DE1270688B - Winding support for the production of saddle-shaped, superconducting, electrical coils from a flat conductor strip - Google Patents

Description

Winding supports for the production of saddle-shaped, superconducting, electrical coils made from a flat conductor strip The invention relates to Winding supports for the production of saddle-shaped, superconducting, electrical Coils from a flat conductor strip.

The invention is based on the task of producing saddle-shaped, to facilitate superconducting, electrical coils from a flat conductor strip.

For a better understanding of the invention, let us first consider the structure of superconducting Magnetic coils briefly described.

The in some proposed large superconducting magnet coils The amount of energy stored is measured in terms of ten times megajoules. Such a solenoid, which stores this enormous amount of energy, returns in an uncontrolled manner If you return to the normal conducting state, it is definitely a complete one Destruction of the magnet coil and its immediate vicinity is to be expected. It is therefore essential that the superconducting magnet coils are operationally safe, d. that is, a circuit must be provided to protect such superconducting magnet coils are used in the event that they return to the normal conducting state during operation. According to an older proposal, superconducting magnet coils can have a large field strength are made operationally safe by the arrangement of inductive shields Segments or preferably layers of winding around that contain all of the magnetic flux Try to keep it constant so that the current in the winding can slowly decay.

It is desirable to protect superconducting coils between Layers of the superconducting coil provide inductive shields made from strips of a highly conductive non-magnetic material and which are in the Keep the energy consumed in the coil to a low level. Or in other words, as a result of the inductive coupling, the inductive shields prevent growth the current flowing in the coil during the transition from one to the other Line condition. The inductive shielding captures most of the surge in current on, which has so far been taken from the position adjacent to a normally conducting area This would delay the spread of the normally conducting region.

Flat conductor strips and the arrangement of the inductive shield between However, the layers of a coil make the production of superconducting magnets difficult with a saddle-shaped shape extraordinarily. While ordinary wire is double can be bent in a curved manner, this is the case with strip-shaped or flat conductors not the case. A strip of material has a preferred axis for bending up, and if there is a bending against the great moment of the axis of inertia, it humps the conductor so that the electrical windings or coils are not tight enough can be produced packed. Though ordinary wire on a cylinder can be successfully wound up in the shape of a saddle, a strip of material cannot treated in this way, since the strip would have to be double-curved, to be able to follow the outline of the cylinder. In the case of strip-shaped material that should be wound in the same way as the ordinary wire, the Strip can be broken into many pieces to make the bends on essentially one limit only curvature. However, such a solution is not desirable.

Saddle-shaped, superconducting coils are said to have a large winding factor have and can also be produced in a simple and economical manner.

The invention aims at a winding support, its configuration it enables an endless tape to be wound into a saddle-shaped spool, which has a high winding factor, is simple and economical to manufacture. Of the Winding supports for the production of saddle-shaped, superconducting, electrical Coils made from a flat conductor strip according to the invention is characterized in that that the support body has a shape that has arisen in that as a Starting body serving flat hollow cylinder two diametrically opposed parts around their tangents lying in the middle of the cylinder height as axes of rotation rotated so that the upper or lower edges of these parts towards each other and their lower and upper edges are moved away from each other, with the intervening Parts of the hollow cylinder deform accordingly.

The material of the winding carrier can be made of non-magnetic metallic Material. The inwardly directed parts of the hollow cylinder are preferably essentially flat surfaces, and those located between them outwardly directed parts of the hollow cylinder are practically in one plane, which forms an acute angle with the first-mentioned flat surfaces, the remaining connecting parts are conical.

The invention is based on the fact that in such Rotation of diametrically opposite parts of the cylinder into diametrically opposite ones radial directions the surface formed by the coil bends only in a single Has curvature, creating a shape that will later be followed by other layers of the strip can be wound up without bulging, as the circumference of this Surface has a constant length from a peripheral edge along lines which in the direction of width at a given and constant distance.

The invention is described in detail below with reference to the drawings for example, in which F i g. 1 is a diagrammatic representation of a cylindrical part which serves as a starting body, F i g. 2 a graphical one Representation of the part according to FIG. 1, which after deformation has a winding carrier forms according to the invention, F i g. 3 is a pictorial representation of another Embodiment of a winding support according to the invention with a support surface for a saddle-shaped electrical coil made from a flat conductor strip and FIG. 4 one Diagrammatic representation of a winding support according to FIG. 3 wound Winding from a flat conductor tape.

