JP2017039181A - Robot control device, robot, and robot system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To downsize a robot control device.SOLUTION: A robot control device is equipped with a power supply substrate including a power supply circuit; and a drive substrate including a drive circuit driving a robot by power supplied from the power supply substrate. In a thickness direction of the power supply substrate, a distance between a surface of the power supply substrate provided with the power supply circuit and a surface of the drive substrate provided with the drive circuit, is shorted than the maximum height of the power supply substrate.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a robot control apparatus.

  2. Description of the Related Art Conventionally, a configuration is known in which a robot control device is connected to a robot, and the robot is driven by power, signals, etc. supplied from the robot control device. For example, Patent Document 1 discloses a configuration in which a substrate is arranged in a housing, electric power and signals to be supplied to the robot are generated by a circuit on the substrate, and these electric power and signals are supplied to the robot by wiring. ing.

JP, 2014-104573, A

  In the conventional technology described above, the substrates disposed in the housing include a substrate disposed in parallel to the bottom surface of the housing and a substrate disposed perpendicular to the bottom surface of the housing. The substrate is generally plate-shaped, and the direction perpendicular to the thickness direction has an extremely long length compared to the thickness direction. Therefore, in a configuration in which a substrate disposed parallel to the bottom surface and a substrate disposed perpendicular to the bottom surface coexist, when these substrates are built in the housing, both the direction parallel to the bottom surface and the direction perpendicular to the bottom surface Requires a long space. Therefore, it is difficult to reduce the size of the housing of the robot control unit.

  A robot control apparatus for solving at least one of the above problems includes a power supply board including a power supply circuit, and a drive board including a drive circuit that drives the robot with electric power supplied from the power supply board. In the thickness direction, the distance between the surface of the power supply substrate provided with the power supply circuit and the surface of the drive substrate provided with the drive circuit is shorter than the maximum height of the power supply substrate. Such a configuration can be realized, for example, by a configuration in which the drive substrate is disposed within a range in the height direction of the maximum height portion of the power supply substrate.

  That is, in the configuration in which the robot control device includes the power supply board and the drive board, the drive board is arranged so as not to protrude from the upper and lower sides in the height direction from both ends in the height direction of the power supply board. Therefore, the height of the structure composed of both the power supply substrate and the drive substrate does not exceed the maximum height of the power supply substrate. For this reason, it can prevent that the magnitude | size of the height direction of the robot control apparatus provided with a power supply board and a drive board becomes large too much. As a result, the robot controller can be downsized.

  Furthermore, in the configuration in which each substrate is arranged on the same plane, the degree of freedom in circuit design is higher than in the configuration in which each substrate is not arranged on the same plane.

  Further, the robot control device may include a housing, and the substrate may be disposed in the housing. As an example of such a configuration, the robot control apparatus includes a plurality of substrates including a power supply substrate and a drive substrate, and the substrate having the largest number of interfaces to external wiring among the plurality of substrates is the plurality of substrates. Instead of the substrate having the least number of interfaces to the external wiring, a configuration may be employed in which the housing is disposed near the front surface of the housing. That is, power and signals are supplied to the substrate in the housing by external wiring existing outside the housing, and power and signals are supplied from the substrate in the housing to external robots and the like by external wiring.

  If a board with many interfaces to the external wiring is placed at a position far from the front of the housing, it is necessary to secure a sufficiently long length for many internal wirings. There will be a lot of internal wiring in the body. Therefore, the board having the largest interface to the external wiring among the plurality of boards is arranged closer to the front of the casing inside the casing than the board having the least interface to the external wiring among the plurality of boards. With this configuration, the internal wiring can be shortened.

  Furthermore, the structure provided with the fan arrange | positioned in the position near a drive board | substrate rather than a power supply board | substrate may be sufficient. If it is a structure provided with the fan arrange | positioned in the position near a drive board rather than a power supply board, it will become possible to cool the drive circuit of a drive board efficiently.

  Furthermore, the structure which a fan is located in a different surface from the front of a housing | casing may be sufficient. If it is this structure, a fan can be arrange | positioned in the position far from the user who can work on the front side of a housing | casing, and it becomes a noise countermeasure.

