Abstract:
The mount comprises a first portion adapted for receiving a yoke, a second portion adapted for connection to a cathode-ray tube, a plurality of adjustable springs interconnecting the first and second portions and means for locking the first and second portions together. The adjustable springs permit movement of the yoke along one axis while securing its position along an orthogonal axis. In one preferred embodiment, a platform is provided with projections extending therefrom. A housing on which a yoke may be mounted, is attached to the projections. The housing includes a plurality of bow springs located between the points of attachment to the projections and the yoke attachment area. Means also are included to secure the bow springs in their adjusted positions.

Description:
BACKGROUND OF THE INVENTION 
     This invention relates to means for mounting a magnetic deflection yoke on the neck of a cathode-ray tube and particularly to an adjustable mount utilizing a plurality of adjustable springs. 
     Cathode-ray tubes, such as color television picture tubes, require a magnetic-deflection yoke mounted on the outside of the tube envelope. The yoke comprises horizontal and vertical deflection coils together with a suitable core. During operation of the tube, the yoke field deflects electron beams within the tube in both the vertical and horizontal directions thereby causing the beams to scan the viewing screen of the tube. 
     Several structures have been proposed for mounting and holding the yoke in a desired position on the tube. In one structure, the yoke is placed in a housing which is in turn positioned on and glued to the tube. In another structure, the housing is clamped on the tube and the yoke is positioned within the housing and clamped in place. In a third structure, a platform first is glued to the outside of the tube and then the yoke and housing are positioned over the tube and clamped to the platform. An improved structure is presented in U.S. Pat. No. 3,786,185 issued to me on Jan. 15, 1974. This patent discloses a combination including a platform affixed to a cathode-ray tube by an adhesive and a yoke housing enclosing a portion of the yoke. The platform has a plurality of projections that are secured within indentations in the yoke housing. 
     A disadvantage shared by all of the foregoing yoke mounting structures is that once they have been attached to a tube, further adjustment of yoke position is not possible without losing the entire alignment of the yoke relative to the tube. Furthermore, in those yoke mounting schemes requiring permanent attachment of the yoke to a tube, once the adhesive has set, the mount may be destroyed when the yoke is removed. Therefore, there is a need for a permanently affixed mount that provides means permitting minor adjustments of the yoke after the mount is attached to a tube. 
     The present invention maintains many of the advantages of prior art structures while providing means that permit minor adjustment along one axis while maintaining rigidity along another axis. 
     SUMMARY OF THE INVENTION 
     A yoke mount for a cathode-ray tube comprises a first portion adapted for receiving a yoke, a second portion adapted for securing to the tube, adjustable spring means connecting the first and second portions, the spring means including means for maintaining the position of the first portion along a first axis while permitting movement of the first portion relative to the second portion along a second axis and means for securing the position of the first portion relative to the second portion. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a partially cutaway side elevational view of a cathode-ray tube having a first yoke mount thereon. 
     FIGS. 2 and 3 are respective top plan and side elevational views of the yoke mount of FIG. 1. 
     FIG. 4 is a top plan view of the platform portion of the mount shown in FIGS. 2 and 3. 
     FIG. 5 is a top plan view of the housing portion of the mount shown in FIG. 1. 
     FIGS. 6 and 7 are side elevational views, respectively, platform and housing of FIGS. 4 and 5 in their preassembly orientation. 
     FIG. 8 is a top plan view of a yoke mounting ring having a terminal board and yoke thereon. 
     FIG. 9 is a side elevational view of the mounting ring of FIG. 8. 
     FIG. 10 is an illustrative plan view of a housing illustrating functioning of bow springs. 
     FIGS. 11 and 12 are respective top plan and side elevational views of a housing for a second mount embodiment. 
     FIGS. 13 and 14 are respective top plan and side elevational views of a platform for the second mount embodiment. 
     FIGS. 15 and 16 are respective top plan and side elevational views of a platform for a third mount embodiment. 
     FIGS. 17 and 18 are respective top plan and side elevational views of a housing for the third mount embodiment. 
     FIG. 19 is a partial side elevational view of a cathode-ray tube incorporating another yoke mount embodiment according to the present invention. 
     FIG. 20 is a plan view of the yoke mount of FIG. 19 taken along line 20--20 of FIG. 19. 
