KR20110026780A - Decal comania fabric supply fabric of the device - Google Patents

Abstract

PURPOSE: A decal material feeding device for a decal material manufacturing device is provided to improve work efficiency by accurately controlling the feeding position of a decal material. CONSTITUTION: A decal material feeding device for a decal material manufacturing device comprises wrinkle prevention rollers(20), position information rollers(30), sensor bars(40), and a material feeding unit(50). The wrinkle prevention rollers flatten materials(18) which are vertically fallen down from material rollers(18a). The position information rollers are horizontally moved in order to control the positions of the materials. The sensor bars sense whether both ends of the fallen materials are within a sensing range. The material feeding unit feeds the materials, passing through the sensor bars, to feeding rollers through a conveyor belt(51).

Description

Decal comania fabric supply fabric of the device

The present invention relates to a fabric feeder for the transfer fabric manufacturing apparatus, in particular the supply position of the fabric exactly The present invention relates to a fabric feed apparatus for a transfer fabric manufacturing apparatus which reduces the defective rate by controlling the transfer completion rate.

The thermal transfer device is to transfer a variety of patterns on the fabric of the fabric paper to print the pattern on the fabric fabric, so that the fabric is transferred by the transfer roller while passing through the transfer roller.

The raw material supplied to the thermal transfer apparatus passes through a transfer roller mounted inside the thermal transfer apparatus, and is discharged to the outside of the thermal transfer apparatus through an outlet while the pattern on the transfer roller is transferred to the original fabric.

The heat transfer device is provided with a front roller, a lower peak, a top roller, a rear roller, a belt positioning roller, a discharge roller, and a plurality of idle rollers, respectively, and the outer surface of the belt wraps around the circumference of the heating roller. Silver feed roller, belt positioning roller, discharge roller, slidably installed on the outer circumferential surface of the plurality of idler roller, and is configured to manufacture a transfer fabric by supplying the transfer paper, fabric, paper laminated between the heating roller and the belt.

However, the conventional thermal transfer apparatus as described above has a problem in that the efficiency of the work is lowered by supplying the transfer paper, the fabric, and the paper by using a human attraction.

In addition, the conventional thermal transfer apparatus as described above has a problem in that a transfer paper or a fabric is not flattened, but is folded or wrinkled and supplied, thereby causing a defect in transfer, thereby reducing loss of raw materials and completeness of a product.

In addition, the conventional thermal transfer apparatus as described above has a problem that it is difficult to adjust the supply position of the fabric when a defect occurs or checks because only a portion of the transfer is not made because the fabric continuously supplied is not accurately stacked with the transfer paper. .

Accordingly, the present invention has been made in view of the problems of the prior art as described above, and an object of the present invention is to provide a fabric manufacturing apparatus which reduces the defect rate and increases work efficiency by improving the supply of fabric using an automated method.

Another object of the present invention is to prevent wrinkles when the fabric is supplied and to adjust the position through two-stage sensor detection so as to supply the correct transfer position, thereby reducing waste of raw materials and at the same time providing a high-quality transfer fabric. It's about making things happen.

In order to achieve the above object, the present invention is installed in the front, lower apex, the upper, the rear of the heating roller, the supply roller, the belt positioning roller, the discharge roller, a plurality of idle rollers are installed, the outer surface of the belt is the circumference of the heating roller Manufacture the transfer fabric to manufacture the transfer fabric by wrapping the inner circumference with the supply roller, the belt positioning roller, the discharge roller, and the outer circumferential surface of a plurality of idle rollers and laminating and supplying transfer paper, fabric, and paper between the heating roller and the belt. In the fabric feeder for the device, a plurality of triangularly arranged anti-wrinkle rollers are rotated in opposite directions so that the fabric is unfolded from the fabric roller so that the fabric is vertically dropped while the fabric is supplied to the supply roller. The lower part of the anti-wrinkle roller is in contact with the fabric by hydraulic operation and link operation Install a pair of position correction rollers to adjust the fall position of the fabric by turning in the right direction, and the lower end of the position correction rollers are in the sensing range when the falling fabric passes through the sensor sensing operation. Forming a pair of sensor rods to detect whether the position, and the fabric supply unit for transfer fabric manufacturing apparatus characterized in that it comprises a fabric supply unit for supplying the fabric passed through the sensor rod to the feed roller by the conveying drive of the conveyor belt Provide the device.

As described above, the present invention has the effect of reducing the defective rate and increasing the work efficiency by improving the supply of the fabric by using the manpower.

