KR20220165492A - device of cog thread for skin surgery and cog thread manufactured therof - Google Patents

Abstract

The present invention relates to a cog thread manufacturing system for skin surgery and procedures and a cog thread manufactured therefrom. The system comprises a deformation device (100) and a cog device (200). The deformation device (100) has a structure in which: an upper chamber (102) and a lower chamber (103) are divided inside a housing (101) of a certain box-shaped size; inside the upper chamber (102), deformation units are installed to transform the chamber into a flat shape; and inside the lower chamber (103), a control unit is installed to control the deformation units installed in the upper chamber (102). The cog device (200) has a structure in which: in order to cog the deformation chamber deformed from the deformation device using a mold method, an upper chamber (202) and a lower chamber (203) are divided inside a housing (201) of a certain box-shaped size; cog units for punching the deformation chamber into a cog shape are installed inside the upper chamber (202); and inside the lower chamber (203), a control unit is installed to control the cog units installed in the upper chamber (202).

Description

Cog thread manufacturing system for skin surgery and procedure and cog thread manufactured therefrom {device of cog thread for skin surgery and cog thread manufactured therof}

The present invention relates to a cog thread manufacturing system for skin surgery and procedures and a cog thread manufactured therefrom, and more particularly, to compression of a deformation device installed inside a housing structure such as a chamber, and cog according to punching of the cog device. It relates to a cog thread manufacturing system for skin surgery and procedures that handles processing in an automated manner, and a cog thread manufactured therefrom.

As the skin ages, it sags and wrinkles a lot. As a way to improve skin sagging and wrinkles, lift threads are being commercialized. The lift thread is inserted into the skin to have a thorn shape along the length of the thread to improve skin sagging and wrinkles.

The thorn formed along the length of the thread is a method of incising a portion of the thread using a sharp tool, and a portion of the thread cut in this way is formed in the form of a thorn protruding from the thread in a split shape.

However, since these thorns are structures protruding from the thread, considerable pain may be involved in inserting the thread into the skin, and there is also difficulty in inserting the thread. Of course, it is used to improve skin sagging and wrinkles in the skin, but over time, cases where the thorns separate from the thread occur, and the resulting skin sagging and wrinkles are not improved, but rather return to their original state. The problem of returning to .

For this reason, there is a demand for a cog process in which a part of the thread is completely removed instead of a thorn shape in an incision method so that the skin lift thread can semi-permanently improve skin sagging and wrinkles.

Patent Document 001: Registered Patent No. 10-1903336 (registration date 2018. 09. 20)

The present invention for solving the above problems is a skin lifting cog thread manufacturing device for processing a part of the thread in a cog method so as to semi-permanently improve skin sagging and wrinkles, and a cog thread manufactured therefrom. Its purpose is to provide

In the present invention for achieving the above objects, the upper chamber 102 and the lower chamber 103 are partitioned inside the housing 101 of a certain box-shaped size, and the inside of the upper chamber 102 is in a flat form The transformation unit 100 including a structure in which transformation units for transformation are installed, and a control unit for controlling the transformation units installed in the upper compartment 102 is installed inside the lower chamber 103, and the transformation unit 100 In order to cog process the deformation chamber deformed from the device in a mold method, an upper chamber 202 and a lower chamber 203 are partitioned inside the housing 201 of a certain box-shaped size, and the inside of the upper chamber 202 is Cog units for punching the transformation chamber in a cog form are installed, while a control unit for controlling the cog units installed in the upper chamber 202 is installed inside the lower chamber 203. Including a structure A cog thread manufacturing system for skin surgery and procedures having a configuration including the cog device 200 is characterized as an example.

The transformation units include an unwinding roller 110 installed in a rotatable structure at one end of the upper chamber 102 and unwinding the wound yarn toward the other end of the upper chamber 102, and the unwinding roller 110 ) is installed at a position maintaining a predetermined width in the direction of the other end of the upper chamber 102 at the installation position, and the tension for the yarn unwound from the unwinding roller 110 is raised and lowered in the adjustment long hole 134 Tension control A first tension adjusting unit 130 that is primarily adjusted through a roll 136, a position maintaining a predetermined width in the direction of the other end of the upper chamber 102 from the installation position of the first tension adjusting unit 130 The deformation unit 140 is installed in the first tension adjusting unit 130 and transforms the primary tension-adjusted yarn into a flat shape through a rotating transformation roll 145 and a pressure roll 148 in contact with each other. ), installed at a position maintaining a predetermined width in the direction of the other end of the upper chamber 102 from the installation position of the deformable part 140, for the deformed chamber deformed into a flat form from the deformable part 140 A second tension control unit 150 that secondarily adjusts tension through a tension control roll 156 that is elevated in the control cabinet hole 154, and the upper chamber 102 at the installation position of the second tension control unit 150 ) Is installed in a rotatable structure at a position maintaining a predetermined width in the direction of the other end of the ), and is configured to include a winding roller 180 that winds the deformation thread. An example of the cog thread manufacturing system for skin surgery and procedure It has a characteristic.

Between the second tension adjusting unit 150 and the winding roller 180, according to the rotation of the horizontally disposed adjustment induction rod 174, the adjustment core 178 of the winding adjustment block 177 controls the adjustment. Skin further comprising a winding distribution control unit 170 that moves left or right on the induction rod 174 and controls the tension-controlled deformation thread from the second tension control unit 150 to be evenly wound around the winding roller 180 An exemplary feature is a cog thread manufacturing system for surgery and procedures.

