KR20230026159A - Mask strap adsorption disc device for mask manufacture - Google Patents

Abstract

The present invention relates to a mask string adsorption disk device, wherein a mask string used for a mask is automatically supplied to enable the mask string to be thermally fused to a mask body and the supplied mask string can be automatically cut to allow the mask string to be thermally fused to the mask body, thereby allowing a mask to be manufactured. The mask string adsorption disk device of the present invention comprises: a disk unit disposed on a support frame and supplied with the mask string cut by predetermined length; a feeding transfer unit feeding the mask body supplied to pass through the lower end portion of the disk unit; and a thermal fusion unit thermally fusing both ends of the mask string respectively to both end portions of the mask body when the mask body seated on the feeding transfer unit is located in the center in a lower part of the disk unit.

Description

Mask strap adsorption disc device for mask manufacture {Mask strap adsorption disc device for mask manufacture}

The present invention relates to a mask strap adsorption disk device for manufacturing a mask, and is used in industrial sites such as factories, quarantine masks for individual quarantine due to the spread of viral diseases such as covid 19 or the spread of fine dust, etc. Mask straps are automatically supplied so that the mask straps used for working masks can be heat-sealed to the mask body, and at the same time, the supplied mask straps are automatically cut to heat-seal the mask body and the mask straps. Mask strap adsorption for mask manufacturing It's about disk devices.

A health mask or a quarantine mask serves to block fine substances in the air and prevent them from entering a person's respiratory tract. For example, a health mask or a protective mask can be used to prevent workers from inhaling such harmful substances when breathing at a work site where the concentration of dust or volatile organic solvents in the air is high.

In addition, it is also used by medical staff performing quarantine beds or close-up procedures to prevent infection by bacteria or viruses. In addition to use in such a special environment, as air pollution such as yellow dust or fine dust has recently emerged as a serious problem, the frequency of use of health masks or quarantine masks by the general public is significantly increasing.

In particular, it is absolutely necessary to wear a health mask or quarantine mask in a situation where infections and deaths continue to occur due to new viruses without vaccines such as Covid 19, which has recently spread worldwide.

In this way, even if the damage caused by the spread of Covid-19 continues and the serious situation that is prevalent worldwide and vaccine development is made, it will inevitably take a considerable period of time for vaccination to be generalized.

Therefore, the production and consumption of masks is expected to continue to increase in the future, and even if the scale of damage is gradually reduced due to the success of Covid-19 quarantine and the spread of vaccine administration, wearing masks is already a daily life. Considering that it is becoming a daily routine, it is expected that the wearing culture or wearing habits of masks will not change easily.

In addition, even when considering the situation in which air pollution such as fine dust is becoming more serious day by day, it is safe to say that the wearing of a quarantine mask or a health mask is becoming a part of life.

In this way, although the consumption of masks is rapidly increasing, the process of producing masks is often produced in a semi-automatic form, so the production cost is not low, so the price of masks recognized as a necessity cannot be lowered.

In particular, the connection between the mask body and the mask strap is joined through a method by thermal fusion. After the transfer of the main body supplied from the main body supply unit is stopped by the strap supplied by the strap supply unit, the mask body and the mask strap are thermally fused and then fed again. A series of processes are repeated, and the process of connecting the mask string and the mask body is going through.

At this time, since the feeding process must be completely stopped during the thermal fusion process between the main body and the strap, there is a problem that productivity cannot be increased. If the feeding process is continuously performed during thermal fusion between the main body and the strap, There is a problem in that the string and the string are not properly fused or the string is thermally fused to the main body at the wrong location due to the fact that the feeding is performed in a state where the heat fusion means has not completely heat fused the string and the main body.

Domestic Patent Registration No. 10-0214786 (Announced on August 26, 2020) Domestic Patent Registration No. 10-0783311 (Announced on December 10, 2007)

Therefore, the present invention has been devised to solve the above problems, and in the process of heat-sealing while supplying the mask string to the mask body, the mask string is automatically supplied and automatically cut at a certain length, as well as continuously supplied from the bottom When heat-sealing the mask straps on both sides of the mask body, as in the past, when the supplied mask straps are heat-sealed after feeding the mask body to a certain length, it is in a stopped state to solve the problem of poor workability. There is a purpose.

In addition, the present invention is configured to automatically supply the mask strap, but when it is supplied over a certain length, it is automatically cut, and then placed to the mask body in a state in which the cut mask strap having a predetermined length is adsorbed, and then heat-sealed. Mask strap Another purpose is to maximize work efficiency by allowing the supply, cutting, and thermal fusion of the process to be performed repeatedly through one process.

The present invention for achieving the above object,

expectation;

a disk unit provided on the base;

a feeding transfer unit feeding the mask body supplied to pass through the lower end of the disk unit;

a thermal fusion unit for heat-sealing both ends of the mask strap and both ends of the mask body when the mask body seated in the feeding transfer unit is located at the lower center of the disk unit;

It provides a mask strap adsorption disk device for manufacturing a mask comprising a.

According to the present invention, in the process of heat-sealing while supplying the mask strap to the mask body, the mask strap is automatically supplied and automatically cut at a certain length, and then the disk rotates while the automatically cut mask strap is adsorbed by air pressure. It is moved downward along the plate so that it is thermally fused with both ends of the mask body supplied to the lower side of the disk, so that the mask body and the thermal fusion part are heat-sealed even when the supplied mask strap is thermally fused after feeding the mask body to a certain length. It moves simultaneously at a low speed, but returns to its original state after being heat-sealed so that heat-sealing of other mask main bodies and mask straps supplied from the rear is repeated, thereby improving workability and significantly reducing the rate of defects generated during heat-sealing. possible effects can be expected.

