KR20090044229A - Transfer machine of superconducting wire - Google Patents

Abstract

The present invention relates to a superconducting tape conveying apparatus, comprising: a supply reel unit for drawing and supplying a superconducting tape, a conveying roller unit for conveying the superconducting tape by a rotating roller, and a superconducting tape conveyed by the conveying roller unit A superconducting tape conveying apparatus comprising a collecting reel unit, wherein the conveying roller unit comprises: a plurality of upper rollers disposed in parallel with the supply reel unit; Comprising a plurality of lower rollers are provided spaced apart from the lower portion of the upper roller, the lower roller is one side is inclined by a certain angle by the width of the superconducting tape is characterized in that the superconducting tape is wound on the outer peripheral surface compared to the thickness When manufacturing a very wide superconducting thin film superconducting tape, it prevents deformation from occurring in the width direction of the superconducting tape.In particular, even when the superconducting tape is heated at a high temperature, the superconducting tape is deformed or broken due to the uneven tension caused by the friction difference of each turn. It is effective to prevent.

Reel to reel, superconducting, thin film, roller, strain, superconducting tape

Description

Superconducting Tape Feeder {TRANSFER MACHINE OF SUPERCONDUCTING WIRE}

The present invention relates to a superconducting tape conveying apparatus, and in particular, the movement direction of the superconducting tape wound several times on the roller and the rotational direction of the surface contacting the rollers are the same to deform the superconducting tape due to slip and friction unevenness. It relates to a superconducting tape feeder to prevent.

In general, there are two methods of using superconducting properties, one using microscopic phenomena and the other using macroscopic phenomena. The macroscopic phenomena refers to using the non-resistance and nonmagnetic properties of superconductors, and using microscopic phenomena occurs within superconductors. The tunneling effect is used.

In the case of using the microscopic phenomenon, it is effective to make the superconductor tapered and thin in the form of a superconductor, and researches on this are being actively conducted.

A method of making such a long superconducting tape includes a method of depositing a superconducting layer on the tape while transferring at regular intervals, and a tension-controlled multiturn reel to reel device was proposed in Korean Patent Application Publication No. 08363377 designed for such a transfer device. .

1 is a perspective view of a tension control multiturn reel to reel device according to the prior art.

As shown in Figure 1, the tension control multi-turn reel to reel device consists of a supply reel (10) for supplying a substrate and a multi-turn reel 30 formed of a plurality and the collecting reel (20) winding the supplied substrate, multi-turn reel At the same time as the 30 is rotated about the axis of rotation, each turn reel has the advantage of automatically adjusting the tension of the plate conveyed by the multiturn reel 30 by rolling the bearings.

Figure 2 is a perspective view of a two-roll type according to the prior art, Figure 3 is a plan view of a two-roll type conveying apparatus according to the prior art.

As shown in Figures 2 and 3, the conventional two-roll type feeder is a superconducting tape that is transported while the two rollers are spaced apart from each other and arranged in parallel so that the two rollers rotate in place to wind the superconducting tape It consists of being deposited on one side of.

The two-roll type conveying apparatus thus constructed differs in the rotational direction (a) of each roller in the portion where the superconducting tape abuts from the conveying direction (b) of the superconducting tape by θ °. Therefore, there is a problem that the superconducting tape may be deformed in the superconducting tape to be transferred to the next turn by the force applied in the rotation direction (a) of the two rollers during the transfer.

In addition, such a device is similar in width and thickness to be suitable for the transfer of materials that are insensitive to deformation, and the superconducting tape whose thickness is very small compared to the width has a problem in that hard bending occurs easily in the width direction.

On the other hand, look at the contact angle that the superconducting tape is in contact with both sides of the roller.

4 is a plan view and a cross-sectional view of a two-roll type conveying apparatus according to the prior art.

As shown in FIG. 4, the direction in which the superconducting tape is in contact with the roller (hereinafter, referred to as the superconducting tape contact angle, shown in bold next to the roller in the drawing) is 180 °, and the direction in which the superconducting tape is conveyed is completely reversed. This can cause a large deformation in the superconducting tape.

That is, the superconducting tape is deformed because the superconducting tape is wound along the roller and the conveying direction is changed, and the superconducting tape exiting from the roller while winding along the outer side of the roller is completely changed and the superconducting tape is bent. There is a problem that can be.

In addition, when the superconducting tape is wound several times on the roller, the superconducting tape on the roller is moved at a distance (hereinafter referred to as a transition pitch) from the position previously wound, i.e., 1/2 of the width of the superconducting tape so that it does not overlap between the superconducting tapes. At this time, the superconducting tape is inclined relative to the rotational direction of the roller, so that a force acts in a different direction on the part where the superconducting tape and the roller contact each other, thereby causing the superconducting tape to be damaged or twisted.

5 is a plan view and a cross-sectional view of a three-roll type conveying apparatus according to the prior art.

