JP6474286B2 - Clean exhaust system - Google Patents

Description

  The present invention relates to a clean exhaust system applicable to a clean oven or the like for performing heat treatment of an object to be heat treated in a clean room or the like.

  Patent Document 1 discloses a clean oven for performing heat treatment of an object to be heat treated in a specific atmosphere gas.

  The clean oven of Patent Document 1 is an apparatus that heat-treats semiconductor devices, liquid crystal display devices, and the like, and heats an object to be heat-treated in a furnace surrounded by a heat insulating material. This clean oven includes an oven fan drive motor outside the furnace, and the oven fan drive motor is provided so as to protrude from the side wall of the clean oven.

  The oven fan drive motor rotates an oven fan arranged in the furnace. When heat-treating the object to be heat-treated, the atmospheric gas heated by the heater in the furnace is blown to the object to be heat-treated through the filter by the rotation of the oven fan. Then, after passing through the object to be heat treated, the atmospheric gas is heated again by the heater and circulated in the furnace.

JP 2007-271126 A

  By the way, when the clean oven disclosed in Patent Document 1 is used as a storage room in which cleanliness of air is ensured, for example, in a clean room, the oven fan drive motor provided outside the clean oven Generates heat and dust in the clean room.

  For this reason, in order to exhaust the exhaust heat from the oven fan drive motor and the air containing dust from the oven fan drive motor from inside the clean room, an exhaust duct for exhausting heat outside the clean room, and dust It is necessary to add a large-scale exhaust system including an exhaust duct for discharging the air outside the clean room. Therefore, the conventional clean oven has a cost associated with the addition of such a large exhaust facility.

  The present invention has been made in view of the above, and an object of the present invention is to prevent contamination of the accommodation room by heat and dust-containing air generated from the motor, eliminating the need for a large-scale exhaust facility and making it large-scale. An object of the present invention is to provide a clean exhaust system that can be applied to a clean oven or the like that can prevent costs associated with the addition of exhaust equipment.

  In order to achieve the above object, a clean exhaust system according to claim 1 is a clean exhaust system that is disposed in a storage room and performs a heat treatment of an object to be heat treated, wherein the base and the base are partitioned. And a housing part having a processing chamber for housing the object to be heat treated, a motor disposed in the base, a blower fan disposed in the processing chamber and rotated by the motor, and the base And an air transfer section for sending air containing heat generated from the motor and generated substances into the processing chamber so as not to leak into the accommodation room.

  In the clean exhaust system according to claim 1, the air transfer unit can send the heat generated from the motor and the air containing the generated substance in the base to the processing chamber from the base so as not to leak into the accommodation room. . Therefore, it is possible to prevent the inside of the accommodation room from being contaminated by the heat generated from the motor and the air containing the generated material, so that a large-scale exhaust facility is not required, and costs associated with the addition of a large-scale exhaust facility can be prevented.

  3. The clean exhaust system according to claim 2, wherein the air transfer part is located outside the housing part and the base part, and the air transfer part is provided in an exhaust port provided in the base part and the storage part. It is characterized by being a tube connected between the intake port.

  In the clean exhaust system according to the second aspect, the air transfer part can be easily attached to the outside of the housing part and the base part of the existing clean exhaust system only by connecting to the exhaust port and the intake port.

  4. The clean exhaust system according to claim 3, wherein the air transfer unit is a through-hole provided through a wall portion that divides the processing chamber and the base of the storage unit, and the air transfer unit. The processing chamber and the base are connected by a section.

  In the clean exhaust system according to claim 3, the air transfer part is a through-hole provided through the wall part that defines the processing chamber and the base part of the storage part. It can be easily provided later on the inside of the housing part and the base part.

  The clean exhaust system according to claim 4, wherein the air containing the heat and the generated material generated from the motor includes the heat and the generated material generated from the motor when the air containing the generated material is sent from the base to the processing chamber. A generated material removal filter for removing the generated material from the air is arranged.

  In the clean exhaust system according to the fourth aspect, the generated substance removal filter can remove the generated substance from the heat generated from the motor and the air containing the generated substance, so that the generated substance is fed into the processing chamber from the base. Can be prevented.

  6. The clean exhaust system according to claim 5, wherein a main filter that passes atmospheric gas circulated in the processing chamber by the blower fan is disposed in the processing chamber, and the main filter is the generated material removal filter. It is characterized by having finer eyes.

  In the clean exhaust system according to claim 5, the generated substance removal filter removes the generated substance from the heat generated from the motor and the air containing the generated substance to prevent the generated substance from being sent into the processing chamber from the base. However, even if a finer generated substance passes through the generated substance removing filter, the finer generated substance can be captured by the main filter, so that contamination in the processing chamber can be prevented.