In addition, wrinkles do not occur when the fabric is supplied, and the position can be adjusted through the two-stage sensor detection so that it is supplied to the exact transfer position, thereby reducing waste of raw materials and producing high-quality transfer fabrics. have.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

As shown in FIG. 1, the fabric supply apparatus for a transfer fabric manufacturing apparatus of the present invention is a fabric supply unit 50 for supplying a transfer unit 10 and a fabric 18 to thermally bond the transfer paper 17 to the fabric 18. ), Is configured to be used in the manufacturing apparatus 100 consisting of a paper supply unit 60 for supplying paper.

The transfer unit 10 is the front, lower apex, the upper, the rear of the heating roller 11, the supply roller 12, belt positioning roller 13, discharge roller 14, a plurality of idle rollers (15) Install it.

At this time, the transfer paper 17 is configured to be unwound and supplied after being wound on a separate transfer paper roller 17a, and the transfer paper roller 17a is installed at the front upper side of the heating roller 11.

Then, the outer surface of the belt 16 surrounds the circumference of the heating roller 11, and the inner circumferential surface of the supply roller 12, the belt positioning roller 13, the discharge roller 14, the outer peripheral surface of the plurality of idle rollers (15) Install to slide.

Here, the belt 16 is locked to the idle roller 15 in a zigzag form to adjust the tension force.

Thus, the transfer paper 17, the original fabric 18, the paper 19 to the transfer portion 10 is laminated and supplied between the heating roller 11 and the belt 16 in the order from the top to the bottom position.

As shown in Figure 2 to 8, the fabric supply unit 50 for supplying the fabric 18, the anti-wrinkle roller 20, the contact detection sensor 52, the position correction roller 30, the sensor rod 40 ) Are sequentially arranged in the longitudinal direction.

The anti-wrinkle rollers 20 are rotated in opposite directions so that the fabric 18 is unwound from the fabric roller 18a so that the fabric 18 is supplied to the supply roller 12, and the fabric 18 falling vertically is flattened as it passes through. Install in batches.

That is, the anti-wrinkle roller 20 is installed so that one in one side, two on the other side in a vertical arrangement 1: 2 ratio when projecting from the side, the fabric 18 is one and two anti-wrinkle rollers ( Passes while touching the outer peripheral surface of 20) at the same time.

Each of the outer circumferential surface of the anti-wrinkle roller 20 is formed by winding a spiral band 21 running in opposite directions to each other in a spiral form.

At this time, the fabric 18 is not only in close contact with the surface of the anti-wrinkle roller 20 by the squary strip 21 is configured to prevent the generation of static electricity.

The touch sensor 52 is installed on both sides of the frame (P) to which the anti-wrinkle roller 20 and the position correction roller 30 of the fabric supply unit 50 is fixed so as to detect the supply position of the fabric (18).

At this time, the contact detection sensor 52 is configured to stop the supply and adjust the initial supply position when the fabric 18 that has passed through the anti-wrinkle roller 20 contacts.

That is, the contact detection sensor 52 is installed at intervals in which the position of the transfer can be changed when both ends of the far end 18 are displaced. It is configured to stop the operation by sending a signal to the control unit (not shown).

In addition, the frame (P) is a pair of longitudinally installed pillars in which the anti-wrinkle roller 20, the position correction roller 30, the sensor rod 40, and the contact detection sensor 52 are fixed.

The position correction roller 30 is rotated in the left and right directions by the hydraulic operation and the link operation while contacting the fabric 18 in the lower portion of the anti-wrinkle roller 20 to adjust the drop position of the fabric 18. It consists of a pair of rollers.

Here, the position correction roller 30 is vertically spaced apart so that both ends are fixed to the fixing bracket (32).

A pair of links 33 are rotatably connected to the rear surface of the fixing bracket 32 and to the front of the frame P installed in the horizontal direction.

Meanwhile, the cylinder rod 35 and the cylinder 36 are rotatably connected to the connection bracket 34 and the frame P, which are coupled to one side of the link 33, respectively.

At this time, the pair of links 33 is configured to be formed inside the portion connected to the frame (P) rather than the portion connected to the fixing bracket 32, the extension and insertion operating range of the cylinder rod 35 It is to.

The link 33 is rotated by the drawing and inserting operation of the cylinder rod 35, and the position correction roller 30 is configured to adjust the position of the deflected fabric 18 while moving.

