CN115323629A - Curtain hidden-seam non-open-line full dress process - Google Patents

Abstract

The invention relates to the field of sewing curtains, in particular to a curtain hidden-seam non-open-line dress process, which comprises the steps of manufacturing a coat bottom plate and a lower skirt bottom plate; manufacturing a jacket upper plate and a lower skirt upper plate; assembling by using a wireless technology; dyeing; ironing and shaping; the steps are carried out on an operation platform, the operation platform is connected with an expansion platform, the expansion platform and the operation platform are located in the same horizontal plane, and a fastening groove is formed in the expansion platform. The locking slider promotes the sliding block to sliding to the one side of keeping away from the extension platform when sliding for the sliding block, and synchronous subassembly drives the sliding block and the synchronous cunning of locking slider, and synchronous subassembly makes the gliding speed of locking slider along articulated shaft axis direction be greater than the gliding speed of fastening components, and then makes extension platform and operation platform contact inseparabler, further increases the stability of extension platform to stability when increasing the no open thread sewing, and then the no open thread sewing process quality when improving the preparation (window) curtain.

Description

Curtain hidden-seam non-open-line full dress process

Technical Field

The invention relates to the field of sewn curtains, in particular to a curtain hidden-seam non-open-line dress process.

Background

The non-open-thread sewing process is a special sewing process which can not see the used thread after sewing two pieces of cloth, so that the cloth sewed by the non-open-thread sewing process is more neat and beautiful, and the non-open-thread sewing process is generally adopted to manufacture the curtain in the processing and manufacturing process.

In the process of processing the curtain by the open-thread-free sewing, because the general volume ratio of the curtain is large, the operation is not easy when the table surface of the general sewing machine is too small, and the operation platform of the sewing machine needs to be expanded so as to conveniently operate the curtain. After the existing expansion platform is connected with the sewing machine operating platform, the vibration generated in the working process of the sewing machine can cause the looseness of the connection part of the expansion platform, so that the clothing making process is unstable, the process quality is reduced in the non-open thread sewing process, and the curtain cannot achieve the non-open thread effect.

Disclosure of Invention

The invention provides a curtain hidden-seam non-open-line dress process, which aims to solve the problem of poor quality of the non-open-line process in the process of manufacturing a curtain by the conventional process.

The curtain hidden-seam non-open-line robe process adopts the following technical scheme:

the curtain hidden seam bright-line-free dress process comprises the following steps:

s1, cutting a finished fabric, sewing by using a sewing machine, and adding about 6 cm of edge covering to each of two sides;

s2, sewing to manufacture a cloth wrapping belt;

s3, mounting the hanging buckle on the curtain, and assembling by using a wireless process in the assembling process;

s4, dyeing the pattern part on the curtain;

s5, ironing and shaping the dyed curtain;

the steps are carried out on an operating platform with a sewing machine, and the operating platform is connected with an expansion platform, a fastening assembly, a locking sliding block and a synchronous assembly; the expansion platform is plate-shaped, and the transverse edge of one side of the expansion platform is hinged with the transverse edge of one side of the operation platform; the expansion platform is in an open state, and when the expansion platform is in the open state, the expansion platform and the operation platform are positioned in the same horizontal plane; a fastening groove is formed in the expansion platform; the fastening assembly comprises a fastening block and a sliding block which are fixedly connected into a whole; the sliding block is slidably arranged on the lower side surface of the operating platform, and the sliding direction is parallel and vertical to the hinge shaft of the expansion platform; the fastening block is provided with a convex block inserted into the fastening groove, so that the fastening block drives the expansion platform to move towards the operating platform when sliding along the axial direction of the articulated shaft of the expansion platform; the locking sliding block can be arranged on the back of the operating platform in a sliding manner along the axial direction of the hinged shaft of the expansion platform and is meshed with the sliding block, so that the locking sliding block pushes the sliding block to slide towards one side far away from the expansion platform when sliding relative to the sliding block; the synchronous component drives the sliding block and the locking sliding block to synchronously slide; when the operating platform is contacted with the expansion platform, the synchronous component enables the locking sliding block to slide along the axial direction of the hinge shaft at a speed higher than the sliding speed of the fastening component.

Further, the synchronizing assembly comprises a synchronizing operation member, a first gear set and a second gear set; the lower end of the operation platform is fixedly provided with a fixed rack; the synchronous operation piece is arranged on the back of the operation platform; the second gear set is arranged below the locking slide block and is respectively connected with the fixed rack and the synchronous operation piece; the first gear set is arranged below the sliding block and is respectively connected with the fixed gear and the synchronous operating member, and the first gear set is used for changing the transmission ratio between the fixed gear and the synchronous operating member after the operating platform is contacted with the expansion platform.

