Apparatus for moving exhaust tube of barrel reactor

An epitaxial barrel reactor for depositing a material on a semiconductor wafer by a chemical vapor deposition process using a reactant gas. The barrel reactor includes a receptacle defining a reaction chamber sized to receive at least one semiconductor wafer. The receptacle has an inlet port for introducing reactant gas to the reaction chamber and an exhaust port for removing reactant gas from the reaction chamber. The reactor also includes an exhaust tube sealingly engageable with the exhaust port of the receptacle for transporting reactant gas to facility piping to remove the gas from the reaction chamber after the chemical vapor deposition process. In addition, the reactor includes an actuator spaced from the receptacle for moving the exhaust tube between an operating position in which the tube sealingly engages the exhaust port of the receptacle and a maintenance position in which the tube is spaced from the exhaust port to provide access to the receptacle. Further, the reactor includes a mechanism operatively connected between the exhaust tube and the actuator for transmitting motion from the actuator to the exhaust tube to move the tube between the operating position and the maintenance position.

BACKGROUND OF THE INVENTION 
The present invention relates generally to barrel reactors and more 
particularly to apparatus for moving an exhaust tube of a barrel reactor 
between an operating position and a maintenance position. 
Barrel reactors, such as generally indicated by the reference numeral 10 in 
FIG. 1, are used to deposit epitaxial layers on semiconductor wafers by a 
process known as chemical vapor deposition. The epitaxial layers have 
lattice structures which are identical to those of the wafers, but may be 
grown so they have different conductivity than the wafers to obtain 
necessary electrical properties. As illustrated in FIG. 2, the barrel 
reactor 10 comprises a reaction chamber 12 constructed from an inverted 
bell jar 14 for containing wafers W. A gas ring 30 sits atop an upper 
opening 16 of the bell jar 14. Nozzles 32 are provided in the gas ring 30 
for introducing a reactant gas (e.g., silicon) into the reaction chamber 
12. This gas forms the epitaxial layer on the wafers W contained in the 
chamber 12. After deposition is complete, the reactant gas is purged from 
the reaction chamber 12 through an exhaust tube, generally designated by 
50' in FIG. 1, at the bottom of the bell jar 14. (Prime symbols are used 
with reference numbers herein to indicate that the designated component 
differs from the present invention.) The exhaust tube 50' includes an 
exhaust cup 52', flexible tubing 54 connected to the cup and rigid 
facility piping 56. Once purged, a seal plate 36 mounted on the gas ring 
30 may be lifted to open the reaction chamber 12 to remove the wafers W 
from the barrel reactor 10. 
Not only does material deposit on the wafers W contained in the reaction 
chamber 12, but it also deposits on the various components of the barrel 
reactor 10 during the chemical vapor deposition process. These deposits 
can become dislodged from the components and contaminate wafers during 
subsequent deposition operations. Consequently, the barrel reactor 
components must be replaced periodically to avoid contaminating wafers. 
Since the reactors 10 must be removed from service when the components are 
replaced, it is beneficial to reduce the time during which the reactors 
are out of service to reduce production costs associated with downtime. 
In the past, apparatus such as that generally designated 150' in FIG. 1 has 
been used to move the exhaust tube 50', and more particularly the cup 52', 
between an operating position in which it is tightly sealed against an 
exhaust port 18 (FIG. 3) of the bell jar 14 and a maintenance position in 
which the exhaust tube is spaced from the exhaust port of the bell jar. 
Separating the exhaust cup 52' from the bell jar 14 permits the bell jar 
and/or portions of the exhaust tube to be replaced or serviced. The prior 
apparatus 150' comprises a cylinder, generally designated 90', positioned 
directly below the bell jar 14 and exhaust tube 50'. The cylinder 90' is 
connected to the exhaust tube 50' so that the exhaust tube seats against 
the bell jar exhaust port 18 when the cylinder is extended and separates 
from the exhaust port when the cylinder is retracted. As shown in FIG. 1, 
flexible tubing 54 is connected between the exhaust tube and facility 
exhaust piping 56 to permit the exhaust tube to move easily between the 
operating position and the maintenance position. 
Prior apparatus 150' such as that described above are prone to failure due 
to the high temperature environment in which they are used. In particular, 
seals (not shown) in the cylinders 90' tend to fail when exposed to heat 
emitted by the bell jar 14 during chemical vapor deposition. Further, the 
prior exhaust cups 52' tend to fail in a region around their upper flanges 
68'. This region has reduced material strength because the flange 68' is 
welded to the tube. Moreover, O-ring seals (not shown) used to seal the 
interface between the flange 68' and the bell jar 14 fail when exposed to 
high temperatures. 
