JP4015818B2 - Semiconductor manufacturing equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a semiconductor manufacturing apparatus that manufactures a semiconductor device by performing required processes such as generation of a thin film, diffusion of impurities, and etching on a semiconductor substrate such as a silicon wafer.
[0002]
[Prior art]
Semiconductor manufacturing equipment for processing that requires high cleanliness has an airtight chamber for preventing air from entering the reaction chamber below the reaction chamber. The airtight chamber is in a vacuum state or inactive. The substrate is loaded and withdrawn from the reaction chamber as a gas atmosphere.
[0003]
A conventional semiconductor manufacturing apparatus having an airtight chamber will be described with reference to FIG.
[0004]
The reaction furnace 1 includes a reaction tube 2 and a heater unit 3 surrounding the reaction tube 2, and an airtight chamber 4 is connected to the lower portion of the reaction tube 2 in an airtight manner.
[0005]
A boat elevator 5 is provided inside the hermetic chamber 4. The boat elevator 5 includes a guide shaft 6 and a ball screw 7 that extend in the vertical direction. The guide shaft 6 and the ball screw 7 are supported by a lower substrate 8 and an upper substrate 9, and the upper end of the ball screw 7 is the airtight chamber. 4 is airtightly penetrated through the ceiling of 4 and a lifting motor 11 is connected to the protruding end of the ball screw 7. An elevating seat 13 is provided on an elevating base 12 that is slidably fitted to the guide shaft 6 and screwed to the ball screw 7, and a boat rotating device 14 is attached to the elevating seat 13.
[0006]
The boat rotating device 14 rotatably supports a boat pedestal 15, and a boat 16 is placed on the boat pedestal 15. The boat 16 holds substrates to be processed 17 such as wafers in a horizontal posture in multiple stages, and the substrates 17 to be processed are processed in the reaction tube 2 while being held by the boat 16. The reaction tube 2 and the hermetic chamber 4 communicate with each other via a furnace port 18, and the furnace port 18 can be hermetically closed by the elevator seat 13 or a furnace port lid (not shown).
[0007]
A substrate 17 to be processed is transferred to the boat 16 by a substrate transfer machine (not shown) from a substrate transfer port 19 provided on a side surface of the hermetic chamber 4 when the boat 16 is lowered. The substrate transfer port 19 is hermetically closed by the gate valve 21.
[0008]
When processing a substrate, the inside of the hermetic chamber 4 is set to a vacuum or an inert gas atmosphere, a furnace lid (not shown) is opened, and the lift motor 11 is driven so that the boat elevator 5 causes the boat 16 to Charged into the reaction tube 2. That is, the ball screw 7 is rotated, the boat 16 holding the substrate 17 to be processed is lifted via the lifting platform 12, the lifting seat 13, and the boat support 15, and the boat 16 is moved into the reaction tube 2. It is inserted.
[0009]
When the boat 16 is completely charged into the reaction tube 2, the furnace port 18 is airtightly closed by the lift seat 13.
[0010]
The inside of the reaction tube 2 is heated by the heater unit 3 and a reaction gas is introduced to perform a required process on the substrate 17 to be processed. While the processing is being performed, the boat 16 is rotated by the boat rotating device 14 via the boat cradle 15. The processing state in the surface of the substrate to be processed 17 is made uniform by the rotation of the boat 16.
[0011]
When the processing is completed, the boat 16 is lowered by the boat elevator 5, and when the furnace port 18 is closed by a furnace port lid (not shown), the inside of the hermetic chamber 4 is purged with gas and the gate is formed when the required atmosphere is obtained. The valve 21 opens the substrate transport port 19 and the processed substrate is unloaded by a substrate transfer machine (not shown). The unprocessed substrate is transferred again to the boat 16 and the processing is continued.
[0012]
[Problems to be solved by the invention]
The hermetic chamber 4 is provided for the purpose of preventing the entry of air into the reaction tube 2 (reaction chamber), that is, the entry of harmful substances into the reaction chamber during substrate processing.