From the F i g. 1 and 2 the basic idea of the invention can be seen. The in FIG. 1 shown flat, hollow cylindrical part 11 can be viewed as a one-piece and thin-walled body, which consists of a layer of wire, which is wound on a conventional cylindrical shape. The axes 13 and 14, which are perpendicular to one another and on the longitudinal axis 12 of the flat hollow cylinder 11, cut through the part 11 at four equally distant points 15, 16, 17 and 18. B. counterclockwise, a positive direction of a circumferential line that intersects the points and which is shown by the broken line 19 can be determined. The aforementioned axes, points and the circumference are also shown in FIG. 2 shown as reference elements. The in FIG. 1 is not intended to form a rigid unit. Therefore, upon rotation of the upper edge 21 of the opposing, z. B. the parts containing the points 15 and 17 in diametrically opposite directions, so to speak away from each other, as in FIG. 2 indicated by the arrows 22 and 23, the part 11 according to FIG. 1 essentially as shown in FIG. 2 take the form shown. The same result can of course also be obtained if the upper edge 21 of the opposing parts containing the points 16 and 18 is twisted inwards towards one another, as is indicated by the arrows 24 and 25. Accordingly, the desired shape of the part forming the winding carrier is achieved when diametrically opposite parts of the flat hollow cylinder are rotated in diametrically opposite directions, regardless of whether the direction of rotation is facing or facing away from the longitudinal axis 12. It is important that the bends in part 11 of FIG. 2 have essentially only a single curvature. Since the scope of the part 11 according to FIG. 2 remains constant along imaginary lines at a given and constant distance of z. B. the upper edge 21 of the part, a strip-shaped material can be wound onto the outside of the part without bulging, with each layer lying against the adjacent layers at practically all points, so that the winding can be carried out with the greatest possible winding factor.

According to FIG. 2, the outside 26 of the part 11 is the wing and is of course ring-shaped and self-contained. Points 15 and 17 are located in a plane containing axes 12 and 13, while points 16 and 18 in a plane containing the axes 12 and 14 lie. Accordingly, by an imaginary connection of these points along the lateral surface has a positive direction of the revolution along the circumferential line 19 can be set. In FIG. 2 are further lines 35, 36, 37 and 38, which are parallel to the longitudinal axis 12, through the Points 15, 16, 17 and 18 drawn.

According to FIG. 2, the position of the sub-areas designated by 15 a, 16 a, 17 a and 18 a, which contain the points 15, 16, 17 and 18, respectively, can be identified in that the above-mentioned imaginary circumferential line 19 and its positive direction of rotation as a reference element lines 35, 36, 37 and 38 are used, which run parallel to the longitudinal axis 12 and pass through these points. The positive direction of the revolution is indicated by the arrow 39. When viewed in the positive direction of rotation 39, the sub-area 15 a containing the point 15 forms an angle (arrow 45) with the line 35 , measured clockwise around the circumferential line 19, the sub-area 16 a containing the point 16 forms with the line 36 an angle (arrow 46), measured counterclockwise, the partial surface 17 a containing the point 17 forms an angle (arrow 47) with the line 37, measured clockwise, and the partial surface 18 a containing the point 18 forms with the line 38 an angle (arrow 48), measured counterclockwise. Furthermore, the parts 41, 42, 43 and 44, the bends of which have essentially only a single curvature, lie between the mentioned partial surfaces 15 a, 16 a, 17 a and 18 a and connect them to one another. The angles mentioned are marked with arrows 45, 46, 47 and 48, which each begin at the aforementioned imaginary lines and end at the peripheral edge 21 of the winding support 11. The end points of the arrows 45, 47 and 46, 48 are located in planes which contain the longitudinal axis 12 and the axis 13 or and the axis 14, respectively.

The shape of the winding support according to the invention can be varied greatly. This can be shown very simply and clearly in that a cylinder according to FIG. 1 is made and twisted in the manner described above. Here, diametrically opposed parts can be rotated by a full 180 °, moved back and forth in the direction of one another and the distance between these parts can be changed from a greatest distance down to the value zero; the parts can be designed so that they run parallel or not parallel to each other, and the diametrically opposed parts 15 a and 17 a can, for example, lie in the same plane or be curved, and the diametrically opposed parts 16 a and 18 a can also be flat or be curved. Furthermore, the parts 41 to 43, either separately or together, can have a generally conical, cylindrical, elliptical, parabolic or similar shape. In either case, however, a winding of a strip-shaped material can be wound on the mold without bulging, because the circumference remains constant along lines extending from a peripheral edge of the mold in the direction of width at a given and constant distance .

