EP3571708A1 - Lampe à plasma commandée par laser cw à faible puissance unique sans électrode - Google Patents
Lampe à plasma commandée par laser cw à faible puissance unique sans électrodeInfo
- Publication number
- EP3571708A1 EP3571708A1 EP18703671.0A EP18703671A EP3571708A1 EP 3571708 A1 EP3571708 A1 EP 3571708A1 EP 18703671 A EP18703671 A EP 18703671A EP 3571708 A1 EP3571708 A1 EP 3571708A1
- Authority
- EP
- European Patent Office
- Prior art keywords
- chamber
- laser
- light source
- laser light
- high intensity
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Pending
Links
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- 229910052724 xenon Inorganic materials 0.000 description 39
- FHNFHKCVQCLJFQ-UHFFFAOYSA-N xenon atom Chemical compound [Xe] FHNFHKCVQCLJFQ-UHFFFAOYSA-N 0.000 description 37
- 239000007789 gas Substances 0.000 description 36
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- 229910052743 krypton Inorganic materials 0.000 description 10
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Classifications
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J65/00—Lamps without any electrode inside the vessel; Lamps with at least one main electrode outside the vessel
- H01J65/04—Lamps in which a gas filling is excited to luminesce by an external electromagnetic field or by external corpuscular radiation, e.g. for indicating plasma display panels
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J61/00—Gas-discharge or vapour-discharge lamps
- H01J61/02—Details
- H01J61/025—Associated optical elements
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J61/00—Gas-discharge or vapour-discharge lamps
- H01J61/02—Details
- H01J61/12—Selection of substances for gas fillings; Specified operating pressure or temperature
- H01J61/16—Selection of substances for gas fillings; Specified operating pressure or temperature having helium, argon, neon, krypton, or xenon as the principle constituent
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J61/00—Gas-discharge or vapour-discharge lamps
- H01J61/02—Details
- H01J61/54—Igniting arrangements, e.g. promoting ionisation for starting
Definitions
- the present invention relates to illumination devices, and more particularly, is related to high intensity lamps.
- High intensity arc lamps are devices that emit a high intensity beam.
- the lamps generally include a gas containing chamber, for example, a glass bulb, with an anode and cathode that are used to excite the gas within the chamber.
- An electrical discharge is generated between the anode and cathode to provide power to the excited (e.g. ionized) gas to sustain the light emitted by the ionized gas during operation of the light source.
- FIG. 1 shows a pictorial view and a cross section of a low-wattage parabolic prior art Xenon lamp 100.
- the lamp is generally constructed of metal and ceramic.
- the fill gas, Xenon, is inert and nontoxic.
- the lamp subassemblies may be constructed with high-temperature brazes in fixtures that constrain the assemblies to tight dimensional tolerances.
- FIG. 2 shows some of these lamp subassemblies and fixtures after brazing.
- a cathode assembly 3a contains a lamp cathode 3b, a plurality of struts holding the cathode 3b to a window flange 3c, a window 3d, and getters 3e.
- the lamp cathode 3b is a small, pencil-shaped part made, for example, from thoriated tungsten.
- the cathode 3b emits electrons that migrate across a lamp arc gap and strike an anode 3g. The electrons are emitted thermionically from the cathode 3b, so the cathode tip must maintain a high temperature and low-electron-emission to function.
- the cathode struts 3c hold the cathode 3b rigidly in place and conduct current to the cathode 3b.
- the lamp window 3d may be ground and polished single-crystal sapphire (A102). Sapphire allows thermal expansion of the window 3d to match the flange thermal expansion of the flange 3c so that a hermetic seal is maintained over a wide operating temperature range.
- the thermal conductivity of sapphire transports heat to the flange 3c of the lamp and distributes the heat evenly to avoid cracking the window 3d.
- the getters 3e are wrapped around the cathode 3b and placed on the struts. The getters 3e absorb contaminant gases that evolve in the lamp during operation and extend lamp life by preventing the contaminants from poisoning the cathode 3b and transporting unwanted materials onto a reflector 3k and window 3d.
- the anode assembly 3f is composed of the anode 3g, a base 3h, and tubulation 3i.
- the anode 3g is generally constructed from pure tungsten and is much blunter in shape than the cathode 3b. This shape is mostly the result of the discharge physics that causes the arc to spread at its positive electrical attachment point.
- the arc is typically somewhat conical in shape, with the point of the cone touching the cathode 3b and the base of the cone resting on the anode 3g.
