JPH07326651A - Multistage process equipment - Google Patents

Abstract

PURPOSE:To constitute muiltistage process chambers of a process equipment main body, and improve the space application efficiency in the height direction in a clean room, by installing sliders capable of elevating, in the process equipment main body. CONSTITUTION:In a process equipment main body 1, process chambers 2 whose front faces are opened are installed as multistage constitution in the vertival direction. Lifters 5 which are vertically driven protrude from both sides of the process equipment main body 1. A slider 71 which loads an object to be treated and slides in the horizontal direction is installed on the front end portion of the lifter 5. When an object to be treated is transferred to the slider 71 from a working robot B at a delivering point, the slider 71 moves to a previouly programmed process chamber 2, and stows the object to be treated into the process chamber 2.

Description

Detailed Description of the Invention

[0001]

FIELD OF THE INVENTION The present invention relates to a multi-stage processing apparatus.
Specifically, the present invention relates to a multi-stage processing apparatus having a plurality of processing chambers arranged at least in the vertical direction and having a function of storing and taking out an object to be processed in an arbitrary processing chamber.

[0002]

2. Description of the Related Art In-line manufacturing equipment is generally used in the manufacturing process of semiconductor devices and liquid crystal display panels. For example, when forming a resist film on the surface of an object to be processed such as a semiconductor wafer or a glass substrate, (1) the object to be processed is taken out and washed, (2) the cleaned object to be treated is dried by heating, 3) Cool, spray (4) an adhesion enhancer to improve the adhesion of the resist solution onto the surface of the object to be treated, (5) place it in a constant temperature bath to maintain a constant temperature, and (6) coat the resist solution. It is necessary to apply the steps of applying to the processed product, (7) drying the applied resist solution to remove the solvent, (8) cooling, (9) exposing, and then (10) developing. Conventionally, each device for performing a series of these processes is installed in a clean room in a line and in a plane, and sequentially performs the process while conveying the object to be processed by a conveyor. Was there.

However, since various environmental conditions are strictly controlled in the clean room, the cost per unit area is very high, and when the production line or the processing line becomes long, the facility cost and the maintenance cost of the clean room become very high. There was the problem of being expensive. In particular, in the processing step with a long tact time, for example, the drying step of the object to be processed, balance with the tact time in other steps,
In order to allow the object to be processed to flow smoothly, for example, the line of the drying device or the like must be lengthened, and the cost of the clean room is high.

Therefore, it is considered to use the space in the height direction in the clean room. FIG. 10 shows a drying processing apparatus 101 having a plurality of drying chambers 102.
In addition, the drying chambers 102 are provided in two vertical stages. 103
Is a working robot, and is an arm 10 that moves in a horizontal plane.
4 has a support plate 105 at the tip thereof, and the base end of the arm 104 is supported by a stretchable column portion 106 so as to be able to move up and down. In addition, the work robot 103 uses the rail 10
It is possible to move along 7. Then, when the work robot 103 receives the signal indicating the completion of the cleaning process in the previous cleaning device, it goes to the cleaning device to receive the object to be processed, places the cleaned object on the support plate 105, and performs the drying process. It is conveyed to the apparatus 101, and the object to be processed is delivered and set in the empty drying chamber 102. On the other hand, the dried object is placed on the support plate 105 and the drying chamber 1
Then, the operation of taking it out from No. 02 and carrying it to the next stage cooling device is repeated.

By using such a drying treatment apparatus, since the drying chambers are provided in two stages, the length of the drying treatment apparatus can be halved and the occupied area in the clean room can be reduced. be able to. However, if the number of drying chambers is further increased, the work robot must move from the lowermost drying chamber to the uppermost drying chamber, so that the working robot is a vertically long and tall robot. Therefore, it was not possible to cope with the multi-stage drying room. For this reason, in the past, the number of vertical drying chambers was limited to two, and the number could not be increased further.

Further, since the work robot moves the object to be processed into and out of the drying chamber, the work robot arm is required to have a large stroke in the direction perpendicular to the rail. However, this short stroke can be solved. It was difficult.

