CN113308819A - Device for shelling dyes before interweaving real silk and purl silk by torsion method - Google Patents

Abstract

The invention relates to the field of metallic yarns, in particular to a device for shelling dyes before interweaving real silk metallic yarns by a torsion method. The technical problem is as follows: provides a device for shelling real silk purl before interweaving by a torsion method. A device for shelling real silk and purl silk before interweaving by a torsion method comprises a twisting mechanism, a shelling mechanism, a straightening mechanism and the like; the torsion mechanism is connected with the hulling mechanism. The invention realizes that the gold and silver silk dye shell can be completely separated from the gold and silver silk by a twisting method on the premise of not damaging the quality of the gold and silver silk while the surface dye of the real silk gold and silver silk is shelled, ensures that the wrinkled part of the gold and silver silk is straightened for the second time, and effectively prevents the waste pulp and the dye shelled object from polluting the environment.

Description

Device for shelling dyes before interweaving real silk and purl silk by torsion method

Technical Field

The invention relates to the field of metallic yarns, in particular to a device for shelling dyes before interweaving real silk metallic yarns by a torsion method.

Background

The metallic yarn is the extremely fine yarn cut by a physical method from the PET polyester film with high degree of color! The metallic yarns are fine yarns formed by twisting metallic yarns and polyester or rayon yarns. The metallic yarn is widely applied to the industries of artware, fashion, embroidery, gift packaging and the like and the processing of products such as knitting wool, yarn, knitted fabric, warp knitting fabric, woven fabric, clothing accessories, decorative cloth, sofa cloth and the like, and is an ideal lining decoration raw material. The woven cloth and the clothes have elegant, noble and gorgeous feeling.

The metallic yarn is processed by vacuum aluminizing or vacuum silvering on a polyester film by a physical method, so that the metallic yarn is unstable in chemical property and cannot be used like common textile fiber, an aluminum film in the metallic yarn is not alkali-resistant and acid-resistant, and a metallic coating is peeled off due to blackening, stretching or severe friction of the silver film when contacting with sulfide, so that the dye on the surface of the metallic yarn is completely peeled off by adding special penetrating slurry to the surface of the metallic yarn, and then the subsequent process is carried out on the metallic yarn, but when the slurry is peeled off on the surface of the metallic yarn, the dye shell on the surface of the metallic yarn cannot be completely separated from the metallic yarn, the later secondary processing is needed, the production cycle is greatly prolonged, and when the secondary processing is carried out, because the metallic yarn is thin, the wrinkling of the metallic yarn is caused during the processing, the condition that twines together leads to the digital printing in later stage not clear enough, seriously reduces the metallic yarn quality, also can reduce the fabric quality for the fabric, influences producer's reputation.

Therefore, the device is needed to solve the problems that the surface dye of the real silk purl can be shelled, the purl dye shell can be completely separated from the purl on the premise of not damaging the quality of the purl, and the purl cannot wrinkle.

Disclosure of Invention

When carrying out the decladding in order to overcome the purl surface, the dyestuff shell on purl surface can not separate with the purl completely, needs later stage secondary operation, production cycle has been prolonged greatly, and when carrying out secondary operation, because the purl itself is thin, when processing, lead to the purl to take place to corrugate, the condition of winding together leads to the digital printing in later stage clear inadequately, seriously reduces the purl quality, be used for the fabric also can reduce the fabric quality, influence the shortcoming of producer reputation, the technical problem: provides a device for shelling real silk purl before interweaving by a torsion method.

A device for shelling dyes before real silk and purl silk interweaving by a torsion method comprises a torsion mechanism, a shelling mechanism, a straightening mechanism, a first slurry barrel, a second slurry barrel, a first electric winder, a second electric winder, simulated purl silk, a waste collecting frame, a fixing frame and a control screen; the torsion mechanism is connected with the hulling mechanism; the torsion mechanism is connected with the first slurry barrel; the torsion mechanism is connected with the second slurry barrel; the torsion mechanism is connected with the simulation filigree; the torsion mechanism is connected with the fixed frame; the shell removing mechanism is connected with the fixed frame; two ends of the simulated metallic yarn are respectively connected with the first electric winder and the second electric winder; the fixed frame is connected with the straightening mechanism; the fixing frame is connected with the first electric winder; the fixed frame is connected with the second electric winder; the fixed frame is connected with the waste collecting frame; the fixed frame is connected with the control screen.

Optionally, the torsion mechanism comprises a support frame, a motor, a first transmission shaft, a first pinion, a first sliding sleeve, a second pinion, a missing gear, a first connecting plate, a first electric push rod, a third pinion, a first hollow rotating shaft, a second connecting plate, a first electric slide block, a first fixer, a second electric push rod, a third fixer, a fourth fixer and a slurry conveying pipe; the supporting frame is fixedly connected with the fixing frame; the support frame is fixedly connected with the second electric push rod; the first slurry barrel is connected; the supporting frame is connected with the hulling mechanism; the support frame is fixedly connected with a plurality of groups of slurry conveying pipes simultaneously; a motor is arranged on the side surface of the support frame; the motor is fixedly connected with the fixed frame; the motor is fixedly connected with the first transmission shaft through an output shaft; the first transmission shaft is rotationally connected with the fixed frame; the first transmission shaft is fixedly connected with the first flat gear and the second flat gear at the same time; the first transmission shaft is connected with the first sliding sleeve; the first sliding sleeve is fixedly connected with the missing gear; the first sliding sleeve is rotatably connected with the first connecting plate; the first connecting plate is fixedly connected with the first electric push rod; the first electric push rod is fixedly connected with the fixed frame; a third horizontal gear is arranged on the side surface of the first sliding sleeve; the third horizontal gear is fixedly connected with the first hollow rotating shaft; the first hollow rotating shaft is rotatably connected with the fixed frame; the first hollow rotating shaft is fixedly connected with the second connecting plate; the second connecting plate is in sliding connection with the first electric sliding block; the second connecting plate is fixedly connected with the second fixer; the first electric sliding block is fixedly connected with the first fixer; the second fixer is contacted with the simulation metallic yarn; the second electric push rod is fixedly connected with the third fixer; a fourth fixer is arranged right below the third fixer; the fourth fixer is contacted with the simulation metallic yarn; the fourth fixer is fixedly connected with the support frame; a group of the supporting frame to the slurry conveying pipe and a group of the simulated metallic yarns are symmetrically arranged on two sides of the waste collecting frame; the other group of supporting frames is fixedly connected with the second slurry barrel; the other group of the second fixer and the fourth fixer are contacted with the other group of the simulation filigrees.