SUMMARY OF THE INVENTION 
Among the several objects of the present invention may be noted the 
provision of improved apparatus for moving an exhaust tube of a barrel 
reactor between an operating position and a maintenance position; the 
provision of such apparatus which reduces the downtime necessary to 
replace barrel reactor receptacles; and the provision of such apparatus 
which is resistant to heat produced by the barrel reactor. 
Briefly, apparatus of this invention is an epitaxial barrel reactor for 
depositing a material on a semiconductor wafer by a chemical vapor 
deposition process using a reactant gas. The barrel reactor includes a 
receptacle defining a reaction chamber sized to receive at least one 
semiconductor wafer. The receptacle has an inlet port for introducing 
reactant gas to the reaction chamber and an exhaust port for removing 
reactant gas from the reaction chamber. The reactor also includes an 
exhaust tube sealingly engageable with the exhaust port of the receptacle 
for transporting reactant gas to facility piping to remove the gas from 
the reaction chamber after the chemical vapor deposition process. In 
addition, the reactor includes an actuator spaced from the receptacle for 
moving the exhaust tube between an operating position in which the tube 
sealingly engages the exhaust port of the receptacle and a maintenance 
position in which the tube is spaced from the exhaust port to provide 
access to the receptacle. Further, the reactor includes a mechanism 
operatively connected between the exhaust tube and the actuator for 
transmitting motion from the actuator to the exhaust tube to move the tube 
between the operating position and the maintenance position. 
In another aspect, apparatus of this invention is for use with an epitaxial 
barrel reactor to move an exhaust tube between an operating position and a 
maintenance position. The apparatus comprises an actuator spaced from the 
reactor for moving the exhaust tube between the operating position and the 
maintenance position. Further, the apparatus includes a mechanism 
operatively connected between the exhaust tube and the actuator for 
transmitting motion from the actuator to the tube to move the tube between 
the operating position and the maintenance position. 
In yet another aspect, the present invention includes an exhaust tube for 
transporting reactant gas from an epitaxial barrel reactor. The tube 
comprises a tubular shell having an inlet and an outlet and a flange 
adjacent the inlet sized and shaped for connecting the tube to an outlet 
port of the barrel reactor. The tube also comprises a water-tight jacket 
surrounding the tube. The jacket and tube define an annular cooling 
passage extending at least partially along the tube for circulating 
cooling water around the tube to cool the tube during chemical vapor 
deposition. 
Other objects and features of the present invention will be in part 
apparent and in part pointed out hereinafter.

Corresponding reference characters indicate corresponding parts throughout 
the several views of the drawings. 
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
Referring now to the drawings and in particular to FIG. 1, a conventional 
epitaxial barrel reactor is designated in its entirety by the reference 
numeral 10. Such barrel reactors 10 are used to deposit epitaxial layers 
on semiconductor wafers by a process known as chemical vapor deposition. 
As illustrated in FIG. 2, the barrel reactor 10 comprises a reaction 
chamber 12 constructed from a receptacle such as an inverted bell jar 14 
for containing wafers W. The bell jar 14 includes an upper opening 16 for 
inserting and removing wafers W and an exhaust port 18 (FIG. 3) at the 
bottom of the bell jar for purging reactant gases from the reaction 
chamber 12 after deposition is complete. A rim 20 is provided around the 
upper end of the bell jar 14 for supporting the bell jar when it is 
installed in a work station platform P as shown in FIG. 1. 
As further illustrated in FIG. 2, a gas ring 30 is mounted on top of the 
bell jar 14 above its upper opening 16. Two nozzles 32 (only one of which 
is shown) are provided in the gas ring 30 for introducing a reactant gas 
(e.g., silicon) into the reaction chamber 12. This gas forms the epitaxial 
layer on the wafers W contained in the chamber 12. The gas ring 30 is held 
in place by screw fasteners 34 (only one of which is shown) which are 
fastened to the platform P. Thus, the gas ring 30 acts as a clamp for 
holding the rim 20 of the bell jar 14 against the work station platform P. 
