Background Information Projection television CRT systems typically include three CRT units, one for each of the colors red, green, and blue. Each CRT unit typically comprises a CRT, a lens, and a CRT-to-lens coupler, which couples the lens to the faceplate of the CRT. The CRT projects light which is magnified by the lens for projection onto another surface.

Referring now to Fig. 1, there is shown a cross-sectional view of an exemplary prior art CRT unit 100 for use in a projection television CRT system. CRT unit 100 comprises CRT 110, plastic lens 160, and die cast coupler or housing 140 for coupling lens 160 to faceplate 114 of CRT 110. CRT 110 comprises a phosphor surface 113 on the inside of CRT 110. As will be appreciated by those skilled in the art, coupler 140 couples lens 160 to faceplate 114 so that lens 160 is positioned with respect to CRT 110 in accordance with focusing and related requirements. Coupler 140 is coupled to faceplate 114 of CRT 110 by tension frame 111, shoulder bolts, such as shoulder bolt 115, and compression springs, such as compression spring 112. Lens 160 and lens clamp plate 161 are coupled to coupler 140 and hence to CRT 110 b y lens clamp plate screws, such as clamp plate screw 162.

When coupler 140 is assembled, the interior of coupler 140 forms a cavity 146. The interior walls of cavity 146 are the CRT faceplate 114, lens 160, and the inside walls 147 of coupler 140.

Cavity 146 is used to hold a fluid, which is designed to provide the correct refraction index for light passing through CRT faceplate 114, the fluid in cavity 146, and lens 160. The cavity fluid typically includes a 70:30 mixture of ethylene glycol and glycerine. As will be appreciated, to prevent fluid leakage, CRT

faceplate gasket 141 is interposed between faceplate 114 and coupler 140, and O-ring 142 is interposed between lens 160 and coupler 140. Gasket 141 is seated in channel 148 of coupler 140, and O-ring 142 is seated in channel 149 of coupler 140.

Gasket 141 and O-ring 142 are typically elastomeric components that perform a sealing function. For example, imperfections in the adjacent surfaces of faceplate 114 and coupler 140 may prevent a perfect seal from forming if gasket 141 is not used. Gasket 141 also performs a spacing function, to keep faceplate 114 physically separated from coupler 140. For example, coupler 140 may be die cast and formed of a metal such as aluminum, which expands due to heat produced during operation of CRT unit 100. The differential thermal expansion between coupler 140 and faceplate 114 can cause coupler 140 to scratch the surface of faceplate 114. By physically separating faceplate 114 from coupler 140, gasket 141 accommodates the differential thermal expansion of faceplate 114 and coupler 1 40 while preventing damage to faceplate 114.

CRT unit 100 also comprises an expansion diaphragm 143, diaphragm cover 144, and diaphragm screw 145, which is used to couple expansion diaphragm 143 to coupler 140. As will b e understood, the periphery of CRT faceplate 114 may have a rectangular, round, or other shape. Where CRT faceplate 114 has a rectangular shape, for example, the shape of coupler 140 is also rectangular.

Unfortunately, during assembly of CRT unit 100, gasket 1 4 1 may not always be seated properly in channel 148 of coupler 140, and O-ring 142 may not always be seated properly in channel 149 of coupler 140. This can lead to leakage of the fluid in cavity 146.

Additionally, before gasket 141 or O-ring 142 are dropped into channels 148 or 149, respectively, a small piece of hair or other debris, or a defect in the casting of the coupler in the channel, can lead to a leakage path for the fluid.

It is undesirable for stray light to reflect off of the inside walls 147 of coupler 140. Therefore, inside walls 147 are often coated with a dull, dark, matte finish. One way to accomplish this

is to utilize black anodizing. Unfortunately, this can tend to release minute particles that contaminate the cavity fluid. The anodized surface may be coated to address this problem, but this may typically involve the use of an expensive coating material, for example a polymer material marketed by Union Carbide Corp., Electronics Division, of San Diego, California, under the trademark PARYLENETM. An epoxy paint called "e-coat" may also be used, but this tends to have a higher reflectivity than is typically desired.

Reflectivity may also be reduced by texturing the inside walls 1 47 to diffuse the stray light. Unfortunately, such textured surfaces tend to erode off of the molding tool after a limited number of molding cycles, or "shots". The erosion of the texturing detail from the molding tool occurs as a result of the interaction between the hot aluminum shot into the molding tool and the steel of the molding tool.

Another problem with prior art CRT units such as CRT unit 100 is that an untreated coupler formed from a material such as aluminum has a certain porosity into which the cavity fluid can leak. Therefore, casting 140 is often resin impregnated to seal the porosity in the casting, and leak testing is performed in some cases.