[0013]
As described above, the boat 16 is loaded into and withdrawn from the reaction tube 2 by the boat elevator 5, and the boat 16 is rotated in the reaction tube 2 by the boat rotating device 14 during processing.
[0014]
In the conventional semiconductor manufacturing apparatus described above, the boat elevator 5 and the boat rotating device 14 are provided in the airtight chamber 4, respectively, and the guide shaft 6 and the ball screw 7 are exposed in the airtight chamber 4. Such guide shaft 6 and ball screw 7 are coated with a lubricant such as grease for lubrication. The boat rotation device 14 has a motor such as a motor, and a cable for supplying power to the motor is wired in the hermetic chamber 4.
[0015]
Under high cleanliness, the vapor of the lubricant and the vapor generated from the cable covering material also become harmful substances. Further, when the ball screw 7 rotates and the elevator 12 moves up and down, organic pollutants are removed. Scatter. When such organic contaminants adhere to the substrate 17 to be processed, it causes film growth failure.
[0016]
Further, when the heated boat 16 and the boat 16 having the residual heat after the processing are lowered (evacuated) into the hermetic chamber 4, the temperature inside the hermetic chamber 4 rises, and the organic pollutants evaporate. There was a problem that the amount of the contaminants increased and the possibility of contaminants adhering to the substrate was further increased.
[0017]
For this reason, after the treatment, the reaction tube 2 was cooled until the temperature in the reaction tube 2 became 100 ° C. or less, and after the temperature of the boat 16 was sufficiently lowered, it was sometimes drawn into the hermetic chamber 4. However, in this case, there is a problem that the cooling time is long until the temperature inside the reaction tube 2 and the temperature of the boat 16 are lowered, and the throughput is lowered.
[0018]
In view of such circumstances, the present invention maintains a highly clean atmosphere even in a high temperature state in a hermetic chamber, thereby improving the reliability of processing quality and improving productivity.
[0019]
[Means for Solving the Problems]
The present invention relates to a semiconductor manufacturing apparatus including a reaction chamber, an airtight chamber connected to the reaction chamber, a boat holding a substrate, and a boat elevator that raises and lowers the boat between the reaction chamber and the airtight chamber. The boat elevator is provided outside the hermetic chamber, a lifting shaft supported by the boat elevator is allowed to penetrate into the hermetic chamber, a penetration portion is hermetically sealed with a bellows, and a lifting seat is provided via the lifting shaft. A boat that is supported so as to be able to move up and down, and that is rotatably provided with a boat cradle on which the boat is placed above the lift seat, and that forms a space isolated from the hermetic chamber at the lower side and rotates the boat cradle The present invention relates to a semiconductor manufacturing apparatus provided with a rotating means so as to be accommodated in the space.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0021]
In FIG. 1 and FIG. 2, the same components as those shown in FIG. FIG. 1 shows a state in which the boat is retracted, and FIG. 2 shows a state in which the boat is loaded.
[0022]
A lower substrate 8 is provided on the outer surface of the hermetic chamber 4, and an upper substrate 9 is provided on the upper end of a guide shaft 6 erected on the lower substrate 8. The ball screw 7 extends between the lower substrate 8 and the upper substrate 9. Is rotatably provided. The ball screw 7 is rotated by a lifting motor 11 provided on the upper substrate 9. An elevating table 12 is fitted to the guide shaft 6 so as to be movable up and down, and the elevating table 12 is screwed into the ball screw 7.
[0023]
When a plurality of semiconductor manufacturing apparatuses are arranged, they are arranged on the side surface adjacent to the side surface having the substrate transfer port 19, so that the facing wall of the substrate transfer port 19 is made open for maintenance. In this case, the lower substrate 8 is provided on the side surface adjacent to the side surface having the substrate transfer port 19.
