The present application claims priority under 35 U.S.C. § 119 to Japanese Patent Application No. 2016-078274, filed Apr. 8, 2016. The contents of this application are incorporated herein by reference in their entirety.
The embodiments disclosed herein relate to a conveyance system, a robot, and a method for controlling a robot.
Japanese Unexamined Patent Application Publication No. 2005-039047 and Japanese Translation of PCT International Application Publication No. JP-T-2009-503811 disclose conveyance systems each including a robot, a locally cleaned conveyance chamber, and a substrate storage cassette or a processing chamber. The robot is a horizontal multi-articular robot with a hand to hold substrates and is located in the conveyance chamber. The substrate storage cassette or the processing chamber is located on a side wall of the conveyance chamber. The robot conveys substrates to the substrate storage cassette or the processing chamber.
For greater efficiency in substrate conveyance, as many cassettes as possible are preferably located on the side wall of the conveyance chamber. For a smaller footprint in the conveyance chamber, the depth of the conveyance chamber (the distance between the front wall, on which the cassettes are located, and the back wall of the conveyance chamber) is preferably as small as possible.
In an attempt to meet these demands, Japanese Unexamined Patent Application Publication No. 2005-039047 increases the number of the links of the robot from three to four, and Japanese Translation of PCT International Application Publication No. JP-T-2009-503811 makes the lengths of the links of the robot (the distances between the rotation axes) unequal.
According to one aspect of the present disclosure, a conveyance system includes a conveyance chamber, a robot, and a controller. The conveyance chamber includes a first side wall and a second side wall. At least one cassette to contain at least one substrate is disposed on a side of the first side wall outside of the conveyance chamber. The second side wall is opposite to the first side wall in a depth direction of the conveyance chamber. The robot is disposed in the conveyance chamber. The robot includes a body, a first arm, a second arm, and a hand. The first arm includes a first base end and a first leading end. The first base end is connected to the body rotatably around a first rotation axis. The first leading end is opposite to the first base end. The second arm includes a second base end and a second leading end. The second base end is connected to the first leading end of the first arm rotatably around a second rotation axis. The first arm has a first inter-axis distance between the first rotational axis and the second rotational axis in a first inter-axis direction. The second leading end is opposite to the second base end. The hand is to hold the substrate. The hand includes a hand base end connected to the second leading end of the second arm rotatably around a third rotation axis. The second arm has a second inter-axis distance between the second rotation axis and the third rotation axis in a second inter-axis direction. The second inter-axis distance is longer than a first inter-axis distance. The second leading end is positioned between a restricted position and the reference position in the depth direction when the first inter-axis direction and the second inter-axis direction are substantially perpendicular to the first side wall. The controller is connected to the robot to control the robot to limit entrance into an area between the first side wall and the restricted position in the depth direction.
According to another aspect of the present disclosure, a robot includes a body, a first arm, a second arm, and a hand. The first arm includes a first base end and a first leading end. The first base end is connected to the body rotatably around a first rotation axis. The first leading end is opposite to the first base end. The second arm includes a second base end and a second leading end. The second base end is connected to the first leading end of the first arm rotatably around a second rotation axis. The first arm has a first inter-axis distance between the first rotational axis and the second rotational axis in a first inter-axis direction. The second leading end is opposite to the second base end. The hand is to hold a substrate and includes a hand base end connected to the second leading end of the second arm rotatably around a third rotation axis. The second inter-axis distance is longer than the first inter-axis distance. The second leading end is positioned between a restricted position and the reference position in the depth direction when the first inter-axis direction and the second inter-axis direction are substantially perpendicular to the first side wall. The robot is controlled by a controller connected to the robot to limit entrance into an area between the first side wall and the restricted position in the depth direction.