  According to the present invention, it is possible to prevent the inside of the accommodation room from being contaminated with air containing heat and dust generated from the motor, eliminating the need for large exhaust facilities and preventing the costs associated with the addition of large exhaust facilities. It is possible to provide a clean exhaust system that can be applied to a clean oven or the like.

It is a perspective view which shows the clean oven to which the clean exhaust system of 1st Embodiment of this invention is applied from diagonally forward. It is a perspective view which shows the clean exhaust system shown in FIG. 1 from the diagonal rear side. It is sectional drawing along the vertical direction of the main-body part shown in FIG. It is a figure simplified and shown in order to make it easy to see the structural example of the main-body part shown in FIG. It is sectional drawing in the DD line of the main-body part shown in FIG. It is a perspective view which shows typically the operation example of the clean exhaust system of 1st Embodiment. It is a figure which shows 2nd Embodiment of the clean exhaust system of this invention, and is simplified and shown in order to make the structural example of a main-body part easy to see. It is sectional drawing in the EE line of the main-body part shown in FIG.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the present invention (hereinafter referred to as embodiments) will be described with reference to the drawings.

(First embodiment)
<Overall configuration of clean exhaust system 1>
FIG. 1 is a perspective view of a clean oven to which a clean exhaust system according to a first embodiment of the present invention is applied from an oblique front side. FIG. 2 is a perspective view showing the clean exhaust system 1 shown in FIG. 1 from an oblique rear side.

  A clean exhaust system 1 shown in FIGS. 1 and 2 is applied to a clean oven for heat-treating an object to be heat-treated such as a semiconductor device or a liquid crystal display device. The clean exhaust system 1 is disposed in a storage room where air cleanliness is ensured, for example, the clean room 200. The clean exhaust system 1 heat-treats an object to be heat-treated in a specific atmosphere gas by a forced air circulation system in a furnace. This clean exhaust system 1 is also called a dust-free heat treatment device. The atmosphere gas is preferably an inert gas such as nitrogen or argon, but is not particularly limited.

  The cleanliness in the clean room 200 is from class 10 to around class 10000 in the US federal standard (fed.Std.209E). US federal standards specify the number of particles in one cubic foot (ft3) of 0.5 μm particles, for example, class 100 means that there are no more than 100 particles of 0.5 μm in 1 ft3. . In the ISO clean room standard (standard number ISO-14644, Part1, name: air cleanliness class classification), class 10 corresponds to ISO class 4, class 100 corresponds to ISO class 5, and class 1000 corresponds to ISO. It corresponds to class 6 and class 10000 corresponds to ISO class 7.

  As shown in FIGS. 1 and 2, the main body 1A of the clean exhaust system 1 is a metal rectangular parallelepiped box, and the main body 1A is composed of a front surface 2, a back surface 3, a left side surface 4, and , Right side surface portion 5, upper surface portion 6, and lower surface portion 7.

  As shown in FIG. 1, a front door 8 and an operation panel 9 are arranged on the front surface portion 2. The front door 8 is held by hinge portions 8A and 8A shown in FIG. The front door 8 can open and close the front opening 8B of the front part 2 indicated by a broken line in FIG. The front door 8 has a handle 8C.

  As shown in FIG. 2, an exchangeable rear door 10 for exchanging a main filter F such as a HEPA filter, which will be described later, is disposed on the back surface portion 3 so as to be openable and closable. A heat radiating hole 11 is provided in the lower portion of the back surface portion 3. The heat dissipation hole 11 can be closed using a closing plate 12 and a plurality of screws 12A. A heat radiating hole 13 is provided in the upper portion of the back surface portion 3.

  As shown in FIG. 2, the left side surface portion 4 is provided with a heat radiating hole 14 in the lower portion. A heat radiating hole 16 is provided in the upper portion of the left side surface portion 4.

  As shown in FIG. 1, the right side surface portion 5 has a cable hole 17 and an air inlet 18. The cable hole 17 and the air inlet 18 communicate with the inside of the main body 1A. The cable hole 17 is used for passing cables such as an electric cable between the inside and the outside of the main body 1A.

  One end 21 of the air transfer unit 20 shown in FIG. 1 can be detachably connected to the intake port 18. A heat radiating hole 23 is provided in the lower portion of the right side surface portion 5. The heat dissipation hole 23 can be closed using a closing plate 24 and a plurality of screws 24A. A heat radiation hole 25 is provided in the upper part of the right side surface part 5.

  The closing plate 24 is provided with an exhaust port 26. The other end 22 of the air transfer unit 20 shown in FIG. 1 can be detachably connected to the exhaust port 26. The air transfer unit 20 may be a flexible tube that can be bent and extended, for example.