Further, the work robot was originally intended to carry the object to be processed from the cleaning device to the drying processing device and to carry the object to be processed from the drying processing device to the cooling device. The control of the work robot was very complicated because the process of delivering and taking out the object to be processed into the chamber and the registration of the process chamber during and after the process were to be performed.

Further, in the conventional in-line equipment, the processing sequence cannot be changed or exchanged between the processing steps, so that it lacks flexibility. Therefore, for example, when it is necessary to change the processing order, such as omitting the drying process, it is necessary to re-install the equipment itself. Similarly, since the conventional drying processing apparatus is provided only with the drying chamber, it is not possible to deal with a change in the processing order.

[0009]

SUMMARY OF THE INVENTION The present invention has been made in view of the problems of the above conventional examples, and an object of the present invention is to realize a multistage structure of processing chambers and to completely disperse processing lines. The purpose is to enable treatment and improve the flexibility of the treatment procedure.

[0010]

According to the multi-stage processing apparatus of the present invention, at least a plurality of processing chambers arranged in the vertical direction are provided in the processing apparatus main body, and an object to be processed is conveyed almost horizontally and delivered to the processing chamber. Alternatively, it is characterized in that a horizontal moving body for taking out the processed object from the processing chamber substantially horizontally is provided in the processing apparatus main body so as to be movable in the vertical direction.

In the multi-stage processing apparatus, the processing apparatus main body may be provided with an up-and-down moving body that is capable of moving up and down by projecting forward from the opening of the processing chamber, and the up-and-down moving body may be provided with the horizontal moving body. it can. Alternatively, a vertical moving body that can move up and down may be provided on the front surface or the side surface of the processing apparatus main body, and the horizontal moving body may be provided on the vertical moving body.

A plurality of the horizontal moving bodies may be provided on the elevating moving body.

Further, the processing chamber may include a processing chamber for performing different processing and a processing chamber for performing the same processing.

Further, it is preferable that the object to be processed is delivered at a fixed position.

Furthermore, the operation of the horizontal moving body and the processing process such as the processing time in the processing chamber can be programmable and controllable.

[0016]

In the multistage processing apparatus of the present invention, for example, the horizontal moving body receives the object to be processed carried by the work robot from the previous processing step at the delivery position, and the vertical moving body moves the horizontal moving body. By moving up and down, the object to be processed is carried to the target processing chamber, and further by moving the horizontal moving body almost horizontally, the object to be processed is delivered to the processing chamber. On the other hand, the horizontal moving body moves substantially horizontally and takes out the processed object from the processing chamber, and moves it up and down to the transfer position of the processed object with the work robot by the moving lifting body. Here, the object to be processed transferred from the horizontal moving body to the work robot is carried to the next processing step by the work robot. Therefore, the control of the horizontal moving body and the control of the work robot can be completely distributed.

Further, it is also possible to take out the object to be processed, which has been processed by the horizontal moving body, from the processing chamber, carry it to another processing chamber, and put it in the processing chamber to perform another processing. That is, it is possible to sequentially perform processing in different types of processing chambers provided in the multi-stage processing apparatus. In particular, the change of the processing procedure and the thinning-out process can be easily performed only by changing the control program of the horizontal moving body.

Further, if a plurality of horizontal moving bodies are provided, the objects to be processed can be put in and taken out in different processing chambers at the same time, the number of movements of the horizontal moving bodies can be reduced, and the takt time can be shortened.