According to further aspect of the present disclosure, a method for controlling a robot includes storing a link length difference between a first inter-axis distance of a first arm and a second inter-axis distance of a second arm. The first arm is connected to a body of the robot rotatably around a first rotation axis. The second arm is connected to the first arm rotatably around a second rotation axis. A hand to hold a substrate is connected to the second arm rotatably around a third rotation axis. The first inter-axis distance is a distance between the first rotation axis and the second rotation axis in a first inter-axis direction. The second inter-axis distance is a distance between the second rotation axis and the third rotation axis. The robot is controlled to convey the substrate along a tangent on a circle having a center at the first rotation axis and having a radius approximately equal to the link length difference.
A more complete appreciation of the present disclosure and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
The embodiments will now be described with reference to the accompanying drawings, wherein like reference numerals designate corresponding or identical elements throughout the various drawings.
It is noted that the following embodiments are provided for exemplary purposes only and are not intended in a limiting sense.
In the following description, the terms “parallel”, “perpendicular”, “vertical”, “front”, “center”, and “overlap” may occasionally be used to not only mean “parallel”, “perpendicular”, “vertical”, “front”, “center”, and “overlap”, respectively, in a strict sense but also mean “parallel”, “perpendicular”, “vertical”, “front”, “center”, and “overlap”, respectively, in an approximate sense. That is, these terms are used taking into consideration production-related, installation-related, processing-related, and detection-related tolerances and errors.
A conveyance system 1 according to this embodiment will be outlined by referring to
As illustrated in
In
The positions, sizes, and intervals of the openings provided on the first side wall 51 to accept the cassettes 200 are compliant with SEMI (Semiconductor Equipment and Materials International) standards. The dimensions of each cassette 200 are also compliant with SEMI standards.
The robot 10 is disposed in the conveyance chamber 50, and is what is called a three-link horizontal multi-articular robot that includes a body 10a, a first arm 11, a second arm 12, and a hand 13. A configuration of the robot 10 and a configuration of the hand 13 will be described in detail later by referring to
Each cassette 200 is what is called a Front-Opening Unified Pod (FOUP) and has multiple levels to store the substrates 100. In the cassette 200, each substrate 100 has its reference position (for example, center) match a conveyance position 200C illustrated in
As illustrated in
When the cassettes 200 come in even number, as in this embodiment, the robot 10 is located at or in the vicinity of the center of the series of cassettes 200, that is, between the cassette 200b and the cassette 200c so as to enhance accessibility of the cassettes 200.
The robot 10 is closer to the first side wall 51 than to the second side wall 52, in the Y axis direction. This configuration is for the purpose of minimizing the depth of the conveyance chamber 50 (the dimension along the Y axis illustrated in
When robots are used to convey substrates to cassettes, common practice is to position the hand perpendicular to the first side wall 51, that is, to the front surface of the cassette, in conveying substrate to the cassette (this practice will be hereinafter referred to as “perpendicular conveyance”).
In some applications, such as the embodiment of
In order for the robot 10 to approach the cassettes 200a and 200d with the hand 13 perpendicular to the first side wall 51, it is necessary to increase the number of the links. Increasing the number of the links, however, increases costs involved in the manufacture of the robot 10.
In light of this situation, the conveyance system 1 according to this embodiment makes substrates 100 enter the cassettes 200a and 200d with the hand base end of the hand 13 inclined toward the robot 10, as illustrated in
For reference purposes, the posture that the hand 13 is taking when the substrate 100 has reached the conveyance position 200C is indicated as posture 13Z by broken lines in the cassette 200a. While the hand 13 is taking the posture 13Z, the hand 13 is approximately perpendicular to the first side wall 51.
In order to make the lengths of the links (the first arm 11, the second arm 12, and the hand 13) as long as possible in the conveyance system 1 according to this embodiment, the body 10a of the robot 10 takes a unique position with a unique arrangement of the turning axes of the links. This will be described in detail later by referring to
Because of the unique position of the robot 10 and the unique arrangement of the turning axes, the conveyance system 1 is able to convey substrates 100 to the four cassettes 200 using the single robot 10. Additionally, there is no need for a traveling axis in the X axis direction in the conveyance system 1; installing the single robot 10 in the conveyance chamber 50 suffices.