     FIGS. 21 and 22 are respective plan and elevational views of the platform portion of the mount of FIG. 19. 
     FIGS. 23 and 24 are respective plan and sectional views of the yoke housing portion of the mount of FIG. 19, FIG. 24 being taken along line 24--24 of FIG. 23. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     FIG. 1 illustrates a color television picture tube 20 of the apertured-mask type comprising an evacuated glass envelope 21. The envelope 21 includes a faceplate panel 22, a funnel 23, and a neck 24. A three-color-emitting phosphor viewing screen 25 is supported on the inner surface 26 of the faceplate panel 22. A preferred viewing screen 25 is of a known type comprising parallel lines or strips of the different color-emitting phosphors. An electron-gun assembly 27 positioned in the neck 24 includes three electron guns (not shown) one for each of the three color phosphors on the viewing screen 25. An apertured mask 28 is positioned in the envelope 21 adjacent the viewing screen 25. The apertured mask 28, used with the line-type viewing screen 25, includes slot-shaped apertures. The electron gun assembly 27 is adapted to project three electron beams toward the faceplate panel 22 through the apertured mask 28 to strike the viewing screen 25. The preferred electron-gun assembly 27 is of an inline type, that is, a type which projects a plurality of electron beams from a common plane toward the screen 25. 
     Attached to the outside of the tube 20, is a yoke mount 29 comprising a platform 30 and a housing 31. The platform 30 is fixed to the outside surface of the funnel 23 and the housing 31 shown with a yoke 32 mounted thereon is positioned on the platform 30 near the intersection of the funnel 23 and neck 24. A preferred yoke 32 is comprised of two pairs of opposed magnetic-field producing coils (not shown) having toroidal windings. The housing 31 with the yoke 32 thereon is mounted on the platform 30, as will be described. 
     The specific details of the platform 30 and housing 31 are shown in FIGS. 2, 3, 4, 5, 6 and 7. FIGS. 2 and 3 illustrate the mount 29, including the platform 30 and the housing 31 in their operational relationship. FIGS. 4 and 5 show the platform 30 and housing 31, respectively, separated. FIGS. 6 and 7 are respective side view of FIGS. 4 and 5. 
     The platform 30 (FIGS. 4 and 6) comprises a short conical member 40 having an interior surface that substantially conforms to the shape of the exterior surface of the funnel to which it will be attached. Four studs or projections 42 extend from the ring 40 parallel to the central axis of the ring. These projections 42 have central slits 44 therein for permitting attachment to the housing 31 as will be described later. 
     In order to facilitate attachment to a tube, the inner surface of the annular ring 40 may have a plurality of recesses 45 therein for receiving a suitable adhesive material. Preferably, a hot-melt thermoplastic adhesive, such as the following, may be used:Material                     MeltingDesignation  Marketed By     Temperature______________________________________Versalon 1300       General Mills     92°C.       Chemical Co.,       Minneapolis, Minn.Versalon 1138       &#34;                125°C.Versalon 1165       &#34;                134°C.Resyln 34-2927       National Starch and                         58°C.       Chemical Corp., New       York, N. Y.______________________________________ 
     The housing 31 (FIGS. 5 and 7) includes four bow springs 46, 48, 50 and 52 disposed in a square pattern about a central retaining ring 54. A bow spring is defined as an elongated straight spring supported at its two ends. In the present embodiment, the springs 46, 48, 50 and 52 are supported by two intermediate portions 49 that are substantially perpendicular to the elongated springs. Because of the intermediate portions 49, the springs are capable of bending or bowing transversely. Two bow springs 46 and 50 comprise one pair of springs and the other bow springs 48 and 52 comprise a second pair. The function of each of the bow spring pairs will be described later. 
     The retaining ring 54 is large enough to fit over the end of a tube funnel without touching it when the housing 31 is mounted on the platform 30. Four lugs 56 are provided on the retaining ring 54 to permit snap-on attachment of a yoke. The ends of each bow spring are connected to a substantially square flange 58 that extends around the retaining ring 54 and is joined to the ring 54 tangentially at four equally spaced points. Web portions 60 also connect the flange 58 to the retainer ring 54 in the corners of the housing 31. 