[0024]
A hollow elevating shaft 24 is suspended from the elevating platform 12, and the support portions of the elevating platform 12 and the elevating shaft 24 are airtight. The elevating shaft 24 penetrates the top plate 4 a of the hermetic chamber 4 and reaches near the bottom surface of the hermetic chamber 4. The penetrating portion of the elevating shaft 24 has a sufficient margin so that it does not come into contact with the elevating movement of the elevating shaft 24, and the protruding portion of the elevating shaft 24 is between the airtight chamber 4 and the elevating platform 12. The bellows 25 is provided in an airtight manner, and the bellows 25 has a sufficient expansion / contraction amount that can correspond to the amount of elevation of the elevator platform 12. The bellows 25 are not expanded and contracted.
[0025]
A lifting substrate 26 is horizontally fixed to the lower end of the lifting shaft 24. A drive unit cover 27 is attached to the lower surface of the elevating board 26 to form a drive unit storage case 28. A seal member 29 such as an O-ring is provided at the joint between the elevating substrate 26 and the drive unit cover 27, and the inside of the drive unit storage case 28 has an airtight structure with respect to the airtight chamber 4.
[0026]
The lift board 26 is provided with a boat rotating means.
[0027]
A boat rotation motor 31 is provided on the lower surface of the elevating substrate 26, an output shaft 32 of the boat rotation motor 31 is concentric with the reaction tube 2, and a boat cradle 15 is provided at the upper end. The bearing portion 33 of the output shaft 32 is hermetically sealed by a magnetic fluid seal or the like, and a bearing cooler 34 is fitted on the bearing portion 33.
[0028]
An elevating seat 35 is airtightly attached to the upper surface of the elevating substrate 26 via a sealing material 36, the elevating seat 35 is concentric with the output shaft 32, and the output shaft 32 passes through the elevating seat 35. ing.
[0029]
A power supply cable 37 is led from the upper end of the elevating shaft 24 through the hollow portion of the elevating shaft 24 and is connected to the boat rotation motor 31. Further, cooling passages 34a and 35a are formed in the bearing cooler 34 and the lift seat 35, respectively, and cooling water pipes 38 and 39 are connected to the cooling passages 34a and 35a. The cooling water pipes 38 and 39, particularly the cooling water pipe 39, are made of a material such as metal that does not cause contamination of the substrate 17 to be treated.
[0030]
The cooling water pipe 38 is guided through the hollow portion of the elevating shaft 24 and connected to the bearing cooler 34, and the cooling water pipe 39 is guided through the hollow portion of the elevating shaft 24 and further the elevating substrate 26. And is connected to the elevating seat 35. The portion of the cooling water pipe 39 that penetrates the elevating board 26 is hermetically sealed by a pipe joint 41.
[0031]
Hereinafter, the operation will be described. Note that the processing of the substrate 17 to be processed and the transfer of the substrate to the boat 16 are the same as in the conventional example, and thus description thereof is omitted.
[0032]
The boat 16 is charged into the reactor 1 from the retracted state shown in FIG.
[0033]
Cooling water is circulated through the cooling flow paths 34 a and 35 a via the cooling water pipes 38 and 39, the bearing portion 33 is cooled via the bearing cooler 34, and the elevating seat 35 is cooled. The elevating motor 11 is driven and the ball screw 7 is rotated to raise the drive unit storage case 28 via the elevating platform 12 and the elevating shaft 24.
[0034]
The elevator seat 35 closes the furnace port 18 near the top dead center of the elevator platform 12 (see FIG. 2). A seal ring 42 is provided on the lower surface of the furnace port 18, and the furnace port 18 is hermetically closed. With the furnace port 18 closed, the seal ring 42 is cooled by cooling water through the lift seat 35. When the processing of the substrate to be processed 17 is started, the boat rotation motor 31 is driven and the boat 16 is rotated.
[0035]
When the processing is completed, the rotation of the boat 16 is stopped, the lifting motor 11 is driven, and the boat 16 is lowered.
[0036]
In the present embodiment, the boat rotation motor 31 is stored in the drive unit storage case 28 and is isolated from the inside of the airtight chamber 4. The power supply cable 37 is housed in the drive unit cover 27 and the lifting shaft 24 and is isolated from the inside of the hermetic chamber 4. Further, the guide shaft 6, the ball screw 7, and other driving parts are provided outside the airtight chamber 4. Therefore, the sliding part and the rotating part of the drive mechanism are not exposed in the hermetic chamber 4, and the power supply cable 37 is not exposed as well.