- the anode 3g is larger than the cathode 3b, to conduct more heat. About 80% of the conducted waste heat in the lamp is conducted out through the anode 3g, and 20% is conducted through the cathode 3b.
- the anode is generally configured to have a lower thermal resistance path to the lamp heat sinks, so the lamp base 3h is relatively massive.
- the base 3h is constructed of iron or other thermally conductive material to conduct heat loads from the lamp anode 3g.
- the tubulation 3i is the port for evacuating the lamp 100 and filling it with Xenon gas. After filling, the tabulation 3i is sealed, for example, pinched or cold-welded with a hydraulic tool, so the lamp 100 is simultaneously sealed and cut off from a filling and processing station.
- the reflector assembly 3j consists of the reflector 3k and two sleeves 31.
- the reflector 3k may be a nearly pure polycrystalline alumina body that is glazed with a high temperature material to give the reflector a specular surface.
- the reflector 3k is then sealed to its sleeves 31 and a reflective coating is applied to the glazed inner surface.
- the anode and cathode become very hot due to electrical discharge delivered to the ionized gas located between the anode and cathode.
- ignited Xenon plasma may burn at or above 15,000 C, and a tungsten anode/cathode may melt at or above 3600 C degrees.
- the anode and/or cathode may wear and emit particles. Such particles can impair the operation of the lamp, and cause degradation of the anode and/or cathode.
- One prior art sealed lamp is known as a bubble lamp, which is a glass lamp with two arms on it.
- the lamp has a glass bubble with a curved surface, which retains the ionizable medium.
- An external laser projects a beam into the lamp, focused between two electrodes.
- the ionizable medium is ignited, for example, using an ultraviolet ignition source, a capacitive ignition source, an inductive ignition source, a flash lamp, or a pulsed lamp. After ignition the laser generates plasma, and sustains the heat/energy level of the plasma.
- the curved lamp surface distorts the beam of the laser.
- a distortion of the beam results in a focal area that is not sharply defined. While this distortion may be partially corrected by inserting optics between the laser and the curved surface of the lamp, such optics increase cost and complexity of the lamp, and still do not result in a precisely focused beam.
- Embodiments of the present invention provide an electrodeless single low power continuous wave (CW) laser driven lamp.
- the present invention is directed to an ignition facilitated electrodeless sealed high intensity illumination device configured to receive a laser beam from a continuous wave (CW) laser light source.
- a sealed chamber is configured to contain an ionizable medium.
- the chamber has an ingress window disposed within a wall of a chamber interior surface configured to admit the laser beam into the chamber, a plasma sustaining region, and a high intensity light egress window configured to emit high intensity light from the chamber.
- the CW laser beam is producible by a CW laser below 250 Watts configured to produce a wavelength below 1100 nm.
- the device is configured to focus the laser beam to a full width at half maximum (FWHM) beam waist of 1-15 microns 2 and a Rayleigh length of 6 microns or less, and the plasma is configured to be ignited by the CW laser beam.
- FWHM full width at half maximum
- FIG. 1 is a schematic diagram of a prior art high intensity lamp in exploded view.
- FIG. 2 is a schematic diagram of a prior art high intensity lamp in cross-section view.
- FIG. 3 is a schematic diagram of a first exemplary embodiment of a laser driven electrodeless sealed beam lamp.
- FIG. 4 is a schematic diagram of a second exemplary embodiment of a laser driven electrodeless sealed beam lamp.
- FIG. 5 is a schematic diagram of a third exemplary embodiment of a laser driven electrodeless sealed beam lamp.
- FIG. 6 is a schematic diagram of a fourth exemplary embodiment of a laser driven electrodeless sealed beam lamp.
- FIG. 7 is a flowchart of a first exemplary method for operating a laser driven
- FIG. 8 is a flowchart of a second exemplary method for operating a laser driven electrodeless sealed beam lamp.
- previous sealed plasma lamps have relied on ignition either by electrodes entering into a plasma chamber, or by a high energy pulsed laser.
- the embodiments described below are directed to igniting a plasma in Xenon lamps of multiple constructions by use of a single CW laser under specified conditions.
- these conditions for ignition include, as a baseline, laser power starting at around 200 Watts and higher, a minimum focal point size for the laser light within the chamber, a minimal lamp fill pressure, for example, starting at 350 psi or higher.
- Several embodiments provide for ignition at a laser power starting below 100 Watts.
