Patent Number: 044977670
Section: description

DESCRIPTION OF A PREFERRED EMBODIMENT Referring now to the drawing, and more particularly to FIG. 1 thereof, there is illustrated therein a portion of a fusion reactor system of the Tokamak-type. More specifically, there is depicted in FIG. 1 of the drawing, a compression hub, generally designated by reference numeral 10, constructed in accordance with the present invention. Cooperatively associated with the compression hub, as shown in FIG. 1, are a plurality of superconducting magnets 12. Inasmuch as all of the superconducting magnets 12 are of identical construction, it has been deemed appropriate to designate each of the magnets by means of the same reference numeral, i.e., 12. In accordance with the illustrated embodiment of the invention, the superconducting magnets 12 comprise six in number. Although the compression hub 10 is intended to be employed in a Tokamak-type fusion reactor system, it is not deemed necessary for purposes of obtaining an understanding of the present invention that a complete description of the nature of the construction and the mode of operation of such a fusion reactor system be set forth herein and/or illustrated in the drawing. Rather, it is deemed sufficient to merely note herein that in accordance with the mode of operation of such a fusion reactor system, thermal power is generated as a consequence of the ignition of plasma. Moreover, there exists a need to effect confinement of the plasma. The latter function, in turn, is accomplished magnetically through the use of a plurality of superconducting magnets, such as the superconducting magnet 12 shown in FIG. 1 of the drawing. Namely, the magnets 12 are capable of generating intense magnetic fields of sufficient strength to achieve the desired confinement of the plasma. In order to be operative for its intended purpose, there are basically two major functional requirements that the compression hub 10 must be capable of fulfilling. First, the compression hub must be capable of successfully resisting the intense forces produced by the magnets 12 tending to draw the latter together towards a common point. Secondly, the compression hub 10 must be susceptible to being cooled to the same relative temperature as the superconducting magnets 12; namely, to a cryogenic temperature of approximately 4.2.degree. kelvin. Moreover, the latter cooling of the compression hub 10 must be achieved without adversely affecting the structural strength thereof. Proceeding now with a description of the nature of the construction of the compression hub shown in FIG. 1, reference will be had for this purpose particularly to FIGS. 2, 3 and 4 of the drawing. Thus, with reference first to FIG. 3 of the drawing, there is depicted therein a prior art form of compression plate, the latter being designated therein generally through the use of the reference numeral 14. In accord with the teachings of the prior art, and as exemplified by the description thereof contained in previously referenced U.S. Pat. No. 4,174,254, the compression plate 14 is designed to be employed as one of a multiplicity of such plates which when suitably assembled one with another collectively function to produce a prior art form of compression hub. Inasmuch as the details of construction and the mode of operation thereof can be adequately found set forth in the aforementioned patent, it is not deemed necessary that they be reiterated herein. Rather, it is deemed sufficient to merely take note of the fact that the compression hub 14 is suitably constructed so as to embody the requisite means whereby the strength and cooling characteristics that a compression hub must possess in order to be operative for its intended purpose when employed in a Tokamak-type fusion reactor system are achievable therewith. To this end, the compression plate 14 is formed of aluminum, stainless steel, or some other metal suitable for employment for purposes of resisting substantial forces at cryogenic temperatures. Further, the compression plate 14 embodies a polygonal shape, i.e., that of a hexagon. In addition, the upper and lower planar surfaces of the compression plate 14 both have formed therein a suitable number of recesses (not shown). The latter recesses (not shown) are suitably located in spaced relation one to another and are suitably dimensioned so as to each be capable of receiving therewithin a shear member 16. The function of the shear members 16 is both that of a force resisting member and that of a spacer. Namely each shear member 16 functions as a torque and shear force resisting member to resist the forces imparted to the compression plate 14 as a consequence of the action of the superconducting magnets cooperatively associated therewith. With regard to the spacer function, each shear member 16 operates to effect a spacing between adjoining, superimposed compression plates 14. The shear members 16 are maintained in the aforementioned recesses (not shown) by virtue of the fact that adjoining, superimposed compression plates 14 are interconnected along their perimetric surfaces such as by means of welding. The inherent strength of the individual compression plates 14 as well as the manner of effecting the interconnection therebetween is operative to provide a prior art form of compression hub that embodies the requisite degree of strength so as to be usable in Tokamak-type