Optionally, the shelling mechanism includes a fourth flat gear, a second sliding sleeve, a third connecting plate, a third electric push rod, a second transmission shaft, a first transmission wheel, a second transmission wheel, a third transmission shaft, a first current limiter, a temporary storage, a second current limiter, a first connecting column, a fixed column, a fifth flat gear, a third sliding sleeve, a fourth connecting plate, a fourth electric push rod, a fourth transmission shaft, a third transmission wheel, a fourth transmission wheel, a fifth transmission shaft, a sixth flat gear, a seventh flat gear, an eighth flat gear, a ninth flat gear, a second hollow rotating shaft, a third hollow rotating shaft, a first cylindrical sheller, a second cylindrical sheller and a sixth transmission shaft; the fourth flat gear is fixedly connected with the second sliding sleeve; the second sliding sleeve is rotatably connected with the third connecting plate; the second sliding sleeve is connected with the second transmission shaft; the third connecting plate is fixedly connected with a third electric push rod; the third electric push rod is fixedly connected with the fixed frame; the second transmission shaft is rotatably connected with the fixed frame; the second transmission shaft is fixedly connected with the first transmission wheel; the outer ring surface of the first driving wheel is in transmission connection with the second driving wheel through a belt; the second driving wheel is fixedly connected with the third transmission shaft; the third transmission shaft is rotatably connected with the fixed frame; the third transmission shaft is fixedly connected with the first current limiter; the first current limiter is fixedly connected with the temporary storage; the temporary storage is fixedly connected with the second current limiter; the second current limiter is fixedly connected with the first connecting column; the first connecting column is rotatably connected with the fixed column; the fixed column is fixedly connected with the support frame; a fifth flat gear is arranged below the fixed column; the fifth flat gear is fixedly connected with the third sliding sleeve; the third sliding sleeve is rotatably connected with the fourth connecting plate; the third sliding sleeve is connected with the fourth transmission shaft; the fourth connecting plate is fixedly connected with a fourth electric push rod; the fourth electric push rod is fixedly connected with the fixed frame; the fourth transmission shaft is rotatably connected with the fixed frame; the fourth transmission shaft is fixedly connected with the third transmission wheel; the outer ring surface of the third driving wheel is in transmission connection with the fourth driving wheel through a belt; the fourth driving wheel is fixedly connected with the fifth transmission shaft; the fifth transmission shaft is rotatably connected with the fixed frame; the fifth transmission shaft is fixedly connected with the sixth flat gear; the sixth flat gear is simultaneously meshed with the seventh flat gear and the ninth flat gear; the seventh flat gear is fixedly connected with the sixth transmission shaft; the sixth transmission shaft is rotatably connected with the fixed frame; the seventh flat gear is meshed with the eighth flat gear; the eighth flat gear is fixedly connected with the second hollow rotating shaft; the ninth flat gear is fixedly connected with the third hollow rotating shaft; the second hollow rotating shaft is rotatably connected with the fixed frame; the second hollow rotating shaft is fixedly connected with the first cylindrical huller through a connecting block; the third hollow rotating shaft is fixedly connected with the second cylindrical huller through a connecting block; a group of fourth flat gear to a group of sixth transmission shaft are symmetrically arranged on two sides of the waste collecting frame.

Optionally, the straightening mechanism comprises a second electric slider, a first U-shaped connecting plate, a second connecting column, a first round roller, a third electric slider, a second U-shaped connecting plate, a third connecting column, a second round roller, a fifth connecting plate and a fourth electric slider; the second electric sliding block is fixedly connected with the first U-shaped connecting plate; the second electric sliding block is in sliding connection with the fifth connecting plate; the first U-shaped connecting plate is fixedly connected with the second connecting column; the second connecting column is rotationally connected with the first round roller; the fifth connecting plate is in sliding connection with the third electric sliding block; the third electric sliding block is fixedly connected with the second U-shaped connecting plate; the second U-shaped connecting plate is fixedly connected with the third connecting column; the third connecting column is rotationally connected with the second round roller; the lower part of the fifth connecting plate is fixedly connected with a group of fourth electric sliding blocks respectively; the two groups of fourth electric sliding blocks are in sliding connection with the fixed frame; and a group of second electric sliding blocks to a group of second round rollers are symmetrically arranged on two sides of the fifth connecting plate.

Optionally, the first, second, third and fourth anchors are all provided with an elliptical shape.

Optionally, both sets of registers are configured in a semi-circular tube shape.

Optionally, the first and second flow restrictors are both provided with hollows.

Optionally, the first cylindrical huller and the second cylindrical huller outer surface are both provided with semi-spherical protruding blocks, and the positions of the semi-spherical protruding blocks are staggered with each other.

The invention has the beneficial effects that: 1. in order to overcome the defects that when slurry is used for shelling the surfaces of the metallic yarns, dye shells on the surfaces of the metallic yarns cannot be completely separated from the metallic yarns, secondary processing is needed in the later period, the production period is greatly prolonged, and in the secondary processing, the metallic yarns are wrinkled and wound together in the processing process due to the fact that the metallic yarns are thin, so that digital printing in the later period is not clear enough, the quality of the metallic yarns is seriously reduced, the quality of the textile can be reduced when the metallic yarns are used for the textile, and the reputation of manufacturers is influenced;