Further, the synchronous operating member comprises a mounting plate, a first rack and a second rack; the installation plate is parallel to a hinged shaft of the expansion platform and is vertical to the operation platform; the mounting plate can slide along the axial direction of a hinge shaft of the expansion platform and is arranged on the back of the operation platform in a sliding manner along one side far away from the expansion platform; the first rack and the second rack are parallel; the arrangement direction of the first rack is consistent with the hinging shaft of the expansion platform; the first rack and the second rack are fixedly arranged on the mounting plate, the first rack is located on one side close to the operating platform, the distances between the first rack and the fixed rack are different from those between the second rack and the fixed rack, the first gear set in the first state is used for connecting the fixed rack and the first rack, and the first gear set in the second state is used for connecting the fixed rack and the second rack.

Further, the first gear set comprises a first rotating shaft, a first gear, a second gear and a third gear; the first rotating shaft is rotatably arranged on the sliding block in a manner of sliding towards one side far away from the operation platform; the first gear, the second gear and the third gear are fixedly sleeved on the first rotating shaft and are sequentially far away from the operating platform; the first gear is meshed with the fixed rack, and the second gear in the first state is connected with the synchronous operating piece; in the second state, the first rotating shaft is pulled to one side far away from the operating platform, so that the third gear is connected with the synchronous operating piece.

Further, the second gear set comprises a second rotating shaft, a fourth gear and a fifth gear; the second rotating shaft is rotatably arranged on the locking sliding block; the fourth gear and the fifth gear are fixedly sleeved on the second rotating shaft and are sequentially far away from the operating platform; the fourth gear is engaged with the fixed rack, and the fifth gear is connected with the synchronous operating member.

Further, a handle is arranged below the first gear set.

Furthermore, a handle is arranged on one side, away from the expansion platform, of the mounting plate.

Further, the locking slide block is provided with a stable slide block; one end of the stable sliding block is fixedly connected with the locking sliding block, and the other end of the stable sliding block is connected with the back of the operating platform in a sliding manner.

The invention has the beneficial effects that: the curtain hidden-seam non-open-line robe process is carried out on the operating platform, because the operating platform is connected with the expansion platform, the fastening assembly, the locking sliding block and the synchronous assembly, and when the expansion platform rotates to be at the same level with the operating platform by taking the hinge shaft as the axis, the convex block on the fastening block is inserted into the fastening groove. The sliding block is pushed, and under the action of the synchronous component, the sliding block and the locking sliding block move synchronously. Simultaneously under the effect on the fastening block, the lug slides along the fastening groove, and then the extension platform moves to one side that is close to operation platform, until contacting with operation platform. Because the sliding block is meshed with the locking sliding block ratchet, and the synchronous component is arranged, when the operating platform shakes due to work, the forward sliding speed of the locking sliding block is higher than that of the sliding block, so that the ratchet surface of the locking sliding block pushes the sliding block to move towards one side far away from the expansion platform, the expansion platform is contacted with the operating platform more tightly, the stability of the expansion platform is further improved, the stability during open-thread-free sewing is improved, and the process quality of the open-thread-free sewing during curtain manufacturing is further improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of a blind seamless non-open-line dress process of the present invention;

FIG. 2 is a partial front view of an embodiment of the blind-seam open-line-free robe process of the present invention;

FIG. 3 is a bottom view of an embodiment of the blind seamless clear-line dress process of the present invention;

FIG. 4 isbase:Sub>A cross-sectional view taken at A-A of FIG. 3;

FIG. 5 is an exploded view of one perspective of an embodiment of the blind seamless clear-line dress process of the present invention;

FIG. 6 is an exploded view of another perspective of an embodiment of the blind-seam open-thread-free robe process of the present invention;

FIG. 7 is a schematic structural diagram of an expansion platform of an embodiment of the curtain blind-seam open-thread-free robe process of the present invention;

in the figure: 111. a sewing machine; 121. an operating platform; 122. fixing a rack; 123. a third chute; 124. a fourth chute; 125. a first chute; 126. connecting grooves; 128. a second chute; 131. an extension platform; 132. a connecting rod; 133. a fastening groove; 15. a synchronous operating member; 151. mounting a plate; 152. a handle; 153. a second rack; 154. a first rack; 16. a first gear set; 161. a handle; 162. a third gear; 163. a second gear; 164. a first gear; 17. a second gear set; 171. a fourth gear; 172. a fifth gear; 18. a fastening assembly; 181. a slider; 182. a fastening block; 184. a bump; 191. locking the sliding block; 192. and (5) stabilizing the sliding block.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

For convenience of description, the left-right direction in the present invention is the left-right direction in fig. 1, and the front-back direction in the present invention is the right-lower-left-upper direction in fig. 1 (i.e., the direction of the rotation axis of the expanding platform 131, wherein the portion of fig. 1 that is not covered by the sewing machine is the front side).