[0037]
For this reason, the vapor of the lubricant used in the drive unit and the vapor generated from the cable covering material do not enter the hermetic chamber 4, and the hermetic chamber 4 is completely cleaned from organic pollutants. Hold. Even when the reaction tube 2 and the treated boat 16 are lowered in a high temperature state and the temperature in the hermetic chamber 4 is increased, the cleanliness in the hermetic chamber 4 is similarly reduced by organic contaminants. There is no damage.
[0038]
Therefore, the time for waiting for the reaction tube 2 and the boat 16 to cool is saved, and the throughput is improved.
[0039]
In the above embodiment, a cooling gas introduction pipe (not shown) is provided so that cooling gas such as air and inert gas is introduced into the elevating shaft 24 and the drive unit housing case 28, and The elevating shaft 24 is evacuated from the upper end portion so that a cooling gas flow is formed inside the elevating shaft 24 and the drive unit storage case 28 to cool the elevating shaft 24 and the drive unit storage case 28, particularly the elevating shaft 24. May be.
[0040]
Furthermore, as means for cooling the elevating shaft 24, the elevating shaft 24 has a double pipe structure, a cooling channel is formed on the inner surface of the elevating shaft 24, and cooling water or other cooling liquid is circulated. The elevating shaft 24 may be cooled. By cooling the elevating shaft 24, thermal expansion of the elevating shaft 24 is suppressed, the positional accuracy of the boat 16 in the vertical direction is improved, and alignment during transfer of the substrate 17 to be processed is facilitated.
[0041]
Next, another embodiment will be described with reference to FIG.
[0042]
In FIG. 3, the same components as those shown in FIG.
[0043]
An upper substrate 9 is fixed to the lower surface of the hermetic chamber 4, a lower substrate 8 is disposed opposite to the upper substrate 9, a guide shaft 6 is provided between the lower substrate 8 and the upper substrate 9, and a ball screw 7. Is rotatably provided. A lift 12 is slidably provided on the guide shaft 6, and the ball screw 7 is screwed to the lift 12. The lifting platform 12 extends in the horizontal direction, and a lifting shaft 45 is erected on the lifting platform 12.
[0044]
A shaft hole 46 is formed in the bottom plate of the hermetic chamber 4, and the elevating shaft 45 extends through the shaft hole 46 into the hermetic chamber 4. A lift seat 35 is fixed to the upper end of the lift shaft 45, and a boat rotation motor 31 is provided on the lower surface of the lift seat 35. The rotating part of the boat rotation motor 31 is magnetically sealed as shown in FIG. 1 and is cooled by a bearing cooler (not shown). As shown in FIG. 1, a cooling flow path is also formed in the elevating seat 35, and cooling water is circulated through the cooling water path via cooling water pipes 38 and 39.
[0045]
A bellows 47 is provided between the elevating seat 35 and the bottom surface of the hermetic chamber 4 so as to cover the elevating shaft 45, and a penetrating portion of the elevating shaft 45 is hermetically sealed. Further, the bellows 47 has an amount of expansion and contraction sufficient to accommodate the raising and lowering of the lifting seat 35.
[0046]
A power supply cable 37 is connected to the boat rotation motor 31, and cooling water is supplied to a bearing cooler (not shown) via a cooling water pipe 38. A boat support 15 is provided at the upper end of the output shaft 32 of the boat rotation motor 31, and a boat 16 is placed on the boat support 15.
[0047]
The operation will be described below.
[0048]
The ball screw 7 is rotated by the drive of the lift motor 11, the lift seat 35 is lifted via the lift platform 12 and the lift shaft 45, and the boat 16 is inserted into the reaction tube 2. In the fully charged state, the lift 35 closes the furnace port 18 in an airtight manner, and a seal member (not shown) is cooled by cooling water supplied from the cooling water pipe 38.