[0019]

1 is a perspective view showing a multistage processing apparatus A and a working robot B according to an embodiment of the present invention, and FIG. 2 is a schematic horizontal sectional view of the multistage processing apparatus A. The processing apparatus main body 1 is provided with a plurality of processing chambers 2, particularly three or more processing chambers, which are vertically stacked, and each processing chamber 2 is opened at the front surface so that an object 3 to be processed can be taken in and out from the front surface. You can do it. Further, in the processing chamber 2, a plurality of support pins 4 for supporting the object 3 to be processed with a small contact area are provided upright. A plurality of processing chambers 2 provided in the processing apparatus main body 1
May all perform the same treatment, but a treatment chamber 2 for performing different treatments such as drying treatment, cooling and spraying of adhesion enhancer may be provided. Further, the same type and different types of processing chambers 2 may be mixed.
In FIG. 1, the processing chambers 2 are integrally incorporated in the processing apparatus main body 1, but it is possible to stack and fix the component type processing chambers 2 that can be recombined.

Further, the latter half of the lifter (elevating moving body) 5 is housed in the space on the left and right sides of the processing chamber 2 in the main body 1 of the processing apparatus, and the latter half of the lifter 5 is guided by the guide rail portion 6. It is held so that it can be raised and lowered. The lifter 5 is a lifter drive mechanism provided in the processing apparatus main body 1, for example, a chain 8 wound around sprockets 7.
A lifter drive mechanism composed of a motor 9 and a motor 9 can be moved up and down together. The front half of the lifter 5 has a vertically long opening 1 opened in the processing apparatus body 1.
It projects from 0 to the front surface of the processing apparatus main body 1. A slider drive mechanism 12 is provided on the opposing inner side surfaces of each lifter 5 via a spacer 11, and a slider (horizontal moving body) 71 is supported by the slider drive mechanism 12. Further, on the inner side surface of the slider 71, a groove portion 13 for holding the object 3 to be processed is provided. By moving the lifter 5 up and down, the slider 71 can be moved up and down at least from the height of the uppermost processing chamber 2 to the height of the lowermost processing chamber 2 and the height of the transfer position p of the workpiece 3. It has become. Also, slider 7
In the state where 1 is moved to an arbitrary height of the processing chamber 2, the slider 71 is positioned in front of the processing chamber 2, and when the slider driving mechanism 12 is driven to move the slider 71 horizontally, the slider 71 is moved. Enters the processing chamber 2 from the front.

3 and 4 are a partially cutaway perspective view and a sectional view showing the slider drive mechanism 12 of the above in detail. The slider drive mechanism 12 includes a fixed frame 51, an intermediate frame 61, and a slider 71, and the intermediate frame 61 and the slider 71 extend in both front and rear directions.

The fixed frame 51 is mainly composed of an E-shaped frame material 52, which is an aluminum extruded product having a substantially E-shaped cross section, and an upper flange portion 53 projecting over the entire length on the inner side surface of the E-shaped frame material 52. Underside of the
A plurality of cam followers (rollers) 56 are provided on the side surface of the intermediate flange portion 54 and the upper surface of the lower flange portion 55, respectively.
57 and 58 are rotatably supported.

The intermediate frame 61 is composed mainly of a deformed frame material 62 which is a deformed pultruded product, and a horizontal protruding portion 64 protrudes over the entire length at the center of both left and right side surfaces.
L-shaped groove-shaped protrusions 63 and 65 are projected above and below the L-shaped protrusions. The groove 63a on the upper surface of the groove-shaped protrusion 63 protruding on one side surface of the intermediate frame 61 and the groove-shaped protrusion 65.
The cam followers 56, 58 of the fixed frame 51 are fitted into the groove portion 65a on the lower surface of the intermediate frame 61 and the fixed frame 51 so as not to separate from each other. Further, the horizontal protrusion 64 is placed on the cam follower 57 of the fixed frame 51, and the weight of the intermediate frame 61 is supported by the cam follower 57. Therefore, the cam followers 56, 57,
The rolling of 58 allows the intermediate frame 61 to slide smoothly.