  As shown in FIG. 1, the upper surface portion 6 has a heat radiating hole 27 and an exhaust port 28. A tank exhaust pipe 29 is detachably attached to the exhaust port 28. The tank exhaust pipe 29 is provided with an exhaust amount adjusting valve 30 for adjusting the exhaust amount in the processing chamber 42.

  FIG. 3 is a cross-sectional view of the main body 1A shown in FIG. 1 along the vertical direction. FIG. 4 is a simplified diagram for easy understanding of the structure example of the main body 1A shown in FIG. 5 is a cross-sectional view taken along line DD of the main body 1A shown in FIG.

  As shown in FIG. 3, casters 31 for moving the main body 1A to four corner positions are provided on the lower surface 7 of the main body 1A. Further, the lower surface portion 7 is provided with a stopper 32 for stopping the movement of the position of the main body portion 1A.

  As shown in FIG. 3, the front door 8 is closed in a sealed state with respect to a rectangular front opening 8 </ b> B via a door packing 33. By opening the front door 8, the worker can take in and out the object to be heat-treated stored in the main body 1 </ b> A.

  The rear door 10 is closed in a sealed state with respect to the rectangular rear opening 10 </ b> B via a door packing 34. The operator can take out the main filter F accommodated in the main body 1 </ b> A by opening the back door 10 and replace it with a new main filter F. For example, a HEPA filter can be used as the main filter F. The HEPA filter is a high performance filter for sterilization having a square or rectangular shape.

<Housing 40 of Main Body 1A>
As shown in FIG. 3, the main body 1 </ b> A includes a housing 40 and a base 41. The accommodating part 40 is arrange | positioned on the base 41, and the inside of the process chamber 42 of the accommodating part 40 is satisfy | filled with the atmospheric gas heated by the heater 65 in the furnace. The operating temperature range in the processing chamber 42 of the storage unit 40 is, for example, a high temperature environment of room temperature +30 to 300 ° C., but is not particularly limited.

  As shown in FIGS. 3 and 4, the processing chamber 42 of the storage unit 40 includes an upper wall 50 and a lower wall 51, a left side surface 4 and a right side surface 5 shown in FIG. 1, and a front door 8 shown in FIG. It is formed by being surrounded by the rear door 10. The upper wall portion 50, the lower wall portion 51, the left side surface portion 4, the right side surface portion 5, the front door 8, and the rear door 10 have a structure in which a heat insulating structure is disposed on a metal plate material. Made of fiber and glass wool.

  As shown in FIGS. 3 and 4, a front opening 8 </ b> B is provided on the front side of the housing portion 40, and a back opening 10 </ b> B is provided on the rear side of the housing portion 40. As shown in FIG. 3, shelf receiving pillars 56 and 57 that hold the shelf board 55 are provided inside the accommodating portion 40. The shelf support pillars 56 and 57 are respectively fixed to the inner surface of the left side surface portion 4 and the inner surface of the right side surface portion 5.

  The left and right shelf support pillars 56 and 57 hold one or a plurality of shelf boards 55. The left and right shelf support columns 56 and 57 can be held by changing the position of one or more shelf plates 55 along the Z direction (up and down direction). Each shelf board 55 can place an object to be heat-treated. The shelf board 55 has a shelf support 55A.

  As shown in FIG. 3, a gas suction port portion 58 is provided along the Z direction at the front portion of the shelf receiving column 56 on the front side of the housing portion 40. The gas inlet 58 is disposed between the front door 8 and the front shelf support column 56 along the front opening 8B.

  The main filter F is detachably provided in the housing portion 40 between the rear shelf support column 57 and the rear door 10 so as to be exchangeable using, for example, a bolt and nut. In addition, a space SP for flowing gas is provided between the rear door 10 and the main filter F.

  As shown in FIG. 3, a temperature control sensor 59 is attached to the upper wall portion 50 in the processing chamber 42 of the housing portion 40. The temperature control sensor 59 is provided between the rear shelf support column 57 and the main filter F. The temperature control sensor 59 is configured to send a temperature information signal SS in the processing chamber 42 to the control unit 100 in order to control the temperature in the processing chamber 42 of the storage unit 40.

<Housing 40 of Main Body 1A>
Next, the base 41 of the main body 1A will be described.

  As shown in FIGS. 3 to 5, the base portion 41 of the main body portion 1 </ b> A is provided at the lower portion of the housing portion 40. As shown in FIG. 3, the casters 31 and the like are attached to the lower surface portion 7 of the base portion 41 as described above.

