Air cleaning apparatus

An air cleaning apparatus according to the present invention includes an apparatus body having a suction port through which air in a processing space is sucked and a discharge port through which the air sucked through the suction port is discharged into the processing space. A blower is provided in the apparatus body for sucking the air from the processing space into the apparatus body through the suction port and discharging the sucked air into the processing space through the discharge port. In addition an impurity gas removing device in the apparatus body is provided for removing impurity gases contained in the air sucked through the suction port and harmful to processing in the processing space, and a particle removing device is provided on the exhaust side of the impurity gas removing device for removing particles in the sucked air cleared of the impurity gases by impurity gas removing device.

BACKGROUND OF THE INVENTION 
A. Field of the Invention 
The present invention relates to an air cleaning apparatus for cleaning air 
in ambient areas in or around processing units of various processing 
apparatuses. 
B. Description of the Related Art 
In order to finish processing of an object to a predetermined state without 
causing any impurities to adhere to the object, an ambient area in or 
around a processing unit for processing the object must be cleaned. For 
example, an air cleaner is incorporated in a CVD apparatus for forming a 
thin film on the surface of semiconductor wafers by chemical vapor 
deposition, in a semiconductor device manufacturing process. The air 
cleaner is designed so that impurities in an ambient area of the CVD 
apparatus are removed by means of a filter in a manner such that air in 
the apparatus, in which the semiconductor wafers are transported and 
processed, is circulated by means of a blast fan. In this arrangement, the 
impurities are prevented from adhering the to the semiconductor wafers, so 
that the wafers can be filmed with a high degree of accuracy. The 
following is a detailed description of a case in which the air cleaner of 
this type is applied to a CVD apparatus. 
In general, a CVD apparatus, especially a vertical CVD apparatus, comprises 
a cylindrical processing unit in which semiconductor wafers are subjected 
to a filming process and other processes, a wafer boat for holding the 
wafers in the processing unit, and a transportation mechanism for 
supporting the wafer boat and delivering it into and from the processing 
unit. Further, the CVD apparatus comprises a transfer mechanism for 
transferring the semiconductor wafers to the wafer boat supported by the 
transportation mechanism, and a housing having a space in which these 
components of the apparatus are arranged. 
A blast fan and a dusting filter for removing dust, such as particles, are 
arranged in the housing to prevent particles from adhering to the 
semiconductor wafers which are moved in the internal space of the housing 
by means of the transfer mechanism or together with the wafer boat. The 
blast fan forms an air flow which is directed from the rear portion of the 
space in the housing toward the front portion thereof. By disposing the 
dusting filter in the air flow in the housing, the air flow can be cleaned 
at all times, so that the particles can be prevented from adhering to the 
semiconductor wafers. 
Semiconductor wafers have recently been increased in diameter, and their 
microfine working has been promoted, so that film layers, such as silicon 
oxide film, silicon nitride film, etc., formed on the wafers have been 
becoming thinner and thinner. Accordingly, the properties, such as 
electrical properties, of the film layers require stricter control, and a 
very small amount of impurities in the processing ambient have come to 
exert a great influence upon the workmanship of the film layers. In fine 
working of 16DRAM or more, fine particles which cannot be attributed only 
to adhesion of dust appear on the surface of the film layers. These fine 
particles worsen the electrical properties and other properties of the 
film layers, thereby lowering the yield. 
In order to solve this problem, the inventor hereof made a detailed 
analysis and examination of the ingredients of impurities which would 
lower the electrical properties or other properties of the film layers of 
the semiconductor wafers, especially a very small amount of impurity gases 
in the processing ambient, by freely utilizing the up-to-date instrumental 
analysis technology. Thereupon, the inventor hereof ascertained that the 
very small amount of impurity gases constitute a main cause of the 
production of the aforesaid fine particles. Further, a qualitative 
analysis of the impurity gases contained in the air in the housing of the 
CVD apparatus revealed the existence of organic compounds such as 
hydrocarbon, phosphorus compounds, boron compounds, etc. 