1 is a view schematically showing the overall structure of the present invention
Figure 2 is a general view showing only the main part of the present invention as a whole
Figure 3 is a schematic view separately showing only the feeding transfer part and the thermal fusion part in the present invention
Figure 4 is a view schematically showing the coupling relationship between the string supply unit applied to the present invention and the cutting unit formed on the front side thereof
Figure 5 is a schematic view showing a state viewed from the angle of the front side of Figure 4
6 to 7 are views showing only the cutting part applied to the present invention in isolation
8 is an overall general view showing only the disc unit applied to the present invention in isolation;
9 is a view showing a state in which the string adsorption disk portion is separated from the disk portion of FIG. 8
10 is a view showing a state in which the flow path conversion disk fixed to one surface is separated from the string adsorption disk separated in the drawing of FIG.
11 is a view showing a state in which the string adsorption disk is separated again in the state of FIG. 10;
12 is a view showing a state in which the central fixed disk applied to the present invention is separated;
Figure 13 is a schematic view of the device of the present invention viewed from the front
Figure 14 is a plan view showing an example in which the disk part in the present invention is supplied along the suction groove of the strap adsorption disk while the mask strap is supplied as viewed from a plane.
Figure 15 is a cross-sectional view schematically showing the state of the flow path, which is the flow of pneumatic fluid when the mask strap is adsorbed by vacuum pressure in the suction groove when the mask strap is supplied to the strap adsorption disk of the disk unit in the present invention.
16 is a schematic view for explaining the state of the suction flow path when the vacuum pressure of FIG. 15 is provided
17 is a view showing only the cutting part applied to the present invention in isolation
18 is a view schematically showing a state in which the mask strap supplied in the present invention is cut to a predetermined set length by a cutting unit and then bent from the suction groove of the strap suction disk to the orthogonal suction groove and adsorbed
19 to 20 show that when the mask strap supplied in the present invention is cut to a certain set length by the cutting unit and then bent and adsorbed from the suction groove of the strap adsorption disk to the orthogonal suction groove, the pushing unit operates to fix the mask strap. A schematic diagram showing the state of being
21 is a view schematically showing the operating relationship between the roller and the guide of the pushing part in the drawing of FIG. 20
22 shows that in the present invention, after the mask strap is supplied to the strap adsorption disk of the disk unit and the mask strap is adsorbed by vacuum pressure in the adsorption groove, the mask strap forms a 'c' shape by changing the air pressure flow path, and the orthogonal suction groove A cross-sectional view schematically showing a flow path state, which is a pneumatic fluid flow in a state of being bent and adsorbed by
23 is a schematic view for explaining a change state of the suction flow path when the vacuum pressure of FIG. 22 is provided
24 shows that in the device of the present invention, the mask body is transported and supplied to the lower center of the disk unit by the feeding transfer unit, and at the same time, the mask strap cut to a certain length by the cutting unit is adsorbed and rotates downward according to the rotation of the disk unit. A drawing showing the general condition
25 is a view schematically showing a state in which the transfer panel of the heat fusion part is simultaneously moved in all directions along the rail while both ends of the front side of the mask body and the mask strap are thermally fused by the heat fusion part
26 is a view schematically showing an operating state in which the fusion jig corresponding to the thermal fusion splicer of the thermal fusion unit protrudes from the strap adsorption disk in the process of thermally splicing both ends of the mask body and both ends of the mask strap, respectively.
27 to 28 show that after the front side of each both ends of the mask body and one end of each mask string are thermally fused by FIGS. 24 to 26, each both ends of the rear end of the mask body and the other end of each mask string are thermally fused. In order to be, the transfer panel of the heat fusion part that was transferred to the front side moves backward and then moves forward again, and the above-described heat fusion between the mask body and the mask strap is finished.
29 to 30 show that after the thermal fusion of the mask body and the mask strap is completed to obtain a completed mask, external air is supplied to the area partitioned by the shielding portion constituted in the central fixed disk to release the vacuum pressure state, A drawing schematically showing a state in which the mask can be discharged to the outside

Specific structural or functional descriptions of the embodiments according to the concept of the present invention disclosed in this specification are only illustrated for the purpose of explaining the embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention Various changes can be made and various forms can be made, so all changes, equivalents, or substitutes included in the spirit and technical scope of the present invention are included, and terms or words used in the specification and claims are conventional or dictionary. Meanings and concepts consistent with the technical idea of the present invention, based on the fact that the inventor can appropriately define the concept of terms in order to explain his/her invention in the best way, as well as not be construed as limited in meaning. should be interpreted as Therefore, the embodiments described in the specification of the present invention and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention, and thus replace them at the time of filing of the present invention. It will be understood that various equivalents and variations are possible or exist.

In addition, unless otherwise defined in the specification of the present invention, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the art to which the present invention belongs. have Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in this specification, it should not be interpreted in an ideal or excessively formal meaning. don't

Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

As described above, the present invention provides a device for automatically heat-sealing the mask body 11 and the mask strap 12.

As shown in FIGS. 1 and 2, the present invention provides a string supply unit 100 for supplying a mask string 12, and a cutting unit for cutting the mask string 12 supplied from the string supply unit 100 to a certain length ( 200), the disk portion 300 that is rotated by adsorbing the mask strap 12 cut to a certain length in the cutting portion 200, and the mask body 11 along the straight direction downward of the disk portion 300 Heat for thermal fusion between the feeding transfer unit 400 for feeding the mask strap 12 guided by the disk unit 300 and the mask body 11 fed and transferred by the feeding transfer unit 400 It consists of a fused portion 500.

The strap supply unit 100 refers to a configuration in which mask straps 12 fused to each other are supplied to both ends of the mask body 11 constituting the mask 10 .

The mask string 12 supplied from the string supply unit 100 is supplied to the string supply unit 100 constituting the present invention in a state wound on a separate bobbin.

As shown in FIGS. 4 and 5, the string supply unit 100 in the present invention should be supplied with two lines of mask strings 12, fixed vertically from one side of the base 101, and mask on both sides of the top, respectively. A vertical panel 110 having a discharge hole 111 through which the string 12 is drawn in and discharged, and a string guide provided to guide the mask string 12 toward the discharge hole 111 of the vertical panel 110. It consists of part 120.

The string guide part 120 is connected to the front side of the vertical panel 110 and is connected in a vertical state, and a plurality of roller parts 140 are formed on the front side so that the mask strap 12 is connected to the discharge hole of the vertical panel 110 The vertical connection panel 130 to be guided to the side of (111) and the vertical connection panel 130 connected to the upper side so that the mask strap 12 is connected to the roller part 140 side of the vertical connection panel 130. Guide It consists of a guide roller 150 to.

Although the guide roller 150 is not shown in the drawings of the present invention, it has a structure in which the mask string 12 is wound on a separate bobbin or the like and has a structure that is guided toward the guide roller 150, which is spaced apart at predetermined intervals. It is made in a group at a location.

On the other hand, as shown in FIG. 5, the roller parts 140 are configured as opposed to each other, and a mask strap guide block 144 for entering the mask strap 12 guided from the guide roller 150 is provided , It is provided directly below the mask strap guide block 144 and is guided by the first roller 141 of the roller part 140 fixed to the vertical connection panel 130, and is provided to the side below it. The discharge hole 111 of the vertical panel 110 is guided by the second roller 142 and through the third roller 143 provided from the second roller 142 to the lower side of the vertical connection panel 130. It is drawn into the side and guided to the cutting part 200 side.

Unlike the first roller 141 and the second roller 142, the third roller 143 is preferably installed in an orthogonal direction so as to facilitate entry into the discharge hole 111.

The cutting unit 200 is configured to cut and cut the mask string 12 supplied from the aforementioned string supply unit 100 to a certain length.

