Passively cooled solid-state laser

Coherent light generators – Particular temperature control – Heat sink

Reexamination Certificate

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C372S039000, C372S075000

Reexamination Certificate

active

06351478

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates generally to a solid-state laser system and, in particular, to a solid-state laser that is passively cooled by heat sink bodies containing phase change material.
BACKGROUND OF THE INVENTION
Solid-state laser systems are characterized in that they have a solid-state laser gain medium which converts energy from an optical pump source to a coherent output laser beam. The pump source can be one of many available energy-producing systems such as flash lamps or semiconductor laser diodes. The energy produced by the pump source is incident upon the laser medium and absorbed by the laser medium.
The absorbed energy in the laser medium causes the atoms in the laser medium to be excited and placed in a higher energy state. Once at this higher state, the laser medium releases its own energy which is placed into an oscillating state by the use of a laser resonator. The laser resonator includes at least two reflective surfaces located on either side of the laser medium. The laser resonator can be designed to continuously release a laser beam from the system. Alternatively, the resonator can be designed such that when the energy oscillating through the laser medium reaches a predetermined level, it is released from the system as a high-power, short-duration laser beam. The emitted light produced from the solid-state laser system is generally coherent and exits the system in a predefined area.
In many systems, the laser medium is Neodymium-doped, Yttrium-Aluminum Garnet (Nd:YAG). A laser medium made from Nd:YAG absorbs optical energy most readily when the energy is at a wavelength of approximately 808 nanometers (nm). Thus, the source to pump the Nd:YAG laser medium should be emitting light energy at approximately 808 nm. Gallium arsenide semiconductor laser diodes can be manufactured with dopants (e.g. aluminum) that will cause the emitted light to be in a variety of wavelengths, including 808 nm. Thus, the semiconductor laser diodes, which are lasers by themselves, act as the pump source for the laser medium.
The conversion of optical energy into coherent optical radiation is accompanied by the generation of heat which must be removed from the device. Cooling of the laser medium reduces the build-up of temperature gradients and, thereby, the strain and stress in the laser medium and also avoids the likelihood of laser medium fracture due to high thermo-elastic stress. Also, variation of the refractive index and its associated optical distortion can be largely controlled or avoided by effective cooling. The result is improved beam quality and/or increased average output power.
Diode array performance is also strongly dependent on temperature. Not only is the output power a function of temperature, but the wavelength of the emitted energy that is to be absorbed by the laser medium is also a function of diode temperature. To maintain desired array performance and to prevent the diode array from being destroyed by overheating, cooling of the area surrounding the array is also important.
It has been an objective for laser manufacturers to develop high-power, solid-state systems. As the output power in these system increases, the waste heat increases which puts more demands on cooling systems and necessitates larger volumes in which to provide adequate cooling. Hence, the efficient and effective removal of waste heat from both the diode arrays and the laser medium is an important factor in developing compact, high-powered laser systems.
Known laser systems utilize active cooling. Active cooling usually requires mechanical pumps, coolant carrying tubing operated at pressure, and electrical supplies to drive the pumps. Another example of a system that utilizes active cooling is one that incorporates thermoelectric coolers. However, these thermo-electric coolers are inefficient and require additional power to control the temperature of the laser. Thus, active cooling requires additional input power to the laser system. It also requires the use of additional space and can often make the laser system quite heavy.
SUMMARY OF THE INVENTION
The present invention is a passively cooled, diode-pumped solid-state laser system producing a high-power laser beam. The system includes at least one diode array producing optical energy that is absorbed by a solid-state laser medium. The solid-state laser medium has a central axis and an outer surface into which optical energy from the diode array is emitted.
The system also includes means for producing laser resonation substantially optically aligned along the central axis of the laser medium. The resonating means include a pair of opposing reflective surfaces positioned with the laser medium therebetween. One of the opposing reflective surfaces is an output coupling mirror for reflecting a portion of energy produced by the laser medium to provide laser resonation and also for transmitting the high-power laser beam.
To provide the passive cooling of the laser medium, a laser medium heat sink assembly contains a substantially solid form of phase change material in thermal communication with the outer surface of the laser medium. The solid form of the phase change material changes to a liquid form of the phase change material in response to heat from the laser medium being transferred to the laser medium heat sink assembly.
To absorb the heat from the laser diodes, a diode array heat sink assembly contains a substantially solid form of phase change material in thermal communication with the diode array. The solid form of the phase change material changing to a liquid form of the phase change material in response to heat from the diode array being transferred to the diode array heat sink assembly.
While the laser system cannot be operated endlessly with only passive cooling, passive cooling can provide the necessary cooling for a laser system for several minutes. Such a system can be useful in many applications such as the terminal guidance system for a missile. Advantages to be gained from passive cooling include more compact, portable, lighter, and vibration free laser systems. Additionally, a laser system with more effective passive cooling can accommodate the increased heat transfer associated with a more powerful laser.
Furthermore, employing a phase change material that transitions from solid to liquid phase as a working medium in a heat exchanger provides thermal control properties in addition to heat dissipation qualities. Thermal control is provided by the latent heat associated with the phase change material. A material in its solid phase will continue to absorb energy and remain at a constant temperature (its melting point) until a specified amount of energy is absorbed completing the transition from solid to liquid phase. Furthermore, an interface in intimate contact with the phase change material proceeding through this transition will be held approximately constant at the material's melting temperature until the transition is complete.


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patent:

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