JP3565577B2 - Processing equipment - Google Patents

Description

[0001]
[Industrial applications]
The present invention relates to a processing device.
[0002]
[Prior art]
2. Description of the Related Art In general, in a semiconductor device manufacturing process, there is a process of performing various processes such as oxidation, diffusion, and CVD on a semiconductor wafer to be processed. This process improves throughput, eliminates dust and saves space. From the viewpoint of achieving this, various processing apparatuses have been proposed (see JP-A-4-133422, JP-A-4-148717, JP-A-4-148140, and the like).
[0003]
For example, a processing apparatus described in Japanese Patent Application Laid-Open No. 4-133422 discloses a box-shaped vertical heat treatment furnace capable of heat-treating a large number of semiconductor wafers at a time via a wafer boat as a workpiece holder. A carrier loading / unloading port for loading / unloading a carrier which accommodates a plurality of semiconductor wafers vertically and is accommodated in a front upper portion of the processing chamber is provided in a front portion of the processing chamber. In this case, since it is necessary to transfer a large number of semiconductor wafers in a horizontal state to a wafer boat that is carried into and out of the heat treatment furnace, the semiconductor wafer is moved in the vicinity of the carry-in / out port so that the semiconductor wafers become vertical to horizontal. An attitude conversion mechanism for changing the attitude is provided, and a carrier storage unit is provided above the attitude conversion mechanism for storing and storing a required number of carriers whose attitude has been changed. Then, the carriers are sequentially transferred from the carrier storage unit to the heat treatment furnace side by the transfer mechanism, and the semiconductor wafers in the carriers are sequentially transferred to the wafer boat by the transfer mechanism.
[0004]
In addition, a first air purifying section that horizontally blows clean air introduced from above and outside into the carrier storage section into the processing chamber, and the clean air blown out from the first air purifying section is drawn into the processing chamber. A second air purifier that blows downward along the carrier carry-in / out port, and a lower side clean air that is blown down from the second air purifier and reaches the lower side through a bottom duct to form a side wall on the heat treatment furnace side; A third air cleaning section that blows out horizontally toward the other side wall portion and an exhaust duct that exhausts clean air that has reached the other side wall portion to the outside outside the processing chamber are provided. As a result, the atmosphere in the processing chamber is cleaned to reduce dust, the adhesion of dust (particles) to the semiconductor wafer is suppressed, and the yield of semiconductor elements that tend to be ultrafine is improved.
[0005]
[Problems to be solved by the invention]
However, in the processing apparatus, since clean air is passed through the air cleaning section many times in the processing chamber, contamination of the semiconductor wafer by dust can be sufficiently prevented. Contamination of organic compounds, such as boron compounds, generated from impurities by impurity gases tends to increase, albeit in a small amount, and it is necessary to take countermeasures.
[0006]
In addition, since the clean air is configured to circulate continuously and continuously throughout the processing chamber, the atmosphere in the processing chamber accommodates a carrier processing space for carrying in / out, storage, and transport of the carrier, and a heat treatment furnace. However, it is difficult to isolate the semiconductor wafer from a wafer processing space (processing object processing space) in which a semiconductor wafer is transferred between a carrier and a wafer boat.
[0007]
Therefore, an object of the present invention is to reduce the contamination of a processing object by an impurity gas and to easily isolate the atmosphere in the processing chamber between the carrier processing space and the processing space. It is to provide a device.
[0008]
[Means for Solving the Problems]
In order to achieve the above object, the processing apparatus according to claim 1 includes a carrier processing space for carrying in, out, storing, and transporting a carrier accommodating a plurality of workpieces in the processing chamber, and a heat treatment furnace. Then, the object holder to be transferred into and out of the heat treatment furnace and the object processing space for transferring the object between the carrier and the like are separated. Independently provided clean air circulation system for introducing, circulating and exhausting clean air to and from the processing spaceA first air cleaning unit in which the clean air circulation system of the carrier processing space section horizontally blows clean air introduced from outside the upper part of the processing chamber to a carrier storage section provided above the carrier processing space section; A second air purifier that sucks clean air blown out from the first air purifier and blows the air downward along a carrier carry-in / out port provided in a front part of the processing chamber; and a second air purifier. An exhaust duct that exhausts clean air that has been blown out from the air and has reached the bottom to the outside.It is characterized by having.