The cutting unit 200 for this purpose is provided at the front end side of the string inlet 210 into which the mask string 12 supplied from the above-described string supply unit 100 is introduced and the string inlet 210, and a feeding roller driving motor. The feeding roller 220 driven by 221, the string guide block 230 provided on the front end side of the feeding roller 220, and the scissors form provided on the front end side of the string guide block 230, the drive cutting machine A cutting machine 240 configured to be rotatable around the rotation axis 260 at the point where the 241 and the driven cutter 242 intersect, and a cylinder 250 for rotating the driving cutter 241 is configured on the side It provides a configuration for cutting the mask strap 12 by rotating the driving cutter 241 according to the driving of the cylinder 250.

The rear side of the driving cutter 241 is configured to interlock with the rod 252, and the rod 252 is configured to be transported forward and backward by the cylinder 250, according to the operation of the cylinder 250, the driving cutter 241 may be cut after the mask strap 12 is drawn out to a certain length by the drive cutter 241 and the driven cutter 242 by rotating about the pivot shaft 260.

In addition, in the present invention, when the drive cutter 241 is rotated toward the front center of the string guide block 230 based on the pivot shaft 260, the driven cutter 242 also interlocks and rotates, and the string guide block 230 It is preferable to easily cut the mask string 12 drawn out through the center of the string guide block 230 by rotating it towards the front center of the.

To this end, in the present invention, the end side of the rod 252 connected to the cylinder 250 and the drive cutter 241 are connected so as to interlock, and the drive pinion 243 connected to the upper end of the drive cutter 241 and the drive cutter 241. The driven pinion 244 gearedly coupled with the drive pinion 243 and the driven cutter 242 connected to interlock with the driven pinion 244 are constituted.

Therefore, when the rod 252 is moved forward by the operation of the cylinder 250, the drive cutter 241 connected to the rod 252 moves in the left direction when viewed from the drawing, that is, the string guide block 230 is rotated towards the center of the drive cutter 241, the drive pinion 243 interlocked therewith is rotated, and the drive pinion 243 and the driven pinion 244 coupled with gears are rotated in reverse. The interlocking driven cutter 242 is also rotated toward the center of the string guide block 230, and operates as if scissors are operated to cut the mask string 12 drawn out through the string guide block 230. do.

The disk unit 300 is provided as a means for circular motion by adsorbing the mask strap 12 having a certain length cut by the above-described cutting unit 200, and in addition, the mask strap 12 in the disk unit 300 ) is bent in a "c" shape to be adsorbed, and then positioned in the direction by the rotation of the disk unit 300, both ends of the mask body 11 transported by the feeding transfer unit 400 to be described later and the mask Both ends of the string 12 serve to guide each other so that they can be fused by the heat fusion unit 500 .

As shown in Figs. A strap adsorption disk 320 for adsorbing and fixing the mask strap 12 so that the mask strap 12 is adsorbed in a straight line by vacuum pressure and disposed in a "c" shape, and the central fixing disk ( 310) and the hollow shaft 330 passing through the center of the string adsorption disk 320 and providing vacuum pressure are connected to the suction hose 340.

The central fixed disk 310 forms vacuum pressure from the hollow shaft 330 through the suction hose 340, and the inside of the central fixed disk 310 communicates with the hollow shaft 330 and is centrally fixed. By forming a suction passage 312 for sucking air inside the disk 310, a short circuit between the side of the string suction disk 320 connected to both sides of the central fixed disk 310 and the suction passage 312 The mask strap 12 is configured to be adsorbed to the side of the strap adsorption disk 320, so that it can rotate.

To this end, as shown in FIGS. 8 to 11, the strap adsorption disk 320 has an adsorption groove 321 along the outer circumferential surface to allow the mask strap 12 to be adsorbed, and from the adsorption groove 321 It is orthogonal and forms an orthogonal suction groove 322 crossing the upper surface of the string suction disk 320.

The orthogonal suction groove 322 is formed along the suction groove 321 in an orthogonal direction as described above, and both ends of the mask strap 12 are bent and adsorbed into the orthogonal suction groove 322.

That is, when the string adsorption disk 320 is rotated around the hollow shaft 330 in the adsorbed state, the mask strap 12 cut to a predetermined length along the suction groove 321 is rotated at a certain angle. Both ends of (12) are sucked into the orthogonal suction groove 322 and are absorbed into the string suction disk 320 while taking a "c" shape as a whole.

As shown in the drawing, the hollow shaft 330 is rotated by power transmission by a pulley P connected to a motor M.

At this time, the length of the mask string 12 cut by the cutting unit 200 is operated to be matched with the length of the ordinary mask string, and the orthogonal suction groove 322 and the orthogonal suction groove 322 have a constant distance. Adsorption grooves 321 that maintain a gap are connected.

As shown in the drawing, the suction groove 321 is formed along the outer circumferential surface of the string suction disk 320 and forms a certain width as described above from the suction groove 321, and the two orthogonal suction grooves 322 are formed as described above. It is orthogonal to and connected to the suction groove 321, and both ends of the mask strap 12 are suctioned and adsorbed in a "c" shape in accordance with the vacuum pressure of the suction hose 340 toward the orthogonal suction groove 322 side. same as bar

That is, the moment the mask string 12 is cut to a predetermined length by the cutting unit 200 described above, the mask string 12 cut from the string suction disk 320 to which vacuum pressure is applied by the suction hose 340 When the string adsorption disk 320 is rotated at a constant speed around the hollow shaft 330 and moved downward, both ends of the mask body 11 side are transported by the feeding transfer unit 400 to be described later. Through a series of processes in which the side and both ends of the mask strap 12 are thermally fused by the operation of the thermal fusion unit 500, the mask 10 in a completed form can be obtained.

In the present invention, as shown in the drawing, the area in which the mask strap 12 is bent and adsorbed in a "c" shape over the entire outer circumferential surface of the strap adsorption disk 320 is divided into equal portions of the outer circumferential surface of the strap adsorption disk 320. It is divided into and formed for each region, for example, in the present invention, while the string adsorption disk 320 is rotated one rotation, the equally divided number of mask straps 12 are cut, and the lower side of the string adsorption disk 320 will be described later By the process of the thermal fusion part 500, the mask body 11 and the mask strap 12 are thermally fused.

Therefore, according to one rotation of the string adsorption disk 320 in the present invention, the number of completed masks 10 divided into equal parts is produced.

On the other hand, the mask strap 12 is adsorbed in a straight line form through the adsorption groove 321 in the strap adsorption disk 320, and a configuration for guiding the adsorption state is required to facilitate this adsorption state.