That is, the position correction roller 30 is for adjusting the position of the far end 18 moved through the contact sensor 52, the far end 18 between the pair of position correction roller 30 It is contacted while passing through to move the deflected opposite side of the fabric 18 to adjust the position.

The sensor rod 40 is a pair for detecting whether both ends of the fabric (18) is located within the sensing range by the sensor detection operation when the fabric (18) falling to the lower portion of the position correction roller 30 passes. To form.

This, one of the pair of sensor rods 40 is formed in the outgoing sensor 41 for transmitting a signal.

On the other hand, the other sensor rod 40 is installed so that the receiving sensor 42 for receiving a signal facing each other so that the far end 18 is out of the detection range when passing through the sensor rod 40.

That is, the transmission and reception sensors 41 and 42 are continuously installed in a long hole (not shown) formed along the longitudinal direction of the sensor rod 40.

The detection range is configured to determine that the far end 18 is biased when the outgoing signal of the outgoing sensor 41 is received by the outgoing sensor 42.

In this way, the fabric 18 passing through the sensor rod 40 is supplied to the supply roller 12 by the transfer drive of the conveyor belt 51, the fabric 18 is zigzag up and down in the top of the Kenvey belt 15 It is placed in the form to ensure the margin when manufacturing the transfer fabric.

As shown in FIG. 1, the paper feeder 60 is a paper roller 61 capable of adjusting a tension force and a feed rate to supply the paper 19 to a lower portion of the fabric 18 supplied to the feed roller 12. Install).

Then, the lower portion of the paper roller 61, the tension force detection roller 62 for sensing the tension force and contacting the paper to be released from the paper roller 61 to convey the rotation speed control signal to the paper roller 61 Install.

As such, the paper 19 passing through the tension force detecting roller 62 is formed to be supplied to the supply roller 12 by the transfer drive of the conveyor belt 63.

At this time, the paper 19 is provided with a plurality of guide rollers (not shown) to the upper portion of the conveyor belt 63 so as not to contact the belt 16 sliding in the belt position adjustment roller (13).

On the other hand, the paper 19 is to use a different paper width 18 in accordance with the width of the fabric 18 to be transferred.

The paper roller 61 of the paper supply unit 60 has no tension force on the paper according to the signal of the tension force detection roller 62 and decreases the rotation speed, and increases the rotation speed when the paper has a lot of tension force. To be configured.

That is, the paper roller 61 adjusts the rotational speed by brake operation according to the signal of the tension force detection roller 62.

On the other hand, by installing the load cell 64 at both ends of the tension force detection roller 62 to transmit a signal sensing the tension force of the paper in contact with the outer peripheral surface of the tension force detection roller 62 to the paper roller (61) Configure.

9 to 10, the both ends of the belt position adjusting roller 13 is provided with moving means 70 and 80 so that the belt 16 is deflected to one side of the heating roller 11 It is configured to adjust the position of the belt 16 by operating the movement means 70, 80 in the front and rear directions by the spindle drive or hydraulic drive away from the center of the).

That is, the movement means 70 and 80 are installed at both ends of the belt position adjustment roller 13, and when one end of the belt position adjustment roller 13 is moved by the operation of the movement means 70 and 80. When turned away from the center of the heating roller 11 to be inclined, the belt 16 is to move along the inclined direction of the belt position adjustment roller (13).

At this time, the moving means 70 is connected to each of the spindle 71 to the bushing (13a) for supporting both ends of the belt position adjustment roller 13, the driving force of the drive means 72 to the spindle 71 Consists of spirally fastening the spindle shaft (73) to receive and rotate.

Here, the drive means 72 may be configured to be connected to one of the spindle shaft 73 and the chain, belt, gear in order to transfer the driving force of the stationary motor 72a to the spindle (71).

The moving means 80 connects one end of the universal joint 81 to a bushing 13a supporting both ends of the belt position adjusting roller 13.

The other end of the universal joint 81 is connected to the driving means 82 so that the driving force is transmitted even when the bushing 13a and the driving means 82 are not located in a straight line.

In this case, the driving means 82 is configured by connecting the cylinder rod 84 to be drawn out and inserted into the cylinder 83 to the other end of the universal joint 81.

At this time, the transfer paper roller (17a), the original roller (18a), the paper roller 61 is formed in two or more transfer paper wound on one transfer paper roller (17a), the original roller (18a), the paper roller (61) (17), the fabric (18), when the paper 19 is finished, another transfer paper roller (17a), the fabric roller (18a), the transfer paper (17) wound on the paper roller (61), the fabric (18), paper ( 19) can be connected and supplied immediately so that the continuous progress of the process is possible.

