Display devices, such as projectors, may include a metal vapor discharge lamp including an electrode pair, as the light source. The light source may generate large amounts of light for operation of the display device. However, the light source may also generate large amounts of heat that may be harmful to other components of the display device. The light source may be housed in an enclosure, such as a quartz enclosure, that may break or explode, causing harm to other components of the display device or to a human operator of the device. Accordingly, it may be advantageous to improve the thermal and safety characteristics of the display device.
Reflector 14 may receive light 22 projected from light source 12 and thereafter may project the light to modulator 16. In the embodiment shown, reflector 14 includes a reflective surface 26 that defines a cavity 28 wherein light source 12 is positioned within cavity 28. Reflector 14 may define any shape as desired, for example, reflector 14 may define a cavity 28 that is shaped in the form of one of a sphere, an ellipse and a parabola. Reflector 14 may be manufactured of any material that may be suitable for a particular application, such as glass, poly crystalline or metal, and may or may not include a reflective coating formed thereon.
Light source 12 may be any light source that operates to produce projected light beam 22 for imaging. In the embodiment shown, light source 12, which may be referred to as a burner, is a metal vapor discharge lamp including an electrode pair 30 positioned within a first enclosure 32. Light source 12 may be an ultra high pressure (UHP) mercury arc lamp but in other embodiments may comprise any type of technology as desired.
First enclosure 32 may completely seal electrode pair 30 therein, wherein first enclosure 32 may define a hermetic seal of electrode pair 30 so as to seal a discharge gas 31 within the first enclosure. First enclosure 32 may be manufactured of a transparent material, such as a quartz (fused silica), that may normally withstand the high temperatures generated by electrode pair 30. Electrode pair 30 may include terminals 30a and 30b which extend through and outwardly of first enclosure 32, without compromising the hermetic seal of the enclosure. Terminals 30a and 30b may be connected to a power source 30c, which may be controlled by controller 24, for powering the electrodes to generate light beam 22. Any discharge gas 31 may be utilized, such as mercury, xenon, or the like.
At extreme temperatures or during prolonged use of device 10, the heat generated by electrode pair 30 and discharge gas 31 may cause breakage of first enclosure 32, such as an explosion during a catastrophic breakage of first enclosure 32. Such breakage of first enclosure 32 may cause harm to the other components of device 10, such as damage to reflector 14 or modulator 16, if the first enclosure is not physically shielded from the other components. Even in cases where first enclosure 32 does not explode or otherwise break, the heat generated by electrode pair 30 and discharge gas 31, without removal of such heat, may cause harm to other components of device 10, such as melting or deformation of reflector 14.
Light source 12, in the embodiments shown, includes a second enclosure 34 that encloses first enclosure 32 therein. In the embodiment shown in
Use of diamond to form second enclosure 34 has many benefits because diamond has the following properties: an extreme mechanical hardness, on the order of approximately 90 gigapascals (GPa); a bulk modulus of approximately 1.2×10E12 N/m2; a low compressibility of approximately 8.3×10E−13 m2/N; a high thermal conductivity at room temperature of approximately 2×10E3 W/mK; a low thermal expansion coefficient at room temperature of approximately 0.8×10E−6 K; a broad optical transparency from the deep ultraviolet (UV) to the far infrared (IR) region of the electromagnetic spectrum; and a good electrical insulation quality having a resistivity of approximately 1×10E16 cm. Diamond can be doped to change its resistivity over the range of approximately 10 to 1×10E6 cm, thereby becoming a semiconductor with a wide band gap of approximately 5.4 electron volts (eV). Diamond is resistant to chemical corrosion, including hot acids, bases and other chemicals, and is biologically compatible. Diamond also exhibits a low or “negative” electron affinity, i.e., it emits electrons from its surface with very little applied voltage.
Referring to
Still referring to
In this embodiment, device 10 may further include a cooling device 62 such as a fan that may force a cooling fluid 64, such as air, over second enclosure 34 to remove heat from within device 10 that is produced by electrode pair 30 and gas 31. Cooling device 62 may be positioned outwardly of a light projection path 66 of device 10 such that the cooling device does not reduce the image quality of device 10.
