed connection, the surface rotation of dyeing case 1 is provided with transmission shaft 903, transmission shaft 903's external surface fixation is provided with second transmission fluted disc 904, second transmission fluted disc 904 meshes with first transmission fluted disc 901, pass through second transmission structure 10 transmission between transmission shaft 903 and the output shaft of driving motor 601 and be connected, second transmission structure 10 transmission is connected by belt pulley and belt and is constituteed, the fixed surface that sets up at driving motor 601 output shaft and two transmission shafts 903 of belt pulley, belt transmission sets up between the surface of three drive wheels.

When the connecting frame 3 is in a locking state, the lifting screw 8 cannot rotate, at the moment, the driving motor 601 is in an operating state, the driving shaft 903 is driven to rotate by the second driving structure 10, the driving shaft 903 drives the second driving fluted disc 904 to rotate, and as the lifting screw 8 is limited, the second driving fluted disc 904 can push the first driving fluted disc 901 to slide along the outer surface of the first driving fluted disc 901 when rotating and is pushed by the reset spring 902 to drive the first driving fluted disc 901 to reset; when the locking state of the connecting frame 3 is released, the second transmission fluted disc 904 and the first transmission fluted disc 901 are in a meshed state under the action of the reset spring 902, at this time, the second transmission fluted disc 904 can drive the lifting screw 8 to rotate through the first transmission fluted disc 901, and the lifting screw 8 pushes the connecting frame 3 to move upwards through the lifting block 801 and the lifting rod 802.

To illustrate, when the sliding bar 505 is positioned on top of the guide block 507, the supporting spring 702 is in a stretched state; when the slide bar 505 is located at the bottom of the guide block 507, the supporting spring 702 is in a compressed state.

And all that is not described in detail in this specification is well known to those skilled in the art.

In operation, the locking block 301 is inserted into the dyeing tank 1 to lock the connecting frame 3, then the wound spun yarn passes through the roller 2 and is hung on the outer surface thereof, then one end of the roller 2 is inserted into the placing cylinder 403, the other end is placed on the placing frame 401, the driving motor 601 is started again to drive the driving rod 602 to rotate, the driving rod 602 drives the rack plate 501 to move rightwards through the push rod 603, when the rack plate 501 moves from leftmost end to rightmost end, that is, the sliding rod 505 moves to the top along the left side of the guide block 507 and moves along the connecting groove 506, at this time, the rack plate 501 is meshed with the transmission gear 502 and drives the rack plate 501 to rotate, when the sliding rod 505 moves to the rightmost end of the connecting groove 506, the driving rod 602 drives the rack plate 501 to start to move leftwards through the push rod 603, so that the sliding rod 505 moves to the bottommost side of the connecting groove 506 along the right side inclined surface of the guide block 507 and continues to move leftwards under the action of the supporting spring 702, at this time, the rack plate 501 and the transmission gear 502 are separated, and the rack plate 501 and the transmission gear 502 are reciprocated in such a way that the rack plate 501 drives the transmission gear 502 to intermittently rotate, the transmission gear 502 drives the placing cylinder 403 to rotate through the first transmission structure 503, the placing cylinder 403 drives the limiting rod 405 to rotate, the limiting rod 405 moves to one side close to the dyeing box 1 while rotating due to the fact that the limiting rod 405 is partially connected with the mounting plate 404 in a threaded manner, the limiting plate 406 is driven to move, when the limiting plate 406 extrudes the roller 2, the other end of the roller 2 is tightly abutted with the placing frame 401, the position of the roller 2 is extruded and fixed, meanwhile, the threaded part on the limiting rod 405 is separated from the mounting plate 404, the placing cylinder 403 continues to rotate at this time, the fixed roller 2 is driven to rotate through the limiting rod 405, and the yarn hung on the outer surface of the roller 2 is driven to rotate, so that the yarn intermittently changes the contact part with the dyeing liquid;

after all the dyeing is finished, the locking state of the connecting frame 3 is released, at the moment, the transmission shaft 903 is driven to rotate through the second transmission structure 10, the transmission shaft 903 drives the second transmission fluted disc 904 to rotate, the second transmission fluted disc 904 drives the lifting screw 8 to rotate through the first transmission fluted disc 901, the lifting screw 8 pushes the connecting frame 3 to move upwards through the lifting block 801 and the lifting rod 802, so that the roller 2 moves out of the dyeing liquid, yarns on the roller 2 are aired, the dyeing liquid on the yarns drops into the dyeing box 1, and redundant dyeing on the yarns is also collected.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. Yarn dyeing apparatus is used in production of fibre protective glove, including being used for splendid attire dye liquor's dyeing case (1), be provided with on dyeing case (1) and be used for hanging roller (2) of lapping yarn, its characterized in that: the outer surface of the dyeing box (1) is provided with a locked connecting frame (3) in a sliding manner, the connecting frame (3) is provided with a placing structure (4) for placing the roller (2), the outer side of the dyeing box (1) is provided with a transmission connecting structure (5), wherein the transmission connecting structure (5) is driven by a driving mechanism (6) to drive the roller (2) to intermittently rotate after being clamped, and meanwhile, the driving mechanism (6) can also drive the connecting frame (3) after unlocking to drive the roller (2) to move out of the dyeing box (1);