Another problem often encountered with prior art CRT units is that, during assembly, lens 160 must be accurately aligned with respect to the center of CRT faceplate 114. This typically requires the use of an expensive CRT alignment machine.

SUMMARY OF THE INVENTION In accordance with an inventive arrangement described herein, a coupler for coupling a CRT faceplate of a CRT to a lens comprises a rigid portion having a CRT faceplate surface for coupling to the CRT faceplate and a lens surface for coupling to the lens. The coupler further comprises an elastomeric layer disposed on at least the CRT faceplate surface and lens surface of the rigid portion.

The above, and other features and advantages of the present invention will become apparent from the following description

read in conjunction with the accompanying drawings, in which like reference numerals designate the same elements.

BRIEF DESCRIPTION OF THE DRAWINGS In the drawings: Fig. 1 is a cross-sectional view of a block diagram of a prior art CRT unit.

Fig. 2 is a cross-sectional view of a CRT-to-lens coupler, in accordance with the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring now to Fig. 2, there is illustrated a cross-sectional view of a CRT-to-lens coupler 200, in accordance with the present invention. As will be appreciated, coupler 200 may be used, instead of a coupler of the type of coupler 140 of CRT unit 100 of Fig. 1, to couple a CRT such as CRT 110 to a lens such as plastic lens 160. As will be understood, lens 160 may also be formed from other suitable material such as, for example, glass. Coupler 200 comprises a rigid portion 201, which has a CRT faceplate surface 202 for coupling to the CRT faceplate 114 and a lens surface 203 for coupling to the lens 160. Coupler 200 further comprises a layer of elastomeric material 220 disposed on at least the CRT faceplate surface 202 and lens surface 203 of rigid portion 201 and, in one embodiment, also disposed on interior surface portion 204 of rigid portion 201. In one embodiment, rigid portion 201 is a casting die cast from a metal such as aluminum, and elastomeric layer 220 is a rubber coating 220. Rubber coating 220 is preferably molded onto the desired parts of the surface of rigid portion or casting 201.

Rubber coating 220 comprises several features, including centering fingers 221, gasket ridge 222 and gasket ridge trenches 223, spacer portions 223a next to trenches 223, anti-reflective surface finish on interior surface portion 225 of rubber coating 220, and O-ring ridge 227 and trench 228. In one embodiment, casting 201 may be coated with rubber coating 220 by liquid injection molding, as will be appreciated by those skilled in the art. In one embodiment, all portions of rubber coating 220, except for centering fingers 221, have a similar cross-section all the way

around the coupler 200. Centering fingers 221, however, only exist at discrete locations along the periphery of coupler 200, as described in further detail below. Thus, for example, coupler 200 may be rectangular-shaped, so as to conform to the shape of a CRT faceplate. In this case, coupler 200 will have top and bottom horizontal bars and left and right vertical bars, each of which has a cross section as illustrated in Fig. 2.

Gasket ridge 222 of rubber coating 220 is formed on the CRT faceplate surface side of casting 201, and is designed to sealably couple to a CRT faceplate such as CRT faceplate 114, as illustrated in Fig. 2. O-ring ridge 227 is formed on the lens surface side of casting 201, and is designed to sealably couple to a lens such as lens 160, as illustrated in Fig. 2. As will be appreciated, gasket ridge 222 performs sealing functions similar to those performed by gasket 141 of CRT unit 100, and O-ring ridge 227 performs sealing functions similar to those performed by O-ring 142 of CRT unit 100. Spacer portions 223a of rubber coating 220 keep casting 201 physically separated from faceplate surface 114 and thus perform spacing functions similar to those performed by gasket 141 of CRT unit 100. When assembled, gasket ridge 222 is compressed and excess rubber material is able to exude or compress into trenches 223. Similarly, when assembled, O-ring ridge 227 is compressed and excess rubber material is able to exude into trench 228 and to the relatively flat area below ridge 227. One advantage of gasket ridge 222 and O-ring ridge 227, however, is that there is a reduced chance of cavity fluid leakage.

This is because the danger in the prior art of gasket 141 and 0- ring 142 not always properly seating in their respective channels 148 and 149 of coupler 140 is not present, since ridges 222 and 227 are already molded onto casting 201 of coupler 200.

Additionally, unlike in the prior art, there is a reduced danger of debris or casting defects between ridges 222, 227 and casting 201, which could also lead to a leakage path.