The cog units are installed in a rotatable structure at one end of the upper chamber 202 and release the deformation chamber deformed from the transformation device 100 toward the other end of the upper chamber 202. 210), installed at a position maintaining a predetermined width in the direction of the other end of the upper chamber 202 from the installation position of the unwinding roller 210, adjusting the tension of the deformable chamber unwinding from the unwinding roller 210 The first tension adjusting unit 230, which is primarily adjusted through the tension adjusting roll 236 that is elevated in the long hole 234, and the other end of the upper chamber 202 at the installation position of the first tension adjusting unit 230 It is installed at a position maintaining a predetermined width in the direction, and the first tension-adjusted transformation chamber from the first tension adjusting unit 230 is first stopped by the stopper 246 that descends with the power of the cylinder 245 is installed at a position maintaining a predetermined width in the direction of the other end of the upper chamber 202 from the installation position of the first stop 240, the first stop 240 The upper chamber ( 202), which is installed at a position maintaining a predetermined width in the direction of the other end, and lowered toward the lower mold frames 261a to 261f by the power of the cylinders 269a to 269f Pressure punching of the upper mold frames 262a to 262f of the upper chamber 202 at the installation position of the mold part 260 consisting of the mold frame 261 for treating the deformation chamber as a cog chamber (CT) in the form of a cog through the It is installed at a position maintaining a predetermined width in the direction of the other end, and the stopper 273 lowers the cog chamber CT treated with cog from the mold part 260 by the power of the cylinder 272. A third stop 270 for stopping the car, and a position maintaining a predetermined width in the direction of the other end of the upper chamber 202 at the installation position of the third stop 270 An exemplary feature of the cog thread manufacturing system for skin surgery and procedures, which is installed in a rotatable structure and includes a winding roller 290 that winds a third stationary thread.

Between the third stop 270 and the take-up roller 290, the tension of the cog thread CT is adjusted through the tension control roll 285 that moves up and down in the control hole 284, and is arranged horizontally The cog thread ( A cog thread manufacturing system for skin surgery and procedures further including a tension control unit 280 that simultaneously winds the CT) evenly has a characteristic as an example.

As described above, according to the present invention, as the cog is automatically processed by punching a part of the yarn, the processing process is convenient and mass production is possible.

In addition, according to the present invention, through cog processing in which a part of the thread is punched out and completely separated from the thread, it is easy to insert the thread into the skin, and the thread inserted into the skin penetrates the skin through the cog. It has the effect of improving sagging and wrinkles that can last semi-permanently.

In addition, according to the present invention, after the yarn is deformed into a flat shape through compression of the deformation device, the yarn is processed into a cog shape through pressure punching of the cog device, so that the effective width of the yarn required for cog treatment can be expanded, , Accordingly, there is an effect of improving the efficiency of cog treatment of yarn and improving the quality of cog yarn.

1 is a three-dimensional perspective view showing the overall appearance of a cog thread manufacturing system for skin surgery and procedures according to an embodiment of the present invention.
FIG. 2 is a three-dimensional view showing transforming component units installed inside the upper chamber 102 of the housing 101 as the transforming device 100 shown in FIG. 1 .
FIG. 3 is an actual view showing components including the second tension adjusting unit 150, the guide bars 160 and 161, the winding distribution adjusting unit 170, and the winding roller 180 shown in FIG. 2 in more detail.
FIG. 4 is a real view showing configurations of the deformable unit 140 shown in FIG. 2 in more detail.
FIG. 5 is a three-dimensional view showing cog component units installed inside the upper chamber 202 of the housing 201 as the cog device 200 shown in FIG. 1 .
FIG. 6 is a three-dimensional view illustrating detailed components of the mold unit 260 shown in FIG. 5 .
FIG. 7 is a detail of the lower mold frame 261a and the upper mold frame 262a of the mold unit 260 shown in FIG. This is an actual drawing.
FIG. 8 is a three-dimensional view illustrating detailed components of the third stopper 270 shown in FIG. 5 .
FIG. 9 is a real object showing detailed components of the tension adjusting unit 280 configured in a vertical arrangement on the rear side of the direction changing rolls 277 and 278 shown in FIG. 5 and an arrangement structure for the take-up roller 290 it is a drawing
10 is a tension adjusting unit 280 shown in FIG. 9, including a rail R, a control bar 288, a slide bar 289, a control motor 289a, a winding roller 290, and a drive motor 291 It is a physical drawing showing the layout structure for .
FIG. 11 is a plan view conceptually illustrating a state in which the yarn T is cog-processed in the lower mold frames 261a to 261f of the mold unit 260 shown in FIG. 7 .
12 is a conceptual diagram of an example for grasping the speed of the descent of the upper mold frames 262a to 262f shown by processing the contents of the photographing information recorded by the speed control unit in blocks.
13 is a conceptual diagram presented per second, which is an example of determining the speed related to the descent of the upper mold frames 262a to 262f shown by processing the contents of the photographing information recorded by the speed control means in blocks.
14 is a view of a Cog Thread (CT) showing a structure of the Cog Thread (CT) in detail.

The present invention should be interpreted in a way that includes the scope of rights to the technical idea through various modified embodiments, but only the present embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to fully inform the holder of the scope of the invention, and the present invention is only defined by the scope of the claims.

Moreover, since the drawings attached to the present invention are attached as a way to aid understanding of the description of the present invention, the technical spirit of the present invention should not be construed as being limited by the attached drawings.

As shown in FIG. 1, the cog thread manufacturing system for skin surgery and procedure according to an embodiment of the present invention includes a deformation device 100 for transforming a thread into a flat shape, and a mold method for flattening the deformed thread. It can be configured as a cog device 200 for cogging.

The deformation device 100 may be composed of a housing 101 having a certain box-shaped size, such as a chamber, and the inside of the housing 101 may be divided into an upper chamber 102 and a lower chamber 103. A controller may be installed in the lower chamber 103 to control the transformation units installed and configured in the upper chamber 102 .

In addition to the housing 101 of a certain box-shaped size, such as the chamber of the deformation device 100, the housing 201 of a certain box-shaped size, such as the chamber of the cog device 200, dust or dust flows into the housing 201 It serves as a protective film to prevent the occurrence of deformation thread processing and cog thread processing through compression of the thread (T) inside the housing 101, 201, and to minimize the occurrence of defects in the quality of the cog thread being processed. It is for

In the deformation unit installed in the upper chamber 102, with reference to FIGS. 2 to 4, a release roller 110, guide bars 120 and 121, a first tension adjusting unit 130, a deformation unit 140, a first 2 tension control unit 150, guide bars 160 and 161, winding distribution control unit 170, winding roller 180 and emergency warning light 190 may be made of components.

The unwinding roller 110 may be installed on any one side of the upper chamber 102, and the winding roller 180 may be installed on any other side of the upper chamber 102. Between the unwinding roller 110 and the winding roller 180, the guide bars 120 and 121, the first tension adjusting unit 130, the transforming unit 140, the second tension adjusting unit 150, the The guide bars 160 and 161 and the winding distribution control unit 170 may be installed in a manner to maintain a constant interval.