[0010]
ContractRequest2The processing equipment describedA carrier processing space for carrying in / out, storage / transportation, etc. of a carrier containing a plurality of objects to be processed in the processing chamber; Process space for transferring and transferring the work between the tool and the carrier, and introducing, circulating and exhausting clean air into the carrier processing space and the work space. Independently provided clean air circulation systemA third cleaning air circulation system of the processing target object processing space which horizontally blows clean air introduced from outside the rear of the processing chamber from one side wall to the other side wall of the processing target processing space; An air purifier is provided, and an exhauster for exhausting the clean air blown out from the third air purifier and reaching the other side wall to the outside is provided.
[0011]
[Action]
According to the processing apparatus of the first aspect, the processing chamber is divided into the carrier processing space and the object processing space, and the clean air circulation systems are independently provided in these processing spaces. Compared to conventional processing equipment that passes through the air purifying section many times and continuously circulates through the entire processing chamber, the number of times that clean air passes through the air purifying section is reduced and generated from the dust filter in the air purifying section. It is possible to reduce the contamination of the object to be treated by the impurity gas with a simple configuration without requiring special preventive measures.,Further, since the atmosphere in the processing chamber can be easily separated from the carrier processing space and the processing object processing space, a desired processing such as setting only the processing object processing space to an inert gas atmosphere can be performed. Method can be easily applied.In particular, the clean air circulation system in the carrier processing space section horizontally blows clean air introduced from outside the upper part of the processing chamber to the carrier storage section above the carrier processing space section via the first air cleaning section. The blown-down clean air is blown downward along a carrier carry-in / out port at the front of the processing chamber through the second air cleaning unit, and the blown-down clean air is discharged through an exhaust duct unit. Since the air is exhausted to the upper outside, the atmosphere in the carrier processing space can be independently and efficiently cleaned.
[0013]
Claim2According to the processing device described,The processing chamber is divided into a carrier processing space and an object processing space, and clean air circulation systems are independently provided in these processing spaces, so that clean air is passed through the air cleaning section many times for processing. Compared with the conventional processing equipment that continuously circulates the entire room, the number of times that clean air passes through the air purifying unit is reduced, and contamination of the object to be processed by impurity gas generated from the dust filter of the air purifying unit is special. It is possible to reduce the atmosphere with a simple configuration without requiring any preventive measures, and it is also possible to easily isolate the atmosphere in the processing chamber between the carrier processing space and the object processing space. It is possible to easily apply a desired processing method such as an inert gas atmosphere only in the processing target object processing space portion.The clean air circulating system of the processing object processing space portion clean air introduced from outside the rear of the processing chamber from one side wall portion of the processing object processing space portion to another side wall portion through a third air cleaning section. To clean the air in the processing space of the processing object independently and efficiently in order to exhaust the clean air that has been blown horizontally toward the other side wall part to the outside through the exhaust part. Becomes possible.
[0014]
【Example】
Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.
[0015]
In FIG. 1, which shows a side sectional view of the processing apparatus, reference numeral 1 denotes a processing chamber which forms a housing of the processing apparatus and which is formed in a box shape by, for example, an iron plate. A vertical heat treatment furnace 2 including a cylindrical reaction tube having a port, a heater disposed so as to cover the periphery thereof, a heat insulating material, and the like is provided.
[0016]
As shown in FIG. 5, a lid 3 for opening and closing the furnace port is provided in a space (loading area) below the heat treatment furnace 2 so as to be able to move up and down by a lifting mechanism 4. A wafer boat 5 made of, for example, quartz, which is a workpiece holder for holding a large number of, for example, about 150 semiconductor wafers W as horizontal bodies at predetermined intervals in a vertical direction, is placed via a heat retaining cylinder 6. Is placed. Wafer boat holding semiconductor wafer W5Are loaded and unloaded (loaded, unloaded) into and out of the heat treatment furnace 2 together with the heat retaining cylinder 6 as the lid 3 moves up and down.
