KR100978163B1 - Method and apparatus for a light weight enclosure for projection televisions - Google Patents

Abstract

The projection display device includes a plastic upper cabinet 300 including a display device that optically interacts with the reflecting means, a plastic upper cabinet 300 having a bottom periphery fitting snugly to the upper periphery of the plastic lower cabinet 400, and optical components. Plastic lower cabinet 400 including supporting optical frame 500. The second cabinet 400 includes an outer shell 403 to allow the optical frame 500 to be fitted into the outer shell to increase the rigidity of the second cabinet 400. The plastic lower cabinet 400 has a bottom periphery that substantially matches the top periphery of the plastic floor interface 600. The plastic upper cabinet 300 and the plastic lower cabinet 400 are separately formed and attached detachably.

Projection Televisions, Display Units, Jackets, Cabinets, Optical Frames, Floor Interfaces

Description

METHOD AND APPARATUS FOR A LIGHT WEIGHT ENCLOSURE FOR PROJECTION TELEVISIONS}

This application claims priority to US Provisional Application No. 60 / 376,098, filed April 26, 2002.

FIELD OF THE INVENTION The present invention relates to television envelopes and, more particularly, to projection television cabinets.

Projection television includes a cabinet comprising a video projector and a video screen optically aligned by one or more mirrors. Such cabinets are usually very large and heavy, and the various optical elements mounted therein must be carefully aligned. If the video projector elements and mirrors inside the cabinet move relative to the screen, proper convergence will not be achieved, resulting in deterioration of the image as it causes color fringing. Projection television cabinets typically include a large mass combination of wood, metal and plastic that is inherently resistant to misalignment forces. Metals generally have high bending strength against warping.

For example, the projection television 100 shown in FIG. 1 has a structure in which wooden board material is used. The plates are formed of a box including a main body 120 and a bottom cabinet 170. The screen mounting frame 140 is mounted in front of the main body 120 to install the screen 130. The mirror mounting shell 160 is mounted to the rear of the body 120 to install the mirror 150. Floor cabinet 170 is adapted to include video devices and electronic components.

The size of the body 120 and the total size of the television, including the mirror mount 160, is determined by the size of the projection screen used. Each part of the housing is shaped to the exact size and dimensions originally designed to provide a single housing based on the size of the projection screen. As a result, the parts are not compatible with projection screens of different sizes.

The projection television 200 shown in FIG. 2 has a structure in which a metal frame 280 of a predetermined shape is located in the floor cabinet 270. The screen mounting frame 240 including the screen 230 and the mirror mounting shell 260 including the mirror 250 are integrally mounted to surround the frame 280.

In the projection television 200 of FIG. 2, the metal frame 280 used is designed as a housing of a predetermined size according to the size of the projection screen. As a result, it is incompatible with other projection screen dimensions.

In order to form a cabinet for a projection television, it is necessary to use wood and high bending strength metal so as to obtain a certain level of rigidity so that the quality of the image due to delivery and handling is not impaired and the projection television can be delivered to the customer. Unfortunately, the use of wood and metal makes the cabinet heavy, more expensive, and lacks compatibility with various projection screen sizes.

The present invention includes methods and apparatus for interchangeable lightweight skins for display devices such as projection televisions. The envelope according to the principles of the present invention comprises a top and bottom cabinet detachably attached. The lower cabinet supported by the floor interface supports the upper cabinet and includes a shell for inserting an optical frame. The optical frame supports optical components that represent picture or video signals. In order to lighten the sheath, the lower cabinet can be made of low bending strength material, which is generally light in weight. However, the optical frame is made of a higher bending strength material (such as steel), and the sheath is designed so that when the optical frame is inserted, the optical frame hardens the lower cabinet by preventing the side walls of the lower cabinet from moving toward each other.

In one embodiment, the upper and lower cabinets and the floor interface are made of plastic. The upper cabinet has position indicators that mate with locators in the lower cabinet so that the lower cabinet limits the lateral movement of the upper cabinet.