     Externally formed on each bow spring is a small bracket 62. A slot 65 is located between each bracket 62 and its associated bow spring. Each slot 65 is dimensioned to receive a projection 42 of the platform 30, leaving sufficient space on either side of the projection to permit adjustment of the projection when aligning the yoke. As shown in FIG. 2, the central slits 44 in the projections 42 are aligned with holes 66 in the brackets 62 and bow springs to permit the insertion of bolts 68 therethrough and the attachment of washers 70 and nuts 72 thereto. Upon tightening the bolts 68 and nuts 72, the bracket 62 and bow spring (46) press against the platform projections 42 thus securing the position of the housing 31 relative to the platform 30. Later or alternately, the projections 42 may be either glued into the slots 64 or ultrasonically welded within the slots 65 to permanently fix the position of the bow springs. If later welded or glued, the bolts may thereafter be removed. 
     FIGS. 8 and 9 show an illustrative yoke 76 mounted on a yoke mounting ring 78 having a terminal board 80 affixed thereto for electrical connection with the yoke 76. The combination of FIGS. 6, 7 and 9 presents an exploded view of the platform 30, housing 31 and mounting ring 78, respectively, in their relative positions prior to assembly. 
     The function of the bow springs is illustrated in FIG. 10. In this illustration, the top and bottom bolts 68 along the vertical axis, V--V, are loosened and the center of the housing 31 on which the yoke 76 may be mounted, is moved to the right. This movement causes the end of the left bow spring 50 to be pulled to the right and the ends of the right bow spring 46 to be forced to the right. Since the projections 42 are rigid, this movement causes the spring 46 and 50 to bow. It should be noted that for this movement, which will provide a horizontal correction in yoke location, the two bolts 68 on the horizontal axis, H--H, are not loosened. Therefore, movement of the yoke horizontally cannot affect vertical position of the yoke. Similarly, if the two horizontal axis bolts are loosened and the vertical axis bolts remain tightened, the yoke may be displaced vertically without affecting horizontal position. Once the yoke is in a desired position, any bolts that have been loosened are retightened. 
     The housing 31 may also be adjusted about the vertical and horizontal axis when all bolts are loosened, if sufficient tolerance is provided between the brackets 62 and the projections 42. Furthermore, when all bolts are loosened, the yoke may be moved forward and back along a central axis, C--C, passing through the tube. 
     A second embodiment of the present invention is shown in FIGS. 11, 12, 13 and 14. The basic structure of a housing 90 and platform 92 in this embodiment is similar to that of the first embodiment except that brackets are formed by double projections 94 on the platform. The bowsprings 96 in this embodiment fit between the double projections 94. The spaces between the projections 94 are sufficiently wide to permit adjustment of the housing 90 relative to the platform once bolts have been inserted through holes in the projections 94 and bowsprings 96. 
     The second embodiment also shows another feature that may be optionally added to the bow springs. This feature is internal protrusions 100 on the bow spring and internal protrusions 102, on an opposite inner flange 104. When the yoke has been positioned into its final location, an adhesive may be applied between the protrusions 100 and 102 so that the position of the yoke, if desired, may be permanently fixed relative to the tube. 
     Although heretofore, the bow springs have been described as being part of the yoke housing, the bow springs alternatively may be made part of the platform. FIG. 15 and 16 show a platform 110 of a third mount embodiment having four bow springs 112 constructed integrally therewith. A yoke housing 114 for the third embodiment is shown in FIGS. 17 and 18. In this particular embodiment, projections 116 are located on the housing 114 and brackets 118 are located on the bow springs 112. Of course this embodiment could also be modified to include a reversal of the projections and brackets and to include protrusions within the bow springs to permit permanent affixation of the springs. 
     Another embodiment of a yoke mount 200 is shown in FIG. 19 wherein the yoke mount 200 is attached to the funnel 202 of a cathode-ray tube 204 (shown in partial view). The yoke mount 200 comprises a platform 206 and a housing 208. The platform 206 is permanently fixed to the outside surface of the funnel 202, and the housing 208, shown with a yoke 210 mounted thereon, is positioned on the platform 206 near the intersection of the funnel 202 and the tube neck 212. A preferred yoke 210 is comprised of two pairs of opposed magnetic-field producing coils (not shown) having toroidal windings. 
     The specific details of the yoke mount 200 are better illustrated in FIGS. 20 through 24. FIG. 20 shows a plan view of the complete mount 200; FIGS. 21 and 22 show two views of the platform 206; and FIGS. 23 and 24 show two views of the housing 208. 