That is, the pushing disk 323 is provided with a means for pushing the mask strap 12 not to be separated from the suction groove 321, and the suction groove of the pushing disk 323 and the strap suction disk 320 ( 321) constitutes a pushing unit 324 for sidewardly pushing the mask strap 12 toward the suction groove 321.

As shown in FIGS. 11 and 20 to 21, the pushing part 324 is inserted into the pushing part concave groove 323a formed at a predetermined position of the pushing disc 323, and the mask strap 12 is moved to the side. A pushing bar 324a rotated by a shaft 324b fixed to the pushing part concave groove 323a for pushing, a roller 324d provided on the lower end side of the pushing bar 324a, and the roller 324d A guide 324e for contacting and providing a rotation force to the pushing bar 324a is provided, and a spring 324c for providing a restoring force of the pushing bar 324a is engaged with the pushing bar 324a, and the pushing bar 324a It is spaced apart at a position opposite to the bar 324a and constitutes a support bar 324h fixed to the outer circumferential surface of the string adsorption disk 320.

Being coupled to the central fixing disk 310, a cylindrical guider 333 having a guide coupling groove 334 on the outer circumferential side is coupled, and the guide 324e is fastened to the guide coupling groove 334 have a structure.

In addition, as shown in FIG. 12, a round curved surface 324f is formed on the outer surface of the guide 324e, and then a guide groove 324g is formed on the end side of the guide 324e.

Since the guider 333 is coupled to the central fixed disk 310 as described above, it remains fixed regardless of the rotation of the hollow shaft 330.

In this state, when the string adsorption disk 320 is rotated according to the rotation of the hollow shaft 330, the pushing unit 324 is cut by the cutting unit 200 according to the rotation of the string adsorption disk 320. When (12) is rotated while being seated in the adsorption groove 321, the roller 324d of the pushing part 324 contacts along the curved surface 324f of the guide 324e and performs a rolling motion in FIG. As you can see, the pushing bar 324a is rotated around the shaft 324b and moved to a position in contact with the suction groove 321.

As the pushing bar 324a rotates to the suction groove 321 in this way, the mask strap 12 cut in a straight line seated in the suction groove 321 is brought into close contact with the suction groove 321, and then communicates with the suction groove 321. By the first suction flow path (312a) of the suction flow path (312), the mask strap (12) undergoes a process of adsorption so as not to be separated.

Then, in a state in which the adsorption of the mask strap 12 to the adsorption groove 321 is completed, when the continuous rotation of the strap adsorption disk 320 is made, the roller 324d of the pushing part 324 is the curved surface of the guide 324e (324f) moves toward the guide groove (324g) side.

When the roller 324d moves to the guide groove 324g, the force applied to the pushing bar 324a centered on the shaft 324b is relieved, and the pushing bar 324a is moved by the restoring force of the spring 324c. will return to its original state.

Detailed configurations of the disk unit 300 will be described in more detail with reference to FIGS. 8 to 12 .

As described above, the disk unit 300 is provided with a central fixed disk 310 at the center to be fixed so as not to rotate, and the string adsorption disks 320 having the same configuration on both sides of the central fixed disk 310 are hollow. It is rotated at a constant speed about the shaft 330.

Meanwhile, as shown in FIGS. 2, 15, and 22, the central fixed disk 310 communicates with the hollow shaft 330 and forms a suction passage 312 for sucking in air from the inside and guiding it to a vacuum state. , The suction passage 312 forms two passages.

The central fixed disk 310 is composed of two components and combined to form a circular body.

That is, in a state in which the central fixed disk 310 is divided into a first fixed disk 310a formed having a certain width on one side and a second fixed disk 310b coupled to and in contact with the first fixed disk 310a. are combined

The above-described suction passage 312 is formed in the same area in the first fixed disk 310a and the second fixed disk 310b of the central fixed disk 310, respectively. That is, the first suction passage 312a and the second suction passage 312b should be formed at the same positions of the first and second fixed disks 310a and 310b, respectively.

On the other hand, the through hole 311 communicating with the connection hole 331 of the hollow shaft 330 in the central fixed disk 310 is formed while vertically penetrating the circular protrusion 314 of the second fixed disk 310b. By doing so, it communicates with the first suction passage 312a and the second suction passage 312b.

On the other hand, the suction passage 312 of the central fixed disk 310 is a first suction passage for adsorbing the mask strap 12 in the suction groove 321 formed along the outer circumference of the strap suction disk 320 ( 312a) is formed facing each other in the same area of the first fixed disk 310a and the second fixed disk 310b, and is configured to face and be spaced apart from the suction groove 321 at a predetermined interval, so that the mask strap 12 ) is bent at right angles to form a second suction passage 312b for adsorption into the orthogonal suction groove 322, facing each other in the same area of the first fixed disk 310a and the second fixed disk 310b. will do

Here, the first suction passage 312a is formed relatively shorter than the second suction passage 312b.

That is, in the first suction passage 312a, the mask strap 12 cut to a predetermined length is always adsorbed in the suction groove 321 of the string suction disk 320, and then the second suction passage 312b flows to the second suction passage 312b. When the change is made, the vacuum pressure is released, so that the length of the passage is relatively shorter than that of the second suction passage 312b, and the second suction passage 312b is formed in a straight line by the first suction passage 312a. After being adsorbed in the adsorption groove 321, it is bent and adsorbed in a 'c' shape in a state of being rotated at a predetermined angle, so it is formed to be relatively longer than the first suction passage 312a.

In addition, as described above, since the string adsorption disk 320 is in close contact with both sides of the central fixed disk 310 and is configured to interlock with the rotation of the hollow shaft 330 in a state connected to the hollow shaft 330, The string adsorption disk 320 may be interlocked and rotated.

However, the central fixed disk 310 is fixed to the fixed frame 313 fixed to the base 101 in a state where it does not interlock with the hollow shaft 330.

In addition, the connection hole 331 for connecting and communicating between the hollow shaft 330 and the first suction passage 312a and the second suction passage 312b, which are the suction passages 312 of the central fixed disk 310, The suction passages 312 are perforated vertically and are the first and second suction passages 312 of the first and second fixed disks 310a and 310b of the central fixed disk 310 according to the rotation of the hollow shaft 330. ) is changed according to the rotation of the strap adsorption disk 320, and the mask strap 12 is adsorbed in a straight line shape, or both ends of the mask strap 12 adsorbed in a straight line shape are bent and adsorbed in a right angle shape.