Thus, the conveyance system 1 improves conveyance efficiency without increase in costs. Additionally, eliminating the need for a traveling axis increases the degree of cleanliness of the inside of the conveyance chamber 50.
When the robot 10 conveys a substrate 100 to the cassettes 200b and 200c, that is, when the robot 10 conveys a substrate 100 to the cassettes 200 other than the farthest cassettes 200a and 200d, the hand 13 takes a position perpendicular to the first side wall 51 and makes the substrate 100 enter the cassette 200b or 200c. Then, with the hand 13 keeping this perpendicular posture, the hand 13 moves the substrate 100 to the conveyance position 200C. Thus, the conveyance system 1 performs the above-described perpendicular conveyance.
While in
For example, in a possible embodiment, four cassettes 200, namely, cassettes 200a, 200b, 200c, and 200d are aligned on the conveyance chamber 50, and the robot 10 is installed at a position facing the front surface of the cassette 200c, which is the second cassette 200 next to one farthest cassette 200d. In this case, the robot 10 may perform the inclination conveyance with respect to the other farthest cassette 200a.
In another possible embodiment, three cassettes 200, namely, cassettes 200b, 200c, and 200d are aligned on the conveyance chamber 50, and the robot 10 is installed at a position facing the front surface of the cassette 200c, which is the center cassette 200. In this case, the robot 10 may perform the inclination conveyance with respect to the farthest cassettes 200b and 200d.
The target of the inclination conveyance will not be limited to the farthest cassettes 200; it is possible to determine any other cassettes 200 as the target based on the target's distance from the robot 10. That is, the cassettes 200 other than the farthest cassettes 200 may be targeted for the inclination conveyance.
For example, it is possible to perform the inclination conveyance with respect to the cassettes 200b and 200c illustrated in
While in
A configuration of the robot 10 will be described by referring to
While in
The body 10a is hung on a side surface of the conveyance chamber 50 (which is illustrated in
The lift shaft 10b supports the first base end of the first aim 11 while ensuring that the first base end is turnable about a first axis A1. The lift shaft 10b is capable of lifting itself up and down along the first axis A1. In a possible embodiment, the lift shaft 10b itself may be turnable about the first axis A1. In another possible embodiment, the first axis A1 may be displaced in the Y axis negative direction, which is opposite to the Y axis (positive) direction, on the upper surface of the lift shaft 10b. This is because if the first axis A1 is displaced in the Y axis negative direction, a longer first arm 11 can be used.
The first arm 11 supports, at its leading end, the second base end of the second arm 12 while ensuring that the second base end is turnable about a second axis A2. The second arm 12 supports, at its leading end, the hand base end of the hand 13 while ensuring that the hand base end is turnable about the third axis A3.
Thus, the robot 10 is a horizontal multi-articular robot with three links, namely, the first arm 11, the second arm 12, and the hand 13. Since the robot 10 is equipped with a lift mechanism, as described above, the robot 10 has access to the multiple levels of substrates 100 in each cassette 200.