Accordingly, the inventor hereof further investigated the source of these 
impurity gases, and estimated that the main source was the synthetic resin 
material of the dusting filter, and that a very small amount of compounds 
remaining in the synthetic resin material had diffused into the housing 
and formed the impurity gases. Comparison between the compounds remaining 
in the synthetic resin material and the ingredients of the impurity gases 
detected by the gas analysis indicated their coincidence. It was also 
found that the impurity gases are generated from a clean room in which the 
CVD apparatus is installed, as well as from the dusting filter in the 
housing. Furthermore, it was indicated that substances which tend to 
accelerate the diffusion of boron compounds and the like from the dusting 
filter flow from the clean room into the CVD apparatus. Thus, the very 
small amount of impurity gases diffusing from the dusting filter (this 
diffusion is accelerated by the substances flowing from the clean room 
into the CVD apparatus in some cases), are transported to the processing 
ambient by means of the blast fan in the housing, and adhere to the film 
layers on the in-process semiconductor wafers, thereby producing fine 
particles on the surface of the film layers. In carrying the wafer boat 
out from the processing unit by means of the transportation mechanism 
after the filming process, in particular, the temperature in the housing 
is considerably increased by radiant heat from the wafer boat, so that the 
temperature of the dusting filter also increases, thereby accelerating the 
diffusion of the impurity gases from the dusting filter. Immediately after 
the filming process, moreover, the film layers are heated and chemically 
active. Due to these two factors, the fine particles are liable to be 
produced on the surface of the film layers. 
SUMMARY OF THE INVENTION 
The object of the present invention is to provide an air cleaning apparatus 
capable of removing impurity gases and particles which have bad influences 
upon processing of an object of processing. 
The above object of the present invention is achieved by an air cleaning 
apparatus constructed as follows. The air cleaning apparatus comprises: an 
apparatus body having a suction port through which air in a processing 
space is sucked and a discharge port through which the air sucked through 
the suction port is discharged into the processing space; blower means in 
the apparatus body for sucking the air from the processing space into the 
apparatus body through the suction port and discharging the sucked air 
into the processing space through the discharge port; impurity gas 
removing means in the apparatus body for removing impurity gases contained 
in the air sucked through the suction port and harmful to processing in 
the processing space; and particle removing means on the exhaust side of 
the impurity gas removing means for removing particles in the sucked air 
cleared of the impurity gases by means of the impurity gas removing means. 
Alternatively, the air cleaning apparatus may comprise an apparatus body 
having a suction port through which air outside a processing space is 
sucked and a discharge port through which the air sucked through the 
suction port is discharged into the processing space. In this case, the 
air outside the processing space is fed into the processing space after it 
is cleaned. 
Preferably, in this arrangement, the impurity gas removing means is an 
activated charcoal filter which can remove the impurity gases. Particles 
which cannot be removed by the activated charcoal filter or particles 
generated from the activated charcoal filter are removed by means of a 
dusting filter, so that the air in the processing space can be kept clean 
at all times. When a semiconductor wafer was actually filmed in the 
processing space cleared of the impurity gases, generation of fine 
particles on the surface of the film layer did not occur. 
Preferably, moreover, air cooling means, such as a radiator, is provided on 
the upper-course side of the activated charcoal filter in the air cleaning 
apparatus, with respect to the direction of suction, in particular, in 
consideration of the case where the processing space is subjected to high 
temperature such that the air sucked into the air cleaning apparatus is 
heated. This is because the activated charcoal filter is activated to 
shorten its own life when the heated air runs against the filter. 