Meanwhile, as described above, in a state in which the hollow shaft 330 is in communication with the first suction passage 312a or the second suction passage 312b of the central fixed disk 310, the first suction passage 312b is connected. It can communicate with the suction passage 312a or communicate with the second suction passage 312b. By changing the passage, the mask string 12 is adsorbed in the suction groove 321 of the string suction disk 320 in a straight line. After being rotated at a certain angle in the state and both ends of the mask strap 12 bent by the second suction passage 312b and placed in the orthogonal suction groove 322, both ends of the mask strap 12 are thermally fused to be described later. It is rotated while maintaining the state until the point of fusion at 500.

On the other hand, as described above, it is preferable that the through hole 311 penetrates the lower end of the circular protrusion 314 protruding in a hollow form towards the center of the second fixed disk 310b. A shielding portion 315 is formed to secure an outside air supply area by forming a space at a predetermined interval from the outer circumferential surface of the circular protruding portion 314 .

The shielding part 315 is preferably configured in an area outside the area of the suction passage 312 described above.

By supplying outside air to the outside air supply area, the adsorption state of the mask strap 12 adsorbed to the strap adsorption disk 320 is removed.

That is, external air is supplied at the time when thermal fusion between the mask strap 12 and the mask body 11 is performed in the thermal fusion part 500 to be described later so that the mask strap 12 is in a state where it can be separated from the strap adsorption disk 320. will be able to be placed.

By the central fixed disk 310 having such a configuration, the above-described operation process will be described again. The circular protrusion of the second fixed disk 310b constituting the central fixed disk 310 through the hollow shaft 330 ( 314) is perforated to suck outside air through the through hole 311 by the suction hose 340 and provide a vacuum state so that the mask strap 12 rotates interlockingly with the hollow shaft 330. String adsorption disk 320 While the cut mask strap 12 is adsorbed through the suction groove 321 of the orthogonal suction groove 322, both ends of the mask strap 12 can perform a process of bending and adsorbing in a 'c' shape. do.

In addition, in a state in which the mask strap 12 is bent and adsorbed in a 'c' shape through the orthogonal suction groove 322, the mask body 11 and the mask strap 12 can be heat-sealed by the strap adsorption disk 320 At the time of rotation to the present position, external air is supplied to the area formed by the shielding portion 315 formed by being spaced apart from the outer circumferential surface of the circular protrusion 314 at a predetermined interval and adsorbed to the string adsorption disk 320. The mask strap 12 may be removed.

In this way, the mask strap 12 must be separated from the suction groove 321 and the orthogonal suction groove 322 of the strap suction disk 320 for easy thermal fusion by the heat fusion machine 530 in the heat fusion part 500. It becomes possible.

On the other hand, on both sides of the central fixed disk 310, as the string adsorption disk 320 is rotated around the hollow shaft 330 as described above, the suction passage 312 of the central fixed disk 310 After the mask strap 12 is adsorbed in a straight line form in the adsorption groove 321 of the strap adsorption disk 320, it is adsorbed by the orthogonal adsorption groove 322 in a "c" shape at the time of rotation at a certain angle. explained.

In this way, in order for the mask strap 12 supplied in a straight line to be bent and adsorbed in a "c" shape at some point, the suction passage 312 between the central fixed disk 310 and the strap suction disk 320 A configuration of a flow path conversion disk 350 is provided separately to enable the conversion of .

That is, the flow path conversion disk 350 has a first suction passage hole 351 for forming a vacuum pressure so that the mask strap 12 can be adsorbed to the suction groove 321 of the strap suction disk 320 in a straight line shape. It is perforated at a position corresponding to the position of the first suction passage 312a described above, and is provided at a position corresponding to the position of the second suction passage 312b for bending and adsorbing the mask strap 12 in a "c" shape. 2 It is configured so that the suction passage hole 352 is perforated.

With this configuration, the first suction passage 312a and the second suction passage 312b of the central fixed disk 310 in a fixed state while the string adsorption disk 320 and the flow path conversion disk 350 rotate and the above At the point where the first suction passage hole 351 and the second suction passage hole 352 coincide, the mask strap 12 remains adsorbed to the suction groove 321 in a straight line shape and is bent in a "c" shape. After being adsorbed, both ends of the mask strap 12 and both ends of the mask body 11 may be thermally fused in the thermal fusion part 500 .

On the other hand, as described above, the feeding transfer unit 400 means a configuration for feeding the mask body 11 passing through the lower end of the disk unit 300 rotated in a state in which the mask strap 12 is adsorbed. .

Such a feeding transfer unit 400 is transported along the trajectory of an infinite trajectory, and connects a plurality of seating plates 410 on which the mask body 11 is seated, and the plurality of seating plates 410, along an infinite trajectory. It consists of a drive unit 420 driven to be rotated, and a follower unit 430 that is spaced apart from both sides of the lower side of the base 101 and rotates in conjunction with the drive unit 420 and the power transmission means.

The driving unit 420 is controlled to be driven at a rotational speed corresponding to the rotational speed of the disk unit 300 .

The thermal fusion part 500 is formed in a 'c' shape by the disk part 300 when the mask body 11 seated on the feeding transfer part 400 is positioned in the lower center of the disk part 300. It means a configuration in which both ends of the mask strap 12 adsorbed to and both ends of the mask body 11 are thermally fused.

The heat fusion part 500 is configured to be transportable along the base panel 510 on which the rail 511 is formed on the upper surface in the same direction as the transfer direction of the feeding transfer unit 400, and the rail 511 A pair of heat splicers 530 having a transfer panel 520 and penetrating the transfer panel 520 and the base panel 510 but being fixed to the transfer panel 520, and the transfer panel 520 A forward and reverse drive motor 540 fixed to the side of the base panel 510 is configured to enable forward and backward reciprocating transfer.

As described above, the thermal splicers 530 disposed in pairs and facing each other are provided while penetrating the transfer panel 520 and the base panel 510, and the distance between the splicers 530 is the length of the mask body 11. Corresponds to, and the contact point between the mask body 11 and the mask strap 12 is heat-sealed.

During the thermal fusion process of the mask body 11 and the mask strap 12 in the thermally fused portion 500, both ends of the mask strap 12 must be thermally fused to one mask body 11, respectively.

That is, mask straps 12 are thermally fused to both ends of the mask body 11, and at one end of the mask body 11, both ends of one mask strap 12 are thermally fused to the front and rear of one end of the mask body 11, respectively. have to lose

In general, when the mask strap and the mask body are fused, the mask strap is transported at a constant speed and the mask strap is heat-sealed, so that the heat-sealing between the mask strap and the mask body is not properly performed at the correct position, resulting in heat fusion in the wrong place or Or there was a problem of thermal fusion in the pushed state.

In the present invention, in order to improve this point, as described above, the transfer panel 520 can be repeatedly transported by the forward and reverse driving motor 540 along the rail 511 of the base panel 510 in the heat-sealed portion 500. It is configured to do so, and the conversion and speed of the forward or reverse driving motor 540 in the forward or reverse direction corresponds to the rotational speed of the string suction disk 320 and is configured to be controllable.