The unwinding roller 110 may be installed horizontally in a rotatable structure for the purpose of unwinding the wound yarn, and the guide bars 120 and 121 are spaced apart from each other at a point maintaining a predetermined distance from the unwinding roller 110. It is installed vertically as a structure and can perform a function of guiding the thread unwound from the unwinding roller 110 within the track.

As the first tension adjusting unit 130 is vertically installed in a mutually spaced structure at a point where a predetermined distance is maintained from the guide bars 120 and 121, passing through the unwinding roller 110 and the guide bars 120 and 121 It can perform the function of adjusting the tension of the thread.

The first tension adjusting unit 130 may be composed of control tables 131, 132, and 133 vertically installed in a mutually spaced structure, and a guide roll 135 installed in a rotatable structure at the top of the control table 132 and the It may be configured to include a tension control roll 136 that rotates between the control tables 131 and 132 and moves up and down. The guide roll 135 serves to guide the thread passing through the guide bars 120 and 121 .

The control table 131, 132 may be formed in such a way that a control cabinet hole 134 passes along its length, and the tension control roll 136 is rotated and moved up and down in the control cabinet hole 134 penetrated in this way. At this time, the tension control roll 136 can adjust the tension of the thread passing through the guide bars 120 and 121 in a manner of being elevated and rotated.

The fact that the tension control roll 136 is lifted and the tension of the yarn can be adjusted may be based on signals transmitted from detection sensors installed at the upper and lower portions of the control tables 131 and 132. That is, the detection sensor may detect the tension of the thread exceeding a set threshold value, and based on the detected signal, the tension control roll 136 may be moved up and down to adjust the tension of the thread.

The transforming part 140 includes fixed bulkheads 141 and 142, fixed plates 143, springs 144, transforming rolls 145, home lines 145a, drive motors 146, elevating bulkheads 147a and 147b, pressurization It may consist of a configuration including a roll 148 and a cylinder 149.

The fixed bulkheads 141 and 142 may be vertically installed in a structure spaced apart from each other while maintaining a predetermined distance from the first tension adjusting part 130, and the fixed plate 143 is at one upper side of the fixed bulkheads 141 and 142. It may be installed in a structure coupled to, and the deformation roll 145 may be rotated between the fixed bulkheads 141 and 142 in a manner connected to the shaft of the driving motor 146. The deformation roll 145 forms a groove line 148 along its central surface.

Elevating partition walls 147a and 147b may be installed between the fixed partition walls 141 and 142, and the lifting partition walls 147a and 147b may be moved up and down by the power of the cylinder 149 and the deformation roll (145).

A pressure roll 148 may be installed in a rotatable structure between the elevating partition walls 147a and 147b installed between the fixed partition walls 141 and 142 in a structure capable of moving up and down. When the thread passing through the first tension adjusting unit 130 passes the groove line 145a of the deformable roll 145, it is rotated in such a way as to press the thread part partially protruding from the upper end of the groove line 145a while descending. .

Of course, when the yarn passes the groove line 145a of the deformable roll 145, the pressure roll 148, which presses the yarn at the upper end, moves down with the operation of the cylinder 149, the elevating bulkhead 147a, The yarn can be pressurized by the lowering operation of 147b).

As the yarn passing through the groove line 145a of the transformation roll 145 through the pressing operation of the pressure roll 148 is pressurized, its cross section can be transformed into a transformation yarn that is deformed into a shape similar to, for example, a square. The transforming chamber is deformed into a rectangular shape in which the horizontal length is longer than the vertical length, so that a horizontal length and width advantageous to mold processing in the cog device 200 can be secured in the future.

Of course, the transforming chamber deformed into a shape similar to a square in this way can be manufactured and produced as a cog chamber (CT) by cog-processing in the cog device 200 to be described later. It enters the second tension adjusting unit 150 installed at a predetermined spaced apart point.

The second tension adjusting unit 150 may also be composed of the same elements as the components of the first tension adjusting unit 130, but only marked with different signs, control tables 151, 152, 153, control cabinet holes ( 154), a guide roll 155, a tension control roll 156, and guide bars 160 and 161.

The second tension control unit 150 may be composed of control units 151, 152, and 153 installed vertically in a mutually spaced structure at a point maintaining a predetermined distance from the deformation unit 140, and the control unit 152 It may be composed of a configuration including a guide roll 155 installed in a rotatable structure at the top of and a tension control roll 156 that rotates and moves up and down between the control tables 151 and 152. The guide roll 155 serves to guide the deformation chamber passing through the guide bars 160 and 161 .

The control table 151, 152 may be formed in such a way that the control cabinet hole 154 passes along its length, and the tension control roll 156 is rotated and moved up and down in the control cabinet hole 154 penetrated in this way. At this time, the tension control roll 156 can adjust the tension of the transformation chamber passing through the guide bars 160 and 161 in a manner of being elevated and rotated.

The fact that the tension control roll 156 is moved up and down and the tension of the transformation chamber can be adjusted may be based on signals transmitted from detection sensors installed at upper and lower portions of the control tables 151 and 152. That is, the detection sensor can detect the tension of the transformation chamber exceeding a set threshold value, and based on the signal detected in this way, the tension control roll 156 is moved up and down to adjust the tension of the transformation chamber. can

The deformation chamber passing through the second tension adjusting unit 150 enters the winding distribution adjusting unit 170 installed at a predetermined distance from the second tension adjusting unit 150 .

The winding distribution control unit 170 may perform a function of adjusting the deformable yarn to be evenly wound around the winding roller 180 to be described later, and the winding distribution control unit 170 has a predetermined interval between them. The adjustment guide rod 174, which can be rotated by being inserted in a way to cross the fixed bulkheads 171, 172 and 173 while maintaining the fixed bulkhead 173, is coupled to the end of the fixed bulkhead 173 to control the rotation of the adjustable guide rod 174. A configuration including a driving motor 175 providing necessary power and a guide rod 176 inserted and fixed in a manner crossing the fixed bulkheads 171 and 172 at a point spaced downward from the adjusting induction rod 174. can be made with

Of course, the above winding distribution control unit 170 is inserted into the adjustment induction rod 174 and the guide rod 176 in the horizontal direction of one side and the other side according to the rotation of the adjustment induction rod 174. It may be moved and may further include a winding adjustment block 177 that evenly guides the winding thickness layer of the deformation chamber wound around the winding roller 180 to be described later, and the upper end of the winding adjustment block 177 is An adjustment core 178 in the form of a through hole 178a through which the transformation chamber passes is coupled.