Hereinafter, the operation and operation of the present invention will be described.

As shown in FIGS. 1 to 14, the manufacturing apparatus 100 supplies hydraulic power to a power switch for controlling a power not shown in the drawing, an emergency switch for emergency stop, a cylinder 36 and a cylinder 83. The control unit is composed of a hydraulic supply control switch for controlling the switch, the outgoing sensor 41 and the receiving sensor 42 of the sensor rod 40 and the operation switch and the sensor control unit of the contact detection sensor 52 and the like.

After that, the power supply is prepared and the transfer paper 17 is wound on the transfer paper roller 17a, the fabric 18 on the fabric roller 18a, and the paper 19 on the paper roller 61, respectively.

Next, while supplying power, the transfer paper 17, the fabric 18, and the paper 19 are unrolled so as to be stacked in the order from the top to the bottom, so that the fabric 18 is the conveyor belt 51 and the paper 19 is the conveyor belt ( 63 is moved by the movement of the 63 and supplied between the belt 16 and the heating roller 11 wound around the supply roller 12.

At this time, the fabric 18 is moved through the guide roller (18b) to pass through while contacting the anti-wrinkle roller 20, the fabric 18 is a rotational force on the anti-wrinkle roller 20 to rotate in the opposite direction to each other By the wrinkles are not generated and flattened.

In addition, the squeegee 21 of the anti-wrinkle roller 20 is in direct contact with the fabric 18 so that no static electricity is generated between the fabric 18 and the anti-wrinkle roller 20 so that the fabric 18 is bundled. Or close to the surface of the anti-wrinkle roller 20 can fundamentally prevent the cause of preventing a smooth supply.

As such, the fabric 18 passing through the anti-wrinkle roller 20 passes between the pair of sensing sensors 52. In the normal case, the fabric 18 is not in contact with the sensing sensor 52. When the far end 18 is in contact with the sensor 52, it is determined that the far end 18 is abnormal in the initial supply position, and when the control unit cuts off the power, the emergency stop state becomes the initial supply position of the far end 18. After correcting, resupply.

And, the fabric 18, which has passed through the sensor 52 without any abnormality, passes between the pair of position correction rollers 30, but the fabric is not detected in the sensor 52 but is slightly out of the supply position. The position of 18 is adjusted.

That is, when the dropping material 18 is deflected to the left and right sides, the cylinder rod 35 is drawn out and inserted by supplying and discharging hydraulic pressure to the cylinder 36.

In this case, when the cylinder rod 35 is drawn out, the link 33 coupled with the connecting bracket 34 is rotated outward due to the drawing operation of the cylinder rod 35.

As a result, the position correction roller 30 fixed to the fixing bracket 32 rotatably connected to the link 33 moves outwardly with the far end 18 to vary the position where the far end 18 is supplied.

In addition, the far end 18 of which the position is corrected and falls is passed between the pair of sensor rods 40.

At this time, the signal transmitted from the outgoing sensor 41 of the sensor rod 40 that is out of the range in which the far end 18 falls to the correct transfer position is received while being blocked by the far end 18 falling out of the transfer position. When received by the sensor 42, the fall position is readjusted.

That is, the fabric 18 can check the supply position of the fabric 18 in real time while passing through the sensor 52, the position correction roller 30, the sensor rod 40 and can be readjusted from time to time The supply failure according to the supply position of the fabric 18 is fundamentally prevented.

In addition, the paper 19 is detected by the load cell 64 while being in contact with the tension force detection roller 62 when being conveyed for supply, the sensed signal is transmitted to the paper roller (61).

When the paper 19 supplied by the transmitted signal is loosely supplied, the rotation speed of the paper roller 61 is reduced to generate a tension force to prevent wrinkles from occurring, and conversely, a tension force is applied to the paper 19. If excessive, the rotation speed of the paper roller 61 is increased to prevent the paper 19 from being torn.

In other words, the supply of the paper 19 is maintained while maintaining a constant tension force to prevent wrinkles from occurring and affecting or tearing the transfer to stop the transfer process.

Thus, the transfer paper 17 supplied in the stacked state is bonded to the fabric 18 by the heat of the heating roller 11 to complete the transfer fabric, the paper 19 is transferred to the transfer paper 17 is transferred to the belt 16 ) Is moved toward the discharge roller 14 by the rotational force of the heating roller 11 and the belt 16 while preventing the deposit on the heating roller 11.