  As shown in FIGS. 3 to 5, the base 41 of the main body 1 </ b> A has a rectangular parallelepiped housing space 60, and the processing space 42 of the housing space 60 and the housing 40 is formed by the lower wall 51. Separated and separated. An attachment portion 61 and a fan motor 62 are provided in the accommodation space portion 60. The fan motor 62 is fixed to the mounting portion 61, and the output shaft 63 of the fan motor 62 is directed upward along the Z direction. The fan motor 62 is controlled to rotate according to a command from the control unit 100.

  As shown in FIGS. 3 and 4, the lower wall portion 51 has a thick portion 51A and a thin portion 51B. The thick part 51A is formed on the front door 8 side, and the thin part 51B is on the rear side of the thick part 51A and is formed from the thick part 51A to the back door 10. The thick part 51A forms a part of the front opening 8B, and the thin part 51B forms a part of the back opening 10B.

  As shown in FIGS. 3 and 4, the thin portion 51 </ b> B has a through hole 51 </ b> C. The through hole 51C is formed along the Z direction, and the output shaft 63 of the fan motor 62 passes through the through hole 51C. As illustrated in FIG. 3, the output shaft 63 of the fan motor 62 has disks 63 </ b> A and 63 </ b> B fixed at upper and lower positions.

  These disks 63A and 63B are positioned at the upper end and the lower end of the through hole 51C, and the output shaft 63 rotates so as to be supported with respect to the thin portion 51B by the disks 63A and 63B in the through hole 51C. It can be done. By providing such disks 63A and 63B, it is possible to prevent the heat and dust of the fan motor 62 generated in the accommodation space 60 from leaking to the processing chamber 42 of the accommodation part 40 through the through hole 51C as much as possible. it can.

  A blower fan 64 is attached to the tip of the output shaft 63 of the fan motor 62. The fan motor 62 and the blower fan 64 constitute a blower for blowing a predetermined atmospheric gas into the processing chamber 42 of the housing unit 40. The blower fan 64 is disposed in the space SQ generated by the difference in thickness between the thick portion 51 </ b> A and the thin portion 51 </ b> B in the lower wall portion 51 in the processing chamber 42.

<Heater 65>
Next, the heater 65 will be described with reference to FIGS.

  The heater 65 shown in FIGS. 3 to 5 heats the inside of the processing chamber 42 of the storage unit 40 described above at a predetermined heating temperature by energization from the control unit 100. The material of the heater 65 is, for example, a stainless steel pipe heater, but the material is not particularly limited.

  The heater 65 shown in FIGS. 3 to 5 includes left and right first portions 65A and 65A, left and right second portions 65B and 65B, and a third portion 65C. The left and right first portions 65A and 65A of the heater 65 shown in FIGS. 3 to 5 are formed along the Z direction. The left and right second portions 65B and 65B of the heater 65 shown in FIGS. 3 and 4 are formed along the X direction. The third portion 65C shown in FIGS. 4 and 5 is formed along the Y direction.

  Here, the Z direction is the vertical direction of the main body 1A, the X direction is the depth direction of the main body 1A, and the Y direction is the width direction of the main body 1A.

  As shown in FIG. 3, the thick portion 51A of the lower wall portion 51 has a through hole 51D along the Z direction. The left and right first portions 65A and 65A pass through the through hole 51D of the thick portion 51A. Terminals 65 </ b> D at the lower ends of the left and right first portions 65 </ b> A and 65 </ b> A reach into the accommodating space 60 and are electrically connected to the controller 100. The upper ends of the left and right first portions 65 </ b> A and 65 </ b> A reach into the processing chamber 42 of the storage unit 40. The left and right second portions 65B and 65B and the third portion 65C of the heater 65 are disposed in the space SP1 below the lowest shelf 55 in the processing chamber 42 of the housing portion 40.

<Air transfer unit 20>
Next, the air transfer unit 20 will be described with reference to FIGS. 1 and 3 to 5.

  The air transfer unit 20 shown in FIG. 1 is indicated by a broken line in FIG. 3 and indicated by a solid line in FIGS. 4 and 5.

  As shown in FIG. 1, one end 21 of the air transfer unit 20 is detachably connected to the intake port 18 of the right side surface 5, and the other end 22 of the air transfer unit 20 shown in FIG. The closing plate 24 is detachably connected to the exhaust port 26. By adopting such an attachment structure of the air transfer part 20, the air transfer part 20 can be attached to the existing clean exhaust system 1 only by attaching the closing plate 24 to the heat radiation hole 23 at the lower part of the right side face part 5. Can be easily installed by retrofitting.

  A dust removal filter 70 is detachably attached to the intake port 18 of the right side surface portion 5. The dust removal filter 70 can also be called a pre-filter, and is a coarser filter than the main filter F. In other words, the eyes of the main filter F are finer than the eyes of the dust removal filter 70.