- each of these embodiments includes an ingress window admitting laser light into the chamber where the ingress window is flat, or incorporates a focusing lens. It is important to note that the high fill pressures to enable auto-ignition in the embodiments described below are not feasible in prior art quartz bubble lamps.
- FIG. 3 shows a first exemplary embodiment of an electrodeless laser driven sealed beam lamp 300.
- the lamp 300 includes a sealed chamber 320 configured to contain an ionizable medium, for example, Xenon, Argon, or Krypton gas.
- the chamber 320 is generally pressurized, for example to a pressure level in the range of 290-1150 psi.
- Xenon quartz "bubble" lamps are typically at 250-300 psi.
- the plasma spot may be smaller and the efficiency of the laser energy to photon conversion improves.
- the smaller spot size at higher pressures may be advantageous for coupling into small apertures, for example, a fiber aperture when 1 : 1 reflection is used between the focus point of the lamp and the fiber aperture.
- the chamber 320 has an egress window 328 for emitting high intensity egress light 329.
- the egress window 328 may be formed of a suitable transparent material, for example quartz glass or sapphire, and may be coated with a reflective material to reflect specific wavelengths. The reflective coating may block the laser beam wavelengths from exiting the lamp 300, or may be configured to pass wavelengths in a certain range such as visible light, or prevent ultraviolet energy from exiting the lamp 300.
- the egress window 328 may also have an anti -reflective coating to increase the transmission of rays of the intended wavelengths. This may be a partial reflection or spectral reflection, for example to filter unwanted wavelengths from egress light 329 emitted by the lamp 300.
- An egress window 328 coating that reflects the wavelength of the ingress laser light 365 back into the chamber 320 may lower the amount of energy needed to maintain plasma within the chamber 320.
- the chamber 320 may have a body formed of metal, sapphire or glass, for example, quartz glass.
- the chamber 320 has an integral reflective chamber interior surface 324 configured to reflect high intensity light toward the egress window 328.
- the interior surface 324 may be formed according to a shape appropriate to maximizing the amount of high intensity light reflected toward the egress window 328, for example, a parabolic or elliptical shape, among other possible shapes.
- the interior surface 324 has a focal point 322, where high intensity light is located for the interior surface 324 to reflect an appropriate amount of high intensity light.
- the high intensity egress light 329 output by the lamp 300 is emitted by a plasma formed of the ignited and energized ionizable medium within the chamber 320.
- the ionizable medium is ignited within the chamber 320 by one of several means, as described further below, within the chamber 320.
- the plasma is continuously generated and sustained at a plasma generating and/or sustaining region 326 within the chamber 320 by energy provided by ingress laser light 365 produced by a laser light source 360 located within the lamp 300 and external to the chamber 320.
- the plasma sustaining region 326 is co-located with a focal point 322 of the interior surface 324 at a fixed location.
- the laser light source 360 may be external to the lamp 300.
- the chamber 320 has a substantially flat ingress window 330 disposed within a wall of the interior surface 324.
- the substantially flat ingress window 330 conveys the ingress laser light 365 into the chamber 320 with minimal distortion or loss, particularly in comparison with light conveyance through a chamber window having one or two curved surfaces.
- the ingress window 330 may be formed of a suitable transparent material, for example quartz glass or sapphire.
- a lens 370 is disposed in the path between the laser light source 360 and the ingress window 330 configured to focus the ingress laser light 365 to a lens focal region 372 within the chamber.
- the lens 370 may be configured to direct collimated laser light 362 emitted by the laser light source 360 to the lens focal region 372 within the chamber 320.
- the laser light source 360 may provide focused light, and transmit focused ingress laser light 365 directly into the chamber 320 through the ingress window 330 without a lens 370 between the laser light source 360 and the ingress window 330, for example using optics within the laser light source 360 to focus the ingress laser light 365 to the lens focal region 372.
- the lens focal region 372 is co-located with the focal point 322 of the interior surface 324 of the chamber 320.
- the interior surface and/or the exterior surface of the ingress window 330 may be treated to reflect the high intensity egress light 329 generated by the plasma, while simultaneously permitting passage of the ingress laser light 365 into the chamber 320.
- the portion of the chamber 320 where laser light enters the chamber is referred to as the proximal end of the chamber 320, while the portion of the chamber 320 where high intensity light exits the chamber is referred to as the distal end of the chamber 320.
- the ingress window 330 is located at the proximal end of the chamber 320, while the egress window 328 is located at the distal end of the chamber 320.
- a convex hyperbolic reflector 380 may optionally be positioned within the chamber 320.