As shown in FIGS. 2, 3, 13, 24 to 25, and 27 to 28, the heat-sealed portion 500 is of the feeding transfer portion 400 passing directly below the disk portion 300. located on the lower side.

When the mask body 11, which is seated on the seat plate 410 of the feeding transfer unit 400 and fed, reaches directly below the disk unit 300, the string adsorption disk 320 of the disk unit 300 It corresponds to the moment when the mask string 12 in a state of being adsorbed in a "c" shape on the side is located in the downward direction.

On the other hand, in order to heat-seal both ends of the mask strap 12 and the mask body 11 in the heat-sealed portion 500, as shown in FIGS. 24 to 28, the fusion jig 360 of the disk portion 300 and the operation of the thermal fusion machine 530 of the thermal fusion unit 500.

The heat-sealing part 500 follows the configuration as described above, and the corresponding fusion jig 360 has a configuration provided on the inner circumferential surface of the string adsorption disk 320, but one end is the string adsorption disk 320 It has a configuration that is drawn out or drawn through the outer circumferential surface of.

That is, when the string adsorption disk 320 is driven by the drive of the hollow shaft 330, the fusion jig 360 is rotated in a retracted state in one area, and protrudes toward the outer peripheral surface of the string adsorption disk 320 in the setting area. The mask body 11 and both ends of the mask strap 12 are sequentially heat-sealed in contact with the heat splicer 530.

Here, at the time when the mask strap 12 is heat-sealed, both ends of the mask strap 12 come into contact with the heat splicer 530, and the fusion jig 360 protrudes, and the mask strap 12 and the mask body 11 ) Both ends are heat-sealed, respectively. In order to enable such an operation, the position of the heat-sealer 530 is the inner circumferential side of the string adsorption disk 320, that is, a position corresponding to the end of the orthogonal adsorption groove 322. will be in

To explain this again, the installation position of the heat splicer 530 is located inside the base 101, but is located at a position corresponding to the inner end of the orthogonal suction groove 322 of the string suction disk 320.

In addition, corresponding to this, that is, to correspond to the heat splicer 530, the fusion jig 360 is configured to be drawn in and out on the inner circumferential side of the string adsorption disk 320.

In this way, the heat splicer 530 and the fusion jig 360 are configured to be positioned on the same arc of the string adsorption disk 320, and as the string adsorption disk 320 rotates, the mask strap 12 moves to the lower side, that is, the base. At a point located on the vertical upper surface of (101), the above-described fusion jig 360 protrudes and comes into contact with the heat splicer 530 located below the base 101, and heat transfer occurs between the mask body 11 and the mask strap 12. ) is thermally fused.

In addition, the fusion jig 360 and the heat splicer 530 do not directly contact each other, but as shown in FIG. 3, the heat splicing panel ( 440), the high-temperature heat generated in the heat fusion machine 530 is transferred to the heat fusion panel 440, and heat fusion between the mask strap 12 and the mask body 11 can be achieved.

On the other hand, as the string adsorption disk 320 rotates toward the heat splicer 530, the fusion jig 360 should protrude to the outer circumferential surface of the string adsorption disk 320. In order to facilitate this, the guider 333 is used do.

That is, the above-described guide coupling groove 334 is formed on the upper side of the guider 333 to allow the guide 324e to be coupled, while the lower side allows the fusion jig 360 to be drawn in and out so that the position can be shifted A fusion jig guide 335 is attached.

The fusion jig guide 335 forms a curved protrusion 336 protruding in a curved surface along the outer circumferential surface, and a curved concave inlet 337 extending from the curved protrusion 336 and having different heights is formed.

The curved protrusion 336 of the fusion jig guide 335 forms a gentle curve and gradually slopes outward, and after forming a horizontal surface at the end of the inclined region, it slopes downward rapidly, and the curved concave portion ( 337).

The moment the fusion jig 360 and the fusion jig guide 335 come into contact while the string adsorption disk 320 rotates by the fusion jig guide 335, as shown in FIG. 25, the fusion jig 360 One end rides on the outer surface of the curved concave part 337 and serves to push the fusion jig 360 outward.

That is, the fusion jig 360 entering the outer circumferential surface of the curved concave portion 337 protrudes while being pushed toward the outer circumferential side of the string adsorption disk 320 until it reaches the horizontal plane of the curved protrusion 336, which is the apex, and the curved protrusion 336 The fusion jig 360 along the curved surface is configured to return to its original state by the restoring force of the spring 324c provided therein.

In this way, the process of drawing or drawing the fusion jig 360 to the outer circumferential side of the string adsorption disk 320 is repeatedly performed.

As described above, the point at which the fusion jig 360 is drawn out to the outer circumferential side of the string adsorption disk 320 is the point at which it is positioned toward the base 101, and that point is the point at which the mask is seated on the seating plate 410 of the feeding transfer unit 400. This is the point at which the main body 11 is positioned below the center of the string adsorption disk 320, and the mask strap 12 of the string adsorption disk 320 is orthogonal to the suction groove 322 toward both ends of the mask body 11. It means the point of contact at the heat fusion panel 440 of the feeding transfer unit 400 by being positioned below the center of the string adsorption disk 320 in a bent and adsorbed state.

On the other hand, the fusing jig 360 may be preferably configured as shown in FIG. 26 in order to be easily drawn in and out of the string adsorption disk 320.

For example, a body 361 having a jig roller 362 at the upper end and a fusion contact hole 363 protruding to the lower end of the body 361, and a recovery spring 364 inside the body 361, One end of the recovery spring 364 is configured to be connected to one side of the flow path conversion disk 350.

Therefore, as described above, the restoring spring 364 has a shape that is supported inside the body 361 in a state in which one end is fixed to the flow path conversion disk 350 and drawn into the body 361, which is fused. After the jig 360 protrudes through the outer circumferential surface of the string adsorption disk 320 by the curved protrusion 336 of the fusion jig guide 335, the heat splicer 530 of the heat fusion part 500 and the fusion junction 363 After the thermal fusion between the mask string 12 and the mask body 11 is completed by ), the jig roller 362 of the fusion jig 360 according to the rotation of the string adsorption disk 320, as shown in FIGS. 27 to 28 It takes the form of being separated from the curved protrusion 336 of the fusion jig guide 335, and the process of being pulled into the string adsorption disk 320 by the restoring force of the recovery spring 364 is repeatedly performed.

Using the present invention having the above configuration, a process of connecting the mask string 12 and the mask body 11 by thermal fusion will be described.