Preferably, furthermore, the particle removing means is a dusting filter 
which is formed of fiberglass or a metallic or ceramic material. If the 
dusting filter is formed of a metallic or ceramic material, in particular, 
the diffusion of the impurity gases from the dusting filter can be 
minimized. The generation of the impurity gases from the dusting filter, 
which is accelerated by heat, can be considerably restrained by means of 
the air cooling means.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
An embodiment of the present invention will now be described with reference 
to the accompanying drawings. FIG. 1 shows an arrangement of a CVD 
apparatus as an example of a processing apparatus. The CVD apparatus 
includes a processing unit 1 in the form of, for example, a closed-topped, 
open-bottomed cylinder, a wafer boat 2, a transportation mechanism 3, a 
transfer mechanism (hereinafter referred to as wafer transfer) 4, and a 
housing 5. A plurality of semiconductor wafers (objects of processing) W 
are arranged vertically at regular intervals in the wafer boat 2 so that 
they are kept horizontal in the processing unit 1. The transportation 
mechanism 3 delivers the wafer boat 2 into and from the unit 1. The wafer 
transfer 4 exchanges the semiconductor wafers W between the wafer boat 2 
supported by means of the mechanism 3 and a wafer cassette C which can 
store, for example, 20 wafers w. The housing 5 has a space 5A in which all 
these elements are arranged. Formed in the front face of the housing 5 is 
an opening 6 which can be opened and closed by means of a door (not 
shown). The wafer cassette C, stored with the semiconductor wafers W, is 
delivered into and from the housing 5 through the opening 6 by means of a 
transportation robot (not shown). Disposed inside the opening 6 is a 
carrier IO port 7 which carries two wafer cassettes C in a manner such 
that the semiconductor wafers W are held vertically. As mentioned later, 
the port 7 forms a passage through which air flows downward from the upper 
side of the interior of the housing 5. Arranged in the port 7, moreover, 
are a wafer aligning mechanism (not shown) and a horizontal-vertical 
conversion mechanism (not shown). The aligning mechanism aligns the 
semiconductor wafers W in each wafer cassette C in a predetermined 
direction by utilizing the orientation flat of each wafer. The conversion 
mechanism rotates the wafer cassette C through 90.degree. for 
horizontal-vertical conversion. Thus, the wafers W in the cassette C are 
arranged horizontally by the horizontal-vertical conversion mechanism 
after being aligned in the predetermined direction by the wafer aligning 
mechanism. 
A carrier transfer mechanism (hereinafter referred to as carrier transfer) 
8 is disposed inside the carrier IO port 7. The wafer cassette C is 
transferred to a shelved carrier stage 9 in the inner part of the housing 
5 by means of the transfer 8. The carrier stage 9 can contain, for 
example, 8 wafer cassettes C in both vertical and horizontal directions, 
thus storing the wafer cassettes C which contain the semiconductor wafers 
W having already been processed or bound to be processed in the processing 
unit 1. 
A transfer stage 10 is disposed under the carrier stage 9, and the wafer 
cassettes C are exchanged between the stages 9 and 10 by means of the 
carrier transfer 8. Further, the semiconductor wafers W are exchanged 
between the wafer cassette C transferred to the transfer stage 10 and the 
wafer boat 2 supported by the transportation mechanism 3, by means of the 
wafer transfer 4. Thus, the wafer transfer 4 picks up the unprocessed 
semiconductor wafers W from the wafer cassette C on the transfer stage 10 
and transfers them to the wafer boat 2 one after another. Also, the 
transfer 4 picks up the processed semiconductor wafers w successively from 
the wafer boat 2 and transfers them to the wafer cassette C on the 
transfer stage 10. 
As shown in FIGS. 2 and 3, the CVD apparatus includes a first air cleaning 
apparatus 12 which has a discharge port 5B and a suction port 5C on either 
side of the housing 5. The main body of the apparatus 12 includes two air 
cleaning sections 20, which are arranged on one side of the space 5A of 
the housing 5, or more specifically, the left-hand side opening (discharge 
port) 5B of the housing 5, and serve also as single-swing doors for 
maintenance. The apparatus body further includes a side duct 13, arranged 
in the right-hand side opening (suction port) 5C of the housing 5, and a 
bottom duct 14 at the bottom of the space 5A. As shown in FIG. 3, a first 
blower 121 for sucking air through the suction port 5C and sending it is 
provided in that region of the bottom duct 14 near the port 5C. Each air 
cleaning section 20 is provided with a container which constitutes a door, 
an opening 12B communicating the interior of the container and the bottom 
duct 14, a first dusting filter 122 formed of, e.g., an HEPA filter 
disposed in the container, and an equalizing plate 123. The filter 122 
removes particles contained in the air which is fed through a duct portion 
12A by the blower 121. The equalizing plate 123 is arranged parallel with 
and inside the first dusting filter 122, with a gap .delta. between the 
filter 122 and has a number of holes 123A, so that the dusted air is 
uniformly sent from the front side of the plate 123 to the side duct 13 in 
the right-hand side opening 5C of the housing 5. 