In another embodiment, the projection display device comprises a display device optically cooperating with the reflecting means and having a plastic upper cabinet having a bottom periphery substantially coincident with the upper periphery of the plastic lower cabinet, and an optical frame for supporting the optical components. A plastic lower cabinet including a shell for inserting the optical frame to fit the optical frame into the shell to increase the rigidity of the plastic lower cabinet and having a bottom periphery substantially coincident with the upper periphery of the plastic floor interface; The plastic upper cabinet and the lower cabinet are formed separately and detachably attached.

The notice of the present invention can be easily understood in view of the following detailed description in conjunction with the accompanying drawings.

1 is an exploded perspective view of a typical wooden frame cabinet of a projection television.

2 is an exploded perspective view of a typical metal frame cabinet of a projection television.

3 is an exploded isometric view of one embodiment of a projection television envelope according to the present invention.

4 is an exploded front view of the projection television envelope of FIG.

5 is an exploded side view of the projection television envelope of FIG.

6 is an exploded plan view of the projection television envelope of FIG.

7 is a plan view and a bottom view of the lower cabinet of the projection television envelope of FIG.

8 is an exploded view of the connection between the circular pocket of the upper cabinet and the circular pocket of the lower cabinet of the projection television envelope of FIG.

 For the sake of understanding, the same reference numerals are used as much as possible to denote common elements in the drawings.

The present invention will be described with respect to rear projection televisions and related devices. However, those skilled in the art will appreciate that the present invention can be usefully applied to general display devices using any projection television or projection technology. Therefore, the inventors are aware of the wider applicability of the present invention in addition to the rear projection television described herein. The present invention can be used to create lightweight, stable and interchangeable shells for front or rear projection televisions or display devices of various screen sizes.

With reference to Figures 3-8, which include commonly designed elements, the projection television envelope of the present invention will be described. The projection television envelope includes an upper cabinet 300, a lower cabinet 400, and a floor interface 600. In addition, the optical frame 500 is illustrated in the projection television envelope of the present invention supporting all the optics needed for a rear projection television except for the screen and mirrors provided in the upper cabinet 300. The optical frame 500 is configured in the form of a cartridge as a whole, and is inserted into the lower frame 400 to give rigidity to the lower frame 400. The upper cabinet 300, the lower cabinet 400, and the floor interface 600 are each independently formed. Although the floor interface 600 of the projection television envelope is shown as a separate component in FIGS. 1-8, it may be useful for the floor interface 600 to be implemented to be substantially incorporated into the lower cabinet 400.

Parts of the projection television envelope of FIGS. 1-8 are constructed such that after the lower cabinet 400 is assembled to the floor interface 600, the upper cabinet 300 is mounted to the assembly of the lower cabinet 400 and the floor interface 600. Is formed. This approach offers the advantage that the screen size of the upper cabinet 300 can be arbitrarily selected for the lower cabinet 400. That is, any size, for example 37 inches, 50 inches or more of the upper cabinet 300 may be used with the general lower cabinet 400. This is made possible by forming the bottom walls of all upper cabinets 300 having screens of essentially different sizes in a substantially similar geometric design for the fittings and mounting components. Thus, the length of the lower cabinet 400 on the side of the screen may be different from the length of the upper cabinet 300. Preferably, by first making the lower cabinet 400 for the smallest screen, such as 37 inches, the lower cabinet 400 is made for the smallest screen length, i.e. the smallest screen, towards the screen. It is preferable to have the same length as the upper cabinet 300. Thus, for screens of other sizes, the length of the upper cabinet 300 towards the screen is longer than the length of the lower cabinet 400. Of course, depending on the range of screen sizes to be supported, it is possible to select the size of the lower cabinet larger than is required for the smallest screen, so that the same lower cabinet 400 can also be used for the largest screen. In this case, the length of the upper cabinet 300 on the screen side is smaller than the lower cabinet 400. This makes it easy to make projection televisions of different sizes simply by replacing the upper cabinet 300. In addition, it is useful to manufacture the upper cabinet 300, lower cabinet 400, and floor interface 600 using lightweight materials capable of mass production. Lightweight materials reduce the weight of the projection television envelope and shorten the manufacturing process, reducing the time and cost associated with the projection television envelope. In the drawings attached herein, the lightweight material is plastic and is produced by an injection molding process. Various plastics are known to those skilled in the art. However, the lightweight material is not limited to plastic only, and other materials such as aluminum can likewise be used.