The embodiment of the curtain hidden-seam non-open-line dress process of the invention is shown in fig. 1 to 7, and comprises the following steps:

s1, cutting a finished fabric, sewing by a sewing machine 111, and adding about 6 cm of edge covering to each side;

s2, sewing to manufacture a cloth wrapping belt;

s3, mounting the hanging buckle on the curtain, and assembling by using a wireless process in the assembling process;

s4, dyeing the pattern part on the curtain;

s5, ironing and shaping the dyed curtain;

the above steps are performed on the operation platform 121 with the sewing machine 111, and the operation platform 121 is connected with the expansion platform 131, the fastening assembly 18, the locking slider 191 and the synchronizing assembly. The extension platform 131 is in a rectangular plate shape, a lateral edge of one side of the extension platform 131 is hinged to a lateral edge of one side of the operation platform 121, the extension platform 131 rotates to be in the same level with the operation platform 121 by taking a hinge shaft as an axis, the hinge shaft is a connecting rod 132, the front end and the rear end of one side of the extension platform 131 are fixedly connected with the connecting rod 132 respectively, so that the extension platform 131 rotates to be in a retracted state in an initial state by taking the connecting rod 132 as an axis at the extension platform 131, the extension platform 131 in the retracted state is perpendicular to the operation platform 121, and the extension platform 131 rotates to be in the same level with the operation platform 121 in use. The expansion platform 131 is provided with a fastening groove 133, and the fastening groove 133 is a straight groove and is at the same level with the expansion platform 131; one end of the fastening slot 133 is open and close to the operating platform 121, the other end is far away from the operating platform 121, the fastening slot 133 is multiple, the fastening slot 133 is arranged on the ground of the expanding platform 131 and close to one side of the operating platform 121, and the opening is close to the operating platform 121.

The fastening assembly 18 includes a fastening block 182 and a sliding block 181; the back of the operation platform 121 is provided with a first sliding slot 125, the first sliding slot 125 is parallel to the connecting rod 132 of the expansion platform 131, and the first sliding slot 125 is arranged in the front-back direction. The sliding block 181 is slidably disposed on the back of the operating platform 121 in a direction parallel and perpendicular to the connecting rod 132 of the expanding platform 131, the upper end of the sliding block 181 is slidably inserted into the first sliding slot 125, and the sliding block 181 is slidable in the first sliding slot 125 in the left-right direction and also slidable in the front-back direction. The fastening block 182 is disposed on the back of the extension platform 131 in the horizontal state, the fastening block 182 is provided with a plurality of protrusions 184 for being inserted into the fastening grooves 133, when the extension platform 131 rotates to the horizontal state, each protrusion 184 can be inserted into one fastening groove 133 from the opening of the fastening groove 133, so that the fastening block 182 slides along the axial direction of the hinge shaft of the extension platform 131 to drive the extension platform 131 to move towards the operation platform 121, specifically, the protrusion 184 drives the extension platform 131 to move rightwards along the horizontal direction under the driving of the inclined plane of the fastening groove 133, so that the connecting rod 132 slides rightwards along the connecting groove 126 until the right side of the extension platform 131 is tightly attached to the left side of the operation platform 121. The sliding block 181 is fixedly connected to the fastening block 182, and when the sliding block 181 slides along the first sliding slot 125, the fastening block 182 is driven to slide backwards and to slide rightwards. The left side of the sliding block 181 is a ratchet surface.

