Substrate rotating apparatus

Details Substrate rotating apparatus Substrate rotating apparatus

2000-07-17

2002-04-16

Mullins, Burton S. (Department: 2834)

Electrical generator or motor structure

Dynamoelectric

Rotary

C118S730000, C118S715000

Reexamination Certificate

active

06373159

ABSTRACT:

BACKGROUND OF THE INVENTION
The present invention relates to a substrate rotating apparatus for rotating a substrate to be processed, e.g. a semiconductor substrate, in a processing chamber. More particularly, the present invention relates to a substrate rotating apparatus for rotating a substrate in a processing chamber of a system in which a substrate is processed in a special atmosphere, e.g. in a CVD system for forming a thin film on a substrate, an etcher system for thinly removing the surface of a substrate, or a rapid thermal annealing (RTA) system.
In a system wherein a substrate is processed in a special atmosphere, e.g. in a cvb system or an etcher system, as shown in
FIG. 1
, a substrate
101
to be processed is mounted on a substrate holder or susceptor
102
and rotated in a processing chamber
103
by rotating the substrate holder or susceptor
102
. This kind of system, however, involves some problems, e.g. generation of dust or release of gas from a rotating mechanism for rotating the substrate holder or susceptor
102
, and a problem in terms of the lifetime of bearings. In view of these problems, there has been proposed a system in which magnetic bearings (radial bearings
105
and
106
and an axial bearing
107
) are used as bearings for rotatably supporting a rotor
104
.
In the above-described system wherein a substrate is processed in a special atmosphere, e.g. in a CVD system or an etcher system for thinly removing the surface of a substrate, a corrosive gas is often used in the processing chamber
103
. Therefore, the gas contact portion of a stator-side constituent member of each magnetic bearing is covered with a cylindrical pressure resistive partition (can). However, as the diameter of the substrate
101
increases, the diameter of the rotor
104
of the rotating mechanism also increases. Consequently, it is necessary to increase the strength (rigidity) of the pressure resistive partition.
For example, when an external pressure of 1 kgf·cm
2
is applied to a stainless steel cylindrical partition having an inner diameter of 400 to 500 mm, the wall thickness to withstand a buckling stress of 1 kgf·cm
2
is about 3 to 5 mm. When the wall thickness is about 0.3 mm, i.e. about one tenth of the above-mentioned value, buckling stress is reached when the pressure difference is 1 Torr. Accordingly, as the diameter of the rotor
104
increases, the wall thickness of the partition also needs to be increased. Increasing the wall thickness of the partition causes an increase in the gaps between stator-side electromagnets
105
a
,
106
a
,
107
a
and
107
b
and rotor-side targets of the radial magnetic bearings
105
and
106
and the axial magnetic bearing
107
, resulting in a reduction in control magnetic force. To obtain satisfactorily large control magnetic force, therefore, it is necessary to increase the number of windings of each electromagnet or to intensify the exciting current. This causes the magnetic bearings to become undesirably large in size. In FIG.
1
: reference numeral
108
denotes a motor stator for applying rotational force to the rotor
104
;
109
denotes a quartz window;
110
denotes a lamp heater unit for heating the inside of the processing chamber
103
; and
111
and
112
denote load-unload gates for loading and unloading the substrate
101
into and out of the chamber
103
.
Moreover, as the diameter of the rotor
104
increases, the diameters of the electromagnets
107
a
and
107
b
of the axial magnetic bearing
107
also increase. Accordingly, unstable torque (unbalanced torque) produced by the electromagnets
107
a
and
107
b
becomes so large that it cannot be ignored. If two radial magnetic bearings
105
and
106
are provided axially spaced (for 4 axes, two for each bearing) for the purpose of compensating for the unbalanced torque, the axial length increases, and hence the space efficiency decreases. Regarding the rotor characteristics, the design is dangerous because the inertia moment ratio of the rotor is close to 1.
SUMMARY OF THE INVENTION
In view of the above-described circumstances, an object of the present invention is to provide a substrate rotating apparatus which is capable of avoiding an increase in size of the diameter of the electromagnet of the axial magnetic bearing and capable of reducing unstable force such as unstable torque produced by the electromagnets, even if the diameter of the rotor is increased.
Another object of the present invention is to provide a substrate rotating apparatus which is capable of avoiding an increase in magnetic reluctance between the rotor-side target and the stator-side magnet yoke even if the partition provided therebetween is formed from thick-walled material and whereby a large control magnetic force can be obtained without enlarging the size of the magnetic bearings or without increasing the number of windings thereof.
To attain the above-described object, the present invention provides a substrate rotating apparatus including a rotor for rotating a substrate mounted thereon. The rotor has a horizontal disk provided thereon and is supported by magnetic bearings. The substrate rotating apparatus further includes a motor for applying rotational force to the rotor to rotate the substrate in a processing chamber. The magnetic bearings include an axial magnetic bearing and a radial magnetic bearing. The axial magnetic bearing is divided into three or more magnetic bearings, which are positioned so that imaginary lines connecting points where the divided axial magnetic bearings are disposed form an approximately regular triangle or polygon. Electromagnets constituting the axial magnetic bearings are disposed substantially above and below the horizontal disk of the rotor.
Because the axial magnetic bearing is divided into three or more magnetic bearings and these magnetic bearings are positioned so that imaginary lines connecting points where the divided axial magnetic bearings are disposed form an approximately regular triangle or polygon, even if the diameter of the rotor increases, the diameter of the electromagnet of each of the axial magnetic bearings will not increase. In addition, because position control in the axial direction is effected at the position of each axial magnetic bearing, motion about the radial axes is also stabilized. Accordingly, any unstable force such as unstable torque (unbalanced torque) produced by the electromagnets of the conventional axial magnetic bearing is minimized.
Preferably, the rotor is placed in a space communicating with the processing chamber, and stator-side constituent members of the magnetic bearings and a stator-side constituent member of the motor are placed in a space defined outside the space communicating with the processing chamber by a partition provided between the rotor and the stator-side constituent members. Further, a material electromagnetically equivalent to yokes of electromagnets as stator-side constituent members of the magnetic bearings is fitted in or inserted in portions of the partition where the yokes are located, and the partition constitutes a stator housing as a whole.
Instead, the ends of yokes of electromagnets as stator-side constituent members of the magnetic bearings may pierce through the partition so as to face the rotor directly.
If a material electromagnetically equivalent to the yokes of electromagnets as stator-side constituent members of the magnetic bearings is fitted in portions of the partition where the yokes are located, or the ends of yokes of electromagnets as stator-side constituent members of the magnetic bearings pierce through the partition so as to face the rotor directly, there is no increase in magnetic reluctance between the rotor-side target and the stator-side magnet yoke even if the partition, which constitutes the stator housing as a whole, is formed by using a thick-walled material. Accordingly, large control magnetic force can be obtained.
In the above-described substrate rotating apparatus, translational motion in two radial axes (X- and Y-directions) is preferably p

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