  Furthermore, a configuration in which the height of the robot control device is 30 mm or more and 89 mm or less may be employed. With this configuration, it is possible to provide a robot control device that can be installed in a rack mount standard of 2U (1.75 inches × 2).

  Further, the robot control device may include a control board including a control circuit for controlling the robot, and the control board may be arranged on the same plane as the power supply board.

  Furthermore, in a configuration in which the robot includes a plurality of drive units, the configuration in which the plurality of drive units are driven by the same drive substrate may be employed. In this configuration, it is possible to drive a robot having a plurality of drive units by a drive circuit on a single drive substrate. Therefore, the driving substrate is easily arranged in a thin space as compared with a configuration in which a plurality of driving units are driven by a plurality of driving substrates (for example, a configuration in which one driving unit is driven by one driving substrate). It is possible. Therefore, the robot control device can be easily reduced in thickness.

  Furthermore, the technical idea of the robot control device as described above may be embodied as a robot controlled by the robot control device or a robot system including the robot and the robot control device, and adopts various configurations. Is possible.

(1A) is a block diagram illustrating a robot system according to an embodiment of the present invention, and (1B) is a diagram illustrating a robot control device installed in a cell. (2A) is a perspective view of the robot control device, and (2B) is a perspective view of the second unit. (3A) is a perspective view showing an example of internal wiring of the second unit, and (3B) is a perspective view showing a comparative example of internal wiring of the second unit. (4A) to (4F) are perspective views of the cover. (5A) and (5B) are perspective views of the robot control device, and (5C) is a perspective view showing a part of the second unit including a handle.

Here, embodiments of the present invention will be described in the following order.
(1) Configuration of the robot controller:
(1-1) Configuration of the housing:
(1-2) Internal configuration of second unit:
(1-3) Cover configuration:
(2) Other embodiments:

(1) Configuration of the robot controller:
FIG. 1A is a block diagram showing a configuration of a robot system 10 according to an embodiment of the present invention. The robot system 10 according to the present embodiment includes a robot control device 20 and a robot 30. The robot control device 20 includes various circuits for controlling the robot 30. The robot 30 is configured to realize a predetermined function by driving a plurality of driving units. In this embodiment, each drive unit is driven by a motor. The robot control device 20 and the robot 30 are connected by external wiring, and power and signals are exchanged between the robot control device 20 and the robot 30 via the external wiring.

  Furthermore, the robot controller 20 can be supplied with electric power from an external power source via an external wiring (not shown). In the present embodiment, the robot 30 is installed on the top of the cell 40. The cell 40 is a structure in which various devices including the robot control device 20 can be installed inside, and in this embodiment, the corner extends in a direction perpendicular to the one surface at four corners of a rectangular parallelepiped member and one surface of the rectangular parallelepiped. A structure having a columnar member. FIG. 1A shows an example in which a UPS (Uninterruptible Power Supply) 41 is installed in the cell 40 as a device other than the robot control device 20.

  FIG. 1B is a perspective view showing a state where the robot control device 20 is installed in the cell 40. In the present embodiment, when the user operates the robot 30 or the robot control device 20, the position where the user is present is regarded as the front of the robot control device 20, and the surface facing the front is regarded as the back. Also, the top and bottom are defined along the vertical direction, and surfaces other than the top surface and the bottom surface are regarded as side surfaces. The bottom surface of the cell 40 is substantially square, for example, a surface of 600 mm × 600 mm. In the cell 40, four prismatic members extend perpendicularly to the bottom surface, so that a device having a length slightly shorter than one side of the bottom surface can be freely put in and out of the cell 40.

  FIG. 2A is a perspective view showing the robot control device 20 extracted. In this embodiment, the robot control device 20 has a substantially rectangular parallelepiped shape, the width W (distance between the side surfaces) is 440 mm, the depth D (distance between the front surface and the back surface) is 430 mm, and the height H (distance between the top surface and the bottom surface). Is 70 mm. In the present embodiment, the housing of the robot control device 20 includes a hexahedron part, and covers 230 and 231 and covers 210 and 211 attached to the front and side surfaces of the hexahedron.