The robot 10 also has access to a processing chamber 300 and an aligner 310. The processing chamber 300 is at a height different from the height of the cassettes 200 (see
A configuration of the hand 13 will be described in more detail by referring to
Also as illustrated in
An arrangement of the body 10a, the first axis A1, the second axis A2, and the third axis A3 in the robot 10 will be described by referring to
Also in
As illustrated in
In this embodiment, the first distance D1 is 100 millimeters (mm) As described above, the spatial intervals and other parameters of the cassettes 200 are determined in compliance with SEMI standards. In order to ensure the conveyance of substrates 100 (see
The region between the inner surface of the first side wall 51 and the restricted position P1 is room for the cassettes 200 to be opened and closed. At the reference position P2, a reference plate 60 is located. The reference plate 60 has a reference surface 60a. The reference surface 60a is approximately parallel to X-Z plane illustrated in
As described above, the reference surface 60a of the reference plate 60 is approximately parallel to the X-Y plane illustrated in
As illustrated in
Thus, the robot 10 is fixed to the reference plate 60. This configuration ensures accuracy in determining the position and posture of the robot 10, improving the efficiency of the installment work of the robot 10. The opposite surface of the reference plate 60 opposite to the reference surface 60a is located between the restricted position P1 and the reference position P2. In
With the first arm 11 lifted down to its lowest position, the upper surface of the reference plate 60 is lower in height than the lower surface of the first arm 11. This configuration prevents the reference plate 60 from obstructing the upward and downward movements of the first arm 11, expanding the range over which the first arm 11 is able to lift up and down.
While in
As illustrated in
The first base end of the first arm 11 is located above the reference plate 60, that is, located between the restricted position P1 and the reference position P2. The first arm 11 has such a turnable range about the first axis A1 that the first leading end of the first arm 11 enters the space between the restricted position P1 and the reference position P2. The second axis A2 is as close to the inner surface of the second side wall 52 as possible.
The second leading end of the second arm 12 is located between the restricted position P1 and the reference position P2. More specifically, the second leading end of the second aim 12 is as close to the restricted position P1 as possible. The third axis A3 is also located between the restricted position P1 and the reference position P2.
While in
As illustrated in
This configuration makes the first arm 11 and the second arm 12 of the robot 10 as long as possible, enabling the single robot 10 to convey substrates 100 (see
The first axis A1 is as close to the reference position P2 as possible, and the second axis A2 is as close to the inner surface of the second side wall 52 as possible. This configuration makes the first arm 11 as long as possible. Also, the third axis A3 is as close to the restricted position P1 as possible. This configuration makes the second arm 12 as long as possible. The lengths of the first arm 11, the second arm 12, and the hand 13 will be described in detail later by referring to
As illustrated in
The lengths of the first arm 11, the second arm 12, and the hand 13 will be described in detail by referring to
While in
First, the first arm 11 will be described. As illustrated in
As illustrated in
As illustrated in
Using these parameters, the length “AL1” of the first arm 11 can be represented by the following Formula (1):
AL1=R1+L1+r1
The second atm 12 will be described. As illustrated in
As illustrated in
As illustrated in
The second leading end of the second arm 12 has a plane surface that is aligned with the hand base end of the hand 13 and that is approximately parallel to the X-Z plane. The plane surface looks as if it has been obtained by cutting an arc (the plane surface will be hereinafter referred to as “D cut”). In other words, the second arm 12 has a first curved side surface 12a1, a plane surface 12b, and a second curved surface 12a2. The plane surface 12b is located at the second leading end (which is located on the negative side of the Y axis direction) of the second arm 12, and connects the curved side surfaces 12a1 and 12a2 to each other. This configuration makes the second link length L2 of the second arm 12 as long as possible.
Using these parameters, the length “AL2” (AL2>AL1, as
AL2=R2+L2+R3
As illustrated in
Using the depth D (see
AL2=D−D1−S1−S2
Cancelling “AL2” in Formula (2) and Formula (3) results in the following Formula (4):
R2+L2+R3=D−D1−S1−S2
This shows that “R2”, “L2”, and “R3” can be determined to satisfy Formula (4).
In
The hand 13 will be described. As illustrated in
Thus, when the hand 13 is perpendicular to the first side wall 51 (see
By referring to
While in
As illustrated in
The controller 20 includes a computer and various circuits. The computer includes CPU (Central Processing Unit), ROM (Read Only Memory), RAM (Random Access Memory), HDD (Hard Disk Drive), and an input/output port.