the placing structure (4) comprises a plurality of placing frames (401) fixedly arranged at the tops of the connecting frames (3), connecting plates (402) are fixedly arranged at the tops of one sides of the connecting frames (3) opposite to the placing frames (401), placing cylinders (403) are rotatably arranged in the connecting plates (402), and limiting structures for fixing the rollers (2) in an extrusion mode are arranged on the placing cylinders (403);

the limiting structure comprises a mounting plate (404) fixedly arranged on a placing rack (401), wherein a limiting rod (405) is arranged on the internal thread of the mounting plate (404), one end of the limiting rod (405) penetrates through the placing cylinder (403) and is fixedly provided with a limiting disc (406), and a limiting spring (407) is fixedly arranged on the outer surface of the limiting rod (405), wherein one end of the limiting spring (407) is fixed with the mounting plate (404);

the transmission connecting structure (5) comprises a rack plate (501), one side of the connecting frame (3) is rotatably provided with a transmission gear (502), the transmission gear (502) is in transmission connection with the placing cylinder (403) through a first transmission structure (503), a connecting rod (504) is fixedly arranged at the bottom of the rack plate (501), a sliding rod (505) in sliding connection with the dyeing box (1) is fixedly arranged at the end part of the connecting rod (504), a connecting groove (506) is formed in the side wall of the dyeing box (1), a guide block (507) is fixedly arranged in the connecting groove (506), and the end part of the sliding rod (505) extends into the connecting groove (506) and is positioned between the side wall of the connecting groove (506) and the guide block (507);

the automatic dyeing machine is characterized in that lifting screws (8) are rotatably arranged on the side walls of adjacent rack plates (501) of the dyeing box (1), lifting blocks (801) are arranged on the outer surface threads of the lifting screws (8), lifting rods (802) are rotatably arranged at the tops of the lifting blocks (801), the ends of the lifting rods (802) are rotatably connected with the connecting frame (3), transmission assemblies (9) are arranged on the outer sides of the dyeing box (1), and the transmission assemblies (9) are started to drive the lifting screws (8) to rotate through driving motors (601).

2. The yarn dyeing apparatus for producing fiber protective gloves according to claim 1, wherein: the inside of link (3) runs through the slip and is provided with locking piece (301), locking piece (301) and the lateral wall joint of dyeing case (1), carry out the locking to the position of link (3).

3. The yarn dyeing apparatus for producing fiber protective gloves according to claim 1, wherein: the outer surface fixing of dyeing case (1) is provided with braced frame (7), the inside slip of braced frame (7) is provided with bracing piece (701), connecting rod (504) run through bracing piece (701) and with its internal surface sliding connection, fixedly be provided with supporting spring (702) between the inner wall of bracing piece (701) and braced frame (7).

4. The yarn dyeing apparatus for producing fiber protective gloves according to claim 1, wherein: the driving mechanism (6) comprises a driving motor (601) fixedly arranged on the outer surface of the dyeing box (1) and on the same side of the rack plate (501), a driving rod (602) is fixedly arranged on an output shaft of the driving motor (601) through a coupler, a push rod (603) is rotatably arranged at the end part of the driving rod (602), and the end part of the push rod (603) is rotatably connected with the rack plate (501).

5. The yarn dyeing apparatus for producing fiber protective gloves according to claim 1, wherein: the transmission assembly (9) comprises a first transmission fluted disc (901) which is arranged on the outer surface of a lifting screw (8) in a sliding mode, a reset spring (902) is fixedly arranged on the outer surface of the lifting screw (8), one end of the reset spring (902) is fixedly connected with the first transmission fluted disc (901), a transmission shaft (903) is rotatably arranged on the outer surface of the dyeing box (1), a second transmission fluted disc (904) is fixedly arranged on the outer surface of the transmission shaft (903), the second transmission fluted disc (904) is meshed with the first transmission fluted disc (901), and the transmission shaft (903) is in transmission connection with an output shaft of a driving motor (601) through a second transmission structure (10).