- the reflector 380 may reflect some or all high intensity egress light 329 emitted by the plasma at the plasma sustaining region 326 back toward the interior surface 324, as well as reflecting any unabsorbed portion of the ingress laser light 365 back toward the interior surface 324.
- the reflector 380 may be shaped according to the shape of the interior surface 324 to provide a desired pattern of high intensity egress light 329 from the egress window 328. For example, a parabolic shaped interior surface 324 may be paired with a hyperbolic shaped reflector 380.
- the reflector 380 may be fastened within the chamber 320 by struts (not shown) supported by the walls of the chamber 320, or alternatively, the struts (not shown) may be supported by the egress window 328 structure.
- the reflector 380 also prevents the high intensity egress light 329 from exiting directly through the egress window 328.
- the multiple reflections of the laser beam past the focal plasma point provide ample opportunity to attenuate the laser wavelengths through properly selected coatings on reflectors 380, interior surface 324 and egress window 328.
- the laser energy in the high intensity egress light 329 can be minimized, as can the laser light reflected back to the laser 360. The latter minimizes instabilities when the laser beam interferes within the chamber 320.
- reflector 380 at preferably an inverse profile of the interior surface 324, ensure that no photons, regardless of wavelength, exit the egress window 328 through direct line radiation. Instead, all photons, regardless of wavelength, exit the egress window 328 bouncing off the interior surface 324. This ensures all photons are contained in the numerical aperture (NA) of the reflector optics and as such can be optimally collected after exiting through the egress window 328.
- NA numerical aperture
- the non-absorbed IR energy is dispersed toward the interior surface 324 where this energy may either be absorbed over a large surface for minimal thermal impact or reflected towards the interior surface 324 for absorption or reflection by the interior surface 324 or alternatively, reflected towards the egress window 328 for pass-through and further processed down the line with either reflecting or absorbing optics.
- the laser light source 360 is a continuous wave (CW) laser, rather than a pulsed laser.
- the laser light source 360 may be a single laser, for example, a single infrared (IR) laser diode, or may include two or more lasers, for example, a stack of IR laser diodes.
- the wavelength of the laser light source 360 is preferably selected to be in the near-IR to mid-IR region as to optimally and economically pump the Xenon gas with available off-the-shelf lasers.
- the laser light source 360 may alternatively produce far-IR wavelengths, for example, a 10.6um C0 2 laser.
- a plurality of IR wavelengths may be applied for improved coupling with the absorption bands of the Xenon gas.
- other laser light solutions are possible, but may not be desirable due to cost factors, heat emission, size, or energy requirements, among other factors.
- ionizing gas may be excited CW at 1070 nm, 14 nm away from a very weak absorption line (1% point, 20 times weaker in general than lamps using flourescence plasma, for example, at 980 nm emission with the absorption line at 979.9nm at the 20% point.
- a 10.6 ⁇ laser can ignite Xenon plasma even though there is no known absorption line near this wavelength.
- C0 2 lasers can be used to ignite and sustain laser plasma in Xenon. See, for example, US Patent No. 3,900,803.
- the path of the laser light 362, 365 from the laser light source 360 through the lens 370 and ingress window 330 to the lens focal region 372 within the chamber 320 is direct.
- the lens 370 may be adjusted to alter the location of the lens focal region 372 within the chamber 320.
- a control system such as an electronic or electro/mechanical control system, may be used to adjust the lens focal region 372 to ensure that the lens focal region 372 coincides with the focal point 322 of the interior surface 324, so that the plasma sustaining region 326 is stable and optimally located.
- the controller may maintain the desired location of the lens focal region 372 in the presence of forces such as gravity and/or magnetic fields.
- FIG. 4 shows a cross sectional view of a second exemplary embodiment of an electrodeless high intensity lamp 500.
- the sealed chamber 520 is enclosed by a dual window cylindrical housing.
- the chamber 520 has a substantially flat ingress window 530, serving as a first wall of the chamber 520.
- the substantially flat ingress window 530 conveys the ingress laser light 365 into the chamber 520 with minimal distortion or loss, particularly in comparison with light conveyance through a curved chamber surface.
- the ingress window 530 may be formed of a suitable transparent material, for example quartz glass or sapphire.
- the lens 370 is disposed in the path between the laser light source 360 and the ingress window 530 configured to focus the ingress laser light 365 to a lens focal region 372 within the chamber 520, in a similar fashion as the first embodiment.