2. the invention designs a torsion mechanism, a shelling mechanism and a straightening mechanism: before the operation, the device is fixed by a fixing frame, then a power supply is connected externally, the device is started by a control screen, at the moment, two groups of simulated metallic yarns are connected to a first electric winder and a second electric winder through a threading machine, the states of the two groups of simulated metallic yarns are in certain relaxation states, then pumps in a first slurry barrel and a second slurry barrel start to operate, the pumps in the first slurry barrel and the second slurry barrel firstly add certain slurry to a torsion mechanism through the torsion mechanism, then the torsion mechanism respectively clamps two ends of the two groups of simulated metallic yarns slightly and clamps the two ends of the two groups of simulated metallic yarns, the slurry soaks partial positions of the simulated metallic yarns, the pigment on the soaked parts of the simulated metallic yarns is automatically shelled, and after the soaking for certain time, the torsion mechanism twists the simulated metallic yarns of the clamped parts to form a shape similar to a twist shape, in the twisting process, part of unshelled matter of the dye is automatically separated from the simulation filigree under the action of twisting force, then the twisting mechanism enables the simulation filigree to be restored, then the twisting mechanism and the shelling mechanism work together, the dye shell remaining on the surface of the simulation filigree is taken out through the shelling mechanism to be fully separated from the simulation filigree, after the operation is repeated for a plurality of times, the shelling mechanism pours the removed dye shell and waste serous fluid into a waste material collecting frame, then the first electric bobbin winder and the second electric bobbin work together to enable the simulation filigree to move towards a position close to the second electric bobbin in a dye shelling part, one end of the simulation filigree in the dye shelling part is contacted with the straightening mechanism, then the shelling mechanism clamps one end close to the second electric bobbin again, then the straightening mechanism starts to work, and the part of the simulation filigree in the twisting process is straightened, the simulation metallic yarns are always in a linear state, when the simulation metallic yarns are completely straightened during the shelling of the dyes, the first electric bobbin winder and the second electric bobbin winder start to work again, the processed simulation metallic yarns are wound on the second electric bobbin winder, and then other mechanisms repeat the shelling of the dyes;

3. the invention realizes that the gold and silver silk dye shell can be completely separated from the gold and silver silk by a twisting method on the premise of not damaging the quality of the gold and silver silk while the surface dye of the real silk gold and silver silk is shelled, ensures that the wrinkled part of the gold and silver silk is straightened for the second time, and effectively prevents the waste pulp and the dye shelled object from polluting the environment.

Drawings

FIG. 1 is a schematic perspective view of a first embodiment of the present invention;

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

FIG. 3 is a schematic perspective view of a first embodiment of the torsion mechanism of the present invention;

FIG. 4 is a schematic diagram of a second perspective structure of the torsion mechanism of the present invention;

FIG. 5 is a schematic view of a first partially assembled body of the torsion mechanism of the present invention;

FIG. 6 is a schematic view of a second partial body configuration of the twisting mechanism of the present invention;

FIG. 7 is a schematic perspective view of the shelling mechanism of the present invention;

FIG. 8 is a schematic view of a first partially separated body configuration of the shelling mechanism of the present invention;

FIG. 9 is an enlarged perspective view of the shelling mechanism of the present invention in area A;

FIG. 10 is a schematic view of a second partial body configuration of the shelling mechanism of the present invention;

fig. 11 is a schematic perspective view of the straightening mechanism of the present invention.

Reference numbers in the drawings: 1: torsion mechanism, 2: hulling mechanism, 3: straightening mechanism, 4: first slurry barrel, 5: second slurry barrel, 6: first electric winder, 7: second electric winder, 8: simulation filigree, 9: waste collection frame, 10: mount, 11: control panel, 101: a support frame, 102: motor, 103: first transmission shaft, 104: first spur gear, 105: first runner, 106: second spur gear, 107: missing gear, 108: first connection plate, 109: first electric putter, 1010: third spur gear, 1011: first hollow shaft, 1012: second connecting plate, 1013: first electric slider, 1014: first holder, 1015: second holder, 1016: second electric putter, 1017: third holder, 1018: fourth anchor, 1019: slurry conveyance pipe, 201: fourth flat gear, 202: second sliding sleeve, 203: third connecting plate, 204: third electric putter, 205: second drive shaft, 206: first drive pulley, 207: second drive wheel, 208: third drive shaft, 209: first flow restrictor, 2010: temporary memory, 2011: second flow restrictor, 2012: first connecting post, 2013: fixed column, 2014: fifth spur gear, 2015: third slip sleeve, 2016: fourth connecting plate, 2017: fourth electric putter, 2018: fourth transmission shaft, 2019: third drive wheel, 2020: fourth transmission wheel, 2021: fifth propeller shaft, 2022: sixth flat gear, 2023: seventh spur gear, 2024: eighth spur gear, 2025: ninth spur gear, 2026: second hollow shaft, 2027: third hollow shaft, 2028: first cylindrical sheller, 2029: second cylindrical desheller, 2030: sixth propeller shaft, 301: second electric slider, 302: first U-shaped connecting plate, 303: second connecting column, 304: first round roller, 305: third electric slider, 306: second U-shaped connecting plate, 307: third connecting column, 308: second round roller, 309: fifth connecting plate, 3010: and a fourth electric slide block.

Detailed Description

Embodiments of the present invention will be described below with reference to the drawings.

Example 1

A device for shelling dyes before real silk and purl silk interweaving by a torsion method is shown in figures 1-11 and comprises a torsion mechanism 1, a shelling mechanism 2, a straightening mechanism 3, a first slurry barrel 4, a second slurry barrel 5, a first electric bobbin winder 6, a second electric bobbin winder 7, a simulation purl 8, a waste collection frame 9, a fixing frame 10 and a control screen 11; the torsion mechanism 1 is connected with the hulling mechanism 2; the torsion mechanism 1 is connected with the first slurry barrel 4; the torsion mechanism 1 is connected with the second slurry barrel 5; the torsion mechanism 1 is connected with the simulation metallic yarn 8; the torsion mechanism 1 is connected with the fixed frame 10; the shell removing mechanism 2 is connected with the fixed frame 10; two ends of the simulated metallic yarn 8 are respectively connected with the first electric winder 6 and the second electric winder 7; the fixed frame 10 is connected with the straightening mechanism 3; the fixed frame 10 is connected with the first electric winder 6; the fixed frame 10 is connected with the second electric winder 7; the fixed frame 10 is connected with the waste collecting frame 9; the fixed frame 10 is connected with a control screen 11.