(1-1) Configuration of the housing:
In the present embodiment, the robot control device 20 is separable. That is, the housing of the robot control device 20 includes the first unit 21 and the second unit 22 provided with a robot control unit (a power board 220, a drive board 221, and a control board 222, which will be described later) for controlling the robot 30. It has. The first unit 21 can be fixed to the cell 40 with a screw or the like, and the second unit 22 can be pulled out from the first unit 21 with the first unit 21 installed in the cell 40 to separate them. Is possible.

  In the present embodiment, the first unit 21 configures the top, bottom, and side surfaces of the rectangular parallelepiped portion of the robot control device 20, and the second unit 22 includes the front, back, and bottom surfaces of the rectangular parallelepiped portion of the robot control device 20. Configure. That is, the first unit 21 is a cylindrical body having a rectangular opening, and the second unit is a structure formed by vertically extending the front surface and the back surface from the bottom surface.

  In the configuration having such a surface, the back surface of the second unit 22 has a size and a shape that can be inserted from the opening of the first unit 21. In addition, with the back surface of the second unit 22 inserted into the opening of the first unit 21, the front and back (in the direction perpendicular to the front and back surfaces) while the bottom surface of the second unit 22 is disposed on the bottom surface of the first unit 21. ). Therefore, in this embodiment, it is possible to pull out the second unit 22 from the first unit 21 installed in the cell 40.

  Further, the first unit 21 includes a restricting portion that restricts the amount of insertion of the first unit 21 into the second unit 22 and does not restrict the withdrawal of the first unit 21 from the second unit 22. Specifically, the second unit 22 is inserted into the first unit 21 so that the second unit 22 cannot be inserted into the back side of the state where the back surface of the second unit coincides with the end surface on the back side of the first unit 21. The first unit 21 is provided with a stopper that regulates the above. The stopper can be realized by various configurations. For example, in the perspective view shown in FIG. 5B, the first unit 21 is provided with a protrusion 210c, and the protrusion 210c contacts the second unit 22 for insertion. The regulated configuration is shown.

  If it is this structure, excessive insertion of the 2nd unit 22 with respect to the 1st unit 21 will be prevented by the control part, and appropriate positioning will be made. On the other hand, when the second unit 22 is pulled out, the second unit 22 can be pulled out from the first unit 21 because it is not regulated by the regulating unit. Of course, in a state where the second unit 22 is restricted by the restriction portion of the first unit 21, the first unit 21 and the second unit may be fixed by screws or the like.

  According to the above configuration, in a state where the robot control device 20 is installed in the cell 40, the second unit 22 can be separated from the first unit 21 and transported to a place where it is easy to work. Therefore, it is possible to easily maintain the robot controller provided in the second unit 22.

(1-2) Internal configuration of second unit:
FIG. 2B is a perspective view showing the internal structure of the second unit 22. As shown in the figure, the second unit 22 has a plurality of substrates attached thereto. Specifically, the power supply board 220, the drive board 221, and the control board 222 are attached to the second unit 22.

  The power supply board 220 includes a power supply circuit. The power supply circuit formed on the power supply board 220 is a circuit that generates power to be supplied to the drive board 221 and the control board 222, and is supplied from an external power supply (in this embodiment, power supplied from the UPS). ) Frequency and voltage are converted and supplied to each substrate. For this purpose, mounting components 220a such as a plurality of transformers and noise filters are mounted on the power supply substrate 220.

  The drive board 221 includes a drive circuit that drives the robot 30 with electric power supplied from the power supply board 220. The drive circuit formed on the drive substrate 221 is a circuit for driving each motor included in the robot 30 and generates electric power to be supplied to one motor by one chip. Therefore, in this embodiment, a plurality of chips (221a to 221f) are mounted on the drive substrate 221 in order to supply electric power to each of the plurality of motors. In the present embodiment, the chips 221a to 221f include a circuit that converts the frequency and voltage of power supplied from the power supply board 220 into three-phase alternating current, and each motor of the robot 30 is driven with three-phase alternating current. .