[0017]
On the other hand, in the front part of the processing chamber 1, a carrier unloader provided with a slide door (not shown) made of a transparent material (not shown) for loading and unloading a carrier 7 which is a plastic container for accommodating a plurality of, for example, about 25 semiconductor wafers W vertically. An inlet 8 is provided, and a mounting table 9 on which the carrier 7 is mounted is provided near the carrier loading / unloading port 8 in the processing chamber 1, and the semiconductor wafer W in the carrier 7 is vertically moved through the mounting table 9. There is provided a posture changing mechanism 10 for changing the posture so as to be horizontal from the position. A known mechanism described in, for example, Japanese Unexamined Patent Application Publication No. 4-148717 can be applied to the attitude conversion mechanism 10. The mounting table 9 is formed on the periphery of the semiconductor wafer W. An alignment mechanism for aligning the semiconductor wafers W such that a notch such as an orientation flat faces in a predetermined direction, a wafer sensor for detecting the number of semiconductor wafers W, and the like may be provided. In addition, the mounting table 9 and the like are formed with a large number of ventilation holes (not shown) for passing an air flow of clean air flowing downward from above the mounting table 9.
[0018]
A shelf-shaped carrier storage unit 11 for accommodating a plurality of carriers 7 whose posture has been changed is provided in an upper region of the posture changing mechanism 10, and the carrier 7 is transferred to the heat treatment furnace 2 side. A transfer mechanism 12 for transferring the carrier 7 is provided between the carrier storage unit 11 and the transfer unit 12, and the transfer unit 12 and the wafer boat in the loading area are provided between the carrier storage unit 11 and the transfer unit 12. Transfer mechanisms 14 for transferring the semiconductor wafer W are provided between the transfer mechanism 5 and the transfer mechanism 5.
[0019]
The carrier storage unit 11 of this embodiment is provided before and after across a traveling space of a transport mechanism 13 that is provided so as to be able to travel in parallel with the mounting table 9 described above. Each carrier 7 is configured to be able to store and store a total of four carriers 7 in the left and right and up and down directions in the front carrier storage unit 11B. Further, the transfer unit 12 of the present embodiment is arranged below the rear carrier storage unit 11A, and is configured so that two carriers 7 can be placed vertically.
[0020]
The transport mechanism 13 has a traveling section 16 having a column 15, an elevating frame 17 provided on the column 15 so as to be able to move up and down, and is provided on the elevating frame 17 so as to be able to bend and extend in the horizontal direction to support a lower portion of the carrier 7. And a transfer arm 18. The transfer mechanism 13 transfers the carrier 7 between the mounting table 9 and the carrier storage unit 11, between the carrier storage unit 11 and the transfer unit 12, and between the mounting table 9 and the transfer unit 12. It is configured to be able to.
[0021]
The transfer mechanism 14 includes an elevating frame 19 provided to be able to move up and down, a rectangular turning frame 20 provided to be able to turn horizontally on the elevating frame 19, and A moving body 21 provided so as to be able to reciprocate along the longitudinal direction, and a flat plate provided at one end in the moving direction of the moving body 21 and supporting a plurality of, for example, about five semiconductor wafers W at appropriate intervals in the vertical direction. And a transfer arm 22. The transfer mechanism 14 sequentially takes out the unprocessed semiconductor wafers W from the carrier 7 of the transfer unit 12 and transfers them to the wafer boat 5, and also takes out the processed semiconductor wafers W from the wafer boat 5 sequentially. It is configured to be loaded into the carrier 7.
[0022]
As described above, the inside of the processing chamber 1 accommodates the carrier processing space portion 23 for carrying in, carrying out, storing, and carrying the carrier 7, the heat treatment furnace 2, and the wafer boat 5 that is carried into and carried out of the heat treatment furnace 2. It is divided into a wafer processing space portion (processed object processing space portion) 24 for transferring the semiconductor wafer W to and from the carrier 7. In the carrier processing space 23 and the wafer processing space 24, clean air circulation systems 25 and 26 for introducing, circulating and exhausting clean air are provided independently of each other as shown in FIGS. Have been.