A winding roller 180 may be installed in a horizontal structure and rotated at a predetermined distance from the winding distribution control unit 177, and the winding roller 180 is provided by a driving motor 181. It is possible to wind the transforming chamber with an even thickness by controlling the movement of the winding control block 177 while being rotated through the power provided.

In addition, an emergency warning light 190 may be installed at one corner where the winding distribution control unit 177 is installed, and this emergency warning light 190 prevents abnormal signs generated in the process of transforming the seal T into a deformation chamber. It can perform a functional purpose that can be quickly notified to the user. Of course, these abnormal signs are abnormalities in the tension of the thread, but the unwinding roller 110, the first tension adjusting unit 130, the deforming unit 140, the second tension adjusting unit 150, and the winding distribution adjusting unit 170 ), problems such as malfunction of the winding roller 180.

On the other hand, the cog device 200 is a device for manufacturing and producing a cog thread (CT) by performing mold processing through cog, that is, punching, for the deformation chamber changed to a flat shape in the above deformation device 100, FIGS. 5 to 5 10, it may be composed of a housing 201 of a certain box-shaped size, and the inside of the housing 201 may be divided into an upper chamber 202 and a lower chamber 203, and the lower chamber 203 ) may be provided with a control unit for controlling the cog units installed in the upper chamber 202.

In the cog unit installed in the upper chamber 202, a release roller 210, guide bars 220 and 221, a first tension adjusting unit 230, a first stop unit 240, a second stop unit 250, It may be composed of components including a mold unit 260, a third stop unit 270, a tension control unit 280, a winding roller 290, and an emergency warning light.

The unwinding roller 210 may be installed on any one side of the upper chamber 202, and the winding roller 290 may be installed on any other side of the upper chamber 202. Between the unwinding roller 210 and the winding roller 290, the guide bars 220 and 221, the first tension adjusting part 230, the first stop part 240, the second stop part 250, the mold The unit 260, the third stop unit 270, and the tension control unit 280 may be installed in a manner to maintain regular intervals.

The unwinding roller 210 is used for unwinding the wound deformation chamber and can be installed horizontally in a rotatable structure, and the guide bars 220 and 221 are mutually connected at a point maintaining a predetermined distance from the unwinding roller 210. It is installed vertically in a spaced structure and can perform a function of guiding the transformation chamber unwinding from the unwinding roller 210 within the track.

As the first tension adjusting part 230 is vertically installed in a mutually spaced structure at a point where a predetermined distance is maintained from the guide bars 220 and 221, the unwinding roller 210 and the guide bars 220 and 221 pass through. It may perform a function of adjusting the tension of the transformation chamber.

The first tension adjusting unit 230 may be composed of control tables 231, 232, and 233 vertically installed in a mutually spaced structure, and a guide roll 235 installed in a rotatable structure at the top of the control table 232 and the It may be configured to include a tension control roll 236 that is rotated and moved between the control tables 231 and 232. The guide roll 235 serves to guide the transformation chamber passing through the guide bars 220 and 221 .

The adjustment table 231 and 232 may be formed in such a way that an adjustment cabinet hole 234 passes along its length, and the tension control roll 236 is rotated and moved up and down in the adjustment cabinet hole 234 penetrated in this way. At this time, the tension control roll 236 can adjust the tension of the transformation chamber passing through the guide bars 220 and 221 in a manner of being elevated and rotated.

The fact that the tension control roll 236 is moved up and down and the tension of the transformation chamber can be adjusted may be based on signals transmitted from detection sensors installed on the top and bottom of the control tables 231 and 232. That is, the detection sensor can detect the tension of the transformation chamber exceeding a set threshold value, and based on the signal detected in this way, the tension control roll 236 is moved up and down to adjust the tension of the transformation chamber. can

The first stopper 240 configured at a predetermined distance from the first tension control unit 230 includes a front guide roll 242 installed in a rotatable structure on the front side of the block plate 241, and the block plate ( 241), the rear guide roll 243 installed in a rotatable structure, the stop support tip 244 configured between the front guide roll and the rear guide roll, and the stop support tip at the top of the stop support tip It may be composed of a configuration including a stopper 246 that is elevated in the direction and a cylinder 245 that provides power necessary for the elevation of the stopper.

The front guide roll 242 and the rear guide roll 243 may perform a function of guiding the deformation chamber that has passed through the first tension adjusting unit 230, and the stop support tip 244 The stopper 246 descending to the top may temporarily hold the deformation chamber according to the deformation chamber punching operation in the mold unit 260 to be described later. That is, the stopper 246 can temporarily stop the movement of the transformation chamber primarily by descending from the upper end of the transformation chamber through the power of the cylinder 245 .

The second stopper 250 configured at a predetermined distance from the first stopper 240 has a front side installed in a rotatable structure at the front side of the slide control plate 250a, the block plate 251, and the block plate 251. A guide roll 252, a rear guide roll 254 installed in a rotatable structure at the rear of the block plate 251, a stop support tip 255 configured between the front guide roll and the rear guide roll, It may be configured to include a stopper 256 that is elevated in the direction of the stop support tip from an upper portion of the stop support tip and a cylinder 257 that provides power necessary for the stopper to move up and down.

The front guide roll 252 and the rear guide roll 254 may perform a function of guiding the deformation chamber through the first stop 240, and to the top of the stop support tip 255 The descending stopper 256 may perform a holding function of a deformation chamber to be cogged by a punching process in the mold unit 260 to be described later. That is, the movement of the transformation chamber can be temporarily stopped secondarily in such a way that the stopper 256 descends to the upper end of the transformation chamber through the power of the cylinder 257 .

Of course, the second stop part 250 may also include a tension control roll (unsigned), a cylinder (unsigned) and an adjustment stop screw (unsigned), and the tension control roll is the front guide described above. The tension of the transformation chamber can be adjusted in a way that it is raised and lowered between the roll 252 and the rear guide roll 254 through the power provided from the cylinder, and the adjustment stop screw bites the guide rail (not marked). It can perform a function of maintaining a fixed state according to the slide movement control of the slide control plate 250a.