To perform the spacing and sealing functions described above, rubber coating 220 is preferably a rubber material having a durometer, or hardness, between approximately 30 and

approximately 50 on the Shore A scale. The rubber coating 220 also should be able to maintain integrity while in prolonged contact with the cavity fluid at normal operating temperatures (e.g., up to approximately 85 degrees Celsius). Further, rubber coating 220 is preferably a rubber material having a low light reflectivity. The interior surface portion 225 of the rubber coating is also preferably molded with an anti-reflective surface finish or texture, such as grooves, ridges, or mesh, so as to further reduce light reflectivity inside a fluid cavity such as fluid cavity 146. One advantage of molding such a texture into the rubber coating mold as opposed to molding a textured surface onto inside walls 147 of a cast aluminum coupler 140 is that the textured surfaces of rubber coating 220 do not tend to erode off of the molding tool as quickly. The use of the rubber coating 220 to reduce light reflectivity inside a fluid cavity also eliminates the need to coat the interior surface of casting 201 with black anodizing and either PARYLENErM or e-coat. Further, because rubber is flexible, slight undercuts may be molded into rubber coating 220, allowing for textured surface and other features not practical with a casting molding of casting 201.

Since rubber performs a sealing function, the application of rubber coating 220 to the interior surfaces of casting 2 0 1 eliminates the need to resin impregnate these surfaces to seal the casting porosity. However, application of a continuous layer of rubber to the interior surface of casting 201 can also interfere with the transfer of heat from the cavity fluid to the casting.

Therefore, in one embodiment, rubber coating 220 is made as thin as possible in the area coating interior surface portion 225 so as to minimize the heat-insulation properties of rubber coating 229. I n an alternative embodiment, an open mesh surface finish in the interior surface portion 225 of rubber coating 220 may be utilized to increase the transfer of heat from the cavity fluid to casting 201. In this embodiment, the interior surface of casting 201 is preferably resin impregnated for sealing and finished with a dull, dark finish to reduce light reflectivity.

Another useful feature that may be formed into rubber coating 220 is centering fingers 221. The use of centering fingers 221 avoids having to use an expensive machine such as a CRT alignment machine. Such alignment is necessary because glass CRTs vary in their dimensions since the glass molds, which are used to form the CRTs, wear over time. Thus, alignment of the coupler with the CRT must be performed to compensate for dimensional variations on the glass of the CRT faceplate. However, since rubber coating 220 can conform to variations in surfaces and objects, centering fingers 221 can be designed such that, when coupler 200 is pushed down onto a CRT faceplate, the centering fingers accommodate the variations in the dimensions of the edges of the CRT faceplate and perform the centering function.

Centering fingers 221 are preferably discretely placed around the periphery of coupler 200 in a manner sufficient to properly align a lens and CRT when coupled together with coupler 200. For example, a plurality of centering fingers 221 in one embodiment are placed at regular intervals all around the perimeter of coupler 200. In an alternative embodiment, centering fingers 221 are placed at all four corners; or in only two opposing corners. Centering fingers 221 are formed such that they spring outward when forced onto the CRT so as to securably grab onto and position coupler 200 (and thus the lens) to the CRT faceplate in a predetermined position relative to the CRT faceplate.

Another advantage of utilizing centering fingers 221 instead of a CRT alignment machine is that it becomes possible to build a light barrier into coupler 200. Typically, there is a significant amount of light that shines from one CRT unit to another in a projection television system. Use of a CRT alignment machine requires access by the CRT alignment machine in areas of the CRT unit that light leaks from. Consequently, light barriers must b e added after alignment, typically to the "green" CRT unit assembly.

However, if a CRT alignment machine is not necessary because centering fingers 221 perform this alignment function, the light barrier functionality can be molded into the rubber coating 220 o r into casting 201.

Although the present invention has been described above a s having a coating 220 formed of rubber, in alternative embodiments other elastomeric compounds may be used instead, such as silicone rubber, or a thermoplastic elastomer material, for example the thermoplastic elastomer marketed by Advanced Elastomer Systems, L.P., of Akron, Ohio, under the trademark SANTOPRENErM. The elastomeric compound used to form coating 220 preferably has a durometer, or hardness, between approximately 30 and approximately 50 on the Shore A scale; is able to withstand prolonged contact with the cavity fluid a t normal operating temperatures (e.g., up to approximately 8 5 degrees Celsius); and is suitable for application by an injection molding process.

As will be appreciated by those skilled in the art, it must be ensured that coating 220 adheres to casting 201. Depending upon elastomeric compound utilized, various techniques may be utilized to ensure proper adhesion. For example, with some elastomeric coatings, such as SANTOPRENErM, an initial surface coating may need to be applied to casting 201 to ensure adhesion of the SANTOPRENUM coating. Alternatively, mechanical interlocking may be utilized, as will be appreciated by those skilled in the art.