[0023]
The clean air circulation system 25 of the carrier processing space 23 is provided with a first air cleaning unit 27 that horizontally blows clean air introduced from above and outside of the processing chamber 1 into the carrier storage unit 11 above the carrier processing space 23. A second air purifying unit 28 that sucks in the clean air blown out from the first air purifying unit 27 and blows the clean air downward along the carrier carry-in / out port 8 at the front of the processing chamber 1; An exhaust duct portion 29 is provided for exhausting the clean air blown downward from the portion 28 to the lower side to the upper outside. The first air purifying unit 27 includes a box-shaped casing 30 installed on the back of the rear carrier storage unit 11A. As shown in FIG. An intake port 31 is provided in the outside of the clean room, and a sponge-like or mesh-like pre-filter 32 having excellent air permeability is attached to the intake port 31.
[0024]
The front surface of the casing 30 is open to the carrier storage unit 11, and a first dust removing device such as a HEPA filter for removing dust contained in clean air introduced from a clean room into the open portion. A filter 33 is attached. Also, a plurality of air blowers, such as sirocco fans, for sucking clean air from the air inlet 31 into the casing 30 and blowing the clean air horizontally through the first dust filter 33 to the carrier storage unit 11 are provided. Is attached, whereby a horizontal air flow X of clean air is formed from the rear carrier storage section 11A to the front carrier storage section 11B, and is horizontally accommodated in the carrier 7 stored in the carrier storage section 11. The atmosphere between the semiconductor wafers W is kept clean.
[0025]
The second air cleaning section 28 is provided below the front carrier storage section 11B and above the carrier carry-in / out port 8. The second air purifying section 28 includes a casing 36 having an open lower portion and a flat intake duct portion 35 standing upright on the rear portion of the front carrier storage portion 11B at the upper portion. A number of punched air holes 37 are formed on the surface facing the carrier storage unit 11. A second dust removing filter 38 similar to the first dust removing filter 33 is attached to a lower opening portion of the casing 36, and clean air sucked from the intake hole 37 is supplied to the second inside of the casing 36. A blower 39 for blowing out downward through a dust filter 38 is attached. As a result, a vertical airflow Y of clean air is formed from the front carrier storage section 11B and directed downward along the carrier carry-in / out port 8, and is housed vertically in the carrier 7 mounted on the mounting table 9 of the attitude changing mechanism 10. The atmosphere between the semiconductor wafers W is kept clean.
[0026]
The exhaust duct 29 is provided below the transfer unit 12 downstream of the vertical airflow Y. The exhaust duct portion 29 is connected to a duct body 40 horizontally arranged so as to cross the bottom of the processing chamber 1, and is connected to one side of the duct body 40. It is mainly composed of a vertical duct 42 opened as an exhaust port 41, and a plurality of exhaust blowers 43 are attached to the front of the duct body 40.
[0027]
On the other hand, the clean air circulation system 26 of the wafer processing space 24 blows clean air introduced from outside the rear of the processing chamber 1 horizontally from one side wall of the wafer processing space 24 toward the other side wall. The air purifying section 44 includes a third air purifying section 44 and an exhaust section 45 for exhausting the clean air blown out from the third air purifying section 44 and reaching the other side wall to the rear outside. Specifically, an opening for maintenance and inspection and a door 46 for opening and closing the opening are provided at a rear portion of the processing chamber 1, and an intake 47 is formed below the door 46, and the third air The cleaning unit 44 is configured to introduce clean air from outside the rear of the processing chamber 1 through the air inlet 47. As shown in FIG. 5, the third air purifying section 44 includes a flat casing 48 attached to one side wall of the loading area, and a suction port 49 is formed at a lower front portion of the casing 48. The front surface of the casing 48 above the suction port 49 is open, and a third dust filter 50 similar to the first dust filter 33 is attached to the open portion.
