KR800000350B1 - Adjustable spring mount for a cathod-ray tube yoke - Google Patents

Abstract

The mount comprises a first portion(31) adapted for receiving a yoke, a second portion(30) adapted for the connection of a cathod ray tube, a plurality of adjustable springs interconnecting the first and second portions, and means(46) for locking the first and second portions, and means(46) for locking the first and second portions together. The adjustable springs permit to move 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.

Description

Spring mount for cathode ray tube yoke

1 is a partially cut away elevational view of a cathode ray tube with a first yoke mount;

2 and 3 are top and elevation views, respectively, of the yoke mount shown in FIG.

4 is a top plan view of the platform portion of the mount shown in FIGS. 2 and 3;

5 is a top plan view of the housing portion of the mount shown in FIG.

6 and 7 are side elevation views of the platform and housing of FIGS. 4 and 5, respectively, in positions immediately before assembly.

8 is a top plan view of a yoke mounting ring having a terminal plate and yoke.

9 is an elevational side view of the mounting ring of FIG.

10 is an exemplary plan view of a housing illustrating the function of a bow spring.

11 and 12 are top and side elevation views, respectively, of a housing for a second mount embodiment.

13 and 14 are top and top views, respectively, of the platform for the second mount embodiment.

15 and 16 are top and elevation views, respectively, of the platform for the third mount embodiment.

17 and 18 are top and side elevation views, respectively, of a housing for a third mount embodiment.

19 is a partial elevational side 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.

21 and 22 are plan and elevation views of the platform portion of the mount shown in FIG. 19, respectively.

The present invention relates to a means for mounting a magnetic deflection yoke on a neck of a cathode ray tube, and more particularly to a mount which is adjustable by utilizing a plurality of springs.

Cathode ray tubes, such as collar television receivers, shall be fitted with a deflector yoke on the outside of the tube shell. This yoke consists of horizontal and vertical deflection coils with suitable cores. While the tube is in operation, the yoke magnetic field deflects the electron beam in the tube in the vertical and horizontal directions, causing the beam to scan the tube's visible screen.

Several structures have been proposed for mounting and securing the yoke in the proper position on the canister. In one of the structures, the yoke is installed in a housing which is positioned and interlocked in order on the pipe. In another configuration, the housing is gripped on the tube and the yoke is located in the housing and held in place. In a third structure, the platform is first interlaced on the outside of the tube and then the yoke and housing are placed on the tube and held in the platform. January 1974 15 mil T.M. The proposal for structural improvement is described in US Patent 3,786,185, which is issued to Mr. Shrader. This patent describes a combination that includes a platform fixed to a cathode ray tube with an adhesive and a yoke housing that encloses a portion of the yoke. This platform has a number of protrusions fixed in the concave surface of the yoke housing.

The disadvantage that is common to all the yoke mounting structures thus far is that once they are attached to the tube, further yoke positioning is impossible without disrupting the complete alignment of the yoke relative to the tube. Furthermore, in such yoke mounting designs that require permanent attachment of the yoke to the tube, once mounted with adhesive, the mount may be destroyed when the yoke is removed. Therefore, it is necessary for a permanently attached mount to provide a means for minimizing the yoke after the mount is attached to the tube.

The present invention retains many advantages over the structure of the prior art while, among other things, provides a means of maintaining robustness along another axis while enabling minimum adjustment along one axis.

The yoke mount of the cathode ray tube consists of a first part suitable for accommodating the yoke, a second part adapted for fixing to the tube, and an adjustable spring means connecting the first part and the second part, The adjustable spring means maintains the position of the first portion along the first axis while the first spring relative to the second portion and the means to enable movement of the first portion relative to the second portion along the second axis. Means for securing the position of the portion.