That is, the adjustment stop screw inserted in a rotatable structure on either side of the slide control plate 250a is inserted through holes (not marked) formed in the guide rail after adjusting the slide movement of the slide control plate 250a. The slide control plate 250a may be fixed by being inserted in a rotational manner toward one of the insertion holes.

Meanwhile, the mold part 260 configured at a predetermined distance from the second stop part 250 has a multi-stage plate structure of a base plate 260a, an intermediate plate 260b, and a top plate 260c. ) and a structure in which cylinders 269 are installed.

That is, the base plate 260a may be installed in a manner in which lower mold frames 261a to 261f and upper mold molds 262a to 262f are configured as the mold mold 261, and the top plate ( 260c) may be installed in a manner in which, for example, six cylinders 269a to 269f are configured as the above cylinders 269. In addition, individual pistons of the cylinders 269a to 269f may be arranged in a vertical manner on the intermediate plate 260b.

In particular, the mold mold 261 may be composed of lower mold molds 261a to 261f and upper mold molds 262a to 262f, and the lower mold molds 261a to 261f are the base plate 260a. ), and the upper mold frames 262a to 262f may be installed in such a way that a vertical lifting operation is possible on the lower mold frames 261a to 261f.

In addition, when the upper mold frames 262a to 262f are moved up and down on the lower mold frames 261a to 261f, for example, two mold processing guards 263 and 264 are placed inside the lower mold frames 261a to 261f. It can be raised and lowered in such a way that it is inserted toward, and the above-described mold processing guards 263 and 264 have a structure facing each other, and a vertical structural mold furnace 265 can be formed in which a transformation room can be inserted therebetween. there is.

Of course, mold grooves MF of a punching processing structure having a cog shape may be formed at the center of each upper end of the lower mold frames 261a to 261f, although they are hidden by the mold processing guards 263 and 264, and the upper mold Mold protrusions MB having a cog-shaped punching structure may be formed at the center of individual bottom surfaces of the frames 262a to 262f, although they are hidden by the mold processing guards 263 and 264.

Therefore, when the upper mold frames 262a to 262f descend toward the lower mold molds 261a to 261f through the power provided from the cylinders 269a to 269f, the mold processing guards 263 and 264 operate on the lower mold mold. It can enter the inside of the molds 261a to 261f, and the deformation chamber inserted into the mold furnace 265 between the mold processing guards 263 and 264 is located on the upper mold mold groove MF of the cog-shaped punching structure. Cog can be processed through the mold protrusions MB of the pressure punching structure according to the descent of the molds 262a to 262f.

Of course, at this time, the mold processing guards 263 and 264 can play a functional role of protecting the cog processing of the deformation chamber so that the cog processing of the deformation chamber is not disturbed by external factors, and the mold projections MB of the pressure punching projection structure It is accommodated in a way that is pressed toward the mold grooves MF of the cog-shaped groove structure, and the cog treatment for the transformation chamber can be performed.

The mold protrusions MB and the mold grooves MF may be formed in a cog shape, and the mold protrusions MB and the mold grooves MF have a specific cog shape. It is not limited, and various forms capable of enhancing the skin lifting effect may all be included.

These mold protrusions (MB) are inserted into the mold grooves (MF) by punching both sides of the deformation chamber reaching the mold furnace 265 in the process of descending, and the cog for both sides of the deformation chamber (Cog) can be formed, and the cog thread (CT: Cog Thread) formed with cogs on both sides in this way can cause sagging skin or wrinkles due to effective skin snag in the cog area while injected into the skin. Not only the lifting effect of the skin can be enhanced, but also the lifting can be maintained.

In particular, the upper mold frames 262a to 262f may be moved up and down by power provided from cylinders 269a to 269f installed on the upper surfaces thereof, and the cylinders 269a to 269f may be moved up and down by means of pneumatic or hydraulic pressure. Various types of cylinders that can be classified according to fluids can be used, and these cylinders can be employed differently depending on the purpose and conditions of use.

On the other hand, the unwinding roller 210, which is used to unwind the deformable thread for cog processing, is a driven rotating body that passively rotates through the pulling force from the take-up roller 1120 and unwinds the thread (T). The winding roller 290 may be a main rotating body for unwinding and winding the deformation chamber from the unwinding roller 210, and the rotational power of the winding roller 290 may be provided from the driving motor 291 .

In particular, the rotational speed of the driving motor 291 can be adjusted according to the lifting speed of the upper mold frames 262a to 262f that are lifted through the lifting power provided from the cylinders 269a to 269f, The fact that the rotational speed of the drive motor 291 can be adjusted is based on data information obtained from the speed control means (unsigned).

As the speed control means, it is preferable to use a multi-flash device. The multi-flash device is used to take a still picture of an object's motion, such as a falling motion or constant speed motion, or to measure the speed of an object. It can be divided into integrated type and separate type.

That is, the multi-flash light device is a device for visualizing a stopped position of a fast-moving object and measuring a moving and rotating speed, and may be configured in such a way that a timer is connected to the flash lamp.

Therefore, the multi-flash device collects photographing information, which is data information recorded by photographing the ascending and descending conditions of the upper mold frames 262a to 262f over a certain period of time. The upper mold frames 262a to 262f recorded along the elevating distance section of the upper mold frames 262a to 262f at regular time intervals, like the principle of a time recorder that grasps the change in the moving speed of the paper tape by analyzing the dots that are stamped. It is possible to grasp the lifting speed of the upper mold frames 262a to 262f through the video related to the lifting operation.

In other words, through the elevation images of the upper mold frames 262a to 262f taken along the lifting distance section at regular time intervals, the lifting speed of the upper mold frames 262a to 262f can be grasped. For example, in the elevation image, the wider the video section of the upper mold frames 262a to 262f, the higher the lifting speed of the upper mold frames 262a to 262f. The narrower the moving image section is, the slower the lifting speed of the upper mold frames 262a to 262f is.

Therefore, the photographing information recorded by the multi-flash device is analyzed by the control unit installed in the PCB substrate structure installed in the lower chamber 203 of the housing 201 to determine the lifting speed of the upper mold frames 262a to 262f. be able to

When the lifting speed of the upper mold frames 262a to 262f is grasped, the control unit instructs to adjust the motor shaft rotation speed of the driving motor 291, and the winding roller connected to the motor shaft of the driving motor 291 ( 290) rotates according to the lifting speed of the upper mold frames 262a to 262f while winding the cog processed cog thread (CT). When instructing the adjustment of the motor shaft rotation speed of the drive motor 291, the control unit may instruct adjustment of the motor shaft rotation speed through a beacon installed in the control unit.