[0049]
Further, after the processing, the boat 16 is lowered by driving the lifting motor 11.
[0050]
In the other embodiment, the boat rotation motor 31 and the boat elevator 5 drive mechanism such as the guide shaft 6 and the ball screw 7 are completely separated from the airtight chamber 4 by the bellows 47, and the air It is provided outside the closed room 4.
[0051]
Therefore, the sliding part and the rotating part of the drive mechanism are not exposed in the hermetic chamber 4, and the power supply cable 37 is not exposed as well.
[0052]
For this reason, the vapor of the lubricant used in the drive unit and the vapor generated from the cable covering material do not enter the hermetic chamber 4, and the hermetic chamber 4 is completely cleaned from organic pollutants. Hold. Even when the reaction tube 2 and the treated boat 16 are lowered in a high temperature state and the temperature in the hermetic chamber 4 is increased, the cleanliness in the hermetic chamber 4 is similarly reduced by organic contaminants. There is no damage. Further, when the boat 16 is lowered, the elevating shaft 45 is positioned below the hermetic chamber 4 and is not affected by the heat in the hermetic chamber 4, so that it is not necessary to take measures against thermal expansion.
[0053]
Accordingly, the substrate processing quality is improved and the time for waiting for the reaction tube 2 and the boat 16 to cool is saved, thereby improving the throughput.
[0054]
【The invention's effect】
As described above, according to the present invention, the reaction chamber, the hermetic chamber connected to the reaction chamber, the boat holding the substrate, and the boat elevator for raising and lowering the boat between the reaction chamber and the hermetic chamber are provided. In the semiconductor manufacturing apparatus, the boat elevator is provided outside the hermetic chamber, a lifting shaft supported by the boat elevator is allowed to loosen into the hermetic chamber, a through portion is hermetically sealed with a bellows, and the lifting shaft The boat is supported so as to be able to move up and down, and a boat cradle on which the boat is placed is rotatably provided above the lift seat, and a space isolated from the airtight chamber is formed below the boat. Since the boat rotation means for rotating the cradle is provided so as to be accommodated in the space, the drive part of the boat elevator and the drive part of the boat rotation means are completely isolated from the inside of the airtight chamber. Infiltration of dyeing substances can be completely prevented, a high-quality film can be produced in a highly clean atmosphere, and even if a boat in a high temperature state is retracted in an airtight room, the invasion of contaminants is not promoted by heat, The boat can be cooled in an airtight room with a low temperature and a high cooling effect, and the cooling time can be shortened and productivity can be improved.
[Brief description of the drawings]
FIG. 1 is a schematic cross-sectional view showing an embodiment of the present invention.
FIG. 2 is a schematic sectional view showing the operation of the embodiment of the present invention.
FIG. 3 is a schematic sectional view showing another embodiment of the present invention.
FIG. 4 is a schematic sectional view of a conventional example.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Reaction furnace 2 Reaction tube 4 Airtight chamber 5 Boat elevator 12 Lifting stand 15 Boat receiving stand 16 Boat 24 Lifting shaft 25 Bellows 28 Drive part storage case 31 Boat rotation motor 35 Lifting seat 45 Lifting shaft 47 Bellows

Claims (1)

In a semiconductor manufacturing apparatus comprising: a reaction chamber; an airtight chamber connected to the reaction chamber; a boat holding a substrate; and a boat elevator that raises and lowers the boat between the reaction chamber and the airtight chamber. An elevator is provided outside the airtight chamber, the lifting shaft supported by the boat elevator is allowed to pass through the airtight chamber, the penetration portion is hermetically sealed with a bellows, and the lifting seat is supported by the lifting shaft so that it can be lifted and lowered. A boat pedestal on which the boat is placed is rotatably provided on the upper and lower seats, a space separated from the airtight chamber is formed on the lower side, and a boat rotating means for rotating the boat pedestal includes A semiconductor manufacturing apparatus provided to be stored in a space.

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