The CPU of the computer reads programs stored in the ROM and executes the programs, and thus functions as the register section 21a and the operation control section 21b of the control section 21.
Alternatively, at least one or both of the register section 21a and the operation control section 21b of the control section 21 may be made up of hardware such as ASIC (Application Specific Integrated Circuit) and FPGA (Field Programmable Gate Array). Also, at least one or both of the selection section 21ba and the switch section 21bb of the operation control section 21b may be made up of the above-described hardware.
The storage section 22 corresponds to the RAM and the HDD. The RAM and the HDD are capable of storing the link length difference 22a and the teaching data 22b. In another possible embodiment, the controller 20 may obtain the above-described programs and the various kinds of information from another computer connected to the controller 20 through a wired or wireless network or from a portable recording medium.
The control section 21 of the controller 20 controls the operation of the robot 10 based on the teaching data 22b in which the link length difference 22a is reflected. The register section 21a obtains the difference between the first link length L1, which is the inter-axis distance of the first arm 11 illustrated in
As described above by referring to
The operation control section 21b controls the operation of the robot 10 based on the teaching data 22b in which the link length difference 22a is reflected. Specifically, in order to control the robot 10 to convey a substrate 100, the operation control section 21b generates a command based on the teaching data 22b stored in the storage section 22 and sends the command to the actuators (not illustrated) of the axes of the robot 10. Also, in order to improve the accuracy of the operation of the robot 10, the operation control section 21b performs, for example, feedback control using encoder values from the actuators.
The selection section 21ba determines whether a substrate 100 can be conveyed to a destination along a linear track in a top view of the robot 10 and the destination. When the selection section 21ba has determined that the substrate 100 can be conveyed to the destination along a linear track, the selection section 21ba selects one type of control that moves the hand 13 along the track (this control will be hereinafter referred to as “cylindrical coordinates control”).
Assume that the first link length L1 and the second link length L2 are equal to each other (hereinafter referred to as “equal length links”). In this case, the cylindrical coordinates control moves the hand 13 radially from the first axis A1. The radial movement enables best use of the rotational speed of the actuator of each turning axis, resulting in expedited conveyance of the substrates 100, in other words, increased substrate conveyance throughputs.
In this embodiment, the second link length L2 is greater than the first link length L1. Even though the second link length L2 is greater than the first link length L1, the hand 13 moves along a tangent on a circle that is centered about the first axis A1 and that has a radius of “second link length L2−first link length L1”. From the standpoint of the amount by which each axis turns, this movement is equivalent to the radial movement of the hand 13 from the first axis A1 in the case of the equal length links. This is because the hand 13 of the robot 10 is at a position away from the hand 13 in the case of the equal length links by the above-described radius.
When the selection section 21ba has determined that the substrate 100 cannot be conveyed to the destination along a linear track, the selection section 21ba selects another type of control that moves the hand 13 while changing the direction of the track on the way to the destination (this control will be hereinafter referred to as “orthogonal coordinates control”).
When the switch section 21bb receives a new selection result different from the previous selection result from the selection section 21ba, the switch section 21bb switches from the cylindrical coordinates control to the orthogonal coordinates control or from the orthogonal coordinates control to the cylindrical coordinates control.
When the operation control section 21b performs the cylindrical coordinates control, the operation control section 21b controls the movement of the robot 10 to make the track of the hand 13 overlap a tangent on a circle that is centered about the first axis A1 (see
The teaching data 22b is information containing a “job” that is a program specifying an operation of the robot 10 including the movement track of the hand 13. The job is generated on the teaching stage, which is when the robot 10 is taught how to operate. In another possible embodiment, the teaching data 22b may be generated on another computer connected to the controller 20 through a wire or a wireless network and then may be stored in the storage section 22.