The working principle is as follows: before the operation, the device is fixed by a fixing frame 10, then a power supply is connected externally, the device is started by a control screen 11, at the moment, two groups of simulated metallic silks 8 are connected to a first electric bobbin winder 6 and a second electric bobbin winder 7 by a threading machine, the states of the two groups of simulated metallic silks 8 are in certain loose states, then pumps in a first slurry barrel 4 and a second slurry barrel 5 start to operate, the pumps in the first slurry barrel 4 and the second slurry barrel 5 firstly add certain slurry to a torsion mechanism 1 by the torsion mechanism 1, then the torsion mechanism 1 respectively clamps two ends of the two groups of simulated metallic silks 8 slightly, the slurry soaks partial positions of the simulated metallic silks 8, pigments on the soaked parts of the simulated metallic silks 8 are automatically shelled, and after soaking for a certain time, the torsion mechanism 1 twists the simulated metallic silks 8 of the clamped parts, the method is characterized in that the imitated filigree is formed into a shape similar to a twist, in the twisting process, part of unshelled matter of the dye is automatically separated from the imitated filigree 8 under the action of twisting force, then the imitated filigree 8 is restored by the twisting mechanism 1, then the twisting mechanism 1 and the unshelled mechanism 2 work together, the dye shell remained on the surface of the imitated filigree 8 is taken out through the unshelled mechanism 2 to be fully separated from the imitated filigree 8, after the operations are repeated for several times, the unshelled mechanism 2 pours the removed dye shell and waste serous fluid into the waste collecting frame 9, then the first electric bobbin winder 6 and the second electric bobbin winder 7 work together to enable the imitated filigree 8 to carry out dye unshelled part movement to be close to the second electric bobbin winder 7, one end of the imitated filigree 8 carrying out dye unshelled part is contacted with the straightening mechanism 3, then the unshelled mechanism 2 clamps one end close to the second electric bobbin 7 again, then the straightening mechanism 3 starts to work, the part of the simulated metallic yarn 8 which is wrinkled in the twisting process is straightened, so that the simulated metallic yarn 8 is always in a linear state, when the part of the simulated metallic yarn 8 which is subjected to the dye shelling is completely straightened, the first electric bobbin winder 6 and the second electric bobbin winder 7 start to work again, the processed simulated metallic yarn 8 is wound on the second electric bobbin winder 7, and then other mechanisms repeat the work of the dye shelling; the invention realizes that the gold and silver silk dye shell can be completely separated from the gold and silver silk by a twisting method on the premise of not damaging the quality of the gold and silver silk while the surface dye of the real silk gold and silver silk is shelled, ensures that the wrinkled part of the gold and silver silk is straightened for the second time, and effectively prevents the waste pulp and the dye shelled object from polluting the environment.

The torsion mechanism 1 comprises a support frame 101, a motor 102, a first transmission shaft 103, a first pinion 104, a first sliding sleeve 105, a second pinion 106, a missing gear 107, a first connecting plate 108, a first electric push rod 109, a third pinion 1010, a first hollow rotating shaft 1011, a second connecting plate 1012, a first electric slide 1013, a first fixer 1014, a second fixer 1015, a second electric push rod 1016, a third fixer 1017, a fourth fixer 1018 and a slurry conveying pipe 1019; the supporting frame 101 is fixedly connected with the fixed frame 10; the support frame 101 is fixedly connected with the second electric push rod 1016; the first slurry barrel 4 is connected; the supporting frame 101 is connected with the hulling mechanism 2; the support frame 101 is fixedly connected with a plurality of groups of slurry conveying pipes 1019 simultaneously; a motor 102 is arranged on the side surface of the support frame 101; the motor 102 is fixedly connected with the fixed frame 10; the motor 102 is fixedly connected with the first transmission shaft 103 through an output shaft; the first transmission shaft 103 is rotatably connected with the fixed frame 10; the first transmission shaft 103 is fixedly connected with the first flat gear 104 and the second flat gear 106; the first transmission shaft 103 is connected with the first sliding sleeve 105; the first sliding sleeve 105 is fixedly connected with the missing gear 107; the first sliding sleeve 105 is rotatably connected with the first connecting plate 108; the first connecting plate 108 is fixedly connected with the first electric push rod 109; the first electric push rod 109 is fixedly connected with the fixed frame 10; a third pinion 1010 is arranged on the side surface of the first sliding sleeve 105; the third flat gear 1010 is fixedly connected with the first hollow rotating shaft 1011; the first hollow rotating shaft 1011 is rotatably connected with the fixed frame 10; the first hollow rotating shaft 1011 is fixedly connected with the second connecting plate 1012; the second connecting plate 1012 is slidably connected to the first motor slider 1013; the second connecting plate 1012 is fixedly connected with the second fixer 1015; the first electric slider 1013 is fixedly connected to the first holder 1014; the second fixer 1015 contacts with the simulation filigree 8; the second electric push rod 1016 is fixedly connected with the third fixer 1017; a fourth holder 1018 is provided right below the third holder 1017; the fourth holder 1018 is in contact with the simulated metallic filament 8; the fourth fixer 1018 is fixedly connected with the supporting frame 101; a group of supporting frames 101 to a slurry conveying pipe 1019 and a group of simulated metallic yarns 8 are symmetrically arranged on two sides of the waste collecting frame 9; the other group of supporting frames 101 are fixedly connected with the second slurry barrel 5; another set of second 1015 and fourth 1018 anchors are in contact with another set of simulated filigrees 8.