  For the main filter F, for example, a heat-resistant HEPA filter or a high-performance heat-resistant HEPA filter can be used. The continuous maximum use temperature of the heat resistant HEPA filter and the high performance heat resistant HEPA filter is, for example, 350 ° C., and the dust collection efficiency of the heat resistant HEPA filter and the high performance heat resistant HEPA filter is 99.97% or more at 0.3 μm.

  Further, as the dust removal filter 70, a coarser filter than the main filter F can be used.

  The air transfer unit 20 connects the interior of the accommodation space 60 in the base 41 and the processing chamber 42 of the accommodation unit 40 via a dust removal filter 70.

  When the fan motor 62 is driven to rotate, the fan motor 62 generates substances such as heat and dust. The generated substances include dust such as metal powder and oil.

  Generated substances such as dust generated from the fan motor 62 are generated in the storage space 60, and air containing generated materials such as heat and dust in the storage space 60 is transferred from the storage space 60 to the air transfer section. By being sent to the dust removal filter 70 through 20, generated substances such as dust are collected by the dust removal filter 70. Then, the air from which generated substances such as dust are removed is sent into the processing chamber 42 of the accommodating portion 40 through the air inlet 18 of the right side surface portion 5.

  As described above, the air transfer unit 20 sends the air containing the generated substance such as heat and dust in the accommodation space 60 into the processing chamber 42 of the accommodation unit 40 so that the outside of the main body 1A, that is, the clean room. It is possible to prevent it from entering 200 at all. The air transfer unit 20 is an external connection type member that can be attached by a retrofitting operation outside the main body 1A.

<Operation example of clean exhaust system 1>
Next, an operation example of the above-described clean exhaust system 1 will be described.

  FIG. 6 is a perspective view schematically showing an operation example of the clean exhaust system 1 of the first embodiment shown in FIGS. 1 to 5.

  As shown in FIG. 3, a main filter F is attached to the rear part of the accommodating portion 40 in the processing chamber 42, and the back door 10 seals the back opening 10 </ b> B of the processing chamber 42 via the door packing 34. . First, the front door 8 shown in FIG. 1 is opened, and an object to be heat-treated is placed on the shelf board 55 in the processing chamber 42 of the accommodating unit 40 shown in FIG. By closing the front door 8, the front door 8 seals the front opening 8 </ b> B of the processing chamber 42 via the door packing 33.

  The control unit 100 shown in FIG. 3 energizes the heater 65 to heat the object to be heat-treated at a predetermined temperature by the heat generated by the heater 65, and the fan motor 62 is driven by a command from the control unit 100. Then, the blower fan 64 rotates together with the output shaft 63. The temperature control sensor 59 sends a temperature information signal SS in the processing chamber 42 to the control unit 100 in order to control the temperature in the processing chamber 42 of the storage unit 40. Thereby, the control unit 100 maintains the inside of the processing chamber 42 at a predetermined temperature by controlling energization to the heater 65.

  By rotating the blower fan 64, the air containing the atmospheric gas in the processing chamber 42 of the accommodating portion 40 can be circulated as indicated by arrows R1 to R5 in FIG. That is, the air containing the atmospheric gas passes through the space SP from the blower fan 64 by the arrows R1 and R2 and enters the main filter F. After the main filter F removes dust and the like from the air containing the atmospheric gas, the air containing the atmospheric gas from which the dust and the like have been removed passes through the object to be heat-treated on the shelf board 55 as indicated by an arrow R3. Then, the air containing the atmospheric gas containing dust or the like by passing through the object to be heat-treated proceeds to the arrow R4 and returns to the blower fan 64 through the gas inlet 58 as indicated by the arrow R5.

  During the heat treatment of the material to be heat treated, as shown in FIG. The opening degree of the exhaust amount adjustment valve 30 is adjusted according to a command from the control unit 100 to adjust the exhaust amount for discharging the atmospheric gas in the processing chamber 42 of the storage unit 40 to the outside of the clean room 200. Thereby, the operation of the clean exhaust system 1 is started and the fan motor 62 starts to operate, and at the same time, a part of the atmospheric gas in the processing chamber 42 is transferred from the processing chamber 42 of the storage unit 40 to the arrow R6 in FIG. As shown in FIG. 1, the air is discharged to the outside of the clean room 200 shown in FIG.

  Since the exhaust pipe 29 in the tank reaches the outside of the clean room 200, a part of the air including the atmospheric gas containing dust or the like does not leak into the clean room 200 at all, and the inside of the clean room 200 is contaminated. There is no.