[0028]
Further, a blower 51 for sucking clean air introduced from the suction port 47 and blowing it out horizontally to the loading area via the third dust filter 50 is mounted in the suction port 49. A horizontal airflow Z of clean air is formed from one side wall part facing the other area to the other side wall part, so that the atmosphere between the semiconductor wafers W horizontally transferred to the wafer boat 5 can be kept clean and from the heat treatment furnace 2. The wafer boat 5 carried out and the semiconductor wafer W after the heat treatment can be cooled. In the lower part of the rear wall of the processing chamber 1, near the other side wall part, the exhaust part 45 composed of, for example, an exhaust fan is provided, and the clean air reaching the other side wall part is exhausted to the rear outside of the processing chamber 1. It has become.
[0029]
Next, the operation of the embodiment will be described. First, the carrier 7 is mounted on the mounting table 9 of the attitude conversion mechanism 10 from the carrier loading / unloading port 8 of the processing apparatus by, for example, a transfer robot. The posture is changed so that the wafer W is changed from vertical to horizontal. Then, the carrier 7 is transported to the carrier storage unit 11 by the transport mechanism 13, and the above operation is repeated to store a desired number of carriers 7 in the carrier storage unit 11.
[0030]
Thereafter, the carriers 7 in the carrier storage unit 11 are sequentially transferred to the transfer unit 12 by the transfer mechanism 13, and the semiconductor wafers W in the carriers 7 are transferred by the transfer mechanism 14 to the wafer boat 5 which has been unloaded into the loading area. Put on. In this case, the empty carriers 7 are sequentially returned to the carrier storage unit 11 by the transport mechanism 13.
[0031]
When the transfer of the desired number of semiconductor wafers W is completed, the wafer boat 5 and the heat retaining cylinder 6 are carried into the heat treatment furnace 2 by the elevating mechanism 4 and the furnace port is closed by the lid 3 for a predetermined time, at a predetermined temperature, and at a predetermined temperature. A desired heat treatment is performed in a predetermined atmosphere, and when the heat treatment is completed, the wafer boat 5 is unloaded from the inside of the heat treatment furnace 2 to a loading area. After cooling, the processed semiconductor wafer W is sequentially transferred from the wafer boat 5 to the carrier 7 in the reverse order to the above, and the carrier 7 is transferred to the carrier storage unit 11 and stored therein. The carrier is carried out of the processing chamber 1 from the carrier carry-in / out port 8 via the mounting table 9 of the conversion mechanism 10.
[0032]
In the processing steps such as the transfer and transfer of the carrier 7 and the semiconductor wafer W, the carrier processing space 23 was first introduced from the upper outside of the processing chamber 1 via the pre-filter 32 by the first air cleaning unit 27. The clean air is blown out to the carrier storage unit 11 as a horizontal airflow X through the first dust filter 33, and then the clean air of the horizontal airflow X is sucked from the air inlet 37 of the air inlet duct 35 by the second air cleaner 28. Then, the air is blown downward as a vertical airflow Y via a second dust filter 38, and then the clean air of the vertical airflow Y is sucked into a duct main body 40 by an exhaust duct section 35, and the upper part of the processing chamber 1 is passed through a vertical duct 42. Exhaust to the outside. Accordingly, the atmosphere between the semiconductor wafers W horizontally accommodated in the carriers 7 stored in the front and rear carrier storage units 11A and 11B can be maintained clean by the horizontal air flow X of the clean air, and the cleanliness can be maintained. The atmosphere between the semiconductor wafers W vertically accommodated in the carrier 7 mounted on the mounting table 9 of the attitude conversion mechanism 10 can be kept clean by the vertical airflow Y of air.
[0033]
Further, in the wafer processing space 24, first, clean air introduced from the rear outside of the processing chamber 1 through the intake port 47 by the third air cleaning section 44 as the horizontal airflow Z via the third dust filter 50 is loaded. The clean air of the horizontal airflow Z is exhausted to the outside of the processing chamber 1 by the exhaust unit 45. Therefore, the atmosphere between the semiconductor wafers W horizontally transferred to the wafer boat 5 can be kept clean by the horizontal air flow Z of the clean air, and the wafer boat 5 unloaded from the heat treatment furnace 2 to the loading area can be maintained. The semiconductor wafer W after the heat treatment can be efficiently cooled.
