1. Technical Field
The present disclosure relates to a crystal growth apparatus and particularly to an Edge-defined film-fed crystal growth (EFG) growth apparatus.
2. Description of Related Art
Single crystals such as sapphire have been a material of choice for demanding, high performance optical applications, including various military and commercial applications. Single crystals possess good optical performance, and additionally possess desirable mechanical characteristics, and chemical stability in harsh environments. Methods for manufacturing single crystal sapphire include Kyropoulos method, Czochralski method, heat exchange method, edge-defined film-fed crystal growth (EFG) method and temperature gradient method. The EFG method can directly form single crystal sapphire with desired shape, so the manufacturing process is simple and the utilization rate of materials is improved. A conventional crystal growth apparatus of the EFG method includes a growth chamber and a cooling chamber positioned above the growth chamber and communicates with the growth chamber. The crystal growth apparatus further comprises a pull rod to lift the shaped crystal and pull the crystal to the cooling chamber to be cooled. After that, the crystal is taken out from the cooling chamber. However, this crystal growth apparatus requires a longer cycle time to produce crystals.
Therefore, there is room for improvement in the art.
The components in the drawings are not necessarily drawn to scale, the emphasis instead being placed upon clearly illustrating the principles of the present disclosure. Moreover, in the drawings, like reference numerals designate corresponding parts throughout several views.
The first housing 10 further includes a receiving portion 13, a heat insulator 14 and a heater 15. The first main body 11 is made of a plurality of insulating layers coated to a cube. The growth chamber 12 is positioned in the first main body 11. The main first body 11 includes a transfer port 17 at an end adjacent to the second housing 20. The receiving portion 13, the heat insulator 14 and the heater 15 are received in the growth chamber 12. The receiving portion 13 is configured for receiving raw materials of the shaped crystal sapphire (α-Al2O3 in molten state), and includes an opening 131. The heat insulator 14 is mounted on the receiving portion 13, and includes a molding cavity 141 with openings at both ends. One end of the molding cavity 141 communicates with the opening 131, and the other end of the molding cavity 141 communicates with the transfer port 17. The heater 15 that surrounds the receiving portion 13 is configured for heating the receiving portion 13.
The second housing 20 further includes a pulling rod 24, a separating sheet 26, a plurality of heating members 27 and a supporting rod 28 received in the second main body 21. The second main body 21 is made of a number of insulating layers coated to a box shape. The second main body 21 protrudes from one side and between the transmission chamber 22 and the cooling chamber 23 to form a housing portion 211 configured for accommodating the controller 30. The bottom wall of the transmission chamber 22 defines a communication port 221 communicating with the transfer port 17 and the molding cavity 141. The pulling rod 24 is slidably arranged on one side of the transmission chamber 22 away from the first main body 11, and in the direct line with the communication port 221 and the transfer port 17. The pulling rod 24 is capable of passing through the communication port 221, the transfer port 17 and the molding cavity 141 to insert into the receiving portion 13. A first seed rod (not figured) is detachably mounted on the pulling rod 24 to pull the shaped crystals. The separating sheet 26 is movably arranged on one side of the communication port 221. When the pulling rod 24 lifts the crystals to the transmission chamber 22, the separating sheet 26 blocks the communication port 221 to separate the transmission chamber 22 and the molding cavity 141. The heating members 27 are positioned in the transmission chamber 22 and the cooling chamber 23. The supporting rod 28 is mounted on the top of the cooling chamber 23. The supporting rod 28 includes a second seed rod (not figured) to exchange with the seed rod on the crystal 40, thus the crystal 40 is transmitted. The second seed rod is detachably mounted on the supporting rod 28.
The controller 30 is mounted in the housing portion 211, including an insulating base 31, a heating body 33, a pair of partition assemblies 35 and a transmission member 37. The insulating base 31 is positioned in the housing portion 211, and the heating body 33 is positioned in the insulating base 31, configured for heating the insulating base 31 and the partition assemblies 35. The two partition assemblies 35 are movably arranged on the two ends of the insulating base 31 and extend between the transmission chamber 22 and the cooling chamber 23, so as to separate the transmission chamber 22 and the cooling chamber 23. The partition assembly 35 includes a connection member 351 and a partition member 353. The connection member 351 is movably mounted on the insulating base 31, and the partition member 353 is fixed to the connection member 351. The connection member 351 is capable of moving upward to enable the cooling chamber 23 to communicate with the transmission chamber 22. In this embodiment, the partition member 353 is plate shape. The transmission member 37 is rotatable and arranged between the two partition assemblies 35.