  On the other hand, as described above, when the fan motor 62 rotates the blower fan 64 to circulate the air containing the atmospheric gas in the processing chamber 42 of the accommodating unit 40 and perform the heat treatment of the heat treatment object, FIG. As shown in FIGS. 5 and 6, the air transfer unit 20 uses the arrows shown in FIGS. 5 and 6 to indicate air containing generated substances such as heat and dust generated when the fan motor 62 is driven in the accommodation space 60. As indicated by T, it is fed through the dust removal filter 70 into the processing chamber 42 of the accommodating portion 40.

  The dust generated when the fan motor 62 is driven is mainly generated by varnish coating the motor coil and dust from the bearing grease, rather than by frictional powder on the motor shaft, for example.

  As a result of confirming the dust generation from the fan motor 62, when the number of particles in one cubic foot (ft3) of 0.5 μm particles is measured, the dust generation amount is 5 to 6 times when the fan motor 62 is off and on. It has been found that the number is doubled (78 particles of 0.5 μm particles are increased to 398 particles / ft3) (ft3 = 0.02832 m3).

  Since the air transfer unit 20 has an external connection structure that allows air containing generated substances such as heat and dust in the accommodation space 60 to pass outside the main body 1A, generation of heat and dust in the accommodation space 60 is generated. Air containing a substance can be prevented from entering the clean room 200. In particular, the air cleanliness in the clean room 200 up to around class 100 is particularly susceptible to dust generation from the fan motor 62, but the substances generated from the fan motor 62 are not scattered in the clean room.

  By adjusting the opening amount of the exhaust amount adjustment valve 30 of the in-tank exhaust pipe 29 and adjusting the exhaust amount of the air containing the atmospheric gas in the processing chamber 42, the heat and dust in the accommodating space 60 are obtained. The amount of air containing a generated substance such as the amount of air taken into the air containing atmospheric gas in the processing chamber 42 through the air transfer unit 20 is determined.

  As shown in FIG. 6, when air containing generated substances such as heat and dust is sent into the processing chamber 42 through the dust removal filter 70, as indicated by arrows R <b> 1 and R <b> 2 by rotation of the blower fan 64. The air passes through the main filter F together with the air containing the atmospheric gas in the processing chamber 42 of the storage unit 40.

  As a result, even if air containing generated substances such as heat and dust passes through the dust removal filter 70, generated substances such as fine dust that could not be removed are captured by the main filter F finer than the dust removal filter 70. Can be collected and removed.

  Incidentally, the main filter F shown in FIG. 3 can be replaced when a predetermined elapsed time has passed or at an arbitrary timing. When replacing the main filter F, the replacement rear door 10 for replacing the main filter F is opened, the main filter F is removed, a new main filter F is attached, and the rear door 10 is again mounted. close up.

  Further, the dust removal filter 70 shown in FIG. 1 can be replaced when a predetermined elapsed time has passed or at an arbitrary timing. The dust removal filter 70 can be fitted with a new dust removal filter 70 by removing one end 21 of the air transfer unit 20 shown in FIG.

  In the clean exhaust system 1 according to the first embodiment of the present invention described above, the air including the generated substances such as heat and dust generated in the accommodation space 60 by the rotation of the fan motor 62 is outside the main body 1A. Since the provided air transfer unit 20 is passed, the inside of the clean room 200 is not polluted by generated substances such as heat and dust.

  In addition, even if air containing generated substances such as heat and dust generated in the accommodation space 60 is sent into the processing chamber 42 through the air transfer unit 20 provided outside the main body 1A, the dust removal filter 70 is used. Since the main filter F in the processing rate 42 that can remove the generated substances such as finer dust can remove the generated substances such as dust from the air containing the generated substances such as heat and dust, the inside of the processing chamber 42 Will not be contaminated by generated materials such as dust. That is, it is possible to prevent dust generated from the fan motor 62 from being scattered in the clean room 200 with the cleanliness adjusted.

  The air transfer unit 20 can be easily provided simply by retrofitting the exterior of the main body 1A of the clean exhaust system 1 that is actually installed. This eliminates the need for large exhaust facilities for the clean exhaust system that is actually installed, prevents costs associated with the addition of large exhaust facilities, and reduces costs.

(Second Embodiment)
Next, with reference to FIG. 7 and FIG. 8, 2nd Embodiment of the clean exhaust system of this invention is described.

  FIG. 7 shows a second embodiment of the clean exhaust system of the present invention, and is a simplified view for easy understanding of the structure example of the main body 1B. FIG. 8 is a cross-sectional view taken along line EE of the main body shown in FIG.