Second enclosure 34 is positioned with central axis 48 positioned parallel to projection axis 66 of reflector 14. This embodiment may be referred to as an axial configuration of second enclosure 34 within reflector 14. In other embodiments, second enclosure 34 may be oriented in any position, such as in a transverse position wherein central axis 48 of second enclosure 34 is positioned perpendicular to projection axis 66 of reflector 14 (see
Second enclosure 34 may function as a measurement surface because the diamond tube may provide improved thermal conduction which may provide improved thermal feedback on the burner temperature, i.e., the temperature of the first enclosure, to controller 24. This thermal feedback information may be gathered by a thermal sensor 68 which may be adhered to an exterior surface of second enclosure 34 by an adhesive 70, such as thermal epoxy. Thermal sensor 68 may be positioned outside cavity 28 of reflector 14 such that a temperature measured by thermal sensor 68 is conducted along second enclosure 34 and outwardly from reflector 14. The temperature measurements of second enclosure 34 gathered by thermal sensor 68 may allow improved thermal regulation of the display device, which may allow improved regulation of the fan speed of cooling device 62, thereby providing improved regulation of the surface temperature of first enclosure 32, over prior art display device designs.
In prior art arc lamps, for example, an electrode pair may heat the outer surface of their enclosure to a temperature of approximately 1000 degrees Celsius (° C.). The hottest part of the reflector may have a temperature in a range of approximately 300 to 350° C. The coldest part of the reflector may have a temperature in a range of approximately 180 to 200° C. Accordingly, inside the closed arc lamp of prior art designs, an intensive air recirculation may take place. Additionally, an air plume around the outer surface of the lamp enclosure may be unstable, especially around the reflector neck, where the temperature gradient may be the largest. Use of a second enclosure 32 of the present design may reduce this temperature gradient and provide a reliable temperature measurement for temperature regulation of the lamp.
Second enclosure 34 may also function as a safety barrier around first enclosure 32 by withstanding physical impact of shards of first enclosure 32, and by containing chemicals within the system, such as containing mercury gas from inside first enclosure 32, in the event that first enclosure 32 ruptures. The strength of diamond fabricated second enclosure 34 may reduce the need for other safety barrier or capture devices within display device 10, thereby reducing the cost, size, and/or weight of display device 10 when compared to prior art devices.
Cooling fluid 64 may then be removed from the system by a second cooling device 74 that forces a second cooling fluid 76 by second end 58 of second enclosure 34 and out a grating 78 and away from reflector 14. In other embodiments, a second cooling device may not be used, or another type of cooling method may be utilized. In this embodiment, spacers 50 may be positioned outwardly of reflector 14 and light projection path 66 of device 72 such that the spacers do not reduce the image quality of device 72. In this embodiment, second enclosure 34 may comprise a transparent tube 80, such as quartz, having a diamond coating 82 formed thereon. The diamond coating 82 may be formed as described with reference to
An adhesion promotion coating 80 may be formed on outer surface 44 of first enclosure 32. Adhesion promotion coating 80 may be formed of silane or the like, which may promote the adhesion of another coating, such as a diamond coating, on the outer surface 44 of first enclosure 32. In another embodiment, coating 80 may be a layer of an index matching material that may be selected to increase transmittance through the burner assembly of predetermined wavelengths of light of interest.
A second enclosure 34 may then be formed on adhesion promotion coating 80 as another layer 82. Layer 82 may be an optical coating of grown/deposited diamond material, such as an alpha carbon coating, which may have a thickness 80a of approximately 50 to 200 nm. Diamond coating 82 may be formed on layer 80 as described with reference to
In this embodiment, an ultra violet and/or infrared (UV/IR) filtering coating 84 may then be formed on diamond coating 82. The infrared coating 84 may allow the display device to utilize regenerative heating to reduce the operational requirements and the initial strike requirements of the light source 12. The UV/IR coating may also eliminate the use of a separate UV/IR filter positioned downstream within projection path 66 (see
In step 94, an operator may determine if the substrate should be removed from the interior of the diamond tube that is formed. If yes, in step 96 the substrate may be removed from inside the formed diamond tube by melting, chemical etching or the like. In step 98 the hollow diamond tube may then be placed around first enclosure 32. In step 100 spacers 50 (see
If the answer to step 94 is no, the diamond coating is left on the substrate and the process may proceed to step 102.
In step 102 second enclosure 34, with first enclosure 32 positioned therein, is placed within a reflector 14, positioned adjacent modulator 16 and connected to controller 24 (see
The foregoing description of embodiments of the invention have been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed, and modifications and variation are possible in light of the above teachings or may be acquired from practice of the invention. The embodiments were chosen and described in order to explain the principles of the invention and its practical application to enable one skilled in the art to utilize the invention in various embodiments and with various modification as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.