The slider 71 has a structure which is substantially plane-symmetrical to the fixed frame 51, and is mainly composed of an E-shaped frame material 72 which is an aluminum extrusion molded product having a substantially E-shaped cross section. Cam followers (rollers) 76, 77, 78 are rotatably supported on the lower surface of the upper flange portion 73 protruding on the inner side surface of the E-shaped frame member 72, the side surface of the intermediate flange portion 74 and the upper surface of the lower flange portion 75, respectively. Has been done. Thus, the cam followers 76, 78 are provided on the other side surface of the intermediate frame 61 with the groove portion 63a on the upper surface of the groove-shaped protruding portion 63 and the groove portion 65 on the lower surface of the groove-shaped protruding portion 65.
It is fitted into the inside of a, and as a result, the intermediate frame 6
1 and the slider 71 are integrally coupled so as not to be separated. A cam follower 77 is mounted on the upper surface of the groove-shaped protrusion 65, and the weight of the slider 71 is supported by the groove-shaped protrusion 65. Therefore, the slider 71 can slide smoothly by rolling the cam followers 76, 77, 78.

Thus, in the slider drive mechanism 12, the intermediate frame 61 is slidably supported by the fixed frame 51, the slider 71 is slidably supported by the intermediate frame 61, and the slider 71 is centered on the fixed frame 51. It is designed to extend in both directions. Moreover, the cam followers 56 of the fixed frame 51,
58 and the diameters of the cam followers 76, 78 of the slider 71 are substantially equal to the inner dimensions of the groove-shaped protrusion 63 and the groove-shaped protrusion 65 of the intermediate frame 61 (that is, the cam followers 56, 58, 76, 78 are groove-shaped). Since there is no rattling in the protrusions 63 and 65, and further, there is no hard fitting in the groove-shaped protrusions 63 and 65), it is possible to prevent the intermediate frame 61 and the slider 71 from swinging in the lateral direction. The diameters of the cam followers 57 of the fixed frame 51 and the cam followers 77 of the slider 71 are also substantially equal to the height between the horizontal protrusion 64 and the groove-shaped protrusion 65 of the intermediate frame 61 (that is, the cam followers 57, 77).
Does not rattle in the horizontal protruding portion 64, and is prevented from being in a hard fit state in the horizontal protruding portion 64).
It is possible to prevent the intermediate frame 61 and the slider 71 from swinging in the vertical direction.

Next, the movement of the slider drive mechanism 12 will be described. The fixed frame 51 is the motor block 9
It is fixed at 1. The motor block 91 includes a drive motor 92, a speed reducer 93, a front plate 94, and a drive pinion mechanism 9.
5, the central portion of the fixed frame 51 is fixed to the front plate 94. The drive pinion mechanism 95 is composed of three pinions 95a, 95b, 95c, the central driving pinion 95a is directly connected to the output shaft 93a of the speed reducer 93, and the two driven pinions 95b, 95c rotate on the front plate 94. It is freely pivoted and meshes with the driving pinion 95a on both sides of the driving pinion 95a. A rack 96 is provided on the lower surface of the intermediate frame 61 over the entire length, and the driven pinions 95b and 95c on both sides are meshed with the rack 96. Therefore, when the drive pinion 95a is driven by the drive motor 92, the driven pinions 95b and 95c and the rack 96 of the intermediate frame 61 are engaged with each other to drive the intermediate frame 61, and the intermediate frame 61 is projected. At this time, as shown in FIG. 5, the rack 96 moves the drive pinion 95c (or 95
Since the intermediate frame 61 can be projected until just before the disengagement with b), the three pinions 95a,
According to the drive pinion mechanism 95 composed of 95b and 95c, the protrusion distance of the intermediate frame 61 is set between the drive and driven pinions 95a and 95b as compared with the case where only one pinion (for example, the drive pinion 95a) is used. It can be extended by the horizontal distance L1. Further, the protruding direction of the intermediate frame 61 can be changed by the rotation direction of the drive pinion 95a.