As shown in FIG. 2, the side duct 13 has inside slits (suction ports) 13A 
through which passes the air from the air cleaning sections 20. The side 
duct 13 and the cleaning sections 20 communicate with one another at their 
respective bottom portions by means of the bottom duct 14 at the bottom of 
the space 5A. The bottom duct 14, the respective duct portions 12A of the 
air cleaning sections 20, and the side duct 13 constitute an air 
circulation path. Thus, the air fed from the air cleaning sections 20 into 
the space 5A in the housing 5, returns into the air cleaning sections 20 
through the side duct 13 and the bottom duct 14, thereby forming a 
horizontal circulating flow X in the space 5A. The particles in the 
circulating air are repeatedly removed by means of the dusting filter 122, 
whereby the circulating air flow X can be cleaned at all times. 
A slit (not shown) is formed in the outer surface of the side duct 13, and 
part of the circulating air is discharged through the slit. As mentioned 
hereinafter, on the other hand, an air inlet 5D, which is defined by a 
metal mesh, is formed in the upper surface of the housing 5. An amount of 
air equivalent to the exhaust is introduced through the inlet 5D from a 
clean room (not shown), in which the CVD apparatus is located, and air for 
the circulating flow X is replenished. Thus, the pressure in the housing 5 
can be kept constant. The CVD apparatus is designed so that the 
circulating flow X in the housing 5 is formed mainly of the air in the 
housing 5, and part of the flow X can be replaced through the air inlet 5D 
and the slit of the side duct 13. An activated charcoal filter 172, which 
constitutes a second air cleaning apparatus 17 (discussed hereinafter), is 
disposed at the top portion of the air inlet 5D. The air from the clean 
room is fed into the housing 5 of the CVD apparatus through the filter 
172. Housed in the bottom duct 14, moreover, are a control device for 
controlling the transportation mechanism 3, wafer transfer 4, etc. and 
wiring members. 
First and second activated charcoal filters 15 and 16 are arranged in the 
bottom duct 14. A radiator 165 for cooling the circulating air is disposed 
on the upper-course side of the filters 15 and 16 with respect to the 
direction of suction. The radiator 165 is driven by a drive unit 167 to 
cool the circulating flow X passing through the radiator 165 at a 
predetermined temperature. Moreover, the first blower 121 is located on 
the upper-course side of radiator 165. The activated charcoal filters 15 
and 16 adsorb a very small amount of impurity gases (hereinafter called 
organic compounds such as hydrocarbon, phosphorus compounds, boron 
compounds, etc. or gases based on gases formed in the filming process) 
generated from the first dusting filter 122 and dusting filters 174 of 
second and third air cleaning apparatuses 17 and 18 (discussed 
hereinafter), etc., thereby preventing these impurity gases from getting 
into the circulating flow X in the space 5A of the housing 5. 
In the first air cleaning apparatus 12, as described above, the air in the 
space 5A is sucked in through the suction port 5C and sent again to the 
space 5A by means of the first blower 121. In doing this, the 
high-temperature air in the space 5A heated by means of radiant heat from 
the wafer boat 2 is first cooled by means of the radiator 165. Then, a 
very small amount of impurity gases (gases from the first dusting filter 
122 and ones attributable to the filming process) in the cooled air are 
removed by adsorption by means of the activated charcoal filters 15 and 16 
in the bottom duct 14. Also, particles (including ones produced by the 
filters 15 and 16) contained in the air discharged into the duct portion 
12A are removed by means of the first dusting filter 122. Thus, clean air 
is fed into the space 5A to form the circulating flow X. 