[0034]
In particular, the inside of the processing chamber 1 is divided into a carrier processing space 23 and a wafer processing space 24, and clean air circulation systems 25 and 26 are provided independently of each other in the carrier processing space 23 and the wafer processing space 24. Therefore, the number of times of passing clean air through the air cleaning unit can be reduced as compared with a conventional processing apparatus in which clean air is passed many times through the air cleaning unit and the entire processing chamber is continuously circulated. It is possible to sufficiently reduce contamination of the semiconductor wafer by the impurity gas generated from the dust removing filter in the air cleaning section with a simple configuration without requiring any special preventive measures. In addition, since the clean air is individually supplied and circulated to the carrier processing space 23 and the wafer processing space 24 by the independent clean air circulation systems 25 and 26, the air volume of each clean air circulation system 25 and 26 is small. The size of the blowers 34, 39, 43 and 51 can be reduced, and the size of the processing device can be reduced.
[0035]
In addition, since the clean air circulation systems 25 and 26 are provided independently in the carrier processing space 23 and the wafer processing space 24, for example, the carrier processing space 23 and the wafer processing space 24 are opened and closed by the shutter. By partitioning the wafer processing space 1 or the like, the atmosphere in the processing chamber 1 can be easily separated into the carrier processing space 23 and the wafer processing space 24. Therefore, only the wafer processing space 24 is inert gas atmosphere such as nitrogen (N₂A) It is possible to easily apply a desired treatment method such as a gas atmosphere. In this case, the intake port 47 and the exhaust unit 45 are shielded, and the inert gas is supplied to and exhausted from the wafer processing space 24 by a supply / exhaust unit dedicated to the inert gas. Further, in the processing apparatus, the inlet 31 and the outlet 41 of the clean air circulation system 25 of the carrier processing space 23 are disposed above the processing chamber 1 and the clean air circulation of the wafer processing space 24 is performed. Since the intake port 47 and the exhaust section 45 of the system 26 are arranged at the rear of the processing chamber 1, even when a plurality of processing apparatuses are installed adjacent to each other, the suction and exhaust of clean air can be performed without any trouble.
[0036]
The present invention is not limited to the above-described embodiment, and various modifications can be made within the scope of the present invention. For example, the first to third air purifying units 27, 28, and 44 in the embodiment may be provided with, for example, an activated carbon filter that adsorbs and removes impurity gas together with the first to third dust removing filters 33, 38, and 50. This makes it possible to prevent contamination of the semiconductor wafer W by the impurity gas. In the above embodiment, the clean air circulating system 26 of the wafer processing space 24 introduces clean air from the inlet 47 provided in the door 46, but instead of the inlet 47, the third air is used. In addition to the suction port 49, the cleaning section 44 may be provided with a suction port for directly introducing clean air from outside the rear of the processing chamber 1. Further, as an object to be processed applied to the processing apparatus of the present invention, for example, an LCD substrate or the like can be applied in addition to the semiconductor wafer W.
[0037]
【The invention's effect】
In short, according to the present invention, the following excellent effects can be obtained.
[0038]
(1) According to the processing apparatus of the first aspect, the processing chamber is divided into the carrier processing space and the object processing space, and the clean air circulation systems are independently provided in these processing spaces. Compared to conventional processing equipment that passes clean air many times through the air cleaning section and continuously circulates the entire processing chamber, the number of times that clean air passes through the air cleaning section is reduced, and dust is removed from the air cleaning section. Contamination of the object to be processed by the impurity gas generated from the filter can be reduced with a simple configuration without requiring any special preventive measures.MaFurther, since the atmosphere in the processing chamber can be easily isolated from the carrier processing space and the processing object processing space, a desired processing method such as setting only the processing object processing space to an inert gas atmosphere can be used. Can be easily appliedIn particular, the clean air circulating system of the carrier processing space section horizontally blows clean air introduced from above and outside of the processing chamber to the carrier storage section above the carrier processing space section via the first air cleaning section, The blown-out clean air is blown downward along a carrier carry-in / out port at the front of the processing chamber through the second air purifier, and the blown-down clean air is blown upward through an exhaust duct. Since the air is exhausted to the outside, the atmosphere in the carrier processing space can be independently and efficiently cleaned.