That is, since the driving motor 291 can be rotated according to the lifting speed of the upper mold frames 262a to 262f by the multi-flash device, the winding roller connected to the motor shaft of the driving motor 291 ( 290) may be rotated in a manner that tracks the transmission signal of the beacon installed in the controller and follows the lifting speed of the upper mold frames 262a to 262f.

Of course, at this time, a separate wireless terminal capable of tracking the transmission signal of the beacon installed in the control unit may be installed in the driving motor 291 . Therefore, the winding roller 290 is cog-processed cog thread (CT: Cog Thread) in such a way that the rotational speed of the drive motor 291 is controlled according to the lifting speed of the upper mold frames 262a to 262f. can be wound in an appropriate rotation method.

In this way, due to the use of the multi-flash device of the speed control means, the winding roller 290 winds the Cog Thread (CT) according to the lifting speed of the upper mold frames 262a to 262f, and thus the winding roller 290 It is possible to prevent the breakage of the Cog Thread (CT) due to the unexpected pulling force of the (290).

The above photographing information is used as judgment data for analyzing the average speed of the upper mold frame 262a to 262f through the control unit, for example, in the direction of the upward movement of the upper mold frame 262a to 262f. When the interval between the lifting movements of the upper mold frames 262a to 262f is widened, it can be determined that the lifting speed of the upper mold frames 262a to 262f is increasing, and the lifting and lowering of the upper mold frames 262a to 262f If the interval between movements is constant, it can be determined that the lifting speed of the upper mold frames 262a to 262f is constant. ~ 262f) can be determined that the ascending and descending speed is decreasing.

The control unit analyzes the average lifting speed of the upper mold frames 262a to 262f by analyzing the interval between the lifting and lowering movements of the upper mold frames 262a to 262f, and determines the lifting speed of the upper mold frames 262a to 262f. The winding of the Cog Thread (CT) can be continued with a constant tension while matching the winding rotational speed of the winding roller 290, and the winding of the Cog Thread (CT) through this constant tension can be maintained. By maintaining the winding, a breakage phenomenon of a cog thread (CT) that may occur due to excessive pulling force of the winding roller 290 may be prevented.

Of course, to explain the average lifting speed of the upper mold frames 262a to 262f as an example, reference can be made to FIGS. 12 and 13, and the first lifting movement section of the mold plate 1211 (a ) to the total section distance (ad) from the middle section (a) through the middle section (b and c) to the last section (d), the total section distance ( The average speed can be calculated by dividing by the value of the time taken to reach ad) (T).

In the case of 'A' shown in FIG. 12, when the images taken of the upper mold frames 262a to 262f are analyzed in the lifting direction, the interval between the pictures a, b, c, and d of the upper mold frames 262a to 262f It can be seen that this gradually widens, and it can be seen that the lifting speed of the upper mold frames 262a to 262f is gradually increasing.

On the other hand, in the case of 'I', when the images taken of the upper mold frames 262a to 262f are analyzed in the lifting direction, the interval between the pictures a, b, c, and d of the upper mold frames 262a to 262f is constant. It can be identified that, it can be seen that the lifting speed of the upper mold frame (262a ~ 262f) is constantly progressing.

On the other hand, in the case of 'C', when the images taken of the upper mold frames 262a to 262f are analyzed in the lifting direction, the interval between the pictures a, b, c, and d of the upper mold frames 262a to 262f gradually increases. It can be seen that it is getting narrower, and it can be seen that the lifting speed of the upper mold frames 262a to 262f is gradually slowing down.

In addition, as shown in FIG. 13, the average speed of the upper mold frames 262a to 262f may take, for example, 1 second for one lifting movement interval of the upper mold frames 262a to 262f. The time taken may be 3 seconds. Therefore, the average lifting speed of the upper mold frames 262a to 262f can be calculated as 30 cm/s by 90/3 seconds as a derived value of the distance/time taken.

In this way, it is possible to determine the lifting speed of the mold plate 1211 by analyzing the section of the ascending and descending pictures of the upper mold frames 262a to 262f taken in the image, and the lifting speed of the upper mold molds 262a to 262f can be determined by the displacement / jammed Not only can it be calculated by time, but also the average lifting speed of the upper mold frames 262a to 262f can be calculated, and this calculation method can be calculated by the control unit based on the photographing information, and the control unit can, for example, calculate the PCB It may be configured as a microcomputer of a substrate structure, but it is not necessary to be limited thereto.

On the other hand, the third stop portion 270 configured at a predetermined distance from the mold portion 260 is a block piece 271 installed in a structure engaged with the guide rail, and a cylinder 272 fixed to the block piece 271 , A stopper 273 lifted by the power of the cylinder 272, a fixing block 274 fixedly installed on one side adjacent to the rear of the block piece 271, and a guide installed in a rotatable manner on one side of the fixing block 274 It may be configured with a structure including a roll 275 and an inspection device 276 fixedly installed at a vertical upper point of the guide roll 275.

The stopper 273 can temporarily hold the cog seal (CT) three times while descending through the power of the cylinder 272, which is fixed to the vertical upper point of the guide roll 275. ) is necessary for the process of checking whether the cog treatment for the cog room (CT) is properly performed.

That is, the inspector 276 may be, for example, an electron microscope, and the cog shape processing state applied to the cog chamber CT can be properly checked through the electron microscope. If the cog shape processing for the cog chamber CT is not performed properly, this may result in a defect.

The cog thread (CT) that has passed through the inspection device 276 changes direction from the horizontal direction to the vertical downward direction through the direction changing rolls 277 and 278 installed at a predetermined distance from the third stop part 270. achieve and move

The cog thread (CT) whose direction has been changed in this way is adjusted in the tension control unit 280 installed at a predetermined distance from the direction change rolls 277 and 278, and also in the take-up roller 290 to be described later. Even winding distribution can be evenly adjusted.