- the lens focal region 372 is co-located with the plasma sustaining region 326, and the focal point 322 of the sealed chamber 520.
- the location of the plasma sustaining region 326 within the chamber 520 may be variable, as there is no optical focal point, since the cylindrical housing does not need a reflector. However, observations of the cylindrical body indicate that by operating the plasma out of the center, for example, closer to the top of the lamp than the bottom of the lamp, the internal turbulence of the ionized gas is affected, which in turn may impact stability.
- the chamber 520 has an egress window 528 for emitting high intensity egress light 529.
- the egress window 528 may be formed of a suitable transparent material, for example quartz glass or sapphire.
- the portion of the chamber 520 where laser light enters the chamber is referred to as the proximal end of the chamber 520, while the portion of the chamber 520 where high intensity light exits the chamber is referred to as the distal end of the chamber 520.
- the ingress window 530 is located at the proximal end of the chamber 520, while the egress window 528 is located at the distal end of the chamber 520.
- the third embodiment may include elements for adjusting the pressure level of the sealed chamber 520.
- the sealed lamp 500 may include a pump system 596 connecting an external source of Xenon gas with the sealed chamber 520 via a fill line 592 connecting the external source of Xenon gas with a gas ingress fill/release valve 594.
- Methods for ignition of Xenon gas/plasma in the chamber 520 may vary depending upon the amount of pressure and/or temperature within the chamber 520, among other factors. At fill pressures below 325 psi and/or low laser operating power below 200 watt, electrical ignition may be preferable with electrodes, for example with a dual cathode electrical ignition system as discussed in the background section. However, the inclusion of electrodes into the chamber and providing electrical connections of the electrodes adds complexity to the design of the lamp. Therefore, it is an objective of the exemplary embodiments to provide for ignition of the gas/plasma in the chamber that omits electrodes.
- a CW laser may be used to thermally ignite Xenon gas within the chamber without the presence of either electrodes or a passive non-electrode igniting agent.
- a power density in the order of 1 x 10 10 W/ cm 2 is generally needed at the beam waist to achieve self-ignition within a fraction of a second of the ionizable medium. This may be achieved under the above described conditions.
- the power needed to ignite the plasma is impacted by fill pressure of the gas and the excitation laser wavelength. The latter affects the diameter of the beam waist with longer wavelength lasers requiring more power. The former impacts the distance between atoms and affects the energy needed to start the ionization process.
- NA Numerical Aperture
- the CW laser light source 360 is focused to a sufficiently small cross section of the beam waist at the lens focal region 372 within the chamber, for example, a cross section on the order of 1-15 micron 2
- the ingress window 530 of the chamber 520 should preferably be a flat surface.
- the ingress window has a concave or convex curved surface, for example, the side of a bubble chamber, it may be difficult or impossible to focus the ingress laser light 365 from the CW laser light source 360 into a sufficiently small lens focal region 372 to successfully ignite the plasma within the chamber 520.
- the ingress window 530 may be fashioned as a lens instead of a flat window, configured to focus the ingress laser light 365 at the focal region 372.
- a passive non-electrode igniting agent 610 is introduced to the chamber 520, as shown in FIG. 5.
- a passive non-electrode igniting agent 610 is a material introduced into the interior of the chamber 520 that may be excited into producing a stream of charge carriers by stimulation of the CW laser light source 360, and without an externally induced current.
- an electrode would be termed an active ignition source, as it ignites the ionizable medium by actively applying an external electric current to the electrodes.
- the passive non-electrode igniting agent 610 may include, for example, an ionizing ignition source, such as 2% thoriated tungsten or Kr-85, among others.
- the self- heating of the Xenon gas with temperature transfer to the passive non-electrode igniting agent 610 causes the passive non-electrode igniting agent 610 to create sufficient charge carriers to self-ignite the Xenon lamp at roughly half the power needed for a non-thoriated solution of the first, and second embodiments.
- ignition may be caused at an intermediate pressure/temperature range, for example a 450psi filled xenon lamp self-ignites at 175 Watt (+/- 15%), via introduction of a passive non-electrode igniting agent 610, such as thoriated tungsten, internally to the lamp chamber 520.
- the third embodiment 600 includes a reflective chamber 520 having the elements of the first embodiment lamp 300 (FIG. 3), in particular, a sealed beam Xenon lamp such as a ceramic or metal body Cermax lamp with integral parabolic or elliptical reflector, and also includes the passive non-electrode igniting agent 610.
- the passive non-electrode igniting agent 610 is not an active electrode, as no external voltage/current is applied.