The upper cabinet 300 provides a display device envelope in optical cooperation with reflecting means for locating one image from the image forming the optics of the projection television. In one embodiment of the invention, the display device is a screen and the reflecting means is a mirror which cooperates to position the image of the picture on the screen. The rectangular frame part 302 is formed in front of the upper cabinet 300. The upper cabinet 300 is made of a top wall 304, side walls 306 ₁ , 306 ₂ (collectively, side walls 306), a rear wall 308, and a bottom wall 310 to form a box as a whole. The front face is open. The bottom wall 310 is made so that the side facing the projection lens is opened when assembled to the lower cabinet 400. Top wall 304, sidewall 306, and bottom wall 310 are generally open toward the front to accommodate larger screens and mirrors.

The bottom wall 310 is formed in the interior of the upper cabinet 300 by two flanges (overlapping walls) 312 ₁ , 312 ₂ (collectively, flanges 312) parallel to the longitudinal direction of the two side walls 306. . The flange 312 is used to join the upper cabinet 300 with the lower cabinet 400. In particular, as described below, the flange 312 of the upper cabinet 300 mate with the ledge 412 in the lower cabinet 400. The flanges 312 are each formed of a front face 313 ₁ , 313 ₂ (collectively the front face 313) and these front faces are also respectively disposed in circular pockets 314 ₁ , 314 ₂ (in general, a circular pocket). (314)]. As described below, the circular pocket 314 mates with two circular pockets 422 on the lower cabinet 400.

Top cabinet 300 also includes a center “hump 320”. The center hump 320 is formed as part of the bottom wall 310. The center hump 320 helps to mechanically couple between the upper cabinet 300 and the lower cabinet 400, which makes the outer shell stronger and more stable. The center hump 320 also increases the strength and stability of the shell by transferring loads from the top of the upper cabinet 300 to the more stable base of the upper cabinet 300. The center hump 320 comprises a front flange 321, two screw holes 322 ₁ , 322 ₂ [collectively, screw holes 322] and two screw mounting tabs 323 ₁ , 323 ₂ [batch] along the front face. Or a screw mounting tab 323]. The front flange 321 on the center hump 320 engages with the ledge 410 on the lower cabinet 400, as described below. The two screw holes 322 mate with the screw holes 414 on the rear wall 416 of the lower cabinet 400. As described below, the two screw mounting tabs 323 engage with the holes 418 on the rear wall 416 of the lower cabinet 400. It will be understood by those skilled in the art that various combinations of ledges, flanges, screw mounting tabs, and screw holes may be formed in the upper cabinet 300 to mount the upper cabinet 300 to the lower cabinet 400. One important thing is that a substantial portion of the bottom periphery of the upper cabinet 300 is supported by the lower cabinet 400 so that the load of the upper cabinet 300 is supported in a stable manner by the lower cabinet 400. In this manner, fasteners (ie, screws, bolts, screw sets, etc.) used to secure the upper cabinet 300 to the lower cabinet 400 are not subjected to excessive loads or stresses.

All the optics required for the rear projection television are provided in the optical frame 500 of the lower cabinet 400, except for the screens and mirrors supplied to the upper cabinet 300, as described above. The optical frame 500 is generally configured in the form of a cartridge and can be easily replaced from the front face. Optical frame 500 includes two metal end plates 502 ₁ , 502 ₂ (collectively, end plate 502) and two metal plate rails 510 ₁ , 510 ₂ (collectively, rail 510). Is made of]. Therefore, the optical frame 500 in this assembly is stronger and harder than the lower cabinet 400 made of plastic. End plate 502 and rail 510 support optronics that produce a picture. Each end plate 502 is formed with an upper edge (collectively 506) and a bottom fold (collectively 520). As described below, the two upper edges 506 mate with the two ledges 424 of the protruding block 431 above the lower cabinet 400. This registration prevents the optical frame 500 from moving above the sidewalls 404 of the lower cabinet 400 toward each other. As will be described later, the bottom folded portion 520 is coupled to the ledge 426 in the lower cabinet 400. As described below, the front edge 503 of each end plate 502 mate with the side 428 of the protruding block 438 to center the optical frame 500 in the lower cabinet 400 during installation. . The mating of the protruding block 438 and the end plate prevents the optical frame 500 from moving below the sidewalls 404 of the lower cabinet 400 relative to each other. The top of the rear edge in each end plate 502 is made of threaded tabs (collectively 504). As described below, two screw mounting tabs 504 mate with two screw holes 430 in the protruding block 431 on the lower cabinet 400. In addition, the rear edge of each bottom fold 520 is formed of a screw mounting tab (collectively mounting tab 521). As will be described below, the two screw mounting tabs 521 mate with two screw holes 432 in the lower cabinet 400.