  As described above, in this embodiment, each driving unit included in the robot 30 is driven by the driving circuit on the single driving substrate 221. That is, in the present embodiment, electric power to be supplied to one motor is generated by one chip (any one of 221a to 221f), and all the chips 221a to 221f are a single drive substrate 221. Implemented above. Therefore, in this embodiment, all the electric power to be supplied to the motor of the robot 30 is generated by the drive circuit on the single drive board 221. Therefore, a driving circuit can be formed in a thin space as compared with a configuration in which a plurality of driving units are driven by a plurality of driving substrates. Therefore, the robot controller 20 can be easily made thin.

  The control board 222 includes a control circuit that controls the robot 30. The control circuit formed on the control board 222 is a circuit that controls the operation of the robot 30, and includes a control unit 222a configured by a CPU, a ROM, a RAM, and the like. The control unit 222a can execute a predetermined control program, and the control unit 222a or the like outputs a control signal to the robot 30 according to the control program, thereby causing the robot 30 to execute a predetermined operation.

  The robot control device 20 includes the power supply board 220, the drive board 221, and the control board 222 described above. In the present embodiment, the drive board 221 and the control board 222 have the maximum height portion of the power supply board 220. It is arranged within the range of the vertical direction. Here, in the power supply board 220, the maximum height part is the highest part among the mounting parts 220a of the power supply board 220, and the range in the height direction of the maximum height part is within the mounting part 220a. This is a range R formed by the sum of the height of the highest portion (Hmax shown in FIG. 2B) and the thickness of the power supply substrate 220. That is, the range R in the height direction of the maximum height portion of the power supply substrate 220 is a range sandwiched between both ends of the power supply substrate 220 in the height direction.

  In the present embodiment, the drive board 221 and the control board 222 are arranged so as to be included in the range R, that is, not to protrude above and below the range R in the height direction. Therefore, in the present embodiment, the height of the structure including the power supply substrate 220, the drive substrate 221, and the control substrate 222 does not exceed the maximum height of the power supply substrate 220. For this reason, it is possible to prevent the robot control device 20 including the power supply substrate 220, the drive substrate 221 and the control substrate 222 from being excessively large in the height direction. For this reason, the robot control device 20 can be reduced in size.

  In the present embodiment, the drive board 221 and the control board 222 are arranged on the same plane as the power supply board 220, so that the drive board 221 and the control board 222 have the maximum height of the power supply board 220. It is comprised so that it may be included in the range of a horizontal direction. With the above configuration, the drive substrate 221 can be easily arranged in the range in the height direction of the maximum height portion of the power supply substrate 220. In addition, according to the above configuration, the visibility of each substrate, the circuit on the substrate, the mounted component, etc. is improved compared to a configuration in which each substrate is not arranged on the same plane, and the work related to the component is also easy. become.

  Furthermore, the degree of freedom in circuit design is higher than in a configuration in which the substrates are not arranged on the same plane. For example, in a configuration in which the substrates are not arranged on the same plane, if the terminals of the internal wiring connected between the substrates are arranged on the edge of the substrate, the workability is lowered, and the positions of the terminals are easily restricted. However, if the substrates are arranged on the same plane, the internal wiring can be connected even if the terminals are arranged on the edge of the substrate.

  Note that, in the circuit arranged inside the robot control device 20, the volume of the power supply circuit that receives power from an external power supply and performs power conversion or the like is generally the largest. That is, in order to configure the power supply circuit on the power supply substrate 220, a bulk-like component having a height larger than the substrate thickness in the height direction from the mounting surface of the substrate such as a transformer is required. On the other hand, in the drive board 221, it is only necessary to generate electric power processed by the power supply board 220 and generate a three-phase alternating current for driving the motor. Can be made smaller chips 221a to 221f. The same applies to the control board 222, and the height of the bulk component can be made smaller than that of the mounting component 220a on the power supply board 220.