fusion reactor system. In conclusion, provision is also made for coolant flow between adjoining, superimposed compression plates 14 by providing each of the latter with a suitable number of openings. More specifically, as shown in FIG. 3 the compression plate 14 is provided with an opening 18 formed therein so as to be located in proximity to one of the hexagonal corners thereof. Moreover, the compression plate 14 has a larger opening 20 formed at the center thereof so as to extend completely therethrough the same as the previously described opening 18. For purposes of clarity of description, another small opening, identified by reference numeral 22, is depicted in FIG. 3 by means of phantom lines. The latter is shown located adjacent one of the other hexagonal corners of the compression plate 14. The opening 22 is intended to depict an opening similar to the opening 18, but one which is suitably provided in the compression plate (not shown) that is located below the compression plate 14 illustrated in FIG. 3. To summarize, the openings 18, 20 and 22 function to establish, along with similar openings provided in others of the multiplicity of compression plates 14, a fluid flow passage for coolant through the compression plates 14 in a manner which can be found more fully described in U.S. Pat. No. 4,174,254. In accord therewith, a prior art form of compression hub is provided that is capable of being cooled to the desired cryogenic temperature. The compression hubs embodying prior art forms of construction that have been known heretofore are disadvantageously characterized in the fact that the constructions which they embody permit eddy currents, which may be induced therein as a consequence of the occurrence of changes in magnetic field flux, to circulate therethrough. The existence in such compression hubs of freely circulating eddy currents in turn provide various losses in the form, for example, of the creation of heat losses, that can have an adverse effect on the performance characteristics of the compression hub. Thus, a need has been evidenced for a new and improved form of compression hub, which is advantageously characterized in the fact that eddy currents, which may be induced in the compression hub from changes in magnetic field flux, are prevented from circulating therethrough. Namely, a need has been evidenced for a compression hub with eddy current prevent means. Moreover, the compression hub 10 shown in FIG. 1 and which is now to be described hereinafter comprises such a compression hub with eddy current prevent means. As best understood with reference to FIGS. 4 and 2 of the drawing, the compression hub 10 embodies, yet to be described, eddy current prevent means, the latter being operative to impede the circulation through the compression hub 10 of eddy currents that may be induced therein due to changes in magnetic field flux. In accord with the preferred form of the invention, the aforesaid eddy current prevent means comprises means with which each of the compression plates that collectively comprise the compression hub 10 is provided. More specifically, the compression hub 10, as best understood with reference to FIG. 2, consists of a multiplicity of compression plates 24 that are superimposed one upon the other so as to form a layered assembly thereof. Each of the compression plates 24 embodies a polygonal shape, i.e., that of a hexagon. However, some other form of a multi-sided figure could be utilized without departing from the essence of the invention. Moreover, each of the plates 24 is formed from a suitable material that is capable of providing the strength characteristics desired at cryogenic temperatures. Preferably, the compression plates 24 are suitably interconnected along their perimeters as a result of being welded one to another. As will be described more fully hereinafter, the compression plates 24 are each provided with suitable flow passages whereby coolant can be made to flow through the compression hub 10. To this end, the compression hub 10 is provided with suitable inlet means and outlet means whereby coolant can be fed to the compression hub 10 and after the passage therethrough can be removed therefrom. Inasmuch as such inlet means and outlet means are of conventional construction which is well-known to those skilled in the art, it is not deemed necessary to further describe them herein. In accord with the illustration of the compression hub 10 in the drawing of the instant application, the aforementioned outlet means has been depicted in FIG. 2 wherein it is identified by the reference numeral 26, whereas a showing of the aforementioned inlet means is omitted from the drawing. Proceeding now with a more detailed description of the nature of the construction of the compression plates 24, reference will be had for this purpose to FIGS. 4 and 5 of the drawing. In accord with the present invention, alternative forms of construction for the compression plates 24 are disclosed. More specifically, alternative constructional forms for the eddy current prevent means with which the compression plates 24 are provided are disclosed. Thus, referring first to FIG. 4 of the drawing, there is illustrated therein a compression plate 24 which in structure bears a resemblance to the prior art form of compression plate 14 described previously above, and illustrated in FIG. 3. That is, the compression plate 24 as