FIG. 1 shows an aperture mask type color television zone and 20 consisting of a vacuum glass shell 21. Shell 21 comprises a panel 22, a funnel 23 and a neck 24. The tricolor emission fluorescent film 25 is supported on the inner surface 26 of the faceplate panel 22. Preferred fluorescent film 25 is a well-known type of fluorescent film composed of parallel lines of thin and long phosphorus emitting different colors. The electron gun assembly 27 located in the neck 24 contains a total of three electron guns (not shown), one for each of the three indexes on the fluorescent film 25. The mask 28 in which the opening is formed is concentrated in the outer shell 21 near the fluorescent film 25. The mask 28 having an opening formed therein for use with the preferred linear fluorescent film 25 comprises a slot-shaped opening. The electron gun assembly 27 is suitably made to project toward the faceplate panel 22 through a mask 28 in which the three electron beams are formed to strike the fluorescent film 25. Preferred electron gun assembly 27 is inline, i.e., projects a plurality of electron beams from the common surface toward the fluorescent film 25.

Attached to the outside of the tube 20 is the yoke mount 29 consisting of the platform 30 and the housing 31. The platform 30 is fixed to the outer surface of the perimeter 23 and the housing 31 shown with the yoke 32 mounted thereon is located on the platform 30 where the perimeter 23 and the neck 24 intersect. Preferred yoke 32 consists of two pairs of opposite magnetic field generating coils (not shown) with annular windings. The housing 31 together with the yoke 32 is mounted on the platform 30 as described later. Specific components of platform 30 and housing 31 are shown in FIGS. 2, 3, 4, 5, 6 and 7. 2 and 3 illustrate mount 29 and include platform 30 and housing 31 in relation to operation. 4 and 5 show the separated platform 30 and the housing 31, respectively.

6 and 7 are side views of FIGS. 4 and 5, respectively.

Platform 30 (see FIGS. 4 and 6) consists of an annular ring 40 which is a short conical member having an inner surface substantially the same as the shape of the outer surface of the perm to which the perm is to be attached. Four studs or protrusions 42 extend from the ring 40 parallel to the central axis of the ring 40. As will be explained later, these projections 42 have a central slit 44 that allows them to be attached to the housing 31.

The inner surface of the annular ring 40 may have a number of trailing edges to accommodate the appropriate adhesive for easy attachment to the tube. First, the following hot melt thermoplastic adhesives can be used.

(Brassaron and Lecillin are trade names)

The housing 31 (see FIGS. 5 and 7) comprises four bow springs 46, 48, 50 and 52 arranged in a square around the central support ring 54. The bow spring is determined as an elongated straight spring supported at both ends thereof.

In this embodiment, the springs 46, 48, 50 and 52 are supported by two intermediate portions 49 which are substantially perpendicular to this elongated spring. Because of the intermediate part 49, the springs can bend or bend laterally. Two bow springs 46 and 50 constitute a pair of springs and the remaining bow springs 48 and 52 constitute a second pair. The function of the bow spring of each pair is as follows.

The support ring 54 is large enough to fit snugly on its end without touching the perimeter of the tube when the housing 31 is mounted on the platform 30. Four projections 56 are provided on the support ring 54 to allow easy attachment of the yoke. The end of each bow spring is connected to a substantially rectangular flange 58 extending around the support ring 54 and continues in contact with the ring 54 at four equally isolated points. The thin metal plate part 60 also connects the flange 58 to the support ring 54 at the corner of the housing 31.

Formed outwardly on each bow spring is a bracket 62. Slot 65 is located between each bracket 62 and its associated bow spring. Each slot 65 is dimensioned to receive the protrusion 42 of the platform 30, so that there is sufficient spacing on any one axis of the protrusion to adjust this protrusion when placing the yoke. As shown in FIG. 2, the slit 44 in the center of the projection 42 is aligned in line with the hole 66 of the bracket 62 and the bow spring, inserting a bolt 68 through the hole and Can be combined. Tightening bolt 68 and nut 72 causes bracket 62 and bow spring 46 to exert pressure on protrusion 42 of the platform, thereby securing the position of housing 31 relative to platform 30. Subsequently, alternately, the projections 42 may alternatively be interlaced with slot 64 or high frequency welds within slot 65 to permanently fix the position of the bow spring. Later welding or gluing may result in the bolts being removed afterwards.