The above-described tension adjusting unit 280 includes control tables 281, 282, and 283, control hole 284, tension control roll 285, guide rolls 286 and 287, rail R, control bar 288, and control plate. 289 and a control motor 289a. The control tables 281, 282, and 283 maintain a predetermined width distance from each other and are fixedly installed in a structure perpendicular to the other side of the upper chamber 101a. has been

Of course, predetermined control cabinet holes 284 may be formed in the lengthwise direction of the control tables 281, 282, and 283, and the shafts of the tension control rolls 285 are inserted into these control cabinet holes 284. The tension control roll 285 is rotated in such a way that it is raised and lowered by the length of the control hole 284, and the tension of the cog thread CT can be adjusted.

Since the operations of the deformation device 100 and the cog device 200 are identical in some sections, the operation of the deformation device 100 will be omitted and only the operation of the cog device 200 will be briefly described.

After passing through the guide bars 220 and 221 while the deformation chamber deformed from the deformation device 100 is released through the release roller 210 configured in the upper chamber 202 of the housing 201 of the cog device 200, the first tension After the primary tension is adjusted by the adjusting unit 230, it passes through the first stop unit 240 and the second stop unit 250, is stopped for a predetermined time, and then enters the mold unit 260.

As this transformation chamber enters the inside of the mold furnace 265 located at the center of the top, the upper mold frames 262a to 262f located at the top are moved through the mold furnace 265 through the power provided from the cylinders 269a to 269f. While descending toward , the mold protrusions (MB) punch both sides of the deformation chamber, are inserted into the mold grooves (MF) of the lower mold frames (261a to 261f), and then rise again to the original position.

At this time, both sides of the deformation chamber may be punched through the mold protrusions (MB) and processed into a cog shape, and the cog thread (CT: Cog Thread) processed into a cog shape in this way is a third stop portion 270 ) and the tension adjusting unit 280 to wind the winding roller 290, the cog processing may be completed.

Of course, when the transformation chamber arrives at and is located in the mold furnace 265, the limit switch installed around the mold furnace 265 detects this and drives the drive motor 291 for rotating the winding roller 290. It is possible to secure the time required for cog processing in the transformation chamber by stopping the movement of the transformation chamber by stopping the driving.

In addition, the limit switch installed around the mold furnace 265 detects that the deformation chamber arrives at the mold furnace 265, and the cylinder 269a provides power necessary for lifting the upper mold frames 262a to 262f. The upper mold frames 262a to 262f may be lowered by applying an electrical signal to the to 269f.

In addition, the internal temperature of the housing 201 should be maintained at a constant temperature, because cog processing of the temperature-sensitive transformation chamber is performed inside the upper chamber 202 . Therefore, since the inside of the upper chamber 202 must always be maintained at a constant room temperature temperature range, regardless of the winter season, summer season, and spring season, although drawings and symbols are not marked, a separate Temperature control units may be configured.

These temperature control units may be composed of, for example, a temperature sensor, a micom, a cooler, and a heater, and the temperature sensor senses the internal temperature of the upper chamber 202 so that it can always be maintained in the room temperature range.

According to the temperature detection information inside the upper chamber 202 sensed by the temperature sensor, the micom is capable of maintaining the internal temperature of the upper chamber 202 within the normal temperature range, providing an operation signal required for driving the cooler or heater and stopping the driving. It transmits the operation stop signal required for cooling to the cooler or heater.

The cooler lowers the internal temperature of the upper chamber 202 so that the internal temperature of the upper chamber 202 can be adjusted to the room temperature range while being driven based on the operation signal provided from the microcomputer.

The heater increases the internal temperature of the upper chamber 202 so that the internal temperature of the upper chamber 202 can be adjusted to the room temperature range while being driven based on the operation signal provided from the microcomputer.

The driving of the cooler or the driving of the heater may be automatically stopped when the internal temperature of the upper chamber 202 is set to the room temperature range, which means that the internal temperature of the upper chamber 202 eventually When the temperature is lower or higher than the normal temperature range through the driving of the heater, the temperature sensor detects this and provides an operation stop signal necessary for stopping the operation of the cooler or the heater to the cooler or the heater.

On the other hand, in the process of cog processing of the transformation chamber, the cog angle of the cog thread (CT: Cog Thread) may be formed differently according to the morphological structure of the mold groove (MF) and mold protrusion (MB), For example, when the shape of the mold groove MF and the mold protrusion MB is, for example, a parallelogram, a cog angle of a cog thread (CT) may also be molded in a shape inclined at a specific angle.

Of course, the shape of the mold groove (MF) and the mold protrusion (MB) is not limited to a parallelogram, but may be formed of, for example, a quadrangle or a higher polygon or a lower angle. Depending on the inclination difference, the cog angle of the cog thread (CT) may be variously modified.

The cog angle of the cog thread (CT: Cog Thread) may be modified, for example, to an angle ranging from 30 ° to 90 °, and various modifications to the cog angle of the cog thread (CT: Cog Thread) The shape of the mold groove (MF) and mold protrusions (MB) can also be configured in various ways, and will be composed of a detachable structure that can be separated from the lower mold frames 261a to 261f and the upper mold frames 262a to 262f. can

Transformation device (100)
Housing (101) Upper chamber (102) Lower chamber (103)
Unwinding roller (110) Guide bar (120,121)
First tension adjusting unit 130, adjusting table 131, 132, 133, adjusting cabinet hole 134
Guide roll (135) Tension control roll (136)
Deformable part (140) Fixed bulkhead (141,142) Fixed plate (143)
Spring (144) Deformation roll (145) Home line (145a)
Drive motor 146, elevating bulkheads 147a, 147b, pressure roll 148
Cylinder(149)
Second tension adjusting unit 150, adjusting table 151, 152, 153, adjusting cabinet hole 154
Guide roll (155) Tension control roll (156)
Guide bar(160,161)
Winding distribution control unit (170) Fixed bulkhead (171,172,173) Control guide bar (174)
Driving motor (175) guide bar (176)
Winding control block (177) control core (178) through hole (178a)
Winding roller (180)
Emergency Warning Light (190)
Cog device (200) Cog thread (CT)
Housing (201) Upper chamber (202) Lower chamber (203)
Unwinding roller (210) Guide bar (220,221)
First tension adjusting unit 230, control table 231,232,233 control cabinet hole 234
Guide roll (235) Tension control roll (236)
First stop 240 Block plate 241 Front guide roll 242
Rear guide roll (243) Stop support tip (244) Cylinder (245)
Stopper(246)
Second stop (250) Slide control plate (250a) Block plate (251)
Front guide roll (252) Tension control roll (253) Rear guide roll (254)
Stop Support Tip(255) Stopper(256) Cylinder(257)
Mold part 260 Base plate 260a Mold frame 261
Lower mold frame (261a ~ 261f) Upper mold frame (262a ~ 262f) Middle plate (260b)
Top plate (260c)
Mold processing guard (263,264) Mold furnace (265)
Cogro (CR) Mold Groove (MF) Mold Protrusion (MB)
Cylinder 269 Cylinders 269a to 269f
Third stop (270) Block piece (271) Cylinder (272)
Stopper (273) Fixed block (274) Guide roll (275)
Inspector(276) Direction changing roll(277)(278)
Tension control part (280) Control table (281,282,283) Control cabinet hole (284)
Tension control roll (285) Guide roll (286) (287) Rail (R)
Control rod (288) Slide bar (289) Control motor (289a)
Winding roller (290) drive motor (291)