As illustrated in FIG. 5, the three-roll type feeder has less contact force than the two-roll feeder because the contact angle between the superconducting tape and the roller is 90 ° to 180 ° compared to the two-roll type feeder. As in the case of a two-roll feeder, the transition pitch is 1/2, and the superconducting tape moved by the transition pitch acts in different directions in contact with the roller, so that the superconducting tape rotates in the direction of the superconducting tape. Compared to the roll type feeder, there is a problem that may cause deformation of the superconducting tape due to the weakness of the force.

The present invention has been made to solve the problems described above, the lower roller is inclined so that the moving direction of the superconducting tape and the roller rotation direction is parallel to the superconducting tape of the superconducting tape is very thin compared to the length of the superconducting tape An object of the present invention is to provide a superconducting tape feeder that prevents deformation and breakage.

In order to achieve the above object, the present invention winds the supply reel unit for drawing and supplying the superconducting tape, the conveying roller unit for conveying the superconducting tape by the rotating roller, and the superconducting tape conveyed by the conveying roller unit. A superconducting tape conveying apparatus comprising a collecting reel unit, wherein the conveying roller unit comprises: a plurality of upper rollers disposed in parallel with the supply reel unit; It comprises a lower roller which is provided with a plurality of spaced apart to the lower portion of the upper roller, the lower roller is characterized in that the one side is inclined at an angle by the width of the superconducting tape, the superconducting tape is wound on the outer peripheral surface.

The lower roller may include a first lower roller which is inclined at a predetermined angle and vertically redirects and transfers the superconducting tape supplied from the upper roller; It is preferable that the one side is inclined by the width of the superconducting tape so that the superconducting tape is transported in parallel; second lower roller.

Here, the upper roller, characterized in that consisting of a pair of rollers spaced apart from each other to transport the superconducting tape supplied in parallel.

Here, the upper roller and the lower roller, it is preferable that the receiving groove for receiving the superconducting tape is formed on the outer peripheral surface.

Here, the receiving groove, the width is preferably formed to the width of the superconducting tape.

According to the present invention, since the driving direction of the roller is moved together with the moving direction of the superconducting tape and the surface in contact with the roller, there is an effect of preventing deformation due to slip and friction unevenness generated in the superconducting tape.

In addition, even if the superconducting tape is heated to a high temperature due to the deposition at high temperature, there is an effect of preventing the superconducting tape from being deformed or broken due to the nonuniform tension caused by the frictional difference of each turn.

Figure 6 (a) is a plan view of the transfer device of the superconducting tape according to the present invention, Figure 6 (b) is a plan view of the upper roller according to the present invention, Figure 6 (c) is a lower roller according to the present invention Top view of the.

As shown in FIG. 6, the present invention provides a feed reel unit 100 for supplying a superconducting tape, and a transfer transported with a predetermined distance so as to deposit a superconducting tape supplied from the supply reel unit 100 at one side. It consists of a roller unit 200 and a collecting unit 300 for collecting the superconducting tape deposited, the transfer roller 200 is composed of an upper roller 210 and a lower roller 220.

First, the supply reel unit 100 is formed of a circular reel to form a circular plate for fixing the superconducting tape to be transported on both sides, the superconducting tape is wound around the space generated between the circular plate to the transfer roller 200 to be described later And to rotate in place in one direction to supply the superconducting tape.

Next, the upper roller 210 of the conveying roller unit 200 is composed of a plurality of rollers of the same shape, in particular, the first upper roller 212 and the first upper portion for switching the conveying direction of the superconducting tape to be conveyed It is preferable that the second upper roller 214 is installed to be spaced horizontally and parallel to the roller 212 so as to respectively rotate in place to transfer the superconducting tape.

Next, the lower roller 220 of the feed roller unit 200 is composed of a plurality of rollers having the same shape as the upper roller 210, preferably a pair of rollers on one side of the upper roller 210 It is spaced apart from and rotated in place to transfer the superconducting tape.

Here, when the superconducting tape is wound several times on the outer circumferential surface of the lower roller 220, the pitch is the sum of the width and the free space of the superconducting tape conveyed compared to the upper roller 210 so that the superconducting tape does not overlap and is conveyed in parallel. One side of the lower roller 220 is inclined and rotated by the distance of the superconducting tape to be formed in parallel.

Here, the superconducting tape wound on the supply reel unit 100 is released at a constant speed and wound around the lower roller 220 via the roller 210 to be transported, and the superconducting tape conveyed from the lower roller 220 is Winding again on the upper roller 210 is repeated so that the superconducting tape is transported to deposit the superconducting material from the outside spaced at a predetermined interval.

At this time, the upper roller 210 and the lower roller 220 is rotated in place to move the superconducting tape, wherein the rotation direction of the upper roller 210 to which the superconducting tape is in contact with the conveying direction of the superconducting tape is the same and superconducting Since there is no other force on the tape, the superconducting tape can be transferred without deformation.

On the other hand, we will look more closely at the operating principle of the superconducting tape is conveyed through the conveying roller.

 7 is a cross-sectional view and a plan view of a joist superconducting tape conveying apparatus according to the present invention.