A seal plate 36 is mounted on the gas ring 30 to seal the top of the 
reaction chamber 12. The seal plate 36 may be lifted to open the reaction 
chamber 12 to remove the wafers W from the barrel reactor 10. A pentagonal 
susceptor 38 suspended from the seal plate 36 includes circular recesses 
40 for holding the wafers W in a generally vertical orientation so one 
face of each wafer is exposed to gases in the reaction chamber 12. The 
susceptor 38 may be lifted out of the reaction chamber 12 to permit the 
wafers W to be removed from the recesses 40 once the deposition is 
complete. A controller 42 (FIG. 1) and motor (not shown) positioned above 
the seal plate 36 spin the susceptor 38 about its vertical axis to evenly 
distribute the epitaxial layer on the wafers W as is well known in the 
art. A cooling jacket 44 surrounds the bell jar 14 for cooling the jar and 
associated equipment. 
After deposition is complete, the reactant gas is purged from the reaction 
chamber 12 through an exhaust tube, generally designated by 50 in FIG. 3, 
extending from the exhaust port 18 at the bottom of the bell jar 14. The 
exhaust tube 50 comprises an exhaust cup 52, flexible tubing 54 connected 
to the cup and conventional facility piping 56 (FIG. 1) connected to the 
flexible tubing for venting reactant gases from the facility. As 
illustrated in FIG. 3, the exhaust cup 52 includes a tubular inner shell 
58 for transporting the reactant gases and a watertight cooling jacket 60 
surrounding the shell. The jacket 60 and shell 58 define an annular 
passage 62 extending along the exhaust cup 52 for circulating cooling 
water around the cup. The inner shell 58 has a gas inlet 64 at its 
upstream end and a gas outlet 66 at its downstream end. A first flange 68 
is provided at the inlet 64 for sealably connecting the exhaust cup 52 to 
the exhaust port 18 of the bell jar 14. A second flange 70 at the outlet 
66 of the shell 58 connects the exhaust cup 52 to the flexible tubing 54. 
A similar flange 72 is provided on the flexible tubing 54 for connecting 
the cup 52 and tubing with screw fasteners 74. Although screw fasteners 74 
are used to connect the exhaust cup 52 to the flexible tubing 54 in the 
preferred embodiment, other connection means such as a strap clamp (not 
shown) are also envisioned as being within the scope of the present 
invention. 
As shown in FIG. 3, the jacket 60 abuts the first flange 68 which includes 
an annular recess 76 extending upward into the flange from the annular 
cooling passage 62. The recess 76 circulates water through the flange for 
cooling. Cooling the flange 68 increases the life of the exhaust cup 52 in 
the region of the flange which was susceptible to cracking in prior art 
designs. Two O-ring seal grooves 78a, 78b are formed in the upper face of 
the first flange 66 for holding O-rings 80a, 80b to seal the interface 
between bell jar 14 and exhaust cup 52 when the first flange is pressed 
upward against the exhaust port 18 of the bell jar. A vacuum may be drawn 
between the O-rings 80a, 80b through a vacuum passage (not shown) to 
further seal the first flange 68 against the exhaust port 18 of the bell 
jar 14. Cooling water circulating through the annular cooling passage 62 
in the first flange 68 also reduces the temperatures of the O-rings 80a, 
80b which prolongs their lives. As illustrated in FIG. 4, an inlet passage 
82 delivers cooling water to the annular passage 62 and an outlet passage 
84 at an opposite end of the annular passage permits water to exit from 
the annular passage to remove heat from the exhaust cup 52 during chemical 
vapor deposition. 
As illustrated in FIG. 3, a gas-operated actuator, generally designated 90, 
moves the exhaust tube 50 between an operating position in which the first 
flange 68 of the exhaust cup 52 sealingly engages the exhaust port 18 of 
the bell jar 14 and a maintenance position in which the first flange is 
separated from the exhaust port for servicing the exhaust tube and the 
bell jar. The actuator 90 comprises a cylinder body 92 and a piston 93 
connected to a piston rod 94 slidably received in the body so the rod 
moves between an extended position and a retracted position corresponding 
to the operating and maintenance positions of the exhaust cup, 
respectively. In addition, the actuator has a head end pressure port 96 
and a rod end pressure port 98 through which pressurized gas (e.g., 
nitrogen) is introduced for moving the piston rod 94 with respect to the 
cylinder body 92 between the extended and retracted positions, 
respectively. A cooling water inlet and outlet 100, 102, respectively, 
permit cooling water to be circulated through an internal cooling passage 
(not shown) in the cylinder body 98 to cool the actuator 90. To further 
reduce the temperature of the actuator 90, it is physically spaced from 
the bell jar 14. 