First, as described above, when the mask string 12 wound on a separate bobbin is supplied by the string supply unit 100, the process of cutting the mask string 12 supplied from the cutting unit 200 to an appropriate length set will go through

The mask strap 12 cut in this way is placed in the suction groove 321 formed on the outer surface of the strap adsorption disk 320 of the disk unit 300 by the pushing unit 324 of the pushing disk 323. It is in close contact with the inside of the suction groove 321 and is in a fixed state, and the vacuum pressure through the suction hose 340 communicates with the first suction passage 312a among the suction passages 312 to form the straight line. The mask strap 12 is maintained in the adsorbed state in the adsorption groove 321, and the strap adsorption disk 320 is rotated.

Subsequently, as the string adsorption disk 320 rotates (rotates), the second suction flow path 312b is opened at the same time, and vacuum pressure is formed toward the orthogonal suction groove 322. This vacuum pressure is formed to adsorb in a straight line. Both ends of the mask strap 12 adsorbed to the groove 321 are sucked into the orthogonal suction groove 322 and undergo a process of adsorption in a 'c' shape.

At this time, the vacuum pressure provided to the suction groove 321 is changed from the first suction passage 312a to the second suction passage 312b and is released, but toward the orthogonal suction groove 322. By the vacuum pressure provided, the mask strap 12 firmly maintains a 'c' shape and is rotated while maintaining a state of adsorption to the strap adsorption disk 320.

On the other hand, since a plurality of modules constituting a set of suction grooves 321 and orthogonal suction grooves 322 are disposed in the string suction disk 320, the above-described process according to the rotation of the string suction disk 320 Repeatedly performed, the mask strap 12 supplied from the above-mentioned string supply unit 100 is cut to a certain length by the cutting unit 200, and then the above-described suction groove 321 and orthogonal suction groove 322 provide vacuum pressure and The release process is repeated.

In addition, the mask string 12 adsorbed in a 'c' shape on the string adsorption disk 320 is rotated toward the center of the device of the present invention, and at the same time, the mask body 11 is fed from the side of the string adsorption disk 320 It is seated on the seating plate 410 by the transfer unit 400 and continuously supplied.

In this way, the moment when the mask body 11, which is seated on the seat plate 410 of the feeding transfer unit 400 and supplied by feeding, is located below the center of the string suction disk 320, the string suction disk 320 This means that the mask strap 12 adsorbed in a 'c' shape by the suction groove 321 and the orthogonal suction groove 322 can be heat-sealed with both ends of the mask body 11.

In this state, as soon as the seating plate 410 of the feeding transfer unit 400 is accurately located below the center of the string adsorption disk 320, as described above, the fusion jig 360 is the curved protrusion of the fusion jig guide 335 ( 336), the fusion junction hole 363 of the fusion jig 360 protrudes outward from the outer circumferential surface of the string adsorption disk 320 and attaches to the thermal fusion panel 440 of the feeding conveyor 400. The contacting end of the mask body 11 and both ends of the mask strap 12 are sequentially thermally fused.

At this time, in the process of thermal fusion as described above, the transport panel 520 is configured to be repeatedly transported by the forward and reverse driving motor 540 along the rail 511 of the base panel 510 in the thermal fusion portion 500. And, the conversion and speed of the forward or reverse driving motor 540 in the forward or reverse direction corresponds to the rotational speed of the string adsorption disk 320 and is configured to be controllable. In the string adsorption disk 320, ' As described above, when the mask strap 12 adsorbed in the form of 'c' is located at the bottom center, one end side of the mask body 11 seated on the seating plate 410 of the feeding transfer unit 400 is the thermal fusion panel 440 ) is located in the state.

In this state, one of the fusion jigs 360 of the two fusion jigs 360 forming a pair first protrudes through the outer circumferential surface of the string adsorption disk 320 and is transferred to the heat fusion panel 440 by the feeding transfer unit 400. The front sides of both ends of the mask body 11 that have reached are thermally fused.

When one end of the mask strap 12 is thermally fused to each front side of both ends of the mask body 11, the feeding transfer unit 400 is moved slowly, and the forward and reverse driving motor 540 of the thermal fusion unit 500 The transfer panel 520 is instantaneously transferred along the rail 511 of the base panel 510 by the drive.

That is, the transfer at this time is in the process of heat-sealing the front side of both ends of the mask body 11 with one end of the mask strap 12. Even in the process of heat-sealing, fine continuous transfer is performed so that the mask strap 12 is mask This is to enable continuous thermal fusion without being pushed at the point of contact with the main body 11 and fusion.

In the case where there is no transfer of the transfer panel 520, as described above, the same problem as in the prior art, that is, the mask body 11 and the mask strap 12 are pushed and fused or fused to a completely different location. In the present invention, this problem can be solved through the above-described process.

On the other hand, when the thermal fusion of the mask strap 12 is completed at both ends of the mask body 11 at the front side, the transfer panel 520 of the thermal fusion portion 500 is returned to its original state by reverse driving of the forward and reverse driving motor 540. As it returns, it is transported backward, and at the same time, both ends of the rear end side of the both ends of the mask body 11 come into contact with the other end of the mask strap 12, and the process of thermal fusion is performed again.

Even at this time, the transfer panel 520 of the thermally fused portion 500 is transported in the forward direction by the forward driving of the forward and reverse driving motor 540, and the mask strap 12 and the mask body 11 are transported during the thermal fusion process. ) is maintained as it is in contact with, and thermally fused.

Since the mask straps 12 must be thermally fused to both ends of the mask body 11, it should be understood that each of the above-described components is opposed to each other around the central fixed disk 310 and a pair of structures are made. .

When the thermal fusion between the mask body 11 and the mask strap 12 in the thermal fusion unit 500 is completed, the completed mask 10 is discharged according to the continuous transfer of the feeding transfer unit 400 .

As described above, although the present invention has been described with limited embodiments and drawings, the present invention is not limited to the above embodiments, of course, from the above description by a person having ordinary technical knowledge in the field to which the present invention belongs. Of course, various modifications and variations may be possible.

Therefore, the technical idea in the present invention should be grasped by the claims described below, but it will be obvious that all equivalent or equivalent modifications belong to the scope of the technical idea of the present invention.