As shown in FIG. 7, when the supplied superconducting tape is transferred downward through the A point of the first upper roller 212, the superconducting tape is transferred to the B point of the second lower roller 224. The superconducting tape is transported and wound to the point C of the second lower roller 224, one side of which is inclined by one pitch in parallel, and the superconducting tape is repeatedly transferred to the point D of the second upper roller 214 in parallel. Is wound around the outer circumferential surface of the roller several times, and the superconducting material is deposited on the superconducting tape by an external deposition apparatus.

At this time, the first upper roller 212 and the first lower roller 222 are disposed up and down substantially in parallel, and at this time, the first lower roller 222 is slightly inclined on one side and the second lower roller 224. The superconducting tape conveyed through is formed to be conveyed in parallel.

On the other hand, when comparing the line extending in parallel and vertically in the second upper roller 214 and the second lower roller 224, one side of the second lower roller 224 of the second upper roller 214 One side and one pitch (the sum of the width of the superconducting tape and the free space) are inclined so as to be different, and the other side of the second lower roller 224 is also provided so that the superconducting tape is transferred to the first lower roller 222 without deformation. It is inclined by a distance smaller than the pitch.

Therefore, in the conventional conveying apparatus consisting of two or three rollers, the contact angle between the superconducting tape and the roller is 180 degrees, so that the tension on the rollers is not dispersed, but the conveying apparatus according to the present invention has a contact angle between the tape and the rollers. Superconductivity is not applied because the tension applied is small and the superconducting tape is parallel to the roller's longitudinal direction at the point where the superconducting tape and roller are in contact with each other. The deformation of the tape can be prevented.

In addition, the outer circumferential surface of the roller of each transfer roller unit 200 is formed so that the superconducting tape is transported in parallel so that the receiving groove 213 is formed to accommodate the superconducting tape without overlapping each other when the superconducting tape is wound several times. do.

Finally, the collecting reel 300 is formed of a circular reel to form a circular plate for winding and fixing the superconducting tape to be transported on both sides, and is formed so that the superconducting tape is wound in the space generated between the circular plates.

The collection unit 300 collects and winds a superconducting tape on which a superconducting material is deposited while being transported for a predetermined distance by the transporting roller unit 200 while rotating in place.

The foregoing has outlined rather broadly the features and technical advantages of the present invention in order to better understand the claims of the invention which will be described later. It should be appreciated by those skilled in the art that the conception and specific embodiments of the invention disclosed may be readily used as a basis for designing or modifying other structures for carrying out similar purposes to the invention.

In addition, such modifications or altered equivalent structures by those skilled in the art as a basis for modifying or designing the structures and embodiments of the invention disclosed in the present invention to other structures for carrying out the same purposes of the present invention are patents Various changes, substitutions and changes may be made without departing from the spirit or scope of the invention as set forth in the claims.

1-perspective view of a tension control multiturn reel to reel device according to the prior art.

2-a perspective view of a two-roll type conveying apparatus according to the prior art.

3-a plan view of a two-roll type conveying apparatus according to the prior art.

4-a plan view and a sectional view of a two-roll type conveying apparatus according to the prior art;

5-a plan view and a sectional view of a three-roll type conveying apparatus according to the prior art;

Figure 6 (a)-plan view of the transfer device of the superconducting tape according to the present invention.

6b-top view of the upper roller according to the invention;

6c-top view of the lower roller according to the invention;

7-A cross-sectional view and a plan view of a superconducting tape conveying apparatus according to the present invention.

** Description of the symbols for the main parts of the drawings **

100: supply reel 200: feed roller portion

210: upper roller 212: first upper roller

213: receiving groove 214: second upper roller

220: lower roller 222: first lower roller

224: second lower roller 300: collecting reel

Claims (5)

Winding and collecting the supply reel unit 100 for drawing and supplying the superconducting tape, the conveying roller unit 200 for conveying the superconducting tape by the rotating roller, and the superconducting tape conveyed by the conveying roller unit 200 In the superconducting tape transfer device consisting of a collecting reel 300, The feed roller unit 200 includes a plurality of upper rollers 210 arranged in parallel with the supply reel unit 100; Comprising a plurality of lower rollers 210 are installed spaced apart from the lower portion of the upper roller 210, The lower roller 210 is a superconducting tape transport apparatus, characterized in that one side is inclined at an angle by the width of the superconducting tape so that the superconducting tape is wound on the outer circumferential surface. The method of claim 1, wherein the lower roller 220, A first lower roller 222 which is inclined at a predetermined angle and transfers the superconducting tape supplied from the upper roller 210 in a vertical direction; And a second lower roller (224) on which one side is inclined by the width of the superconducting tape so that the superconducting tape is parallelly conveyed. The method of claim 1, wherein the upper roller 210, A superconducting tape feeder, characterized in that consisting of a pair of rollers spaced apart from each other to transport the superconducting tape supplied in parallel. According to any one of claims 1 to 3, wherein the upper roller 210 and the lower roller 220, Superconducting tape transfer apparatus, characterized in that the receiving groove (213) for receiving the superconducting tape is formed on the outer peripheral surface. The method of claim 4, wherein the receiving groove 213, Superconducting tape transfer apparatus characterized in that the width is formed by the width of the superconducting tape.

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