A mechanism, generally designated 110, operatively connects the exhaust 
tube 50 and the actuator 90 for transmitting motion from the actuator to 
the exhaust tube to move the tube between the operating and maintenance 
positions. The mechanism 110 includes a base 112 having two vertical 
parallel plates 114 (only one of which is shown) and a lever 116 
positioned between the plates. The lever 116 is pivotally connected to the 
plates 114 with a bolt 118. 
One end of the lever 116 is pivotally connected to the rod 96 of the 
actuator 90. The cylinder body 98 is pivotably attached to a bracket 120 
connected across the top of the plates 114 so the actuator 90 is free to 
pivot as the rod 96 moves in and out of the cylinder body. Because the 
actuator 90 is free to pivot with respect to both the base 112 and the 
lever 116, bending forces in the rod 96 are avoided. A heat shield 122 
attached to the bracket 118 is positioned between the bell jar 14 and the 
actuator 90 for reflecting heat away from the actuator and thereby 
preventing damage to the actuator. 
The end of the lever 116 opposite the actuator 90 is attached to a slider 
assembly, generally designated 130. The slider assembly 130 comprises a 
hollow guide 132 and a cylindrical follower 134 slidably received within 
the guide. The follower 134 slides up and down in the guide 132 as the 
piston rod 94 moves between its extended and retracted positions, 
respectively. The follower 134 has a circular hole 136 extending inward 
from one side. A ball 138 mounted on the end of the lever 116 attached to 
the slider assembly 130 is received in the hole 136 so the follower 134 
slides freely up and down in the guide 132 as the actuator 90 pivots the 
lever. A slot 140 formed in the side of the guide 132 provides clearance 
for permitting the lever 116 to travel up and down. A clevis 142 extending 
from the bottom of the exhaust cup 52 receives an eye 144 attached to the 
top of the follower 134. The clevis 142 and eye 144 are pivotally joined 
by a bolt 146. Together the mechanism 110 and the actuator 90 form an 
apparatus, generally designated 150 for raising and lowering the exhaust 
tube 50 in response to the actuator rod 94 moving between the extended and 
retracted positions. 
Under normal operating conditions, the head end pressure port 96 of the 
actuator 90 is pressurized to extend the rod 94. With the rod 94 extended, 
the lever 116 is pivoted to the position shown in FIG. 3 in which the 
first flange 68 of the exhaust cup 52 is pressed upward against exhaust 
port 18 of the bell jar 14 to seal the corresponding interface between the 
cup and port. Periodically, when deposits form in the exhaust tube 50 and 
bell jar 14, the rod end pressure port 98 of the actuator 90 is 
pressurized to retract the rod 94. As the rod retracts, the lever 116 
pivots (clockwise as shown in FIG. 3) to separate the exhaust cup 52 from 
the exhaust port 18 of the bell jar 14. Once separated, the bell jar 14 
and/or the exhaust tube 50 may be serviced. 
As will be apparent to those skilled in the art, when the actuator 90 
presses the cup upward against the bell jar 14, the bell jar rim 20 is 
pushed upward against the gas ring 30 which tensions the screw fasteners 
34 holding the ring against the platform P. Lowering the exhaust cup 52 
relieves the tension so that the fasteners may be unscrewed when the bell 
jar 14 is being replaced. 
As previously explained, prior apparatus 150' for raising and lowering the 
exhaust cup 52' are prone to failure due to the high temperature 
environment in which they are used. In particular, the actuators 90' fail 
because seals (not shown) inside the actuators fail when exposed to heat 
emitted by the bell jar 14 during chemical vapor deposition. As explained 
above, the apparatus of the present invention overcomes this problem by 
increasing the distance between the bell jar 14 and the actuator 90, by 
shielding the actuator with a heat shield 122, and by circulating cooling 
water through the actuator. Further, the upper flanges 68' of prior 
exhaust cups 52' and the seals between the flanges and the bell jars 14 
fail due to the high temperature environment. As explained above, the 
exhaust tube 50, and more particularly, the exhaust cup 52 of the present 
invention are water cooled to prolong the life of the exhaust tube and 
seals 80a, 80b. 
In view of the above, it will be seen that the several objects of the 
invention are achieved and other advantageous results attained. 
As various changes could be made in the above constructions without 
departing from the scope of the invention, it is intended that all matter 
contained in the above description or shown in the accompanying drawings 
shall be interpreted as illustrative and not in a limiting sense.