Subsequently, the finished transfer paper waste paper 17 is wound on the waste transfer paper roller 17b, and the transfer paper 18 and the paper are moved and separated from the fabric 18 while the paper 19 is closed. The fabric 18 wound on the paper roller 19a and the transfer is completed is dropped and stored in a separate storage box.

In this case, when the transfer 18 is required to cool the cooling is passed through a plurality of cooling rollers (not shown in the drawing), and then stored in a separate storage space, and the paper 19, respectively, depending on the width It is wound around another waste paper roller 19a.

When the belt 16 is used for a long time in the form of a flat belt, the belt 16 has a heating roller 11, a belt positioning roller 13, a discharge roller 14, and a center of a plurality of idle rollers 15. It is not located in and is pushed to one side and deflected.

As such, when the belt 16 is deflected to one side, the transfer paper 17 and the fabric 18 may not be compressed to be in close contact with the heating roller 11, thereby causing a defect in the transfer.

In this case, the belt position adjusting roller 62 is operated by the movement means 70 and 80 to adjust the position of the belt 16.

First, when the position of the belt 16 is adjusted using the moving means 70, the belt 16 moves the end of the belt position adjusting roller 62 on the side biased from the heating roller 11.

That is, when the stationary motor 72a of the moving means 70 is rotated, the spindle shaft 73 is rotated through the chain, belt, and gear connection.

As the spindle shaft 73 rotates, the end portion of the belt positioning roller 62 moves while the bushing 13a connected while the spindle 71 moves forward and backward.

On the other hand, when adjusting the position of the belt 16 using the moving means 80 to supply and discharge the hydraulic pressure to the cylinder 83 to pull out and insert the cylinder rod 84, the universal joystick 81 moves together While one end of the belt position adjustment roller 62 is moved.

Further, by connecting the cylinder rod 84 and the bushing 13a by using the universal joint 81, even if the cylinder rod 84 and the bushing 13a are positioned out of a straight line, the universal joint 81 is bent and moved. Efficiently delivers no restriction on usage.

Thus, when one end of the belt position adjusting roller 62 is moved away from the center of the heating roller 11, the other end is inclined to maintain a fixed position so that the belt 16 is inclined. The position is adjusted while moving along.

In addition, the position of both ends of the belt positioning roller 62 can be adjusted using the moving means 70 and 80 so that only one side of the belt 16 is moved to adjust the position of the belt 16. Not only is the position adjustment easy and simple, but the deflection elongation of the belt 16 can be prevented, so that the durability can be increased.

In conclusion, the manual process of supplying the fabric 18 and the paper 19 to manpower is improved by an automatic process, thereby increasing the flatness of the process, increasing productivity, and reducing labor costs.

In addition, by checking and adjusting the supply position of the fabric 18 through a sensor, it is possible to fundamentally prevent defective products from occurring during the transfer process due to the poor supply position of the fabric 18, thereby improving the completeness of the product. have.

In addition, by adjusting the tension force when supplying the paper 19, there is an advantage that the defective process does not occur by constantly supplying so that no tearing or loosening occurs.

In the above, the present invention has been illustrated and described with reference to specific preferred embodiments, but the present invention is not limited to the above-described embodiments and is not limited to the spirit of the present invention. Various changes and modifications can be made by those who have

1 is a schematic configuration diagram of a transfer fabric manufacturing apparatus according to the present invention,

2 is a front view of the fabric supply unit,

3 is a front view showing a state in which the fabric is supplied to FIG.

4 is a perspective view of the anti-wrinkle roller,

5 is a perspective view of a position correction roller,

6 is an operation of FIG. 5,

7 is a perspective view of a sensor rod,

8 is a longitudinal cross-sectional view of FIG.

9 is a front view showing the chain driving means of the moving means for adjusting the belt positioning roller;

10 is a front view showing the belt driving means of the moving means for adjusting the belt positioning roller;

11 is a front view showing the gear driving means of the moving means for adjusting the belt positioning roller;

12 is a front view showing the hydraulic drive means of the moving means for adjusting the belt positioning roller;

FIG. 13 is a front view showing a state in which the hydraulic drive means of FIG. 12 is inclined with the belt positioning roller and is bent by the universal joint;

14 is an operation diagram for adjusting the position of the belt by adjusting the belt positioning roller.