Since the first air cleaning apparatus 12 can prevent high-temperature air 
from touching the activated charcoal filters 15 and 16 and the dusting 
filter 122 by means of the radiator 165, the life/performance of the 
filters 15 and 16 can be improved, and the generation of the impurity 
gases from the dusting filter 122 cannot be accelerated by heat. Since the 
filters 15, 16 and 122 are located in the bottom duct 14, moreover, they 
can never be directly subjected to the radiant heat from the wafer boat 2. 
The radiator 165 may be situated in a position where it directly receives 
the radiant heat from the wafer boat 2, for example, in the region 
corresponding to the suction port 5C. The dusting filter 122 is formed of 
fiber glass or metallic or ceramic material. If the filter 122 is formed 
of metallic or ceramic material, in particular, the generation of the 
impurity gases therefrom can be minimized. 
In the first air cleaning apparatus 12, the two activated charcoal filters 
15 and 16 are arranged in succession on the upper-course side of the first 
dusting filter 122. Therefore, the time for the contact between the 
filters 15 and 16 and the impurity gases in the air which forms the 
circulating flow X can be extended. Thus, the impurity gases can be 
securely removed by means of the activated charcoal filters. 
The activated charcoal filters 15 and 16 and activated charcoal filters 172 
and 173 of the second and third air cleaning apparatuses 17 and 18 
(discussed hereinafter) are each fabricated by, for example, reducing 
activated charcoal particles to fibers, and forming the fibers into a 
porous mat or a sheet with a number of dispersed pores. These filters 
serve as the so-called prefilters. 
Provided in the top portion of the housing 5, on the other hand, is the 
second air cleaning apparatus 17 which prevents the impurity gases and 
particles in the clean room from getting into the housing 5. As shown in 
FIG. 2, the apparatus 17 extends along the back of the carrier stage 9, 
and is situated under the air inlet 5D. Moreover, the third activated 
charcoal filter 172 is located over the inlet 5D in close vicinity 
thereto. As shown in FIG. 4, the second air cleaning apparatus 17 
comprises a container (apparatus body) 171, a second blower 177, the 
fourth activated charcoal filter 173, and the second dusting filter 174. 
The container 171 has a slit (suction port) 171A which faces the air inlet 
5D of the housing 5. The second blower 177 serves to introduce a small 
amount of air from the clean room into a discharge port 175, which opens 
to the carrier stage 9, through the slit 171A of the container 171 and the 
inlet 5D. The fourth activated charcoal filter 173, which is located on 
the upper-course side of the discharge port 175, adsorbs and removes a 
very small amount of impurity gases in the air sent by means of the second 
blower 177. The second dusting filter 174 is used to remove particles from 
the air passed through the filter 173. Thus, the air cleared of the 
impurity gases and the particles is delivered to the semiconductor wafers 
W stored on the carrier stage 9, thereby forming an air flow Y, as shown 
in FIGS. 2 and 4. An air flow Y.sub.1, which is reflected and returned by 
the front face of the housing 5, is sucked into the container 171 through 
slits 171B in the opposite side faces of the container 171 by means of the 
second blower 177. Thus, the impurity gases generated from the second 
dusting filter 174 are removed by adsorption by means of the fourth 
activated charcoal filter 173. 
According to the arrangement described above, the two activated charcoal 
filters 172 and 173 are arranged in succession on the upper-course side of 
the second dusting filter 174. Therefore, the time for the contact between 
the filters 172 and 173 and the impurity gases in the air in the clean 
room can be extended. Thus, the impurity gases can be securely removed by 
means of the activated charcoal filters. 