10; mask 11; mask body
12; mask strap
100; String supply department
101; expect 110; vertical panel
111; discharge hole 120; string guide
130; Vertical connection panel 140; roller part
141; First roller 142; 2nd roller
143; third roller 144; Mask strap guide block
200; cutting part
210; String inlet 220; feeding roller
221; Feeding roller driving motor 230; String guide block
240; cutter 241; driven cutting machine
242; Followed cutter 243; drive pinion
244; driven pinion 250; cylinder
252; load 260; pivot
300; disk part
310; central fixed disk 310a; 1st fixed disk
310b; second fixed disk 311; Through hole
312; Suction flow path 312a; 1st suction passage
312b; Second suction passage 313; fixed frame
314; circular protrusion 315; shield
320; String adsorption disk 321; Adsorption groove
322; Orthogonal adsorption groove 323; pushing disc
323a; Pushing unit yiphom 324; Pushing part
324a; Pushing bar 324b; axis
324c; spring 324d; roller
324e; guide 324f; curved surface
324g; guide groove 324h; support bar
330; hollow shaft 331; connector
332; Grooves 333; guider
334; guide coupling groove 335; Fusion jig guide
336; curved protrusion 337; curved inlet
340; suction hose 350; Euro Conversion Disc
351; A first suction passage hole 352; 2nd intake passage hole
360; Fusion jig 361; body
362; Zigrowler 363; fusion junction
364; return spring
400; Feeding transport part
410; Seating plate 420; driving part
430; follower 440; heat-sealed panel
500; heat spliced part
510; base panel 511; rail
520; transfer panel 530; heat splicer
540; forward/reverse drive motor

Claims (13)

A disk unit provided on the base and supplied with a mask string cut to a certain length;
a feeding transfer unit feeding the mask body supplied to pass through the lower end of the disk unit;
a thermal fusion unit for heat-sealing both ends of the mask strap and both ends of the mask body when the mask body seated in the feeding transfer unit is located at the lower center of the disk unit;
Mask strap suction disk device for manufacturing a mask comprising a.
According to claim 1,
The disk part,
The mask strap supplied after being cut to a certain length is adsorbed and rotated by a circular motion, and both ends of the mask body passing through the lower end of the disk unit are bent and absorbed in a "c" shape so that both ends of the mask strap come into contact. A mask strap adsorption disk device for manufacturing a mask that includes rotating in a state of being.
According to claim 1,
The disk part,
A hollow shaft having a connection hole drilled into the central outer circumferential surface to be driven in connection with the motor;
a central fixing disk positioned at the center of the hollow shaft and fixed so as not to rotate by a fixing frame connected to a frame surrounding the disk unit;
A string adsorption disk that is opposite to each other on the left and right based on the central fixed disk and adsorbs the mask strap cut to a certain length in a straight line shape by vacuum pressure, and then bends and adsorbs it in a 'c' shape and rotates in conjunction with the hollow shaft. ;
a suction hose connected to the hollow shaft that passes through the center of the central fixing disk and the string suction disk and provides vacuum pressure;
A mask strap adsorption disk device for manufacturing a mask comprising:
According to claim 3,
Inside the central fixed disk, a suction passage communicating with the hollow shaft and sucking air inside the central fixed disk is formed, and a short circuit between the side of the string suction disk connected to both sides of the central fixed disk and the suction passage is formed. A mask strap adsorption disk device for manufacturing a mask comprising allowing the mask strap to be adsorbed to the strap adsorption disk side by means of
According to claim 3,
The string adsorption disk,
Adsorption grooves are formed so that the mask strap supplied along the outer circumferential surface can be adsorbed, and orthogonal suction grooves orthogonal to the suction grooves and crossing the upper surface of the strap adsorption disk are formed as a set to form a plurality of sets along the outer circumferential surface of the strap adsorption disk A mask strap suction disk device for manufacturing a mask comprising being.
According to claim 3,
The string adsorption disk,
Adsorption groove provided to adsorb the mask strap supplied along the outer circumferential surface;
A plurality of orthogonal suction grooves orthogonal to the suction groove and crossing the upper surface of the string suction disk;
a pushing disk coupled to the outside of the string adsorption disk and having pushing grooves at a plurality of positions on the outer circumferential surface;
a pushing unit provided inside the pushing unit inlet groove to push the mask strap sideways toward the suction groove in an area where the suction groove of the pushing disk and the string suction disk are formed;
Mask strap suction disk device for manufacturing a mask comprising a.
According to claim 6,
The pushing part,
A pushing bar (324a) rotated by a shaft (324b) fixed to the pushing part concave groove (323a);
a roller (324d) provided at the lower end side of the pushing bar (324a);
a guide 324e for contacting the roller 324d and providing a rotational force to the pushing bar 324a;
a spring supported to provide restoring force of the pushing bar 324a;
A support bar spaced apart from the pushing bar and fixed to the outer circumferential surface of the string adsorption disk;
Mask strap suction disk device for manufacturing a mask comprising a.
According to claim 3,
A cylindrical guider coupled to the central fixed disk and having a guide coupling groove 334 on the outer circumferential side;
A guide that is fastened to the guide coupling groove to form a curved surface in a round shape on an outer surface and a guide groove is formed toward an end of the curved surface;
Mask strap suction disk device for manufacturing a mask comprising a.
According to claim 3,
The central fixed disk,
A first fixed disk having a suction passage formed having a predetermined width on one side and comprising a first suction passage and a second suction passage;
Having a suction passage made of a first suction passage and a second suction passage that comes into contact with and is coupled to the first fixed disk, has a circular protrusion protruding to one side, and has a through hole vertically penetrating the circular projection. 2 fixed disc;
A mask strap adsorption disk device for manufacturing a mask comprising: the first fixed disk and the second fixed disk are coupled and the first suction passage and the second suction passage communicate with each other by the through hole.
According to claim 9,
In the suction passage of the central fixed disk, the first suction passage for allowing supplied mask straps to be absorbed in the suction groove formed along the outer circumferential surface of the suction disk is opposite to the same area of the first fixed disk and the second fixed disk. and is formed,
The second suction passage for adsorption into the orthogonal suction groove by bending both ends of the mask strap at right angles is formed to be opposed to the suction groove at a predetermined distance from the suction groove in the same area of the first fixed disk and the second fixed disk. A mask strap adsorption disk device for manufacturing a mask comprising facing each other and forming.
According to claim 9 or 10,
The first suction passage is a mask strap suction disk device for manufacturing a mask comprising forming a relatively shorter than the second suction passage.
According to claim 9,
A mask strap adsorption disk device for manufacturing a mask comprising forming a set of shielding parts to secure an outside air supply area by forming a space at a predetermined interval from the outer circumferential surface of the circular protrusion to an area outside the area of the suction passage.
According to claim 9,
To be coupled to the outer surface of the first fixed disk of the central fixed disk,
The first suction passage hole for forming a vacuum pressure so that the mask strap cut to a certain length and supplied can be adsorbed to the suction groove of the strap suction disk in a straight line shape is located at a position corresponding to the position of the first suction passage 312a. It is perforated, and the second suction passage hole 352 is perforated at a position corresponding to the position of the second suction passage for bending and adsorbing the mask strap 12 in a "c" shape. A mask strap adsorption disk device for manufacturing a mask.

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