<Description of Symbols for Main Parts of Drawings>

10: transfer unit 11: heating roller

12: Feed roller 13: Belt position adjustment roller

14: discharge roller 15: children roller

16: belt 17: transfer paper

18: fabric 19: paper

20: wrinkle prevention roller 21: squary belt

30: position correction roller 32: fixed bracket

33: link 34: connection bracket

35: cylinder rod 36: cylinder

40: sensor rod 41: outgoing sensor

42: receiving sensor 50: fabric supply unit

51: Kenvey belt 60: paper supply unit

61: paper roller 62: tension detection roller

63: conveyor belt 64: load cell

65 bushing 70: moving means

71: spindle 72: drive means

73: spindle axis 80: feed means

81: universal joint 82: driving means

83: cylinder 84: cylinder rod

100: manufacturing apparatus P: frame

Claims (7)

The supply roller 12, the belt positioning roller 13, the discharge roller 14, and a plurality of idle rollers 15 are installed on the front, lower apex, the upper and the rear of the heating roller 11, respectively. ) The outer surface surrounds the circumference of the heating roller 11 and the inner circumferential surface is installed to slide on the outer circumferential surface of the supply roller 12, the belt positioning roller 13, the discharge roller 14, a plurality of idle rollers 15, In the fabric supply apparatus for transfer fabric manufacturing apparatus for manufacturing a transfer fabric by supplying the transfer paper 17, the fabric 18, the paper 19 laminated between the heating roller 11 and the belt 16, A plurality of triangularly arranged anti-wrinkle rollers rotated in opposite directions so that the fabric 18 is unwound from the fabric roller 18a so that the fabric 18 is supplied to the supply roller 12, and the fabric 18 falling vertically is flattened as it passes through. Install 20, The pair of position correction rollers 30 adjust the falling position of the fabric 18 by pivoting in the left and right directions by the hydraulic operation and the link operation while contacting the fabric 18 at the lower portion of the anti-wrinkle roller 20. ), In the lower portion of the position correction roller 30, a pair of sensor rods 40 for detecting whether both ends of the fabric 18 are located within a sensing range by a sensor detecting operation when the fabric 18 falling falls. Forming, fabric transfer unit characterized in that the fabric (18) passing through the sensor rod 40 is composed of a fabric supply unit 50 for supplying to the supply roller 12 by the transfer drive of the conveyor belt (51) Fabric feeder. According to claim 1, A pair of contacts for sensing the supply position of the fabric 18 to both sides of the frame (P) to which the anti-wrinkle roller 20 and the position correction roller 30 of the fabric supply unit 50 is fixed By installing the detection sensor 52, when the fabric 18 that has passed through the anti-wrinkle roller 20 is in contact with the supply fabric manufacturing apparatus, characterized in that the supply is stopped and configured to adjust the initial supply position Feeder. According to claim 1, wherein each of the outer peripheral surface of the wrinkle supply roller 20 of the fabric supply unit 50 is formed by winding the spiral band 21 running in the opposite direction to each other in the form of a spiral fabric (18) anti-wrinkle roller ( 20) A fabric feeder for transfer fabric manufacturing apparatus, characterized in that configured to prevent contact with the surface of. According to claim 1, wherein the position correction roller 30 of the fabric supply unit 50 is vertically spaced apart so that both ends are fixed to the fixing bracket 32, the rear surface and the frame (P) of the fixing bracket (32) A pair of links 33 are rotatably connected to the front of the cylinder, and the cylinder rod 35 and the cylinder 36 are respectively connected to the connection bracket 34 and the frame P, which are coupled to one side of the link 33. ) Is rotatably connected, the link 33 is rotated by the withdrawal and insertion of the cylinder rod 35 and the position correction roller 30 adjusts the position of the deflected end 18 while moving. Fabric feeder for the transfer fabric manufacturing apparatus characterized in that configured to. The fabric of the transfer fabric manufacturing apparatus according to claim 4, wherein the pair of links (33) is configured such that a portion connected to the frame (P) is formed inside rather than a portion connected to the fixing bracket (32). Feeder. According to claim 1, Outgoing sensor 41 for transmitting a signal to one of the sensor rod 40 consisting of a pair of the far-end supply unit 50, the receiving sensor 42 for receiving a signal to the other sensor rod 40 ) Facing each other to install the fabric feeder for the transfer fabric manufacturing apparatus characterized in that the fabric (18) is configured to confirm that out of the detection range when passing through the sensor rod (40). The fabric supply according to claim 6, wherein the sensing range is configured to determine that the far end 18 is biased when the outgoing signal of the outgoing sensor 41 is received by the receiving sensor 42. Device.

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