- the self-heating of the Xenon gas via a solid state CW laser light source 360 transfers temperature to the passive non- electrode igniting agent 610, for example thoriated materials, creating sufficient charge carriers within the chamber to self-ignite the Xenon lamp at roughly half the power needed for a non- thoriated solution.
- the CW laser light source 360 is focused at a fixed location within the chamber 520, relatively near to the thoriated tungsten 610 to provide expedited heating and thermal ignition.
- the thoriated tungsten 610 may be configured as a single passive element, a multitude of passive elements in a geometrical configuration, for example, pointed at each other, or as a ring within the chamber 520, such that the CW laser light source 360 is focused at a location close to the passive elements or within the ring of thoriated tungsten 610, such as the center of the ring.
- the thoriated tungsten ring 610 may be positioned such that the center of the ring is co-located with the lens focal region 372 within the chamber 520, further co- located with the plasma sustaining region 326, and the focal point 322 of the sealed chamber 520.
- the passive non-electrode igniting agent 610 may not be configured as a ring, for example, the passive non-electrode igniting agent 610 may be configured as a rod, disk, or other configuration such that at least a portion of the passive non-electrode igniting agent 610 is substantially adjacent to the chamber focal region 372. For example, it may be desirable that at least a portion of the passive non-electrode igniting agent 610 may be in the range of 1-5 mm from the focal region 372. It should be noted the appropriate distance of the passive non-electrode igniting agent 610 from the focal region 372 may depend upon other parameters, such as the pressure of the chamber 320, or the power of the CW laser 360.
- the same CW laser light source 360 used to ignite the plasma is used to sustain the plasma after ignition.
- the thoriated tungsten ring 610 may be brazed or floating. It should be noted that in the schematic drawings FIG. 5 and FIG. 6, the thoriated tungsten ring 610 and/or the plasma sustaining region 326 and focal point 322 of the sealed chamber 520 are not necessarily drawn to scale.
- FIG. 6 shows a cross sectional view of a fourth exemplary embodiment of an
- the fourth embodiment 700 includes a cylindrical chamber 520 including the elements of the second embodiment lamp 500 (FIG. 4), and also including the passive non-electrode igniting agent 610.
- the absence of electrodes in the lamp eliminates tungsten deposits on the walls and windows of the lamp eliminate the main source of light output degradation or reduction in the lamp.
- No electrodes in the lamp allows for less expensive construction without the need to provide exit seals for the electrodes through the lamp body. The exit seals are known to detonate over life and to be potentially end-of-life sources for the lamp.
- No thoriated electrodes in the lamp allows for less ionizing radiation pollution potential.
- No electrodes through the lamp chamber wall allows for smaller lamp construction which in turn allows for increasing the internal fill pressure, and in turn increasing the conversion efficiency of the lamp. This results in a more robust lamp.
- the absence of electrodes eliminates any need for ceramic insulation materials in the lamp. This is advantageous, as ceramic insulation materials may outgas during operation of the lamp and may contribute to light output degradation.
- an electrodeless lamp includes eliminating the need for a power supply to electrically ignite the lamp.
- the higher fill pressure facilitates use of smaller lamps, which may reduce cost and increase energy-to-photon conversion efficiency.
- Elimination of electrodes further removes undesirable side effects of electrodes, such as electrodes interfering with the gas turbulence in the lamp, thereby improving the light output stability. Further, the absence of electrodes eliminates a source of shadows produced by the high intensity light.
- FIG. 7 is a flowchart of a first exemplary method for operating a laser driven
- any process descriptions or blocks in flowcharts should be understood as representing modules, segments, portions of code, or steps that include one or more instructions for implementing specific logical functions in the process, and alternative implementations are included within the scope of the present invention in which functions may be executed out of order from that shown or discussed, including substantially concurrently or in reverse order, depending on the functionality involved, as would be understood by those reasonably skilled in the art of the present invention.
- a window for example ingress window 530 is provided.
- the window is configured to receive energy from a CW laser light source 360 disposed outside a sealed lamp chamber 320 to a focal region 372 within the chamber 320, as shown by block 710.
- a pressure level of the chamber 320 is set to a predetermined pressure level appropriate to igniting an ionizable medium within the chamber 320, as shown by block 720. For example, if the CW laser light source is in the range of (250- 500W), a pressure level of (300-600psi) may be suitable to ignite the ionizable medium with just the CW laser energy.