  Therefore, in the present embodiment, the maximum height of the power supply board 220> the maximum height of the drive board 221, and the maximum height of the power supply board 220> the maximum height of the control board 222. For this reason, the height of the robot controller 20 is reduced by disposing the drive board 221 and the control board 222 within the range in the height direction of the maximum height portion of the power supply board 220 as in this embodiment. It becomes possible.

  Further, in the present embodiment, the power supply board 220, the drive board 221, and the control board 222 are arranged at positions that do not overlap when the power supply board 220, the drive board 221, and the control board 222 are viewed from the top surface of the casing. Has been. In other words, when a plurality of substrates are projected in a direction perpendicular to the bottom surface, the projections of the plurality of substrates on the bottom surface do not overlap. According to this configuration, when performing maintenance on a certain substrate, other substrates are unlikely to become an obstacle.

  In this embodiment, the power supply board 220 and the control board 222 are arranged on the front side, and the drive board 221 is arranged on the back side. Among the plurality of boards, the board having the most interfaces to the external wiring is a plurality of boards. The board is arranged closer to the front of the casing inside the casing than the board having the smallest interface to the external wiring. That is, power and signals are supplied to the power supply board 220, the drive board 221, and the control board 222 in the casing including the first unit 21 and the second unit by external wiring existing outside the casing. Electric power and signals are supplied from the substrate to the external robot 30 and the like by external wiring.

  As shown in FIG. 2B, holes for attaching various connectors are formed on the front surface of the second unit 22, and each board in the housing and external devices (UPS, robot 30 and the like) are formed through these holes. Connected. Since it is necessary to connect external wiring to the connector, it is preferable that the wiring is concentrated in a small number of locations. In the present embodiment, the connector is used so that external wiring can be connected only to the front surface of the second unit 22. (A connector hole is not provided on a surface other than the front surface of the second unit 22).

  Usually, the internal wiring extending from the substrate is connected to the external wiring through a connection portion such as a connector, but the number of internal wirings to be connected to make such a connection differs depending on the substrate. Therefore, the board with the largest interface to the external wiring (in this example, the internal wiring connected to the external wiring) is closer to the front of the housing inside the housing than the board with the fewest interfaces to the external wiring. If it is set as the arrangement | positioning, the internal wiring in a housing | casing can be concentrated on the front of a housing | casing as much as possible. FIG. 3A is a diagram schematically showing internal wiring extending from the power supply board 220, the drive board 221, and the control board 222 to a connector attached to the front surface of the second unit 22, and the internal wiring is indicated by a thick curve. In the present embodiment, as shown in FIG. 3A, the number of internal wirings connected to the control board 222> the number of internal wirings connected to the power supply board 220> the number of internal wirings connected to the drive board 221. is there.

  Each internal wiring is connected to a connection portion such as a connector, and external wiring is connected to the connection portion. Therefore, the number of internal wirings to be connected is control board 222> power supply board 220> drive board 221. In the embodiment, the board having the largest interface to the external wiring is arranged closer to the front of the casing inside the casing than the board having the smallest interface to the external wiring. On the other hand, FIG. 3B changes the positions of the power supply board 220, the drive board 221, and the control board 222 in the second unit 22, and arranges the drive board 221 with the least interface to the external wiring near the front of the housing. The example of a structure in the case of having carried out is shown. Again, the internal wiring is shown by a thick curve.

  As shown in FIG. 3B, in a configuration in which a board with few interfaces to external wiring is arranged closer to the front of the casing inside the casing than a board with many interfaces, this arrangement is not shown in FIG. 3A. Compared with the configuration, the length of the internal wiring becomes long. That is, if a board with many interfaces to external wiring is arranged at a position far from the front of the housing, a long wiring is required for many internal wirings. As a result, it becomes difficult to handle the internal wiring, and many internal wirings exist in the housing. However, if the board having a relatively large number of interfaces to the external wiring is arranged closer to the front surface than the board having a relatively small number, the internal wiring can be minimized. Furthermore, when the connection parts to the external wiring are concentrated on the front surface of the housing, the user of the robot control device 20 only needs to perform the external wiring connection work on the front surface of the robot control device 20, and the maintenance work can be performed. It becomes extremely easy.