Claims (5)

An upper chamber 102 and a lower chamber 103 are partitioned inside the housing 101 of a certain box-shaped size, and transformation units for transforming the yarn into a flat shape are installed inside the upper chamber 102, while the Inside the lower chamber 103, a transforming device 100 including a structure in which a control unit for controlling the transforming units installed in the upper chamber 102 is installed; and
In order to cog-process the deformation chamber deformed from the deformation device by a mold method, an upper chamber 202 and a lower chamber 203 are partitioned inside the housing 201 of a certain box-shaped size, and the inside of the upper chamber 202 On the other hand, cog units for punching the transformation chamber in a cog form are installed, while inside the lower chamber 203, a control unit for controlling the cog units installed in the upper chamber 202 is installed. A cog device 200 comprising;
Cog thread manufacturing system for skin surgery and procedures, characterized in that consisting of a configuration comprising a. According to claim 1,
The transformation units include: an unwinding roller 110 installed in a rotatable structure at one end of the upper chamber 102 and unwinding the wound yarn toward the other end of the upper chamber 102;
It is installed at a position maintaining a predetermined width in the direction of the other end of the upper chamber 102 from the installation position of the unwinding roller 110, and the tension of the thread unwound from the unwinding roller 110 is controlled through the adjusting device hole 134 A first tension control unit 130 for primary control through the tension control roll 136 that is elevated in the;
It is installed at a position maintaining a predetermined width in the direction of the other end of the upper chamber 102 from the installation position of the first tension adjusting unit 130, and the primary tension is adjusted from the first tension adjusting unit 130 a transforming unit 140 that transforms the yarn into a flat shape through a transforming roll 145 and a pressure roll 148 rotating in contact with each other;
It is installed at a position maintaining a predetermined width in the direction of the other end of the upper chamber 102 from the installation position of the deformable part 140, and the tension for the deformable chamber deformed into a flat form from the deformable part 140 A second tension adjusting unit 150 that performs secondary adjustment through the tension adjusting roll 156 that is elevated in the adjusting cabinet hole 154; and
a winding roller 180 installed in a rotatable structure at a position maintaining a predetermined width in the direction of the other end of the upper chamber 102 from the installation position of the second tension adjusting unit 150 and winding the deformation chamber;
Cog thread manufacturing system for skin surgery and procedures, characterized in that consisting of a configuration comprising a. According to claim 2,
Between the second tension adjusting unit 150 and the winding roller 180, according to the rotation of the horizontally disposed adjustment induction rod 174, the adjustment core 178 of the winding adjustment block 177 controls the adjustment. Further comprising a winding distribution control unit 170 that moves left or right on the induction rod 174 and adjusts the tension-adjusted transformation chamber from the second tension control unit 150 to be evenly wound around the take-up roller 180 Characterized by a cog thread manufacturing system for skin surgery and procedures. According to claim 1,
The cog units are installed in a rotatable structure at one end of the upper chamber 202 and release the deformation chamber deformed from the transformation device 100 toward the other end of the upper chamber 202. 210);
It is installed at a position where a predetermined width is maintained in the direction of the other end of the upper chamber 202 from the installation position of the unwinding roller 210, and the tension for the deformable chamber unwinding from the unwinding roller 210 is controlled through the adjusting device hole 234. ) A first tension control unit 230 for primary control through the tension control roll 236 that is raised and lowered;
It is installed at a position maintaining a predetermined width in the direction of the other end of the upper chamber 202 from the installation position of the first tension adjusting unit 230, and the primary tension is adjusted from the first tension adjusting unit 230 A first stopper 240 for first stopping the transformation chamber by the stopper 246 that descends with the power of the cylinder 245;
It is installed at a position maintaining a predetermined width in the direction of the other end of the upper chamber 202 from the installation position of the first stop part 240, and the deformable chamber stopped from the first stop part 240 is a cylinder ( A second stop 250 that is secondarily stopped by the stopper 256 descending with the power of 255;
It is installed at a position maintaining a predetermined width in the direction of the other end of the upper chamber 202 from the installation position of the second stop 250, and the lower mold frames 261a to 261f are formed by the power of the cylinders 269a to 269f. A mold unit 260 composed of a mold mold 261 that processes the deformation chamber into a cog-type cog chamber (CT) through pressure punching of the upper mold frames 262a to 262f descending toward the upper mold dies 262a to 262f; and
A cog seal (CT) installed at a position maintaining a predetermined width in the direction of the other end of the upper chamber 202 from the installation position of the mold part 260 and treated with cog from the mold part 260 A third stopper 270 for third stop by the stopper 273 descending with the power of the cylinder 272; and
A winding roller 290 installed in a rotatable structure at a position maintaining a predetermined width from the installation position of the third stopper 270 toward the other end of the upper chamber 202 to wind the third stopped yarn. );
Cog thread manufacturing system for skin surgery and procedures, characterized in that consisting of a configuration comprising a. According to claim 4,
Between the third stop 270 and the take-up roller 290, the tension of the cog thread CT is adjusted through the tension control roll 285 that moves up and down in the control hole 284, and is arranged horizontally The cog thread ( Cog thread manufacturing system for skin surgery and procedure, characterized in that it further comprises a tension control unit 280 that parallelly winds the CT).

Images