When the optical frame 500 is mounted to the lower cabinet 400, the optical frame 500 is mounted on the lower cabinet so that the sheet metal plate end plate 502 of the optical frame 500 can strengthen the structure of the lower cabinet 400. (400) fits snugly. We conclude that it is important to reinforce the lower cabinet 400 with the optical frame 500 to provide the strength required in the projection television envelope of the present invention. Once again, those skilled in the art will appreciate that various combinations of ledges, flanges, screw mounting tabs, and screw holes may be formed in the optical frame 500 to mount the optical frame 500 to the lower cabinet 400. There will be. Importantly, the main part of the periphery of the optical frame 500 is supported by the lower cabinet 400 so that the load of the optical frame 500 is supported in a stable manner by the lower cabinet 400. will be.

The lower cabinet 400 is a convoluted thin wall structure. Since the lower cabinet 400 is designed to support the upper cabinet 300 and surround and support the optical frame 500, the lower cabinet 400 may be configured such that the load of the upper cabinet 300 and the optical frame 500 limits the stress of any fixture. It is delivered to the cabinet 400. In addition, the lower cabinet 400 may be formed to accommodate the speakers of the projection television. The lower cabinet 400 is formed in a general rectangular shape. If the speakers are to be accommodated in the lower cabinet 400, two additional rectangular rear cabinets are provided substantially integrally with a portion of the rear wall of the lower cabinet 400.

The lower cabinet 400 is formed of an upper wall 402, side walls 404 ₁ , 404 ₂ (collectively 404), a rear wall 416, and a bottom wall 408, the entire shape of which has a partial front face. It is in the form of an open box. The embodiment shown in the drawings herein shows two additional rectangular rear cabinets 415 ₁ , 415 ₂ (collectively, rear cabinet 415) for embedding a speaker.

The front face of the lower cabinet 400 is formed of two circular pockets 422 ₁ , 422 ₂ (collectively, the circular pocket 422) at both upper corners of the front face of the lower cabinet 400. As noted above, the circular pocket 422 of the lower cabinet 400 is mated with the circular pocket 314 of the upper cabinet 300 to position the upper cabinet 300 on the lower cabinet 400. These pairs of pockets together prevent the lower cabinet 400 from moving to the side of the upper cabinet 300. Lateral movement herein is defined as the movement from one of the side walls 300 to the other side wall direction. An exploded view of this junction is shown in more detail in FIG.

The connection between the top wall 402 and the side wall 404 of the lower cabinet 400 is a ledge 412 ₁ , 412 ₂ (collectively, the ledge 412 which occupies substantially the same space as the width of the lower cabinet 400). )]. As described above, the ledge 412 of the lower cabinet 400 mates with the flange 312 of the upper cabinet 300. As shown in detail in FIG. 5, the center of the top wall 402 is a protruding partial cutout suitably formed as an optical position indicator for positioning the optics (eg, cathode ray tubes) of the optical frame 500. It is formed to have 406. The rear edge of the protruding portion cutout forms the ledge 410. As described above, the ledge 410 of the lower cabinet 400 mate with the front flange 321 over the center hump 320 of the upper cabinet 300.