  Furthermore, in this embodiment, as shown in FIG. 2B, a fan 221g is provided on the back surface of the second unit. That is, on the back surface of the second unit, the fan 221g is attached so that the main body of the fan 221g is disposed above the drive substrate 221 and inside the housing. As a result, in the present embodiment, the fan 221g is disposed at a position closer to the drive board 221 than the power supply board 220 and the control board 222.

  In this embodiment, the robot 30 includes a plurality of driving units, and motors that drive the driving units are driven by the chips 221a to 221f. Since these chips 221a to 221f include a power conversion unit for generating electric power for driving the motor, the same number of heating elements (chips) as the number of motors of the robot 30 are provided on the driving substrate 221. 221a to 221f) exist. Therefore, if the fan 221g is disposed at a position closer to the drive substrate 221 than the power supply substrate 220, the chips 221a to 221f of the drive substrate 221 can be efficiently cooled.

  In this embodiment, since the fan 221g is attached to the rear surface of the housing (see FIG. 5B), the fan 221g can be arranged at a position far from the user who can work on the front surface side of the housing. Become. Furthermore, in this embodiment, since the fan 221g is located on the back surface of the second unit 22, the second unit 22 is separated from the first unit 21 together with the fan 221g by pulling out the second unit 22 from the first unit 21. Therefore, the fan 221g can be easily maintained.

  As described above, in the present embodiment, the robot controller 20 is thinned by disposing the drive board 221 and the control board 222 within the range in the height direction of the maximum height portion of the power supply board 220. Is adopted. As a result, the height of the housing of the robot control device 20 becomes 70 mm, and the robot control device 20 that can be installed in the range of 2U (1.75 inches × 2) of the rack mount standard can be provided.

(1-3) Cover configuration:
4A and 4B are covers 230, FIGS. 4C and 4D are covers 231, FIG. 4E is a cover 211, and FIG. 4F is a perspective view showing the structure of the cover 210. 4A shows the cover 230 viewed from the same direction as FIG. 2A, FIG. 4B shows the cover 230 viewed from the back side of FIG. 2A, and FIG. 4C shows the cover 231 from the same direction as FIG. FIG. 4D shows a state where the cover 231 is viewed from the back side of FIG. 2A. 4E and 4F show the covers 211 and 210 viewed from the same direction as in FIG. 2A, and show the covers 211 and 210 in a separated state.

  4A and 4B, the cover 230 is formed of a thin plate-like member, and two of the six surfaces of the rectangular parallelepiped (the back surface and one side surface in the direction illustrated in FIG. 2A) are omitted. It is a shape, and one ridge has a round shape. As shown in FIGS. 4C and 4D, the cover 231 has the same structure as the cover 230, but the side surfaces omitted from the six surfaces of the rectangular parallelepiped are side surfaces at positions different from the cover 230. That is, the cover 230 is attached to the cover 210 side on the front surface of the housing shown in FIG. 2A, and the cover 210 side is open in this state. The cover 231 is the cover 211 on the front surface of the housing shown in FIG. 2A. It is attached to the side, and in this state, the cover 211 is open. Further, the lengths and heights of the covers 230 and 231 are different. That is, the cover 230 has a longer length in the width direction shown in FIG. 2A than the cover 231, and the cover 230 has a shorter length in the height direction shown in FIG. 2A than the cover 231. As a result, when the cover 230 is attached to the front surface of the second unit 22, the vent is exposed above the cover 230, and a part of the connector on the front surface of the second unit 22 is exposed between the covers 230 and 231. It is configured as follows.

  As shown in FIG. 4E, the cover 211 is formed of a thin plate-like member, and includes a rectangular thin plate-like first member 211a and a second member 211b having two rectangular surfaces orthogonal to each other. The rectangular surface of the first member 211a and the smaller rectangular surface of the second member 211b have substantially the same shape, and the first member 211a can be attached to the second member 211b with both surfaces facing each other. it can. The cover 210 has the same structure as that in FIG. 4F. In the present embodiment, the covers 210 and 211 have the same length in the depth direction of FIG. 2A and are shorter than the length of the first unit 21 in the depth direction. Of course, the lengths of the covers 210 and 211 may be different. For example, in one of the covers 210 and 211, the length in the depth direction may coincide with the length in the depth direction of the first unit 21.