The back of the operating platform 121 is provided with a second sliding slot 128, the second sliding slot 128 is arranged parallel to the first sliding slot 125 and is located at the left side of the first sliding slot 125, a locking slider 191 is slidably mounted in the second sliding slot 128 in the front-back direction, the locking slider 191 is slidably mounted at the back of the operating platform 121 along the axis direction of the hinge shaft of the expanding platform 131 and is engaged with the sliding block 181, so that the sliding of the locking slider 191 relative to the sliding block 181 pushes the sliding block 181 to slide to the side away from the expanding platform 131. The right side of the locking slider 191 is a ratchet surface, the locking slider 191 is engaged with the sliding block 181 by ratchet, and the locking slider 191 is configured such that when the locking slider 191 slides forward relative to the sliding block 181, the ratchet surface of the locking slider 191 pushes the sliding block 181 to slide rightward, so that the fastening block 182 drives the expansion platform 131 to slide rightward. The synchronous component drives the sliding block 181 and the locking sliding block 191 to synchronously slide. When the operation platform 121 and the expansion platform 131 are in contact, the synchronizing assembly makes the locking slider 191 slide in the axis direction of the hinge shaft at a speed greater than that of the fastening assembly 18.

In operation, when a window covering is to be made, the expanding platform 131 is rotated clockwise 90 ° around the connecting rod 132, so that the expanding platform 131 and the operating platform 121 are at the same level, and each protrusion 184 on the fastening block 182 is inserted into an opening in one fastening slot 133. The sliding block 181 is pushed backward, and under the action of the synchronizing assembly, the sliding block 181 and the locking sliding block 191 synchronously move backward. Meanwhile, under the action of the fastening block 182, the protrusion 184 slides along the fastening slot 133, so that the expansion platform 131 moves rightwards, and the expansion platform 131 is driven to move rightwards horizontally until contacting with the operation platform 121. Due to the ratchet engagement of the sliding block 181 and the locking slider 191, and the arrangement of the synchronization assembly, when the operation platform 121 vibrates due to operation, the speed of forward sliding of the locking slider 191 is faster than the speed of forward sliding of the sliding block 181, so that the ratchet surface of the locking slider 191 pushes the sliding block 181 to move rightward, the contact between the expansion platform 131 and the operation platform 121 is tighter, and the stability of the expansion platform 131 is further improved.

In the present embodiment, as shown in fig. 1 to 6, the synchronization assembly includes a synchronization operating member 15, a first gear set 16 and a second gear set 17. The lower end of the operation platform 121 is fixedly provided with a fixed rack 122, the fixed rack 122 is parallel to the first sliding groove 125, and the fastening block 182 slidably penetrates through the fixed rack 122. The synchronization operator 15 is provided on the back of the operation platform 121. The second gear set 17 is disposed below the locking slider 191 and is connected to the fixed rack 122 and the synchronous operating member 15, respectively, so that the synchronous operating member 15 drives the locking slider 191 to slide in the second sliding slot 128 through the second gear 163 and the lever set. The first gear set 16 is disposed below the sliding block 181 and is respectively connected to the fixed rack 122 and the synchronous operating device 15, the first gear set 16 is used for changing the transmission ratio between the fixed rack 122 and the synchronous operating device 15 after the operating platform 121 contacts the expanding platform 131, the second gear set 17 is used for enabling the synchronous operating device 15 to drive the sliding block 181 to slide along the first sliding slot 125, meanwhile, when the expanding platform 131 contacts the operating platform 121, the first gear set 16 changes the transmission ratio between the synchronous operating device 15 and the fixed rack 122, and further, when the synchronous operating device 15 pushes the locking sliding block 191 and the sliding block 181 to slide synchronously, the speed of the locking sliding block 191 is greater than that of the sliding block 181.