The rear wall 416 of the lower cabinet 400 is located at the rear wall 416 at both ends of the protruding optical position indicator 406, which includes two screw holes 414 ₁ , 414 ₂ (collectively, screws Hole 414]. As mentioned above, the two screw holes 414 in the rear wall 416 mate with the two screw holes 322 in the center hump 320 of the upper cabinet 300. The back wall 416 is formed of two further screw holes 418 ₁ , 418 ₂ (collectively screw holes 418). Two screw holes 418 are positioned on the rear wall 416 such that the screw holes 418 mate with the two screw mounting tabs 323 on the center hump 320 of the upper cabinet 300. Also, as will be described later, a plurality of screw holes 420 (example four screw holes 420) are formed in the rear wall 416 to mate with the screw mounting tabs 620 on the floor interface 600. do. See FIG. 4. Screw holes 417 ₁ , 417 ₂ (collectively screw holes 417) are formed near the bottom of each rear cabinet 415 on the rear wall 416. As described below, the two screw holes 417 mate with the threaded tabs 617 on the floor interface 600. Protruding ledges 446 ₁ and 446 ₂ (collectively, ledge 446) are formed at the base of each rear cabinet 415. As described below, the protruding ledge 446 mates with the edge 618 of the floor interface 600.

The bottom wall 408 of the lower cabinet 400 is designed to mate with the floor interface 600. The two ends of the bottom wall 408 extend slightly outwardly toward the side wall 404 and are connected with the side wall 440 of the front face of the cavity 403 and are integrated with the ledges 434 ₁ , 434 ₂ (collectively, ledges). (434)]. Similarly, both ends of the sidewall 404 slightly protrude toward the center of the bottom wall 408 to form two ledges 436 ₁ , 436 ₂ (collectively the ledge 436). As described below, the ledges 434 and 436 form channels that mate with the two protruding arms 611 of the floor interface 600. Channel-projecting arm pairs prevent the floor interface 600 from moving the lower cabinet 400 laterally.

Lower cabinet 400 also has an internal cavity 403 for tolerance to optical frame 500 and optics (eg, cathode ray tube components) in optical frame 500. The cavity 403 is open to the front side of the lower cabinet 400 so that the optical frame 500 is inserted into the lower cabinet 400.

The front face of the cavity 403 in the lower cabinet 400 is the protruding blocks 431 ₁ , 431 ₂ (collectively, the protruding block 431) located above the front face of the cavity 403, the cavity 403. Protruding blocks 438 ₁ , 438 ₂ (collectively, protruding block 438) located in front of the upper front of the two sidewalls 440 ₁ , 440 ₂ (collectively sidewalls) of the front face of the cavity 403. 440, and the bottom wall 408 of the front face of the cavity 403.

Screw holes 430 ₁ , 430 ₂ (collectively screw holes 430) are formed in each front surface of the protruding block 431 in the cavity 403. As noted above, the two screw holes 430 mate with the two screw mounting tabs 504 of the optical frame 500. Each side of the protruding block 431 of the cavity 403 forms two ledges 424 ₁ , 424 ₂ (collectively 424). As noted above, the two ledges 424 mate with the two upper edges 506 of the end plate 502 in the optical frame 500.

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In the front face of the cavity 403, the protruding blocks 438 are formed with sides 428 ₁ , 428 ₂ (collectively 428), respectively. As noted above, the side surfaces 428 of the protruding block 438 mate with the front edge 503 of the end plate 502 of each optical frame 500.

The two sidewalls 440 defining the cavity 403 form two ledges 426 ₁ , 426 ₂ (collectively, the ledge 426). As discussed above, the two ledges 426 of the sidewall 440 mate with the bottom fold 520 of the optical frame 500. Two screw holes 432 ₁ , 432 ₂ (collectively, screw holes 432) located near the top of the front face of the side wall 440 are made in the side wall 440, as described above. 432 mate with two threaded tabs 521 of the optical frame 500. In addition, screw holes 444 ₁ , 444 ₂ (collectively, screw holes 444) located near the front bottom of the side wall 440 are made in the side wall. As described below, the two screw holes 444 mate with the two screw mounting tabs 644 on the floor interface 600.

It will be understood by those skilled in the art that various combinations of ledges, flanges, screw mounting tabs, and screw holes may be formed in the lower cabinet 400 to mount the lower cabinet 400 to the floor interface 600. One important thing is that a substantial portion of the bottom periphery of the lower cabinet 400 is supported by the floor interface 600 so that the load of the lower cabinet 400 is supported in a stable manner by the floor interface 600. In this manner, the fixtures used to secure the lower cabinet 400 to the floor interface 600 (ie, screws, bolts, screw sets, etc.) are not subjected to excessive loads or stresses.