The link length difference 22a is reflected in the teaching data 22b as a parameter value. While in
By referring to
Also in
Assume that the second link length L2 of the second arm 12 and the first link length L1 of the first arm 11 of the robot 10 are equal to each other. In this case, if the body 10a is placed so that the first axis A1, which is the turning axis of the first arm 11, is located on the center line 300CL, substrates 100 can be conveyed to the processing chamber 300 by the cylindrical coordinates control.
In this embodiment, however, the second link length L2 of the second aim 12 is greater than the first link length L1 of the first arm 11 of the robot 10, as described above by referring to
In other words, the center line 300CL of the processing chamber 300 may be shifted from the front surface (straight line passing through the first axis A1 and approximately parallel to the Y axis illustrated in
While in
While in
In
When in
When in
Thus, the robot 10 is shift-arranged relative to the destination such as the cassettes 200 and the processing chamber 300. The shift-arrangement provides more opportunities to perform the cylindrical coordinates control in the operation control of the robot 10, resulting in expedited conveyance of the substrates 100.
Thus, the shift-arrangement of the robot 10 relative to the destination such as the cassettes 200 and the processing chamber 300 has been described by referring to
As illustrated in
A conveyance operation to a destination located on the second side wall 52 will be described by referring to
The hand 13 moves straight along the tangent TL1 with the center line 13CL (see
When the conveyance position 300C of the processing chamber 300 is located on the tangent TL2, the robot 10 takes such a posture that the portion of connection between the first arm 11 and the second arm 12 protrudes in the X axis negative direction. Then, the robot 10 moves the hand 13 along the tangent TL2.
A conveyance operation to a destination located in the conveyance chamber 50 will be described by referring to
As illustrated in
The hand 13 moves straight along the tangent TL11 with the center line 13CL (see
When the conveyance position 310C of the aligner 310 is located on the tangent TL12, the robot 10 takes such a posture that the portion of connection between the first arm 11 and the second arm 12 protrudes in the Y axis negative direction. Then, the robot 10 moves the hand 13 along the tangent TL12.
While in
While in
By referring to
Along the tangent TL1, which passes through the conveyance position 300C, the robot 10 moves the hand 13 in a straight manner, that is, without changing the posture of the hand 13, so as to convey the substrate 100 to the conveyance position 300C. As described above, the tangent TL1 is one of the tangents on the circle C.
As illustrated in
This causes the hand 13 to move along the tangent TL1 to the conveyance position 300C in a straight manner, that is, without changing the posture of the hand 13. Then, as illustrated in
As illustrated in
As illustrated in
This configuration eliminates the need for deceleration that would otherwise be necessitated by the change of the turning direction. As a result, the conveyance of the substrates 100 is expedited and performed more accurately. Also in the above configuration, the amount by which the first arm 11 moves is smaller than when the turning direction is changed on the way to the conveyance position 300C. As a result, the conveyance of the substrates 100 is expedited and performed more accurately.
As illustrated in
When the robot 10 moves the hand 13 away from the conveyance position 300C along the tangent TL1, the order of movement may be
In
Next, a procedure for a conveyance operation performed by the conveyance system 1 (see
As illustrated in
When at step S102 the selection section 21ba has determined that the conveyance track to the destination matches the tangent (Yes at step S102), the switch section 21bb of the operation control section 21b determines whether the current control is the orthogonal coordinates control (step S103). When the current control is the orthogonal coordinates control (Yes at step S103), the orthogonal coordinates control is switched to the cylindrical coordinates control (step S104). When the current control is the cylindrical coordinates control (No at step S103), step S104 is skipped to step S105.
Next, the operation control section 21b controls the robot 10 to take a stand-by posture relative to the destination (step S105). Then, the operation control section 21b controls the robot 10 to move to the destination and hand the substrate 100 to the destination (step S106). Thus, the conveyance operation ends. In the case of the cylindrical coordinates control, the operation control section 21b controls the robot 10 to convey the substrate 100 along a tangent on the circle C (see
When at step S102 the selection section 21ba has determined that the conveyance track to the destination does not match the tangent (No at step S102), the switch section 21bb of the operation control section 21b determines whether the current control is the cylindrical coordinates control (step S107). When the current control is the cylindrical coordinates control (Yes at step S107), the cylindrical coordinates control is switched to the orthogonal coordinates control (step S108), and the conveyance operation proceeds to step S105. When the current control is the orthogonal coordinates control (No at step S107), step S108 is skipped to step S105.