- Ingress laser light 365 from the laser light source 360 is focused to a focal region 372 within the chamber 320 having a predetermined volume as shown by block 730, for example a cross sectional beam waist of 1 to 15 micron 2 with a Rayleigh length of 6-18 microns.
- the ionizable medium within the chamber 320 is ignited with the laser light source to form a plasma, as shown by block 740.
- the plasma is sustained within the chamber 320 by the continuous wave laser light source 360, as shown by block 750.
- FIG. 8 is a flowchart 800 of a second exemplary method for operating a laser driven electrodeless sealed beam lamp. Reference is made to FIGS. 5 and 6 regarding the flowchart in FIG. 8.
- the window is configured to receive energy from a continuous wave laser light source 360 disposed outside a sealed lamp chamber 320 to a focal region 372 within the chamber 320, as shown by block 810.
- a pressure level of the chamber 320 is set to a predetermined pressure level appropriate to igniting an ionizable medium within the chamber 320, as shown by block 820.
- Ingress laser light 365 from the laser light source 360 is focused to a focal region 372 within the chamber 320 having a predetermined volume as shown by block 830, for example a cross sectional FWHM (full width of the beam at half its maximum intensity) beam waist of 1 to 15 micron 2 with a Rayleigh length of 6-18 microns.
- FWHM full width of the beam at half its maximum intensity
- a passive non-electrode igniting agent 610 disposed entirely within the chamber 320 is positioned adjacent to the focal region 372, as shown by block 840.
- the passive non-electrode igniting agent 610 may be heated either directly or indirectly.
- the passive non-electrode igniting agent 610 is heated directly by focusing the laser light onto the thoria and once hot, redirecting the laser into the desired focal point of the lamp cavity. Indirect heating of the thoria occurs through thermal convection of the ionizing gas with the laser light source 360, as shown by block 850.
- the ionizable medium within the chamber 320 is ignited by the heated passive non- electrode igniting agent 610 to form a plasma, as shown by block 860.
- the CW laser light source is in the range of 125-200 Watts, with a pressure level of 300-600 psi may be suitable to ignite the ionizable medium with a passive non-electrode igniting agent 610 heated with energy from the CW laser 360.
- the plasma within the chamber 320 is sustained with energy from the continuous wave laser light source 360, as shown by block 870.
- self-ignition refers to ignition of an inert gas, for example Xenon, or a combination of gasses, for example, Xenon and Krypton, within a sealed, pressurized chamber 320 solely by a steady state (CW) laser 360, with or without the presence of a passive non- electrode igniting agent 610.
- inert gas for example Xenon
- CW steady state
- one approach is to make the beam waist smaller, in particular, the beam waist at the lens focal region 372, which is generally co-located with the plasma sustaining region 326.
- optics for example, the lens 370
- to reduce the beam waist size may have practical and cost limitation. For example by changing the NA of the optics 370 from 0.38 to 0.5 and higher, an anticipated self-ignite at a demonstrable lower power of the laser light source 360 based on beam waist volume reduction may not occur in practice due to several reasons, including limits to the accuracy in grinding optics 370, as well as difficulties adjusting parameters of the laser light source 360, for example, divergence, etc.
- a first parameter that may be adjusted to reduce the beam waste without affecting optical production limitations is the wavelength of the laser light source 360.
- a higher wavelength results in a smaller beam waist and shorter Rayleigh length.
- a beam waist volume reduction on the order of four times may result when switching from a 1070nm laser light source 360 to a 532nm pumping laser light source 360 (frequency double Nd: YAG laser, also frequency doubled Nd:YLF laser around 535nm). Accordingly the beam waist diameter and length are both reduced by a factor two.
- the wavelength of the laser light source 360 is eliminated from the egress light 329 emitted by the lamp 300, 600, in particular for visible light applications.
- Visible light applications typically force the wavelength of the laser light source 360 to be outside the spectrum of a black body radiation desired for the application.
- the laser light source 360 is typically selected in the 700-2000nm for the generation of visible light in the 400-700nm range or the use of 1064-1070nm for generation of an application spectrum in the 400-900nm range.
- a 532-535nm wavelength may be used for the laser light source 360, and in this case the superfluous energy may be filtered out at the egress window 328 and/or ingress window 330 of the chamber 320.
- NIR near infrared
- a 500-900nm limited light source may self-ignite when pumped with a lower power 532-535nm the laser light source 360 compared to a 400-900nm system pumped with a 1064-1070nm the laser light source 360, and may also incorporate smaller plasma size based on thermal/gravity conditions.