The floor interface 600 is a relatively thin wall structure and a plurality of ribs can be selectively added to reinforce it. In addition, the floor interface 600 optionally provides mobility by having a caster 630 at the bottom. The floor interface 600 is designed to receive and support the lower cabinet 400, so that the load of the lower cabinet 300 is transmitted to the floor interface 600 in a manner that limits the stress on any fixture. The floor interface 600 is generally rectangular and has two protruding arms that protrude from the front end of the rectangular body.

The rectangular body 610 of the floor interface 600 includes an upper wall 601, two side walls 602 ₁ , 602 ₂ (collectively, side walls 602), a rear wall 603, a bottom wall 604, And a front wall 605, which is in the form of a box with the front surface partially open. The two protruding arms 611 ₁ , 611 ₂ (collectively, the protruding arms 611) of the floor interface 600 include an upper wall 612, an outer wall 613 ₁ , 613 ₂ (collectively, an outer wall ( 613), two inner walls 614 ₁ , 614 ₂ (collectively, an inner wall 614), a bottom wall 615, and a front wall 616. The outer wall 613 of the protruding arm 611 extends laterally beyond the side wall of the rectangular body 610 to create two edges 618 ₁ , 618 ₂ (collectively, the edge 618). As noted above, the two edges 618 mate with the protruding ledges 446 at the base of the rear cabinet 415 of the lower cabinet 400. As noted above, the two protruding arms 611 mate with the channels 435 of the lower cabinet 400.

A plurality of screw mounting tabs 620 (eg, four screw mounting tabs 620) are formed on the front wall 605 of the rectangular body 610 of the floor interface 600 and above the front wall 605. Located along the edge. As noted above, the plurality of screw mounting tabs 620 mate with the plurality of screw holes 420 on the rear wall 416 of the lower cabinet 400.

The front wall 616 of each protruding arm 611 of the floor interface 600 is made with thread mounting tabs 644 ₁ , 644 ₂ (collectively, thread mounting tab 644), and each front wall 616. Is located along the top edge. As noted above, the screw mounting tabs 644 mate with two screw holes 444 located near the front bottom of the sidewall 440 of the lower cabinet 400.

Two screw mounting tabs 617 ₁ , 617 ₂ (collectively, screw mounting tab 617) are formed on the top wall 612 of the rectangular body 610 of the floor interface 600, and the side wall 602 Along the upper edge of the upper wall 612, the front wall 605 is sufficient to mate with the two screw holes 417 near the bottom of each rear cabinet 415 in the lower cabinet 400. Placed at a distance.

Those skilled in the art will appreciate that a variety of combinations of ledges, flanges, screw mounting tabs, and screw holes in the floor interface 600 may be used to mount the lower cabinet 400 to the floor interface 600. Importantly, the main part of the bottom periphery of the bottom cabinet 400 is supported by the floor interface 600, which is that the load of the bottom cabinet 400 is supported by the floor interface 600 in a stable manner. In this manner, excessive loads and stresses are not imposed on the fasteners (ie, screws, bolts, set screws, etc.) used to secure the lower cabinet 400 to the floor interface 660.

When assembled together, the upper cabinet 300, the lower cabinet 400 including the optical frame 500, and the floor interface 600 prevent the image damage of the projection television due to the movement of components made of lightweight materials and prevent glass It is advantageously to provide a projection television envelope that is substantially robust enough to enable mass production.

While the various holes and tabs are shown and described in the above embodiments as "screw" holes and "screw" mounting tabs, those skilled in the art will appreciate that various other types of fasteners (ie, bolts, set screws, adhesives, etc.) It will be appreciated that it can be usefully used as a tool for fixing branch components. In addition, although a certain number of holes and tabs are illustrated in the embodiments of the invention shown in the drawings herein, it will be understood by those skilled in the art that other numbers of holes and tabs may also be usefully employed in other embodiments of the invention. will be. According to the present invention, the number of holes and tabs ultimately introduced in order to fix the envelope of the projection television is determined depending on the degree of fixation required and required in the projection television and the number of elements used. An important aspect is that the various components of the present invention are interlocked in such a way as to provide the necessary rigidity for the projection television in order to prevent image damage of the projection television caused by the movement of the components. We also propose these important points in light weight materials and in an advantageous way to enable mass production of the proposed projection television envelope.