The third air cleaning apparatus 18 is provided on the lower-course side of 
the air flow Y over the carrier IO port 7. The apparatus 18 sucks in most 
of the air flow Y and forms a descending air flow Z. The third air 
cleaning apparatus 18 comprises a third blower, a fifth activated charcoal 
filter, and a third dusting filter on the lower-course side of the fifth 
activated charcoal filter (none of which are shown), and is arranged in 
the same manner as the second air cleaning apparatus 17. The apparatus 18 
is designed so as to remove a very small amount of impurity gases 
contained in the descending air flow z and diffused from the second 
dusting filter 174 and residual particles, and send the cleaned air 
through an opening 14A into the bottom duct 14 via the carrier IO port 7, 
thereby allowing it to join the air returned from the side duct 13. The 
impurity gases generated from the third dusting filter of the third air 
cleaning apparatus 18 are removed by adsorption by means of the activated 
charcoal filters 15, 16 in the bottom duct 14. 
The following is a description of the operation of the CVD apparatus 
furnished with the air cleaning system arranged in this manner. In 
subjecting, for example, 8-inch semiconductor wafers W to a filming 
process or the like by means of the CVD apparatus, the processing unit 1 
is first heated to a predetermined temperature, depending on the details 
of processing for the wafers W, and the first, second, and third air 
cleaning apparatuses 12, 17 and 18 are driven. The apparatuses 12, 17 and 
18 form the circulating flows X, Y and Z, respectively, in the housing 5, 
as indicated by the arrows in FIG. 2. Thereafter, two wafer cassettes C, 
stored with the semiconductor wafers W each, are placed in position in the 
carrier IO port 7 by means of the transportation robot. The wafers W in 
each cassette C in the port 7 are aligned in the predetermined direction 
and set in a horizontal state by means of the wafer aligning mechanism and 
the horizontal-vertical conversion mechanism. In this state, the cassettes 
C are transferred to the carrier stage 9 by the carrier transfer 8. After 
a given number of wafer cassettes C are stored on the carrier stage 9 by 
repeating this operation several times, the door (not shown) of the 
opening 6 is closed. 
when the wafer cassettes C on the carrier stage 9 are transferred to the 
transfer stage 10 by the carrier transfer 8, thereafter, the semiconductor 
wafers w in the wafer cassettes C on the stage 10 are successively 
transferred to the wafer boat 2 by the wafer transfer 4. When a given 
number of semiconductor wafers W are transferred to the wafer boat 2, the 
transportation mechanism 3 is driven to feed the boat 2 into the 
processing unit 1, whereupon the wafers W are processed in a specific 
ambient/environment at a predetermined temperature for a given period of 
time. When processing the semiconductor wafers W is completed, the wafers 
are in reverse from the processing unit 1 reversely following the 
aforesaid sequence. 
When the first air cleaning apparatus 12 is driven during the semiconductor 
wafer processing operation, the circulating flow X is formed in the 
housing 5 of the CVD apparatus by the apparatus 12. Thereupon, clean air 
is always circulated in the housing 5, so that particles and impurity 
gases can be prevented from adhering to the semiconductor wafers W. Thus, 
when the first blower 121 is driven to suck air through the bottom duct 14 
of the housing 5, the air flows through the activated charcoal filters 15, 
16 into the duct portions 12A in the air cleaning sections 20. At this 
time, a very small amount of impurity gases in the air sucked through the 
bottom duct 14 into the duct portions 12A are removed by adsorption by 
means of the filters 15, 16. As the air introduced into the air cleaning 
sections 20 passes through the first dusting filter 122, thereafter, a 
very small amount of particles are removed by the filter 122. The air 
cleaned by means of the filters 15, 16 and 122 is delivered uniformly into 
the whole region of the space 5A by means of the equalizing plate 123 
which is situated on the lower-course side of the first dusting filter 
122, and is fed through the slits 13A into the side duct 13. Most of the 
air introduced into the side duct 13 is sucked, through the lower portion 
of the duct 13, into the bottom duct 14 by means of the first blower 121, 
and forms the circulating flow X in the space 5A. Thus, a very small 
amount of impurity gases diffused from the first dusting filter 122 and a 
very small amount of formed gases attributable to the filming process are 
removed again from the reflux air by adsorption by means of the activated 
charcoal filters 15, 16. 