noted above embodies a hexagonal configuration and is made of a material that possesses the strength desired at cryogenic temperatures. In addition, the compression plate 24 shown in FIG. 4 is provided with a plurality of suitable recesses (not shown) in each of which a shear member 28 is designed to be suitably received such that the latter is captured therein when another compression plate 24 is superimposed thereover. Like the shear member 16 with which the prior art compression plate 14 is provided, the shear member 28 is intended to not only offer resistance to the torque and shear forces which are imparted to the compression hub 10 from the superconducting magnets 12, but also to establish the desired spacing between adjacent compression plates 24. Continuing with the description of the compression plate 24 of FIG. 4, the latter further includes a plurality of openings, i.e., the small opening 30 provided therein adjacent one of the hexagonal corners of the plate 24 and the larger opening 32 formed substantially at the center thereof. The openings 30 and 32 are operative in the manner of the openings 18 and 20 of the compression plate 14 to establish a flow passage through the compression plate 24 as well as between adjacent compression plates 24. To this end, there is depicted in phantom lines in FIG. 4 another small opening, identified therein by the numeral 34, which is intended to denote the small opening similar to the opening 30, which is formed in the plate 24 that is located directly below the plate 24 that is shown in FIG. 4. Note is taken here of the fact that preferably the compression plates 24 are suitably positioned relative to each other so as to form a layered assembly wherein the openings 30 are offset as between adjacent plates 24. This is best understood with reference to FIG. 2 of the drawing. The compression plate 24, unlike the prior art compression plate 14, embodies an eddy current prevent means that is operative to impede the circulation of induced eddy currents therethrough. In this end, the compression plate has a radial cut provided therein. The latter radial cut extends from the outer perimeter of the plate 24 to the inner perimeter thereof, i.e., the surface that defines the circumference of the large opening 32. Furthermore, the radial cut extends completely through the plate 24, i.e., through the entire thickness of the latter. Finally, in accord with the best mode embodiment of the invention, the afore-described radial cut which effectively forms an interruption in the circumference of the plate 24 has inserted therein a suitably dimensioned and configured piece 36 of insulative material. Any suitable known type of material possessing the desired insulative characteristics and capable of being employed at the cryogenic temperatures to which the compression plates 24 are designed to be cooled may be employed. Moreover, any conventional form of securing means may be employed for purposes of retaining the piece 36 of insulative material in place within the afore-described radial cut. It is to be understood that in accord with the best mode embodiment of the invention each of the compression plates 24 which the compression hub 10 embodies would be provided with such a radial cut in which a piece 36 of insulative material is emplaced. Moreover, as best understood with reference to FIG. 2 of the drawing, the compression plates 24 are preferably suitably arranged when in the assembled condition such that the insulative pieces 36 are offset relative to each other at least as between adjacent plates 24. For purposes of completing the description of the compression plates 24 of FIG. 4, note is taken of the slots 38 that are provided in the outer surfaces of each of the six sides thereof. The slots 38 extend the full thickness of the plate 24, and are intended to be operative for purposes of effecting the interconnection of the superconducting magnets 12 to the compression hub 10. To this end, each of the superconducting magnets 12 embodies a protrusion 40, as shown in FIG. 1, which is designed to be received within a corresponding one of the slots 38. Inasmuch as the function of the slots 38 and protrusions 40 is not related directly to the subject matter of the present invention, any further discussion of the nature of the construction and/or mode of operation thereof has been omitted from herein. Should a further description thereof be desired, reference may be had for this purpose to the teachings thereof that are to be found contained in the prior art. Turning next to a consideration of the structure that is to be found illustrated in FIG. 5 of the drawing, the latter Figure depicts a compression plate constructed in accord with the teachings of the present invention that embodies an alternative form of eddy current prevent means. More specifically, there is shown in FIG. 5, a compression plate, generally designated by the reference numeral 24', which is basically similar in construction and mode of operation to the compression plate 24 illustrated in FIG. 4 that has been described hereinabove. In view of the similarity therebetween, any elements of the compression plate 24' of FIG. 5 that find correspondence with an element of the compression plate 24 of FIG. 4 is identified in FIG. 5 through the use of the same reference numeral that has been employed in FIG. 4 for designating the similar element therein, but