Before the work is started, the simulation metallic yarns 8 are connected to the first electric bobbin winder 6 and the second electric bobbin winder 7 through threading machines, the simulation metallic yarns 8 are respectively contacted with the second fixer 1015 and the fourth fixer 1018, then the pumps in the first slurry barrel 4 and the second slurry barrel 5 start to work, the pumps in the first slurry barrel 4 and the second slurry barrel 5 add slurry into the two groups of temporary storages 2010 through the multiple groups of slurry conveying pipes 1019, so that the simulation metallic yarns 8 on the two groups of temporary storages 2010 are partially and completely soaked in the slurry, after the soaking for a certain time, the simulation metallic yarns 8 are automatically shelled by the dye at the soaked parts, then the first electric sliding block 1013 drives the first fixer 1013 to slide downwards on the second connecting plate 1012 until the first fixer 1014 and the second fixer 1015 completely clamp one end of the simulation metallic yarns 8 close to the second electric bobbin winder 7, meanwhile, the second electric push rod 1016 drives the third fixer 1017 to move downwards until the third fixer 1017 and the fourth fixer 1018 slightly clamp one end of the simulated filigree 8 close to the first electric winder 6, then the motor 102 starts to work, the motor 102 drives the first transmission shaft 103 to rotate through the output shaft, the first electric push rod 109 drives the first connecting plate 108 to move close to the third flat gear 1010, namely, the first sliding sleeve 105 and the missing gear 107 are driven to move close to the third flat gear 1010 until the missing gear 107 is meshed with the third flat gear 1010, then the first transmission shaft 103 lacks the gear 107 through the length of the first sliding sleeve 105, the missing gear 107 passes through the first hollow rotating shaft 1012 through the length of the third flat gear 1010, the first hollow rotating shaft 1011 drives the second connecting plate, the first electric slider 1013, the first fixer 1014 and the second fixer 1015 to rotate a certain angle, namely, the simulated filigree 8 is driven to rotate a certain angle, because one end of the simulated metallic yarn 8 is completely clamped by the first fixer 1014 and the second fixer 1015, when one end of the simulated metallic yarn 8 clamped by the first fixer 1014 and the second fixer 1015 rotates for a certain angle, the clamped part of the simulated metallic yarn 8 is twisted into a shape similar to a twist, so that the unshelled dye part is separated from the simulated metallic yarn 8 under the action of torsional force, then the motor 102 is reversely rotated to restore the simulated metallic yarn 8 to a normal state, then the unshelling mechanism 2 is driven to work by the first flat gear 104 and the second flat gear 106, the unshelled dye on the simulated metallic yarn 8 is subjected to secondary treatment, after the treatment is finished, the twisting mechanism 1 repeats the twisting work again, after the twisting is finished, the simulated metallic yarn 8 is restored to a normal state again, then the unshelling mechanism 2 is removed to treat the unshelled dye again, and the unshelled dye on the surface of the simulated metallic yarn 8 is ensured to be completely cleaned, meanwhile, the other group of the support frames 101 to the slurry conveying pipe 1019 also repeats the operation on the other group of the simulation filigrees 8; the mechanism completes the shelling work of the dye of the clamped part of the simulated metallic yarn 8 and assists the secondary shelling work of the shelling mechanism 2.

The shelling mechanism 2 comprises a fourth flat gear 201, a second sliding sleeve 202, a third connecting plate 203, a third electric push rod 204, a second transmission shaft 205, a first transmission wheel 206, a second transmission wheel 207, a third transmission shaft 208, a first flow restrictor 209, a temporary storage 2010, a second flow restrictor 2011, a first connecting column 2012, a fixed column 2013, a fifth flat gear 2014, a third sliding sleeve 2015, a fourth connecting plate 2016, a fourth electric push rod 2017, a fourth transmission shaft 2018, a third transmission wheel 2019, a fourth transmission wheel 2020, a fifth transmission shaft 2021, a sixth flat gear 2022, a seventh flat gear 2023, an eighth flat gear 2024, a ninth flat gear 2025, a second hollow rotating shaft 2026, a third hollow rotating shaft 2027, a first cylindrical sheller 2028, a second cylindrical sheller 2029 and a sixth transmission shaft 2030; the fourth flat gear 201 is fixedly connected with the second sliding sleeve 202; the second sliding sleeve 202 is rotatably connected with the third connecting plate 203; the second sliding sleeve 202 is connected with a second transmission shaft 205; the third connecting plate 203 is fixedly connected with a third electric push rod 204; the third electric push rod 204 is fixedly connected with the fixed frame 10; the second transmission shaft 205 is rotatably connected with the fixed frame 10; the second transmission shaft 205 is fixedly connected with the first transmission wheel 206; the outer ring surface of the first transmission wheel 206 is in transmission connection with a second transmission wheel 207 through a belt; the second driving wheel 207 is fixedly connected with the third transmission shaft 208; the third transmission shaft 208 is rotatably connected with the fixed frame 10; the third transmission shaft 208 is fixedly connected with a first current limiter 209; the first current limiter 209 is fixedly connected with the temporary storage 2010; the temporary storage 2010 is fixedly connected with a second flow restrictor 2011; the second flow restrictor 2011 is fixedly connected with the first connecting column 2012; the first connecting post 2012 is rotatably connected with the fixing post 2013; the fixing column 2013 is fixedly connected with the support frame 101; a fifth flat gear 2014 is arranged below the fixing column 2013; the fifth flat gear 2014 is fixedly connected with a third sliding sleeve 2015; the third sliding sleeve 2015 is rotatably connected with the fourth connecting plate 2016; the third sliding sleeve 2015 is connected with the fourth transmission shaft 2018; the fourth connecting plate 2016 is fixedly connected with a fourth electric push rod 2017; the fourth electric push rod 2017 is fixedly connected with the fixed frame 10; the fourth transmission shaft 2018 is rotatably connected with the fixed frame 10; the fourth transmission shaft 2018 is fixedly connected with a third transmission wheel 2019; the outer annular surface of the third driving wheel 2019 is in driving connection with a fourth driving wheel 2020 through a belt; the fourth driving wheel 2020 is fixedly connected with the fifth transmission shaft 2021; the fifth transmission shaft 2021 is rotatably connected with the fixed frame 10; the fifth transmission shaft 2021 is fixedly connected with the sixth flat gear 2022; the sixth spur gear 2022 meshes with the seventh spur gear 2023 and the ninth spur gear 2025 at the same time; the seventh flat gear 2023 is fixedly connected with the sixth transmission shaft 2030; the sixth transmission shaft 2030 is rotatably connected with the fixing frame 10; the seventh spur gear 2023 meshes with the eighth spur gear 2024; the eighth spur gear 2024 is fixedly connected with the second hollow rotating shaft 2026; the ninth spur gear 2025 is fixedly connected with the third hollow rotating shaft 2027; the second hollow rotating shaft 2026 is rotatably connected with the fixed frame 10; the second hollow rotating shaft 2026 is fixedly connected with the first cylindrical huller 2028 through a connecting block; the third hollow rotating shaft 2027 is fixedly connected with the second cylindrical huller 2029 through a connecting block; the fourth through sixth transfer shafts 201 through 2030 are provided in a set symmetrically on both sides of the trash collecting frame 9.