- a 532-535nm pump laser may self-ignite Xenon at about half the power needed for a 1064-1070nm the laser light source 360, assuming all other boundary conditions remaining same.
- the beam waist may be made smaller without resorting to optics 370 that are more accurate.
- the wavelength of the laser light source 360 for example, an IPG fiber laser from 1000 nm or above to, for example, a range of 532 nm to 535 nm, the beam waist volume may be approximately 4 times smaller than when using the higher bandwidth laser light source 360.
- a laser light source 360 with a wavelength below 1000 nm, there may be, for example, around 20% spill of the laser drive power into the plasma.
- the spill includes unabsorbed laser power and appears in the output of the lamp 300, 600, similar to when using a 1070nm laser light source 360.
- the laser wavelength may be removed from the egress light 329, for example, using a laser line filter. This is a technique generally known to persons having ordinary skill in the art, and is not described further herein. Removing or attenuating the 532nm laser wavelength from the output of the laser light source 360 generally does not have a negative impact on the illumination application.
- the size of the beam waist is reduced from the higher wavelength waist size.
- a 450nm diode laser from IPG may produce a self-igniting plasma well below 75 watts when a non-electrode igniting agent 610 is used, while self-ignition may occur in the 125 watt range when no electrodes are present.
- a benefit of operating a lamp 300, 600 at lower laser power includes the resulting smaller plasma size. Since the plasma size is governed by thermal (gravity) performance, lower power results in a smaller plasma size and that can be coupled with a smaller egress aperture 328 for the high intensity light. This may be desirable for applications where, for example, small apertures are preferred over photon output.
- a dip may occur centered around 885nm in the black body spectrum. Therefore, the egress light 329 does not exhibit a black body spectrum and in some applications the reduced output at this wavelength is an issue.
- the 885nm dip may be caused by the reabsorption of generated photons by the high density Xenon gas as the end of an on-axis elongated "cigar-shaped" plasma cone. So an observer in line with the plasma axis will have a reduced spectral performance around 885nm.
- Lamps 300, 600 with a 90%Xe and 10%Kr mix may not exhibit any ignition issues and barely any efficiency loss, although still exhibit a dip at 885nm. The dip is reduced as the Kr/Xe ratio increases.
Abstract
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
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US15/409,702 US10057973B2 (en) | 2015-05-14 | 2017-01-19 | Electrodeless single low power CW laser driven plasma lamp |
PCT/US2018/014327 WO2018136683A1 (fr) | 2017-01-19 | 2018-01-19 | Lampe à plasma commandée par laser cw à faible puissance unique sans électrode |
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EP3571708A1 true EP3571708A1 (fr) | 2019-11-27 |
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EP18703671.0A Pending EP3571708A1 (fr) | 2017-01-19 | 2018-01-19 | Lampe à plasma commandée par laser cw à faible puissance unique sans électrode |
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EP (1) | EP3571708A1 (fr) |
JP (2) | JP2020505733A (fr) |
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US11533800B2 (en) | 2018-12-06 | 2022-12-20 | Excelitas Technologies Singapore Pte. Ltd. | Laser sustained plasma and endoscopy light source |
US11587781B2 (en) | 2021-05-24 | 2023-02-21 | Hamamatsu Photonics K.K. | Laser-driven light source with electrodeless ignition |
CN113586283B (zh) * | 2021-07-28 | 2022-08-19 | 中国人民解放军国防科技大学 | 超燃冲压发动机燃烧室一维可控点火装置 |
US20230319959A1 (en) * | 2022-03-29 | 2023-10-05 | Hamamatsu Photonics K.K. | All-Optical Laser-Driven Light Source with Electrodeless Ignition |
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US3900803A (en) | 1974-04-24 | 1975-08-19 | Bell Telephone Labor Inc | Lasers optically pumped by laser-produced plasma |
US7989786B2 (en) * | 2006-03-31 | 2011-08-02 | Energetiq Technology, Inc. | Laser-driven light source |
US7435982B2 (en) * | 2006-03-31 | 2008-10-14 | Energetiq Technology, Inc. | Laser-driven light source |
US8698399B2 (en) * | 2009-02-13 | 2014-04-15 | Kla-Tencor Corporation | Multi-wavelength pumping to sustain hot plasma |
US9576785B2 (en) * | 2015-05-14 | 2017-02-21 | Excelitas Technologies Corp. | Electrodeless single CW laser driven xenon lamp |
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2018
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