In the present embodiment, as shown in fig. 1 to 6, the synchronization operating member 15 includes a mounting plate 151, a first rack 154, and a second rack 153. The mounting plate 151 is parallel to the hinge axis of the expansion platform 131 and perpendicular to the operation platform 121. A third sliding chute 123 is arranged below the operating platform 121, and the third sliding chute 123 and the first sliding chute 125 are arranged in parallel. The mounting plate 151 can slide along the axial direction of the hinge shaft of the expansion platform 131 and is slidably disposed on the back of the operating platform 121 toward the side away from the expansion platform 131, specifically, the upper end of the mounting plate 151 is slidably disposed in the third sliding groove 123 in the front-back direction and in the left-right direction, and the right side of the mounting plate 151 is provided with a pressure spring so as to be contracted when the mounting plate 151 slides to the right. A handle 152 is disposed on a side of the mounting plate 151 away from the expansion platform 131, and the handle 152 is pushed to drive the mounting plate 151 to slide backwards along the third sliding groove 123. The first rack gear 154 and the second rack gear 153 are parallel, the tooth surfaces of the first rack gear 154 and the second rack gear 153 are located on the left side, and the arrangement direction of the first rack gear 154 is coincident with the hinge shaft of the extension platform 131, that is, the axis of the connecting rod 132, and is arranged in the front-rear direction. The first rack 154 and the second rack 153 are fixed on the mounting plate 151, the first rack 154 is located at a side close to the operation platform 121, distances between the first rack 154 and the fixed rack 122 are different, a distance between a tooth surface of the first rack 154 and the fixed rack 122 is smaller than a distance between the second rack 153 and the fixed rack 122, the first gear set 16 is used for connecting the fixed rack 122 and the first rack 154 in the first state, and the first gear set 16 is used for connecting the fixed rack 122 and the second rack 153 in the second state. The first state expanding platform 131 has just rotated to the horizontal state, and then the mounting plate 151 is pushed to slide the sliding block 181 backwards and backwards synchronously with the locking sliding block 191. The second state is a state after the expansion platform 131 and the operation platform 121 are completely contacted, and the transmission ratio is changed through the first rack 154 and the second rack 153, so that when the operation platform 121 drives the locking slider 191 to slide in the second sliding slot 128 in the vibrating process, the speed of the locking slider 191 is greater than the speed of the sliding block 181 sliding in the first sliding slot 125.

The first gear set 16 includes a first rotating shaft, a first gear 164, a second gear 163 and a third gear 162, and there may be two first gear sets 16. The first rotating shaft is rotatably and slidably disposed on the sliding block 181 at a side away from the operating platform 121, and specifically, the first rotating shaft is rotatably and slidably connected to the sliding block 181 up and down. The first gear 164, the second gear 163 and the third gear 162 are all fixedly sleeved on the first rotating shaft and are sequentially away from the operating platform 121, the first gear 164, the second gear 163 and the third gear 162 are sequentially arranged from top to bottom, and the diameters of the gears are sequentially increased. The first gear 164 is engaged with the fixed rack 122, so that when the first gear 164 rotates, the fixed rack 122 drives the sliding block 181 to slide along the first sliding slot 125, and the second gear 163 is connected with the synchronous operating member 15 in the first state, and specifically, the first gear 164 is engaged with the first rack 154, so that when the first rack 154 slides backwards, the first rotating shaft is driven to rotate. In the second state, the first rotating shaft is pulled to a side away from the operating platform 121, specifically, the first rotating shaft is pulled downward, so that the third gear 162 is connected to the synchronous operating device 15, specifically, the third gear 162 is engaged with the second rack 153, and simultaneously, the second gear 163 is disengaged from the first rack 154. A handle 161 is disposed below the first gear set 16, and the handle 161 is used to connect the two first gear sets 16, so that when the handle 152 is pulled downwards, the two first rotating shafts are slid downwards. The second gear set 17 includes a second rotating shaft, a fourth gear 171 and a fifth gear 172, the second rotating shaft may be two, the second rotating shaft is rotatably disposed on the locking slider 191, the fourth gear 171 and the fifth gear 172 are both fixedly sleeved on the second rotating shaft, and are sequentially away from the operating platform 121, the specific fourth gear 171 and the fifth gear 172 are disposed from top to bottom, the fourth gear 171 and the first gear 164 have the same structure, and the fifth gear 172 and the second gear 163 have the same structure. The fourth gear 171 meshes with the fixed rack 122, and when the fourth rack rotates, the fourth rack is driven by the fixed rack 122, the fifth gear 172 is connected to the synchronous operating member 15, and the fifth gear 172 meshes with the first rack 154. Locking slider 191 is provided with firm slider 192, firm slider 192 one end and locking slider 191 rigid coupling, the other end is connected with the back of operation platform 121 with slidable, the second pivot is rotationally installed on fastening component 18, the back of operation platform 121 is equipped with fourth spout 124, fourth spout 124 sets up the right side at mounting panel 151, the other end of firm slider 192 runs through mounting panel 151 slidable and installs in fourth spout 124, the stability of the multiplicable locking slider 191 of firm slider 192.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (8)