In assemble, first, the receiving portion 13 is positioned in the growth chamber 12, the heat insulator 14 is mounted above the receiving portion 13, and the opening 131 is communicated with the transfer port 17. The heater 15 is positioned around the receiving portion 13. Then, the pulling rod 24 is movably arranged on the transmission chamber 22 above the communication port 221, and a first feed rod is mounted on the pulling rod 24. The separating sheet 26 is movably arranged above the communication port 221. A plurality of heating members 27 are positioned in the transmission chamber 22 and the cooling chamber. The supporting rod 28 is mounted above the cooling chamber 23, and a second feed rod is mounted on the support rod 28. After that, the insulating base 31 is positioned between the transmission chamber 22 and the cooling chamber 23, and the heating body 33 is positioned in the insulating base 31. The two partition assemblies 35 are movably positioned at the two ends of the insulating base 31, configured for closing the transmission chamber 22 and the cooling chamber 23. The transmission member 37 is positioned between the two partition assemblies 35.
In use, the raw material of the sapphire in the receiving portion 13 are heated to a molten state by the heater 15. A seed is mounted on the first seed rod of the pulling rod 24, and the pulling rod 24 passes through the communication port 221, the transfer port 17 and the molding cavity 141 to insert into the receiving portion 13, so as to grow crystal. The cooling chamber 23 is evacuated and then charged with protect gas (such as argon gas). The cooling chamber 23 is heated by the heating member 27, and the temperature of the second seed rod on the supporting rod 28 is raised. After the crystal growing process is completed, the crystal 40 is lifted to the transmission chamber 22 by the pulling rod 24, and the communication port 221 is blocked by the separating sheet 26 to separate the partition assembly 35 and the transmission member 37. The temperature of the crystal 40 is descend in the transmission chamber 22. The heating body 33 is stated to heat the partition assemblies 35 and the transmission member 37. When the crystal 40, the second feed rod in the cooling chamber 23, the partition assemblies 35 and the transmission member 37 have the similar temperature (for example: 1350° C.), the connecting members 351 move upward with the partition members 353 relative to the insulating base 31 to communicate the transmission chamber 22 with the cooling chamber 23. The rotary part 371 rotates 90 degrees with the transfer part 373. Thereby the two ends of the transfer part 373 are positioned near the support rod 28 and the pulling rod 24. One end of the transfer part 373 grasps the first seed rod on the pull rod 24, and the rotary part 371 rotates 180 degrees, thus the first seed rod and the crystal on the first seed rod are transmitted to the support rod 28. At the same time, the second seed rod on the support rod 28 are transmitted to the pulling rod 24. The transmission member 37 rotates 90 degrees again to be parallel with the partition assemblies 35. The partition assemblies 35 separate the transmission chamber 22 and the cooling chamber 23. The heating members 27 in the cooling chamber 23 and the heating body stop heating to cool the crystal 40 and the controller 30. The heating members 27 start to heat in the transmission chamber 22, then a separating sheet 26 moves to expose the communication port 221, and the pulling rod 24 inserts into the growth chamber 12 to grow crystal again. When the cooling chamber is cooled to room temperature, the cooling chamber 23 is opened to pull out the crystal, and then a seed is mounted. The crystal growth process is repeated.
The controller 30 is positioned between the transmission chamber 22 and the cooling chamber 23, so the pulling rod 24 is inserted into the growth chamber 12 for growing crystals when the crystal 40 is cooled in the cooling chamber. Therefore, the cycle time of producing the single sapphire crystal is reduced.
The crystal growth apparatus may include a plurality of cooling chambers 23, and a plurality of corresponding controllers 30. The transmission chamber 22 communicates with the cooling chamber 23 at one end. The controllers 30 are positioned between the transmission chamber 22 and the cooling chamber 23, and between the plurality of controllers 30.
The crystal growth apparatus may have only one partition assembly 35, and the transmission member 37 is positioned at one side of the transmission chamber 22 or the cooling chamber 23.
The transmission member 37 may be a flexible gripper claw. When the transmission chamber 22 is communicated with the cooling chamber 23, the flexible gripper claw is enable to extend to the pulling rod 24 to grasp the seed rod, and then extend to the supporting rod 28 with the crystal 40.
It is believed that the present embodiments and their advantages will be understood from the foregoing description, and it will be apparent that various changes may be made thereto without departing from the spirit and scope of the embodiments or sacrificing all of its material advantages.
Number | Date | Country | Kind |
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2012105892792 | Dec 2012 | CN | national |