Further, the fixed frame 51 and the slider 7
On the inner side surface of the rack 1, racks 59 and 79 are provided above the intermediate flange portions 54 and 74, respectively, over the entire length. On the other hand, an opening 97 is provided between the upper surface of the horizontal protruding portion 64 and the lower surface of the upper groove-shaped protruding portion 63 at the center of the intermediate frame 61, and the upper surface of the horizontal protruding portion 64 is doubled in the opening 97. A stroke transmission pinion mechanism 98 is provided. The double stroke transmission pinion mechanism 98 includes a plurality of transmission pinions 80a, 80b, 8 arranged in a line with the meshing pinions 99a, 99b at both ends.
0c and one meshing pinion 99a
Is transmitted to the other meshing pinion 99b via the transmission pinions 80a, 80b, 80c. Further, one meshing pinion 99a meshes with the rack 59 of the fixed frame 51 (also meshes with the rack 79 of the slider 71 when contracted), and the other meshing pinion 99a.
b is engaged with the rack 79 of the slider 71 (when contracted, also engaged with the rack 59 of the fixed frame 51). Therefore, when the intermediate frame 61 is slid by the drive pinion mechanism 95, the meshing pinion 99a is rotated by the meshing of the rack 59 and the meshing pinion 99a, and this rotation is transmitted to the transmission pinions 80a, 80.
It is transmitted to the other meshing pinion 99b through b and 80c, and the meshing pinion 99b rotates. As a result, the rack 79 is fed by the rotation of the meshing pinion 99b, so that the slider 71 is driven and the slider 71 is projected. Therefore, when the intermediate frame 61 is projected by the drive pinion mechanism 95, the slider 71 is further projected from the intermediate frame 61 by the double stroke transmission pinion mechanism 98, and when the intermediate frame 61 is retracted, the slider 71 is also retracted at the same time. Moreover, when the slider 71 is projected, the rack 79 of the slider 71 is engaged with the meshing pinion 99b (or 9) as shown in FIG.
9a), the slider 71 can be projected until just before it is disengaged. Therefore, when the double stroke transmission pinion mechanism 98 is used, power is transmitted to the slider 71 by one pinion (for example, the meshing pinion 99a). Compared with the above, the protrusion distance of the slider 71 can be extended by the distance L2 between the meshing pinions 99a and 99b. The slider 71 also slides in both directions according to the protruding direction of the intermediate frame 61.

The horizontal distance from the center of the driven pinion 95c (95b) of the drive pinion mechanism 95 to the end of the rack 59 of the fixed frame 51 and the meshing pinion of the double stroke transmission mechanism 98 from the end of the rack 96 of the intermediate frame 61. The horizontal distance to the center of 99a (99b) is almost equal. Further, the fixed frame 51, the intermediate frame 61, and the slider 71 have the same length.

In addition, the work robot B shown in FIG. 1 carries the object 3 to be processed, which is received by the processing device (not shown) at the preceding stage, to the delivery position p of the multi-stage processing device A, and the delivery of the multi-stage processing device A. The object to be processed 3 received at the position p is carried to the next-stage processing device (not shown), and the support plate 15 for mounting the object to be processed 3 is provided on the tip of the arm 14 that moves in the horizontal plane. Has been. The work robot B can move along the rails 16.

Next, the operation of the multistage processing apparatus A will be described with reference to FIG.
A description will be given according to (a) to (e). The slider 71 stands by at the transfer position p of the object 3 to be processed, as shown in FIG.
As shown in (b), the workpiece 3 carried by the work robot B from the processing apparatus at the preceding stage is the slider 71.
It is inserted into the groove portion 13 of and is transferred to the slider 71. Alternatively, since the slider 71 can move forward, the object to be processed 3 may be picked up by the slider 71. In this way, the object to be processed 3 is attached to the slider 71.
7C, the slider 71 is moved up to the intended height of the processing chamber 2 by the lifter 5 as shown in FIG. 7C, and the slider driving mechanism 12 moves the slider 71 to the processing chamber 2 at that height. Inserted in Figure 7
The object 3 to be processed is carried onto the support pin 4 as shown in FIG. Then, the lifter 5 is slightly lowered so that the workpiece 3 is placed on the support pin 4 from the slider 71. When the workpiece 3 is placed on the support pin 4, the slider 71 returns from the processing chamber 2 to the original position, and the lifter 5 returns to the original delivery position p and waits.