As the circulating flow X of clean air cleared of the impurity gases and 
particles is thus formed in the space 5A, the impurity gases and particles 
are prevented from adhering to the semiconductor wafers w moving in the 
space 5A. Thus, deterioration of the electrical properties of the wafers 
W, which is believed to be caused by impurity gases, can be restrained in 
particular. 
Meanwhile, the air which forms the circulating flow X is partially 
discharged through the side duct 13. An amount of air equivalent to the 
exhaust from the duct 13 is resupplied from the clean room by means of the 
second air cleaning apparatus 17. Thus, when the second blower 177 is 
driven, the air from the clean room is introduced through the air inlet 5D 
of the housing 5 and the slit 171A of the container 171. The air retrieved 
from the clean room is delivered toward the carrier stage 9 by the second 
blower 177, and forms the air flow Y which is directed to the front face 
of the housing 5. Part of the air flow Y returns as the air flow Y.sub.1 
from the front face of the housing 5, is sucked again into the container 
171 through the slit 171B, and joins the air from the clean room. However, 
most of the air flow Y is guided downward by suction by means of the third 
air cleaning apparatus 18, and forms the descending air flow Z. AS the 
descending air flow Z passes through the third air cleaning apparatus 18, 
a very small amount of impurity gases in the flow Z and residual particles 
are removed by means of the fifth activated charcoal filter and the third 
dusting filter. Thereafter, the cleaned descending air flow Z is delivered 
into the bottom duct 14, whereupon it joins the clean circulating flow X 
returning from the side duct 13 to the bottom duct 14. The clean air flows 
(descending air flow Z and circulating flow X) in different directions, 
which join in the bottom duct 14, are passed through the activated 
charcoal filters 15, 16 and dedusted in the air cleaning sections 20. 
Thus, the circulating flow X is formed as a clean one-direction flow. 
The CVD apparatus which is provided with the air cleaning apparatuses 
according to the present embodiment, as described herein, is arranged so 
that air flows are formed around the circulating flow X in the space 5A of 
the housing 5, and the air in the housing 5 is continually circulated by 
means of the air flows to remove the particles and impurity gases in the 
air. More specifically, the particles in the air are removed by means of 
the dusting filters 122 and 174 of the first to third air cleaning 
apparatuses 12, 17 and 18, while the impurity gases from the filters 122 
and 174 and the gases attributable to the filming process are removed by 
means of the activated charcoal filters 15, 16,172 and 173. Accordingly, 
the impurity gases and particles, which are regarded as harmful to the 
semiconductor wafers W, can be prevented from adhering to the wafers W in 
the housing 5. Thus, the electrical properties of the surface of each 
wafer W and the surface of its film layer can be prevented from being 
lowered, so that the yield can be improved. 
According to the present embodiment, in particular, the circulating flow X 
as the center of the air circulation is formed in the space 5A by means of 
the first air cleaning apparatus 12, and the particles and impurity gases 
are removed by the activated charcoal filters 15 and 16 of the apparatus 
12, whereby the impurity gases are prevented from adhering to the film 
layers which are chemically active in a high-temperature state immediately 
after processing operation. Thus, chemical reactions between the impurity 
gases and the film layers are prevented, so that fine particles cannot be 
produced, and deterioration of the properties, such as electrical 
properties, of the film layers can be restrained considerably or 
prevented. 
It is to be understood that the present invention is not limited to the 
embodiment described above, and that various changes and modifications may 
be effected therein by one skilled in the art without departing from the 
scope or spirit of the invention. According to the above-described 
embodiment, in particular, each activated charcoal filter is in the form 
of a mat or a sheet with a number of dispersed pores. However, the 
activated charcoal filters used in the present invention may be any ones 
which are air permeable and can adsorb impurity gases, and their 
configurations are not limited in particular. Moreover, the number and 
location of the activated charcoal filters may be suitably set in 
accordance with the installation conditions and construction of the 
processing apparatus.