     The platform 206 comprises an annular ring 214 having an inside surface 216 that substantially conforms to the exterior surface of the funnel 202. Four spaced cantilever leaf springs 218 extend tangentially clockwise around the outer surface of the ring 214 from posts 220 which are parallel to the central axis of the platform 206. The posts 220 provide the sole support for the springs 218. A flange 222 spaced from but parallel to the springs 218, is molded directly to each post 220 and to the annular ring 214 to provide rigidity for the posts 220 and springs 218. Each springs 218 has an open slot 224 extending in the longitudinal direction of the spring to receive a bolt 226 used in attaching the housing 208 to the springs 218. Although the cantilevered leaf springs 218 are shown extending clockwise, they alternatively may be disposed counterclockwise. 
     In this embodiment, the posts 220 have central conduits 228 extending through to the inside surface 216 of the ring 214 to permit the insertion of an adhesive material to permanently affix the platform 206 to the tube 204. 
     In order to facilitate attachment to a tube, the inner surface of the annular ring 214 may have a plurality of recesses (not shown) therein for receiving a suitable adhesive material. 
     The housing 208 is cylindrically shaped and includes an annular inner ledge 230 therein to facilitate attachment of the yoke 210. The yoke 210 is held in the housing 208 by four integrally formed clips 232 spaced around the periphery of the housing 208. Four brackets 234 are spaced peripherally around the exterior surface of the housing 208 to mate with the four leaf springs 218 on the platform 206. Each bracket 234 extends down the side of the housing 208 and is formed to support the head of the bolt 226 in correct position to mate with the slots 224 in the springs 218. 
     The mount 200 is assembled by first attaching the platform 206 to the tube 204. The position of this platform is not critical but it must be positioned within reasonable tolerances to permit full motion of the housing 208 during adjustment of the yoke 210. 
     Separate from the tube 204, the yoke 210 is mounted in the housing 208 by inserting the yoke 210 and snaping the clips 232 over detents formed on the yoke 210. The bolts 226 are next slipped into the brackets 234 and washers and nuts 236 attached thereto. At this point, the nuts 236 are not tightened but remain loose at the end of the bolts 226. 
     Next the housing 208 is inserted into the platform 206 in an orientation approximately 45° clockwise from its intended final orientation. Thereafter, the housing 208 is rotated counterclockwise to position the bolts 226 within the slots 224 of the springs 218. Now, the tube 204 is activated and the yoke 210 and housing 208 are moved until the yoke 210 is aligned with the electron beams within the tube 204. Once correct alignment is achieved, the nuts 236 are tightened. Thereafter if desired, the springs may be either ultrasonically welded or glued to the brackets 234. 
     It should be noted that the springs 218 provide great latitude for moving the yoke 210 transverse to the central axis C--C of the tube 204. Rotation of the yoke 210 is permitted by the slots 224 in the springs 218 and movement along the tube axis is permitted by slots 238 in the brackets 234. Transverse adjustment of the yoke 210 will cause a bending of the springs 218. This bent position of the springs is maintained once all four nuts 236 are tightened. 
     Once the yoke 210 position has been fixed, its position can later be adjusted in the vertical direction without affecting its position in the horizontal direction, or its position can be adjusted in the horizontal direction without affecting its position in the vertical direction. For example, if it is desired to move the yoke slightly vertically without affecting its horizontal position, the two horizontal nuts 236 can be loosened and the yoke 210 moved vertically while the two vertical nuts 236 remain tightened. Similarly, horizontal movement can be made by loosening the vertical nuts 236. Such confined single-axis adjustment greatly simplifies procedures for aligning the yoke with the electron beams. 
     Although the foregoing described embodiment shows placement of the cantilevered leaf springs on the platform, the leaf springs alternately may be located on the housing instead. In such case, the leaf springs would be attachable to posts or brackets located on the platform. 
     The material for the foregoing embodiment may be any nonconductive material that can be formed with sufficient strength. Various plastics may be used for both the platform and housing. However, because of the heat encountered in an operational tube, a material should be selected that will not deform substantially with increased temperature. Materials that have been found suitable for this purpose are manufactured by the G. E. Corporation under the brand names Lexan 2014 and Noryl SEO-225.