While the present invention has been described with reference to some preferred embodiments of the present invention, it is intended to illustrate the invention and is not meant to limit the invention to the embodiments and the accompanying description. Those skilled in the art will recognize that various modifications and variations can be made within the scope of the invention as defined in the claims.

Claims (20)

It includes a first cabinet disposed on the second cabinet 400, The second cabinet 400 includes an outer shell 403 for inserting an optical frame 500 for supporting the optical component and is disposed on the floor interface 600. The first and second cabinets are detachably attached, and the optical frame 500 and the second cabinet 400 are made of first and second materials, respectively, and the first material is the optical frame 500. Display device shell having a higher bending strength than the second material to prevent side walls (404) of the second cabinet (400) from moving toward each other when the shell is inserted into the shell (403). The method of claim 1, wherein the first cabinet 300, the second cabinet 400, and the floor interface 600 are made of plastic, and the first cabinet 300 includes the second cabinet 400. A display device envelope having a first position indicator 314 that mates with a second position indicator 422 to limit lateral movement of the first cabinet 300. 3. The protruding arm of the floor interface 600 of claim 2, wherein the second cabinet 400 limits the lateral deformation of the floor wall 408 of the lower cabinet 400. 611. Display device envelope having channel 435 that mate with 611. The display device envelope of claim 2, wherein the second material is metal. 3. The second cabinet 400 has two bottom ledges 426 extending from the bottom surface 408 and two top ledges extending from the top surface 402 of the second cabinet 400. 424, the upper ledge 426 mates with the two bottom folds 520 of the optical frame 500, and the bottom ledge 424 has two upper edges 506 of the optical frame 500. Display device outer shell to match with. delete delete The display device envelope according to claim 2, wherein the optical frame (500) is disposed inside the envelope (403) of the second cabinet (400) to increase the rigidity of the second cabinet (400). The shell of claim 2, wherein the first cabinet (300), the second cabinet (400), and the floor interface (600) are formed by an injection molding method. The display device envelope of claim 2, wherein the floor interface (600) is substantially integrated as part of the second cabinet (400). Projection display device, A first cabinet 300 having a display device optically cooperating with reflecting means and disposed above the second cabinet 400 and having a bottom peripheral portion substantially coincident with the upper peripheral portion of the second cabinet 400. Including, The second cabinet 400 includes an optical frame 500 for supporting an optical component, and the optical frame 500 is fitted to the shell 403 so that the rigidity of the second cabinet 400 can be achieved. A shell 403 for inserting the optical frame 500 to increase, wherein the second cabinet 400 is disposed above the floor interface 600 and substantially at the upper periphery of the floor interface 600. Has a bottom periphery to match, The first cabinet (300) and the second cabinet (400) are made of plastic, and are formed separately and detachably attached to the projection display device. 12. The projection display device of claim 11, wherein the display device is a screen. The projection display apparatus of claim 11, wherein the first cabinet (300), the second cabinet (600), and the floor interface (600) are formed by an injection molding method. 12. The projection display device of claim 11, wherein the floor interface (600) comprises reinforcing ribs. 12. The projection display device of claim 11, wherein the floor interface (600) further comprises a caster (630). To provide a display device envelope, As a step of forming the first cabinet 300, The first cabinet 300 is disposed above the second cabinet 400 and has a bottom periphery substantially coincident with the top periphery of the second cabinet 400, and when coupled together the first cabinet 300. The portion of the bottom periphery of the first cabinet 300 is supported by the second cabinet 400 so that the load transferred from the) to the second cabinet 400 is supported by the second cabinet 400, Forming the first cabinet 300 in plastic; As the step of forming the second cabinet 400, The second cabinet 400 includes an outer shell 403 for inserting the optical frame 500 so that the second cabinet 400 when the optical frame 500 fits snugly into the outer shell 403. Forming the second cabinet 400 of plastic, the stiffness of the second cabinet 400 having a bottom periphery disposed on top of the floor interface 600 and substantially coincident with the top periphery of the floor interface 600; , And forming the floor interface (600) from plastic, wherein the floor interface (600) is coupled to the second cabinet (400). delete delete delete delete

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