When the metallic wire 8 is first twisted and returns to a normal state, the fourth electric push rod 2017 drives the fourth connecting plate 2016 to move toward the second spur gear 106, i.e. the fifth spur gear 2014 and the third sliding sleeve 2015 move toward the second spur gear 106 until the fifth spur gear 2014 is engaged with the second spur gear 106, then the motor 102 starts to work again, the motor 102 drives the first transmission shaft 103 to rotate, the first transmission shaft 103 drives the fifth spur gear 2014 through the second spur gear 106, the fifth spur gear 2014 drives the fourth transmission shaft 2018 through the third sliding sleeve 2015, the fourth transmission shaft 2018 drives the fourth transmission wheel 2020 through the third transmission wheel 2019, the fourth transmission wheel 2020 drives the sixth spur gear 2022 to rotate, the sixth spur gear 2022 drives the seventh spur gear 2023 and the ninth spur gear 2025 to rotate at the same time, so that the seventh spur gear 2023 and the ninth spur gear 2025 rotate in opposite directions, and the seventh spur gear 2023 drives the eighth spur gear 2024 and the first spur housing 2028 to rotate, meanwhile, the ninth spur gear 2025 drives the third hollow rotating shaft 2027 and the second cylindrical huller 2029 to rotate reversely, and because the outer surfaces of the first cylindrical huller 2028 and the second cylindrical huller 2029 are provided with a plurality of groups of semi-spherical protruding blocks, and the positions of the plurality of groups of semi-spherical protruding blocks are staggered with each other, after the first cylindrical huller 2028 and the second cylindrical huller 2029 rotate reversely by a certain angle, the plurality of groups of semi-spherical protruding blocks on the outer surfaces of the first cylindrical huller 2028 and the second cylindrical huller 2029 are all in contact with the simulated filigree 8, and meanwhile, the plurality of groups of semi-spherical protruding blocks on the outer surfaces of the first cylindrical huller 2028 and the second cylindrical huller 2029 are in contact with each other, so that the simulated filigree 8 is pulled by the plurality of groups of semi-spherical protruding blocks on the outer surfaces of the first cylindrical huller 2028 and the second cylindrical huller 2029 and is rubbed, thereby cleaning the hulled dye on the surface of the simulated filigree 8, separating the shelling dye on the surface of the simulated metallic filament 8 from the simulated metallic filament 8 and dropping the shelling dye into the temporary storage 2010, then separating the fifth flat gear 2014 from the second flat gear 106 by the fourth electric push rod 2017 after a plurality of groups of semi-spherical protrusions on the outer surfaces of the first cylindrical sheller 2028 and the second cylindrical sheller 2029 are separated from the simulated metallic filament 8, then twisting the simulated metallic filament 8 by the twisting mechanism 1 for two times, meshing the fifth flat gear 2014 with the second flat gear 106 by the fourth electric push rod 2017 again after the twisting is finished, repeating the above secondary treatment on the shelling dye on the surface of the simulated metallic filament 8 by related parts, driving the third electric push rod 204 to drive the third connecting plate 203 to move towards the first flat gear 104 after the treatment is finished, namely driving the fourth flat gear 201 and the second sliding sleeve 202 to move towards the first flat gear 104 until the fourth flat gear is meshed with the first flat gear 104, then the motor 102 starts to work again, the motor 102 drives the first transmission shaft 103 to rotate, the first transmission shaft 103 drives through the fourth flat gear 201, the fourth flat gear 201 drives the second transmission shaft 205 through the second sliding sleeve 202, the second transmission shaft 205 drives the second transmission wheel 207 through the first flat gear 104, the second transmission wheel 207 drives the third transmission shaft 208 to rotate, the third transmission shaft 208 drives the first current limiter 209, the temporary storage 2010, the second current limiter 2011 and the first connecting column 2012 to rotate for a certain angle, so that the shelling dyes and waste slurry existing in the temporary storage 2010 fall down into the waste collection box 9, in the process, the first connecting column 2012 rotates on the fixed column 2013 to ensure the stability of the device, and the first current limiter 209 and the second current limiter 2011 can prevent the slurry and the shelling dyes existing in the temporary storage 2010 from flowing out from two sides of the temporary storage 2010 to other parts of the device, thereby influencing the operation of the device, the other group of fourth flat gears 201 to sixth transmission shafts 2030 repeats the above cleaning work of the surface peeling dye of the simulated metallic yarns 8; this mechanism has accomplished the work to 8 surface shelling dyestuff secondary cleanings of simulation metallic yarn to collect the harmful substance of clearance, effectively the environmental protection.

The straightening mechanism 3 comprises a second electric slide block 301, a first U-shaped connecting plate 302, a second connecting column 303, a first round roller 304, a third electric slide block 305, a second U-shaped connecting plate 306, a third connecting column 307, a second round roller 308, a fifth connecting plate 309 and a fourth electric slide block 3010; the second electric slide block 301 is fixedly connected with the first U-shaped connecting plate 302; the second electric slide block 301 is connected with the fifth connecting plate 309 in a sliding manner; the first U-shaped connecting plate 302 is fixedly connected with the second connecting column 303; the second connecting column 303 is rotatably connected with the first round roller 304; the fifth connecting plate 309 is slidably connected to the third electric slider 305; the third electric slider 305 is fixedly connected with the second U-shaped connecting plate 306; the second U-shaped connecting plate 306 is fixedly connected with a third connecting column 307; the third connecting column 307 is rotatably connected with the second round roller 308; the lower part of the fifth connecting plate 309 is fixedly connected with a group of fourth electric sliders 3010; the two groups of fourth electric sliding blocks 3010 are connected with the fixed frame 10 in a sliding manner; the second electric slider 301 to the second round roller 308 are symmetrically provided with one set on both sides of the fifth connecting plate 309.

After the part of the simulated metallic silks 8 are processed, the first electric bobbin winder 6 and the second electric bobbin winder 7 start to work, the processed part of the simulated metallic silks 8 of the first electric bobbin winder 6 and the second electric bobbin winder 7 move towards the second electric bobbin winder 7 until one end of the processed part of the simulated metallic silks 8 close to the first electric bobbin winder 6 moves to a position between the third electric slider 305 and the third connecting column 307, then the first electric slider 1013 drives the first fixer 1014 to move downwards, so that the first fixer 1014 and the second fixer 1015 clamp one end of the simulated metallic silks 8 again, then the second electric slider 301 and the third electric slider 305 respectively drive the first U-shaped connecting plate 302, the second connecting column 303, the first round roller 304 and the second U-shaped connecting plate 306, the third connecting column 307 and the second round roller 308 to move towards the simulated metallic silks 8 until the first round roller 304 and the second round roller 308 slightly compress the simulated metallic silks 8, meanwhile, the other group of second electric sliding blocks 301 to the second round rollers 308 also complete the above work on the other group of simulated metallic yarns 8, then the two groups of fourth electric sliding blocks 3010 work simultaneously, the two groups of fourth electric sliding blocks 3010 drive the second electric sliding blocks 301 to the fifth connecting plates 309 to move at a constant speed close to the second electric bobbin winder 7, and at the same time of movement, the two groups of first round rollers 304 and the second round rollers 308 straighten parts of the processed parts of the two groups of simulated metallic yarns 8, which may have wrinkles, and the simulated metallic yarns 8 can be effectively reduced and broken by the first round rollers 304 and the second round rollers 308 when the parts of the processed parts of the simulated metallic yarns are self-transmitted through the second connecting columns 303 and the third connecting columns 307 respectively, so that the first electric bobbin 6 and the second electric bobbin 7 start to work again after the parts of the processed parts of the simulated metallic yarns 8 are straightened, at the same time, the first electric slider 1013 again causes the first and second holders 1014 and 1015 to loosen the simulated metallic yarns 8, so that the first and second electric winders 6 and 7 wind the processed partially simulated metallic yarns 8 onto the second electric winder 7; the mechanism completes the straightening work of the work of simulating the straightening of the metallic silks 8.