F i g. 3 shows an embodiment of the winding support according to the invention. The partial areas 15 a and 17 a are in the same plane, and the partial areas 16 a and 18 a are flat. The remaining parts 41, 42, 43 and 44 have a generally conical shape. However, all parts or parts that are bent have bends with essentially only a single curvature. The lugs 51 and 52 running essentially in the direction of the axis 14 and the lugs 53 and 54 running essentially in the direction of the longitudinal axis 12 facilitate the winding of the coil and give the winding support additional rigidity. The winding support is preferably made of copper so that it can also act as an inductive shield.

F i g. 4 shows a coil made of a strip-shaped material 55, that on the in the F i g. 3 shown form of the winding support wound is.

Since there are many for the general shape of the support body described above There are different designs, so can a support body according to the invention depending on the various factors, the most important of which is the complexity of the chosen Form is, by casting, molding and / or machining, or by Manufacture the surface to be made in sections.

A support body which is shown in FIG. 3 shown form, which is practical and is in favor of the conventional calculation and manufacturing processes suitable, consists of four sections that are shaped on a conical base and afterwards were united with one another into a single member. In this Case was (Fig. 3) each of the four sections which are essentially from the axes 13 and 14 are delimited individually by bending flat straight strips one at a time Materials, e.g. B. copper, made around a suitable conical shape, after which cut the strips to a predetermined length and then into one annular surface with the required shape of the support body according to the invention were welded together. The sections containing the parts 41 and 43 are equal to each other for all practical purposes. The parts 42 and 44 containing Sections are also alike for all practical purposes; However these are curved in the opposite direction as those of the parts 41 and 43 containing sections, d. that is, two sections are curved to the left.

Taking into account, among other things, the required distance W between parts 15 a and 17 a, the length L of the support body shape and the height H of each part 16 a and 18 a, an included angle is selected for the (not shown) conical shape in which the smallest amount of conductor is required to generate the required magnetic field compared to the required volume.

Based on the conventional geometrical considerations, now the orientation of the conical shape can be chosen with respect to the axis 14, the a self-contained wing, the required crossing height H in the direction of the axis 12, the distance W in the direction of the axis 13 and the length L in the direction the axis 14 results. Around the conical shape you can now use the appropriate Make two right and two left sections bent to the required length cut to size and finally formed into a support body 11 substantially in the F i g. 3 form shown are welded together. If necessary or is held as desired, the lugs 51 to can then be provided on the support body 11 54 molded or welded.

Although the support body 26 according to FIG. 3 actually made up of sections is composed, its shape is from the outside of a flat hollow cylinder determined who obtained this shape by the deformation specified in claim 1 has by placing diametrically opposed parts in radially opposite Directions have been twisted. Accordingly, the scope of the load-bearing Surface 26 has a constant length of longitudinal lines extending from a peripheral edge of the surface from extending at a given and constant distance, and has bends with essentially only a single curvature.

Claims (3)

Claims: 1. Winding support for the production of saddle-shaped, superconducting, electrical coils made from a flat conductor strip, d a d u r c h G e k e n n -z e i c h n e t that the support body has a shape that was created by it is that when serving as a starting body flat hollow cylinder two diametrically opposite parts about their tangents lying in the middle of the cylinder height are rotated as axes of rotation so that the upper or lower edges of this Divide towards each other and their lower and upper edges, respectively from each other be moved away, the intermediate parts of the hollow cylinder moving accordingly deform. 2. winding carrier according to claim 1, characterized in that its Material consists of non-magnetic metallic material. 3. Winding support according to claim 1 or 2, characterized in that the towards one another, inwardly directed parts (16 a, 18 a) of the hollow cylinder are substantially flat surfaces and the outwardly directed parts (15 a, 17 a) located between these ) of the hollow cylinder are practically in a plane which forms an acute angle with the first-mentioned flat surfaces (16 a, 18 a), the other connecting parts being conical.