  The main body 1B of the clean exhaust system 1 according to the second embodiment shown in FIGS. 7 and 8 will be described next when compared with the main body 1A of the clean exhaust system 1 according to the first embodiment shown in FIGS. Although the elements are different, since the other elements are substantially the same, the same reference numerals are given to the same portions, and the description thereof is incorporated.

  In the main body 1A of the clean exhaust system 1 of the first embodiment, as shown in FIG. 1, the air transfer unit 20 externally connects the intake port 18 and the exhaust port 26 outside the main unit 1A.

  On the other hand, in the main body 1B of the clean exhaust system 1 of the second embodiment shown in FIGS. 7 and 8, the air transfer unit 20R is provided inside the main body 1B. The air transfer part 20 </ b> R is a through hole provided in the thin part 51 </ b> B of the lower wall part 51. The air transfer part 20 </ b> R is formed in the Z direction, and connects the accommodation space part 60 and the processing chamber 42 of the accommodation part 40.

  A dust removing filter 70R is detachably attached to the accommodation space 60 side of the air transfer unit 20R.

  7 and FIG. 8 is rotated to circulate the air containing the atmospheric gas in the processing chamber 42 of the accommodating portion 40 to perform the heat treatment of the object to be heat-treated. The portion 20R can directly send air containing generated substances such as heat and dust in the accommodation space portion 60 into the processing chamber 42 of the accommodation portion 40 via the dust removal filter 70R as indicated by an arrow T. .

  Since the air transfer unit 20 has an internal connection structure that allows air containing generated substances such as heat and dust in the accommodation space 60 to pass inside the main body 1B, It is possible to prevent the air containing the generated material from entering the clean room 200.

  Thus, as shown in FIG. 6, when air containing generated substances such as heat and dust is sent into the processing chamber 42 through the dust removal filter 70 </ b> R and the air transfer unit 20 </ b> R, rotation of the blower fan 64 causes As indicated by the arrows R1 and R2, the air passes through the main filter F together with the air containing the atmospheric gas in the processing chamber 42 of the container 40. Thereby, even if air containing generated substances such as heat and dust passes through the dust removal filter 70R, the generated substances such as fine dust that could not be removed are removed by the main filter F finer than the dust removal filter 70R. can do.

  Accordingly, the air containing the generated substances such as heat and dust generated in the accommodation space portion 60 by the rotation of the fan motor 62 passes through the air transfer portion 20R provided inside the main body portion 1B. It is not polluted by generated substances such as heat and dust. It is possible to prevent dust generated from the fan motor 62 from being scattered in the clean room whose cleanness is adjusted.

  Moreover, even if the air containing the generated substances such as heat and dust generated in the accommodation space 60 is sent into the processing chamber 42 through the air transfer part 20R provided inside the main body 1B, the dust removal filter 70R. Since the main filter F in the processing rate 42 that can remove the generated substances such as finer dust can remove the generated substances such as dust from the air containing the generated substances such as heat and dust, the inside of the processing chamber 42 Will not be contaminated by generated materials such as dust.

  The air transfer unit 20R can be easily obtained by simply providing a through-hole in a retrofitting operation on the lower wall portion 51 that is a partition wall of the main body portion 1B of the clean exhaust system 1 that is actually installed. This eliminates the need for large exhaust facilities for the clean exhaust system that is actually installed, prevents costs associated with the addition of large exhaust facilities, and reduces costs.

  In the first embodiment and the second embodiment of the present invention described above, the air containing the generated material such as heat and dust generated in the accommodation space 60 is passed through the through-hole 51C of the thin portion 51B in the processing chamber 42. Even if only a small amount enters, generated substances such as dust and oil can be removed by the main filter F.

  A clean exhaust system 1 according to an embodiment of the present invention is a clean exhaust system that is disposed in a clean room 200 that is an example of a storage room and can be applied to a clean oven or the like for performing heat treatment of an object to be heat treated. This clean exhaust system 1 is provided with a base 41, a base 40, a storage part 40 having a processing chamber 42 for storing a material to be heat-treated, a motor 62 disposed in the base 41, a processing The blower fan 64 disposed in the chamber 42 and rotated by the motor 62 and the air including the heat and the generated substance generated from the motor 62 in the base portion 41 from the inside of the base portion 41 so as not to leak into the accommodation chamber 200. The air transfer part 20 sent in the process chamber 42 is provided.

  Thereby, the air transfer part can send the heat | fever which generate | occur | produces from a motor in the base, and the air containing a generation | occurrence | production substance from the inside of a base to a process chamber so that it may not leak in a storage chamber. Therefore, it is possible to prevent the inside of the accommodation room from being contaminated by the heat generated from the motor and the air containing the generated material, so that a large-scale exhaust facility is not required, and costs associated with the addition of a large-scale exhaust facility can be prevented.