First retainer 1014, second retainer 1015, third retainer 1017 and fourth retainer 1018 are each configured as an oval.

The simulation metallic yarns 8 are clamped at two ends better.

Both registers 2010 are configured in the shape of a half-pipe.

Make the thick liquids can stop in two sets of temporary storage devices 2010 for two sets of simulation metallic yarn 8 are soaked completely, can effectively collect the shelling dyestuff that clears up simultaneously, prevent its polluted environment.

The first flow restrictor 209 and the second flow restrictor 2011 are both provided with hollows.

It is ensured that the dummy metallic yarn 8 can be smoothly fixed on the first electric bobbin 6 and the second electric bobbin 7 through the first current limiter 209 and the second current limiter 2011.

The outer surfaces of the first cylindrical huller 2028 and the second cylindrical huller 2029 are both provided with semi-spherical convex blocks, and the positions of the semi-spherical convex blocks are staggered.

The unshelling dye on the simulated metallic yarns 8 is effectively pulled in a staggered mode, so that the unshelling dye is separated from the simulated metallic yarns 8.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by the present specification, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (8)

1. A device for shelling real silk and purl silk before interweaving by a torsion method comprises a first sizing barrel (4), a second sizing barrel (5), a first electric bobbin winder (6), a second electric bobbin winder (7), a simulation purl (8), a waste collection frame (9), a fixing frame (10) and a control screen (11); the method is characterized in that: the device also comprises a twisting mechanism (1), a shelling mechanism (2) and a straightening mechanism (3); the torsion mechanism (1) is connected with the hulling mechanism (2); the torsion mechanism (1) is connected with the first slurry barrel (4); the torsion mechanism (1) is connected with the second slurry barrel (5); the torsion mechanism (1) is connected with the simulation filigree (8); the torsion mechanism (1) is connected with the fixed frame (10); the shell removing mechanism (2) is connected with the fixed frame (10); two ends of the simulated metallic yarn (8) are respectively connected with the first electric winder (6) and the second electric winder (7); the fixed frame (10) is connected with the straightening mechanism (3); the fixed frame (10) is connected with the first electric winder (6); the fixed frame (10) is connected with the second electric winder (7); the fixed frame (10) is connected with the waste collecting frame (9); the fixed frame (10) is connected with the control screen (11).

2. The device for shelling the dyes before real silk and purl silk interweaving by the torsion method as claimed in claim 1, which is characterized in that: the torsion mechanism (1) comprises a support frame (101), a motor (102), a first transmission shaft (103), a first flat gear (104), a first sliding sleeve (105), a second flat gear (106), a missing gear (107), a first connecting plate (108), a first electric push rod (109), a third flat gear (1010), a first hollow rotating shaft (1011), a second connecting plate (1012), a first electric slide block (1013), a first fixer (1014), a second fixer (1015), a second electric push rod (1016), a third fixer (1017), a fourth fixer (1018) and a slurry conveying pipe (1019); the supporting frame (101) is fixedly connected with the fixed frame (10); the support frame (101) is fixedly connected with the second electric push rod (1016); the first slurry barrel (4) is connected; the supporting frame (101) is connected with the hulling mechanism (2); the support frame (101) is fixedly connected with a plurality of groups of slurry conveying pipes (1019) at the same time; a motor (102) is arranged on the side surface of the support frame (101); the motor (102) is fixedly connected with the fixed frame (10); the motor (102) is fixedly connected with the first transmission shaft (103) through an output shaft; the first transmission shaft (103) is rotationally connected with the fixed frame (10); the first transmission shaft (103) is fixedly connected with the first flat gear (104) and the second flat gear (106) at the same time; the first transmission shaft (103) is connected with the first sliding sleeve (105); the first sliding sleeve (105) is fixedly connected with the gear lacking wheel (107); the first sliding sleeve (105) is rotatably connected with the first connecting plate (108); the first connecting plate (108) is fixedly connected with a first electric push rod (109); the first electric push rod (109) is fixedly connected with the fixed frame (10); a third flat gear (1010) is arranged on the side surface of the first sliding sleeve (105); the third flat gear (1010) is fixedly connected with the first hollow rotating shaft (1011); the first hollow rotating shaft (1011) is rotatably connected with the fixed frame (10); the first hollow rotating shaft (1011) is fixedly connected with the second connecting plate (1012); the second connecting plate (1012) is in sliding connection with the first electric slider (1013); the second connecting plate (1012) is fixedly connected with the second fixer (1015); the first electric slide block (1013) is fixedly connected with the first fixer (1014); the second fixer (1015) is contacted with the simulation filigree (8); the second electric push rod (1016) is fixedly connected with the third fixer (1017); a fourth fixer (1018) is arranged right below the third fixer (1017); the fourth fixer (1018) is contacted with the simulation filigree (8); the fourth fixer (1018) is fixedly connected with the support frame (101); a group of supporting frames (101) to a slurry conveying pipe (1019) and a group of simulated metallic yarns (8) are symmetrically arranged on two sides of the waste collecting frame (9); the other group of supporting frames (101) is fixedly connected with the second slurry barrel (5); the other set of second (1015) and fourth (1018) anchors are in contact with the other set of simulated metallic filaments (8).