When the processing of the object 3 to be processed is completed, the object 3 to be processed in the processing chamber 2 is taken out by the slider 71 and carried to the delivery position p in the order opposite to the above order. At the delivery position p, the workpiece 3 is transferred from the slider 71 to the work robot B, and is transported by the work robot B to the processing device at the next stage.

Alternatively, when the multi-stage processing apparatus A is provided with processing chambers 2 of different types, the processed object 3 to be processed is taken out of the processing chamber 2 by the slider 71 and the next processing is performed. It is transported to the processing chamber 2 and delivered to the processing chamber 2 for processing. As a result, the object to be processed 3 is sequentially subjected to a plurality of processes in the multistage processing apparatus A.

The multi-stage processing apparatus A is programmable, and the sequence and processing time for processing the object 3 by the lifter 5 and the slider 71 are programmed in the multi-stage processing apparatus A in advance. Therefore, when the processing order in the multi-stage processing apparatus A is changed or the processing is thinned (for example, when the cooling process is omitted), it can be dealt with only by changing the program of the multi-stage processing apparatus A. . Further, since the control of the processing sequence and the like in the multi-step processing apparatus A is independent of the work robot B, the multi-step processing apparatus A and the work robot B can be completely decentralized control, and the work robot B can be controlled. Control can be simplified.

Further, since the object 3 to be processed in the multi-step processing apparatus A is operated by the lifter 5 and the slider 71, the number of steps in the processing chamber 2 is not limited by the constraint of the working robot B, and the processing is performed. The chamber 2 can be multistage. Therefore, the utilization efficiency of the space in the height direction of the clean room can be improved, and the occupied area in the clean room can be reduced.

FIG. 8 is a partially cutaway schematic plan view showing a multi-stage processing apparatus C according to another embodiment of the present invention. In this multi-stage processing apparatus C, lifting units 17 are provided on both sides of the front surface of the processing apparatus main body 1 having a plurality of processing chambers 2. The lifter 5 and the lifter drive mechanism are housed in the lift unit 17, and the slider drive mechanism 12 is provided.
The slider 71 is provided so as to project from the lifter 5 to the front side of the processing chamber 2. In this embodiment, the lifter 5 and the lifter drive mechanism are not provided in the processing apparatus main body 1 but are separate bodies, so that the lifter drive mechanism and the like can be easily inspected and repaired. Further, it may be retrofitted to the multi-stage processing device. Further, it may be considered that the processing chambers 2 are provided in a plurality of rows in the horizontal direction and the elevating unit 17 is also movable in the horizontal direction.

In the embodiment of FIG. 8, the elevating unit is provided on the front surface of the processing apparatus main body. However, if the slider is positioned in front of the processing chamber, the elevating unit is attached to the side surface of the processing apparatus main body. It doesn't matter.

FIG. 9 is a front view showing a part of still another embodiment of the present invention. In FIG. 9, only one lifter 5 and the slider 71 are shown, but the other slider 71
Also has a symmetrical morphology. In this embodiment, the slider drive mechanism 12 and the slider 71 are provided on the side surface of the lifter 5 in upper and lower two stages.
The center-to-center distance of is approximately equal to the center-to-center distance of the processing chamber 2. In this embodiment, the workpieces 3 can be placed on the upper and lower sliders 71 and carried, and two workpieces 3 can be simultaneously taken in and out of the processing chamber. Alternatively, the workpiece 3 on one slider 71 can be delivered to the processing chamber 2, while the workpiece 3 processed by the other slider 71 can be taken out of the processing chamber 2 at the same time. Therefore, in this embodiment, the number of movements of the slider 71 can be reduced and the tact time can be shortened.

In each of the above embodiments, the pair of left and right sliders is provided to hold the object to be processed from the left and right, but the number of sliders may be one. For example, the lower surface of the central portion of the object to be processed may be supported by a slider having a supporting portion having the same shape as the supporting plate of the work robot.