8 and 9 show an example yoke 76 mounted on a yoke mounting ring 78 having a terminal plate 80 in electrical connection with the yoke 76. The combination of FIGS. 6, 7 and 9 shows the rupture of the platform 30, the housing 31 and the mounting ring 78 in their respective relative positions prior to assembly.

The function of the bow spring is illustrated in FIG. In this figure, the upper and lower bolts 68 along the vertical axis V-V are loosened, and the center of the housing 31 on which the yoke 76 can be mounted is shifted to the right. This movement pulls the end of the left bow spring 50 to the right and forces the end of the right bow spring 46 to the right. Since the protrusion 42 is rigid, this movement causes the springs 46 and 50 to bend. Note that the two bolts 68 on the horizontal axis H-H are not loosened during this movement, which provides a horizontal calibration of the yoke position. Therefore, the horizontal movement of the yoke can affect the vertical position of the yoke. Likewise, if the two bolts on the horizontal axis are loosened and the bolts on the vertical axis are tightened, the yoke can be displaced vertically without affecting the horizontal position. Once the yoke is in a satisfactory position, the loosen loosens must be tightened again.

If sufficient tolerances are provided between the bracket 62 and the protrusion 42, the housing 31 can also be adjusted around the vertical and horizontal axes when all the bolts are loosened. Moreover, when all bolts are loosened, the yoke can be moved back and forth along the central axis C-C through the tube.

A second embodiment of the invention is shown in FIGS. 11, 12, 13 and 14. The basic structure of the housing 90 and the platform 92 in this embodiment is the same as that of the first embodiment except that the bracket is formed by the double protrusion 94 on the platform.

The bow spring 96 of this embodiment fits between the double protrusions 94. The spacing between the protrusions 94 is wide enough so that once the bolt is inserted through the holes of the protrusion 94 and the bow spring 96, the housing 90 can be adjusted in relation to the platform.

The second embodiment also shows another feature that can be suitably attached to the bow spring. This feature is the inner ridge 102 formed on the inner flange 104 opposite the inner ridge 100 of the bow spring. When the yoke is in its final position, an adhesive may be applied between the container portions 100 and 102 if desired so that the position of the yoke is permanently fixed relative to the tube.

Although the bow spring has been described as being part of the yoke housing, this spring may also be part of the platform. 15 and 16 show platform 110 of a third mount embodiment with four bow springs 112 integrally configured. The yoke housing 114 for the third embodiment is shown in FIGS. 17 and 18. In this particular embodiment, the protrusion 116 is located on the housing 114 and the bracket 118 is located on the bow spring 112. Of course, this embodiment can also be modified to include opposing protrusions and brackets and ridges in the bow spring to permanently attach the spring.

Another embodiment of the yoke mount 200 is shown in FIG. 19, where the yoke mount 200 is attached to the perimeter 202 of the cathode ray tube 204 (part view is shown). The yoke mount 200 consists of a platform 206 and a housing 208. The platform 206 is permanently secured to the outer surface of the perimeter 202 and the housing 208 shown with the yoke 210 mounted thereon is located on the platform 206 where the perimeter 202 and the neck 212 of the cathode ray tube intersect. Preferred yoke 210 consists of two pairs of opposing magnetic field generating coils (not shown) with annular windings.

Yoke mount 200 is more specifically illustrated throughout FIGS. 20 through 24. FIG. 20 shows a plan view of the integrally mounted 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. FIG.

The platform 206 consists of an annular ring 124 having an inner surface 216 that substantially matches the outer surface of the perimeter 202. Four isolated cantilever plate springs 218 extend clockwise around the outer surface of the ring 214 from a strut 220 parallel to the central axis of the platform 206. The strut 220 serves as the sole support for the spring 218. The flange 22, isolated in parallel with the spring 218, is molded directly into each strut 220 and the annular ring 214, so that the strut 220 and the spring 218 are rigid. Each spring 218 has. The slot 224 extends in the longitudinal direction of the spring so that the bolt 226 used to attach the housing 208 to the spring 218 can be fitted. Although cantilever plate spring 218 appears to extend in the direction of clockwise movement, they may be disposed in the opposite direction of clockwise movement.