While in the embodiment of
As illustrated in
An aid member 70, which is shaded in
The use of the aid member 70 more reliably prevents the wobbling of the body 10a while the robot 10 is in operation. While in
Insofar as the aid member 70 is capable of preventing the wobbling of the body 10a, the shape of the aid member 70 may be other than the shape illustrated in
By referring to
As illustrated in
As has been described hereinbefore, the conveyance system 1 according to this embodiment includes the conveyance chamber 50 and the robot 10. The conveyance chamber 50 includes the first side wall 51 and the second side wall 52. On the first side wall 51, the cassettes 200 are disposed. The cassettes 200 contain the substrates 100. The second side wall 52 is opposed to the first side wall 51. The robot 10 is disposed in the conveyance chamber 50, and includes the body 10a, the first arm 11, the second arm 12, and the hand 13. The first base end of the first arm 11 is turnably connected to the body 10a. The second base end of the second arm 12 is turnably connected to the first leading end of the first arm 11. The hand base end of the hand 13 is turnably connected to the second leading end of the second arm 12. The hand 13 is configured to hold a substrate 100.
The conveyance chamber 50 includes the restricted position P1 and the reference position P2. The restricted position P1 is located at the first distance D1 from the side of the first side wall 51 inside the conveyance chamber 50 toward the second side wall 52, and the robot 10 passing beyond the restricted position P1 is limited. The reference position P2 is located at the second distance D2 from the restricted position P1 toward the second side wall 52, and indicates the installment position at which the robot 10 is to be installed. The body 10a of the robot 10 is located on the side of the reference position P2 facing the second side wall 52. The inter-axis distance of the second arm 12 is longer than the inter-axis distance of the first arm 11. With the robot 10 taking such a normal posture that the first arm 11 and the second arm 12 overlap each other and are perpendicular to the first side wall 51, the second leading end of the second arm 12 is located between the restricted position P1 and the reference position P2.
With this configuration, the conveyance system 1 according to this embodiment makes the first arm 11 and the second arm 12 as long as possible without interference with the conveyance chamber 50, improving conveyance efficiency without increase in costs.
The method according to this embodiment for controlling the robot 10 uses the robot 10. The robot 10 includes the body 10a, the first arm 11, the second arm 12, and the hand 13. The first base end of the first arm 11 is turnably connected to the body 10a. The second base end of the second arm 12 is turnably connected to the first leading end of the first arm 11. The hand base end of the hand 13 is turnably connected to the second leading end of the second arm 12. The hand 13 is configured to hold a substrate 100. The inter-axis distance of the first arm 11 and the inter-axis distance of the second arm 12 are different from each other.
The method includes: controlling the robot 10 to store the difference between the inter-axis distance of the first arm 11 and the inter-axis distance of the second arm 12 as the link length difference 22a; and controlling the robot 10 to convey the substrate 100 along a tangent on the circle C, which is centered about the turning axis of the first arm 11 (the first axis A1) and which has a radius equal to the link length difference 22a.
With this configuration, the method according to this embodiment for controlling the robot 10 enables best use of the rotational speeds of the first aim 11, the second arm 12, and the hand 13, resulting in expedited conveyance of the substrates 100. In other words, the method according to this embodiment for controlling the robot 10 increases substrate conveyance throughputs.
Obviously, numerous modifications and variations of the present disclosure are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the present disclosure may be practiced otherwise than as specifically described herein.
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Number | Date | Country | |
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20170294334 A1 | Oct 2017 | US |