[0039]

According to the present invention, since the object to be processed can be carried to the predetermined processing chamber by the vertically movable body provided in the main body of the processing apparatus, the processing chamber can be multi-staged as in the conventional case. Even if it is configured, the work robot does not become long and the burden does not increase. Therefore, the processing chambers can be configured in multiple stages, and the space in the height direction such as a clean room can be used to shorten the processing line. As a result, the processing line can be shortened, and the cost of a clean room or the like can be significantly reduced.

Further, unlike the conventional example, the problem of short stroke of the work robot is eliminated. Furthermore, it becomes possible to separately control the work robot that moves the object to be processed between the processing steps and the horizontal moving body that moves the object to be processed in the multi-stage processing apparatus, and it is possible to realize complete distributed processing control. Especially, the control of the work robot can be simplified.

Further, if the object to be processed is transferred between the work robot and the horizontal moving body at a fixed position, the work robot can be controlled more easily.

Further, when the processing chambers for performing different processings are provided in multiple stages, the processing procedure can be easily changed and the thinning processing can be easily performed only by changing the program of the control procedure of the horizontal moving body.

Furthermore, if a plurality of horizontal moving bodies are provided, the objects to be processed can be taken in and out of different processing chambers at the same time, the number of times of moving the horizontal moving bodies can be reduced, and the tact time can be shortened.

[Brief description of drawings]

FIG. 1 is a perspective view showing a multi-stage processing apparatus according to an embodiment of the present invention.

FIG. 2 is a schematic plan sectional view of the above.

FIG. 3 is a perspective view showing a structure of a slider driving mechanism of the above.

FIG. 4 is a cross-sectional view of the slider driving mechanism of the above.

FIG. 5 is a view for explaining the operation of the drive pinion mechanism of the above slider drive mechanism.

FIG. 6 is a view for explaining the operation of the double stroke transmission pinion mechanism of the slider drive mechanism of the above.

7 (a), (b), (c), (d), and (e) are operation explanatory views of the multi-stage processing device of the above.

FIG. 8 is a partially cutaway schematic plan view showing a multi-stage processing apparatus according to another embodiment of the present invention.

FIG. 9 is a schematic front view showing a part of still another embodiment of the present invention.

FIG. 10 is a perspective view showing a multi-stage processing apparatus according to a conventional example.

[Explanation of symbols]

 A multi-stage processing device B work robot 1 processing device main body 2 processing chamber 3 processed object 5 lifter 12 slider driving mechanism 71 slider

Claims (8)

[Claims] 1. A processing apparatus main body is provided with a plurality of processing chambers arranged at least in a vertical direction, and an object to be processed is conveyed substantially horizontally to be delivered into the processing chamber, or an object to be processed after processing is almost removed from the processing chamber. A multi-stage processing apparatus, wherein a horizontal moving body for taking out horizontally is provided in the processing apparatus body so as to be vertically movable. 2. An elevating and lowering movable body is provided on the main body of the processing apparatus so as to project forward from an opening of the processing chamber, and the elevating and lowering movable body is provided with the horizontal moving body. Item 1. The multi-stage processing device according to Item 1. 3. The multi-stage processing apparatus according to claim 1, wherein a vertical moving body that is vertically movable is provided on a front surface or a side surface of the processing apparatus main body, and the horizontal moving body is provided on the vertical moving body. . 4. The multi-stage processing apparatus according to claim 2, wherein the elevation moving body is provided with a plurality of horizontal moving bodies. 5. The process chambers for performing different processes, wherein the plurality of process chambers include process chambers for performing different processes.
The multi-stage processing device according to 3 or 4. 6. The plurality of processing chambers include processing chambers for performing the same processing.
The multi-stage processing device according to 3, 4, or 5. 7. The multi-stage processing apparatus according to claim 1, 2, 3, 4, 5, or 6, wherein an object to be processed is delivered at a fixed position. 8. A process control such as an operation of the horizontal moving body and a processing time in the processing chamber can be programmed and controlled.
The multi-stage processing device according to 6 or 7.