1. The curtain hidden-seam non-open-line robe process is characterized in that: the method comprises the following steps:

s1, cutting a finished fabric, sewing by using a sewing machine, and adding about 6 cm of edge covering to each of two sides;

s2, sewing to manufacture a cloth wrapping belt;

s3, mounting the hanging buckle on the curtain, wherein in the assembly process, the curtain is assembled by using a non-open-wire process;

s4, dyeing the pattern part on the curtain;

s5, ironing and shaping the dyed curtain;

the steps are carried out on an operating platform with a sewing machine, and the operating platform is connected with:

the expansion platform is plate-shaped, and the transverse edge of one side of the expansion platform is hinged with the transverse edge of one side of the operation platform; the expansion platform is in an open state, and when the expansion platform is in the open state, the expansion platform and the operation platform are positioned in the same horizontal plane; a fastening groove is formed in the expansion platform;

the fastening assembly comprises a fastening block and a sliding block which are fixedly connected into a whole; the sliding block is slidably arranged on the lower side surface of the operating platform, and the sliding direction is parallel and vertical to the hinge shaft of the expansion platform; the fastening block is provided with a convex block inserted into the fastening groove, so that the fastening block drives the expansion platform to move towards the operating platform when sliding along the axial direction of the articulated shaft of the expansion platform;

the locking sliding block can be arranged on the back of the operating platform in a sliding mode along the axial direction of the hinged shaft of the expansion platform and is meshed with the sliding block, so that the locking sliding block pushes the sliding block to slide towards one side far away from the expansion platform when sliding relative to the sliding block;

the synchronous component drives the sliding block and the locking sliding block to synchronously slide; when the operating platform is contacted with the expanding platform, the synchronous component enables the locking sliding block to slide along the axial direction of the hinge shaft at a speed higher than the sliding speed of the fastening component.

2. The curtain hidden-seam open-line-free robe process as claimed in claim 1, wherein:

the synchronous component comprises a synchronous operating piece, a first gear set and a second gear set; the lower end of the operation platform is fixedly provided with a fixed rack; the synchronous operation piece is arranged on the back of the operation platform; the second gear set is arranged below the locking slide block and is respectively connected with the fixed rack and the synchronous operation piece; the first gear set is arranged below the sliding block and is respectively connected with the fixed rack and the synchronous operating element, and the first gear set is used for changing the transmission ratio between the fixed rack and the synchronous operating element after the operating platform is contacted with the expanding platform.

3. The curtain hidden-seam open-line-free dress process according to claim 2, wherein:

the synchronous operating piece comprises a mounting plate, a first rack and a second rack; the installation plate is parallel to a hinged shaft of the expansion platform and is vertical to the operation platform; the mounting plate can slide along the axial direction of a hinge shaft of the expansion platform and is arranged on the back of the operation platform in a sliding manner along one side far away from the expansion platform; the first rack is parallel to the second rack; the arrangement direction of the first rack is consistent with the hinging shaft of the expansion platform; the first rack and the second rack are fixedly arranged on the mounting plate, the first rack is located on one side close to the operating platform, the distances between the first rack and the fixed rack are different from those between the second rack and the fixed rack, the first gear set is used for connecting the fixed rack and the first rack in the first state, and the first gear set is used for connecting the fixed rack and the second rack in the second state.

4. The curtain hidden-seam open-line-free robe process as claimed in claim 3, wherein:

one side of the mounting plate, which is far away from the expansion platform, is provided with a handle.

5. The curtain hidden-seam open-line-free dress process according to claim 2, wherein:

the first gear set comprises a first rotating shaft, a first gear, a second gear and a third gear; the first rotating shaft is rotatably arranged on the sliding block in a manner of sliding towards one side far away from the operation platform; the first gear, the second gear and the third gear are fixedly sleeved on the first rotating shaft and are sequentially far away from the operating platform; the first gear is meshed with the fixed rack, and the second gear in the first state is connected with the synchronous operating element; in the second state, the first rotating shaft is pulled towards one side far away from the operating platform, so that the third gear is connected with the synchronous operating piece.

6. The curtain hidden-seam open-line-free robe process as claimed in claim 5, wherein:

a handle is arranged below the first gear set.

7. The curtain hidden-seam open-line-free robe process as claimed in claim 2, wherein:

the second gear set comprises a second rotating shaft, a fourth gear and a fifth gear; the second rotating shaft is rotatably arranged on the locking sliding block; the fourth gear and the fifth gear are fixedly sleeved on the second rotating shaft and are sequentially far away from the operating platform; the fourth gear is engaged with the fixed rack, and the fifth gear is connected with the synchronous operation member.

8. The curtain hidden-seam open-line-free dress process according to claim 7, wherein:

the locking slide block is provided with a stable slide block; one end of the stable sliding block is fixedly connected with the locking sliding block, and the other end of the stable sliding block is connected with the back of the operating platform in a sliding manner.

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