[0040]
(2) Claims2According to the processing device described,The processing chamber is divided into a carrier processing space and an object processing space, and clean air circulation systems are independently provided in these processing spaces, so that clean air is passed through the air cleaning section many times for processing. Compared with the conventional processing equipment that continuously circulates the entire room, the number of times that clean air passes through the air purifying unit is reduced, and contamination of the object to be processed by impurity gas generated from the dust filter of the air purifying unit is special. It is possible to reduce the atmosphere in the processing chamber without the need for simple preventive measures and to easily isolate the atmosphere in the processing chamber between the carrier processing space and the processing space. A desired processing method such as an inert gas atmosphere only in the processing space can be easily applied.The clean air circulating system of the processing object processing space portion cleans the clean air introduced from outside the rear of the processing chamber from one side wall portion of the processing object processing space portion to another side wall portion through a third air cleaning section. Clean air that has been blown out horizontally to the other side wall is exhausted to the rear and outside through the exhaust unit, so that the atmosphere in the processing space of the workpiece can be independently and efficiently cleaned. Can be.
[Brief description of the drawings]
FIG. 1 is a sectional view showing a processing apparatus according to an embodiment of the present invention.
FIG. 2 is a perspective view showing a clean air circulation system in a carrier processing space.
FIG. 3 is a perspective view showing a clean air circulation system in a wafer processing space.
FIG. 4 is a sectional view showing a clean air circulation system in a carrier processing space.
FIG. 5 is a sectional view showing a part of a clean air circulation system in a wafer processing space.
[Explanation of symbols]
W Semiconductor wafer (workpiece)
1 processing room
2 Heat treatment furnace
5 Wafer boat (workpiece holder)
7 career
8 Carrier loading / unloading entrance
11 Carrier Storage Department
23 Carrier processing space
24 Wafer processing space (substrate processing space)
25, 26 Clean air circulation system
27 First air purifier
28 Second air purifier
29 Exhaust duct
44 Third air purifier
45 Exhaust section

Claims (2)

A carrier processing space for carrying in, carrying out, storing, and transporting a carrier containing a plurality of workpieces in the processing chamber, and a workpiece holder that houses a heat treatment furnace and is carried in and out of the heat treatment furnace. And a carrier processing space for transferring a workpiece between the carrier and the carrier, and introducing, circulating and exhausting clean air into the carrier processing space and the workpiece processing space. A clean air circulation system is provided independently, and the clean air circulation system of the carrier processing space horizontally feeds clean air introduced from above and outside of the processing chamber into a carrier storage unit provided above the carrier processing space. A first air purifying section that blows out, and a second air that blows clean air blown out from the first air purifying section and blows down along a carrier carry-in / outlet provided in a front part of the processing chamber. A cleaning unit, the processing apparatus characterized by comprising an exhaust duct for exhausting the second blown out from the air cleaning unit clean air that has reached the bottom to the top outside. A carrier processing space for carrying in, carrying out, storing, and transporting a carrier containing a plurality of workpieces in the processing chamber, and a workpiece holder that houses a heat treatment furnace and is carried in and out of the heat treatment furnace. And a carrier processing space for transferring a workpiece between the carrier and the carrier, and introducing, circulating and exhausting clean air into the carrier processing space and the workpiece processing space. A clean air circulating system is provided independently, and the clean air circulating system in the processing object processing space portion cleans the clean air introduced from outside the rear of the processing chamber from one side wall portion of the processing object processing space portion to another side wall. A third air purifying section that blows out horizontally toward the section, and an exhaust section that exhausts the clean air blown out from the third air purifying section and reaching the other side wall portion to the rear outside. processing equipment you.

Images