3. The device for shelling the dyes before real silk and purl silk interweaving by the torsion method as claimed in claim 2, which is characterized in that: the shelling mechanism (2) comprises a fourth flat gear (201), a second sliding sleeve (202), a third connecting plate (203), a third electric push rod (204), a second transmission shaft (205), a first transmission wheel (206), a second transmission wheel (207), a third transmission shaft (208), a first current limiter (209), a temporary storage (2010), a second current limiter (2011), a first connecting column (2012), a fixed column (2013), a fifth flat gear (2014), a third sliding sleeve (2015), a fourth connecting plate (2016), a fourth electric push rod (2017), a fourth transmission shaft (2018), a third transmission wheel (2019), a fourth transmission wheel (2020), a fifth transmission shaft (2021), a sixth flat gear (2022), a seventh flat gear (2023), an eighth flat gear (2024), a ninth flat gear (2025), a second hollow rotating shaft (2026), a third hollow rotating shaft (2027), a first cylindrical sheller (2028), A second cylindrical huller (2029) and a sixth drive shaft (2030); the fourth flat gear (201) is fixedly connected with the second sliding sleeve (202); the second sliding sleeve (202) is rotatably connected with the third connecting plate (203); the second sliding sleeve (202) is connected with the second transmission shaft (205); the third connecting plate (203) is fixedly connected with a third electric push rod (204); the third electric push rod (204) is fixedly connected with the fixed frame (10); the second transmission shaft (205) is rotationally connected with the fixed frame (10); the second transmission shaft (205) is fixedly connected with the first transmission wheel (206); the outer ring surface of the first transmission wheel (206) is in transmission connection with a second transmission wheel (207) through a belt; the second driving wheel (207) is fixedly connected with the third transmission shaft (208); the third transmission shaft (208) is rotationally connected with the fixed frame (10); the third transmission shaft (208) is fixedly connected with the first current limiter (209); the first current limiter (209) is fixedly connected with the temporary storage (2010); the temporary storage (2010) is fixedly connected with a second current limiter (2011); the second current limiter (2011) is fixedly connected with the first connecting column (2012); the first connecting column (2012) is rotatably connected with the fixed column (2013); the fixing column (2013) is fixedly connected with the supporting frame (101); a fifth flat gear (2014) is arranged below the fixing column (2013); the fifth flat gear (2014) is fixedly connected with a third sliding sleeve (2015); the third sliding sleeve (2015) is rotatably connected with the fourth connecting plate (2016); the third sliding sleeve (2015) is connected with the fourth transmission shaft (2018); the fourth connecting plate (2016) is fixedly connected with the fourth electric push rod (2017); the fourth electric push rod (2017) is fixedly connected with the fixed frame (10); the fourth transmission shaft (2018) is rotatably connected with the fixed frame (10); the fourth transmission shaft (2018) is fixedly connected with the third transmission wheel (2019); the outer ring surface of the third driving wheel (2019) is in transmission connection with a fourth driving wheel (2020) through a belt; the fourth driving wheel (2020) is fixedly connected with the fifth transmission shaft (2021); the fifth transmission shaft (2021) is rotatably connected with the fixed frame (10); the fifth transmission shaft (2021) is fixedly connected with the sixth flat gear (2022); the sixth flat gear (2022) is simultaneously meshed with the seventh flat gear (2023) and the ninth flat gear (2025); the seventh flat gear (2023) is fixedly connected with the sixth transmission shaft (2030); the sixth transmission shaft (2030) is rotatably connected with the fixed frame (10); the seventh flat gear (2023) is meshed with the eighth flat gear (2024); the eighth spur gear (2024) is fixedly connected with the second hollow rotating shaft (2026); the ninth spur gear (2025) is fixedly connected with the third hollow rotating shaft (2027); the second hollow rotating shaft (2026) is rotatably connected with the fixed frame (10); the second hollow rotating shaft (2026) is fixedly connected with the first cylindrical huller (2028) through a connecting block; the third hollow rotating shaft (2027) is fixedly connected with the second cylindrical huller (2029) through a connecting block; a group of fourth flat gears (201) to a group of sixth transmission shafts (2030) are symmetrically arranged on two sides of the waste collecting frame (9).

4. The device for shelling the dyes before real silk and purl silk interweaving by the torsion method as claimed in claim 3, which is characterized in that: the straightening mechanism (3) comprises a second electric slider (301), a first U-shaped connecting plate (302), a second connecting column (303), a first round roller (304), a third electric slider (305), a second U-shaped connecting plate (306), a third connecting column (307), a second round roller (308), a fifth connecting plate (309) and a fourth electric slider (3010); the second electric slider (301) is fixedly connected with the first U-shaped connecting plate (302); the second electric slide block (301) is connected with the fifth connecting plate (309) in a sliding manner; the first U-shaped connecting plate (302) is fixedly connected with the second connecting column (303); the second connecting column (303) is rotationally connected with the first round roller (304); the fifth connecting plate (309) is in sliding connection with the third electric slider (305); the third electric slider (305) is fixedly connected with the second U-shaped connecting plate (306); the second U-shaped connecting plate (306) is fixedly connected with the third connecting column (307); the third connecting column (307) is rotationally connected with the second round roller (308); the lower part of the fifth connecting plate (309) is fixedly connected with a group of fourth electric sliding blocks (3010) respectively; the two groups of fourth electric sliding blocks (3010) are in sliding connection with the fixed frame (10); and a group of second electric sliding blocks (301) to a group of second round rollers (308) are symmetrically arranged on two sides of the fifth connecting plate (309).

5. The device for shelling the dyes before real silk and purl silk interweaving by the torsion method as claimed in claim 4, which is characterized in that: the first holder (1014), the second holder (1015), the third holder (1017) and the fourth holder (1018) are all provided with an oval shape.

6. The device for shelling the dyes before real silk and purl silk interweaving by the torsion method as claimed in claim 5, which is characterized in that: both registers (2010) are arranged in a semi-circular tube.

7. The device for shelling the dyes before real silk and purl silk interweaving by the torsion method as claimed in claim 6, is characterized in that: the first flow restrictor (209) and the second flow restrictor (2011) are both provided with hollowed-out portions.

8. The device for shelling the dyes before real silk and purl silk interweaving by the torsion method as claimed in claim 7, is characterized in that: the outer surfaces of the first cylindrical huller (2028) and the second cylindrical huller (2029) are respectively provided with a semi-spherical convex block, and the positions of the semi-spherical convex blocks are staggered.

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