with the addition in FIG. 5 of a prime to the numeral. Thus, by way of a brief description of the nature of the construction of the compression plate 24', the latter embodies the shape of a hexagon, and is formed from a suitable material possessing adequate strength at cryogenic temperatures. A plurality of shear members 28' are received in recesses (not shown) provided for this purpose in both the upper and lower planar surfaces of the plate 24'. Openings 30' and 32' of differing dimensions are suitably formed in the plate 24' so as to be operative as flow passages for coolant. There is also shown in phantom lines in FIG. 5 an opening 34' that is formed in the plate 24' which lies immediately below the plate 24' that appears in FIG. 5. Slots 38' are provided in the outer surface of each of the six sides of the plates 24', and are designed to cooperatively receive therewithin the protrusions 40 with which the superconducting magnets 12 are provided. As stated above, the compression plate 24' of FIG. 5 differs structurally from the compression plate 24 of FIG. 4 insofar as concerns the eddy current prevent means which the former embodies. By way of reiteration, in both cases, the function of the eddy current prevent means is to impede the circulation of induced eddy currents through the compression plate, be it the plate 24 of FIG. 4 or the plate 24' of FIG. 5. To this end, both the plate 24 and the plate 24' are provided with at least one interruption that is formed in the circumference thereof. In the case of the plate 24 of FIG. 4, as has been described above, the interruption takes the form of a radial cut that is suitably located therein, and which is designed to receive therewithin a piece 36 of insulative material. However, in the case of the plate 24' of FIG. 5, the latter in essence embodies two interruptions that are suitably located therein so as to be aligned along a common axis. More specifically, the aforesaid two interruptions are preferably created by making the plate 24' in two segments that are designed to mate with each other such that a space exists therebetween, i.e., so that the aforedescribed two interruptions exist therebetween. Moreover, each of the two interruptions is designed to extend from the outer surface of the plate 24' to the inner surface thereof, i.e., the inner surface thereof that defines the circumference of the opening 32'. Thus, in essence, the aforesaid two interruptions coact to provide the plate 24' with a through cut that extends across the entire width and thickness of the plate 24'. Finally, in accord with the teachings of the present invention, a piece of insulative material, 42 and 44, respectively, is inserted in each of the two interruptions that exist by virtue of forming the plate 24' as two mating segments. Briefly then, the two pieces 42 and 44 function in a manner similar to the piece 36 with which the plate 24 is provided. In conclusion, it is to be understood that the plates 24' could be substituted for the plate 24 to form the compression hub that is illustrated in FIGS. 2 and 1 of the drawing. Thus, in accordance with the present invention, there has been provided a novel and improved compression hub that is designed to be cooperatively associated with a plurality of superconducting magnets in a Tokamak-type fusion reactor system. Moreover, the subject compression hub of the present invention embodies a sufficient structural strength as to be capable of resisting the intense forces produced by the superconducting magnets that tend to draw the latter together towards a common point whereat the compression hub is located. In addition, in accord with the present invention, the compression hub embodies a construction that permits the latter to be cooled to a temperature that is commensurate with the operating temperature of the superconducting magnets, while yet enabling the compression hub to retain the structural strength required thereof. Further, the compression hub of the present invention embodies means operative to impede the circulation of eddy currents therethrough, while yet possessing the strength and cooling characteristics desired of a compression hub. Additionally, in accordance with the present invention, a compression hub is provided embodying such eddy current prevent means wherein the latter consists of an interruption provided in the surface of the elements that collectively comprise the compression hub. Also, the compression hub of the present invention embodies eddy current prevent means wherein the interruption provided in the surface of the elements takes the form of a radial cut in which an insulative material is inserted. Finally, in accord with the present invention, a compression hub is provided wherein the interruption provided in the surface of the elements is effected by fabricating the elements from multiple segments that in the assembled state are separated one from another by means of insulative material. While only one embodiment of my invention has been shown, it will be appreciated that modifications thereof, some of which have been alluded to hereinabove may readily be made thereto by those skilled in the art without departing from the essence of the invention. I, therefore, intend by the appended claims to cover the modifications alluded to herein as well as all other modifications which fall within the true spirit and scope of my invention.