In this embodiment, to insert an adhesive material for permanently attaching the platform 206 to the tube 204, the strut 220 has a central conduit 228 extending through the inner surface 216 of the ring 214.

To facilitate attachment to the tube, a number of trailing sites may be formed on the inner surface of the annular ring 214 to accommodate the appropriate adhesive material.

The housing 208 is cylindrical and includes an annular inner shelf 230 to facilitate attachment of the yoke 210. The yoke 210 is gripped in the housing 208 by four integrally formed clips 232 spaced about the circumference of the housing 208. Four brackets 234 are isolated on the circumference around the outer surface of the housing 208 to engage four leaf springs 218 on the platform 206. Each bracket 234 extends down the side of the housing 208 and is configured to support the head of the bolt 226 in the correct position to engage the slot 224 of the spring 218.

Mount 200 is assembled by first attaching platform 206 to tube 204. The position of this platform is not critical but should be within a range with adequate tolerances to allow sufficient movement of the housing 208 during adjustment of the yoke 210. Apart from the tube 204, the yoke 210 is mounted to the housing 208 by inserting the yoke 210 over a detent shaped over the yoke 210 and closing the clip 232. Then bolt 226 is inserted into bracket 234 to attach to washer and nut 236. At this point, the nut 236 does not tighten and remains loose at the end of the bolt 226.

The housing 208 is then inserted into the platform 206 with an angle of approximately 45 ° in the direction of clockwise movement from the intended final orientation. The housing 208 is then rotated in the opposite direction of clockwise movement to place the bolt 226 in the slot 224 of the spring 218. At this time, the tube 204 is operated to move the housing 208 until the yoke 210 is aligned with the electron beam in the tube 204. Tighten nut 236 immediately after correct alignment is achieved. The spring may then be ultrasonically welded or adhesively attached to the bracket 234, if desired.

It is noteworthy that the spring 218 provides a wide range to move the yoke 210 laterally about the central axis C-C of the tube 204. Rotation of the yoke 210 is made possible by the slot 224 in the spring 218, and movement along the side of the tube is made possible by the slot 238 of the bracket 234. Adjusting the yoke 210 laterally will cause the spring 218 to bend. The bending position of this spring is maintained when all four nuts are tightened.

Once the yoke 210 position is fixed, its position can be adjusted vertically without affecting its position in the horizontal direction. For example, if you want to move the yoke slightly vertically without affecting the horizontal position, you can move the yoke vertically with the two horizontal nuts 236 loosened and the other two vertical nuts 236 tightened. In the same way, loosen the vertical nut 236 to move horizontally. This limited single axis adjustment greatly simplifies the process of lining up the electron beam and the yoke.

Although the above embodiment shows the placement of the cantilever plate spring on the platform, this leaf spring may be disposed on the housing. In such a case, the leaf spring may be attached to a post or bracket positioned on the flat spring.

The material for the above-described embodiment may be a non-conductive material which can be molded to a sufficient strength. Various plastics may be used as the material for the platform and housing. However, due to the heat produced when operating the cathode ray tube, the material should be chosen not to deform at high temperatures. Suitable materials for this purpose are manufactured and marketed by General Electric Corporation under the trade names Lexan2014 and Noryl SEO-225.

Claims (1)

As described in the text and illustrated in the drawings, the spring mount for cathode ray tube yoke, which is composed of a first portion adapted to receive the yoke and a second portion adapted to contact the cathode ray tube, is adjustable. Spring means 46-52, 96, 112, 218 are connected to the first portions 31, 90, 114, 208 and the second portions 30, 92, 110, 206, which spring means enable movement of the first portion relative to the second portion. Cathode and yoke spring mount with bend features.

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