  In the clean exhaust system 1, the air transfer unit 20 is positioned outside the storage unit 40 and the base 41, and the air transfer unit 20 includes an exhaust port 26 provided in the base 41 and an intake port provided in the storage unit 40. 18 is a tube connected between the two. Thereby, the air transfer part can be easily attached to the outside of the housing part and the base part of the existing clean exhaust system only by connecting to the exhaust port and the intake port.

  In the clean exhaust system 1, the air transfer unit 20 is a through-hole provided through a wall (for example, the lower wall 51) that partitions the processing chamber 42 and the base 41 of the storage unit 40, The processing chamber 40 and the base 42 are connected by the transfer unit 20. Thereby, since the air transfer part is the through-hole 20R provided by penetrating the wall part which divides the processing chamber and base part of an accommodating part, the accommodating part 40 and the base part 41 of the existing clean exhaust system are provided. It can be easily provided on the inside by retrofitting.

  In the clean exhaust system 1, when air containing heat and generated substances generated from the motor 62 is sent from the inside of the base 41 to the processing chamber 42, the generated substances are removed from the air generated from the motor 62 and air containing the generated substances. A generated material removal filter 70 (70R) is disposed for this purpose. As a result, the generated material removal filter 70 (70R) can remove the generated material from the heat generated from the motor and the air containing the generated material, so that the generated material is fed into the processing chamber 42 from the base 41. Can be prevented.

  In the clean exhaust system 1, a main filter F through which atmospheric gas circulated in the processing chamber 42 by the blower fan 64 is disposed in the processing chamber 42, and the main filter F is a generated material removal filter 70 (70 </ b> R). ) Is finer than. As a result, the generated material removal filter removes the generated material from the heat generated from the motor and the air containing the generated material to prevent the generated material from being sent into the processing chamber from inside the base, but the fine generated material is temporarily Even if it passes through the generated material removal filter, the finer generated material can be captured by the main filter, so that contamination in the processing chamber can be prevented.

  The present invention has been described with reference to the embodiments. However, each embodiment is an example, and the scope of the invention described in the claims can be variously modified without departing from the scope of the invention. .

  For example, in the illustrated example, the opening degree of the exhaust amount adjustment valve 30 for adjusting the exhaust amount in the processing chamber 42 can be adjusted by a command from the control unit 100, but the present invention is not limited to this, and the exhaust amount adjustment is not limited thereto. The opening degree of the valve 30 may be adjusted manually by an operator.

  The accommodation room in which the air cleanliness is ensured is not limited to a clean room, but may be other types of rooms.

  As the external air transfer unit 20, for example, a flexible tube that can be bent and extended is used, but a normal metal tube that does not expand and contract may be used.

  The clean exhaust system of the embodiment of the present invention is applied to a clean oven. However, the present invention is not limited to this, and the clean exhaust system of the present invention can be applied to apparatuses other than the clean oven.

DESCRIPTION OF SYMBOLS 1 Clean exhaust system 1A Main-body part 18 Inlet port 20 (20R) Air transfer part 26 Exhaust port 40 Storage part 41 Base part 42 Processing chamber 51 Lower wall part (Example of wall part)
60 Housing Space 62 Fan Motor (Motor)
64 Blower 70 (70R) Dust removal filter 200 Clean room (example of accommodation room)
F Main filter

Claims (4)

A clean exhaust system that is disposed in a storage room and heat-treats an object to be heat-treated,
The base,
A container having a processing chamber that is provided separately from the base and that stores a material to be heat-treated;
A motor disposed within the base;
A blower fan disposed in the processing chamber and rotated by the motor;
An air transfer section for sending heat generated from the motor in the base and air containing the generated substance into the processing chamber from the base so as not to leak into the storage chamber;
Equipped with a,
Generation of heat generated from the motor and the generated material for removing the generated material from the air including the generated heat and the generated material when the air containing the generated material is sent from the base to the processing chamber. A clean exhaust system in which a substance removal filter is arranged .   The air transfer part is located outside the housing part and the base part, and the air transfer part is connected between an exhaust port provided in the base part and an intake port provided in the storage part. The clean exhaust system according to claim 1, wherein   The air transfer part is a through hole provided through a wall part that divides the processing chamber and the base part of the housing part, and the processing chamber and the base part are connected by the air transfer part. The clean exhaust system according to claim 1, wherein Wherein said processing the chamber, by the blower fan are mainly filters arranged to pass the atmospheric gas circulated in the treatment chamber, said main filter, characterized in that the eye is finer than the generation substance removing filter Item 4. The clean exhaust system according to any one of Items 1 to 3 .

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