  The covers 230 and 231 and the covers 210 and 211 are attached to the casing so that a space inside each cover (between the cover and the outer surface of the casing) serves as a path for external wiring. Specifically, the covers 230 and 231 are attached to the front surface of the housing of the robot control device 20. In addition, the covers 230 and 231 are attached so that a space formed by the covers 230 and 231 and the front surface of the housing of the robot control device 20 opens on the side surface side. FIGS. 5A and 5B show that the covers 230 and 231 and the covers 210 and 211 are attached to the housing of the robot control device 20 in a state where external wiring is attached to the front connection portion (connector or the like) of the robot control device 20. FIG.

  In FIG. 5A and FIG. 5B, the external wiring is shown by a black solid curve, and FIG. 5A is a diagram showing the robot controller 20 viewed from the front side and FIG. In this embodiment, when the covers 230 and 231 are attached to the front surface of the housing of the robot control apparatus 20, openings are formed on the side surfaces as shown in FIGS. 5A and 5B. In the present embodiment, the external wiring connected to the connection portion on the front surface of the housing of the robot control device 20 passes between the covers 230 and 231 and the front surface of the housing, and is routed to the opening side on the side surface side. Yes.

  The covers 210 and 211 are attached to the side surface of the housing of the robot control device 20. When the covers 210 and 211 are attached to the side surfaces, spaces are formed between the covers 210 and 211 and the side surface of the housing of the robot control device 20, and the front side and the back side are opened. In the present embodiment, external wiring routed from an opening formed between the covers 230 and 231 and the front surface of the housing of the robot control apparatus 20 passes between the covers 210 and 211 and the side surface of the housing. The street is routed to the back side. As described above, in the present embodiment, the external wiring is routed to the back side along the front and side surfaces by the covers 230, 231, 210, and 211. Note that there are connectors that are not covered by the covers 230 and 231 in front of the second unit 22. The external wiring connected to these connectors is used, for example, when the user works in front of the second unit 22.

  In the present embodiment, the covers 230 and 231 are detachable. Various configurations can be adopted as the configuration for making the covers 230 and 231 detachable. For example, a configuration in which the covers 230 and 231 can be attached and detached with screws or the like can be adopted. Furthermore, in the present embodiment, as shown in FIG. 2B, an external wiring connection portion is provided only on the front surface of the second unit 22 (the front surface of the housing of the robot control device 20). Therefore, the user can easily attach / detach external wiring to / from the connecting portion existing in front of the second unit 22 with the robot control device 20 installed in the cell 40 and the covers 230 and 231 removed. is there.

  Furthermore, in the present embodiment, it is possible to pull out the second unit 22 from the first unit 21 and separate them from each other while the robot control device 20 is installed in the cell 40. Then, when the second unit 22 is pulled out from the first unit 21 with the external wiring removed from the front connection portion of the second unit 22, the external wiring is connected to the first unit 21 side (the covers 210 and 211 and the first unit 21). It is possible to pull out the second unit 22 in a state of being left between the two sides. Therefore, when the external wiring is removed from the connection portion, the second unit 22 installed in the installation portion can be easily pulled out without applying a load to the external wiring.

  Further, when the second unit 22 is attached to the first unit 21, the second unit 22 is inserted into the first unit 21 with the first unit 21 installed in the cell 40, and then the external wiring is connected to the connection portion. Can be attached. Therefore, it is not necessary to pull out the external wiring when performing maintenance of each board installed in the second unit 22, and work such as pulling the external wiring after the robot controller 20 is installed in the cell 40 occurs. do not do. For this reason, in the present embodiment, the length of the external wiring can be fixed in a predetermined state so that it can be installed in the cell 40. Therefore, it becomes easy to manage the extra length of the external wiring.

  Furthermore, in the above configuration, the external wiring passes through a predetermined path formed by the covers 230, 231, 210, and 211, and is directed from the front surface of the robot control device 20 to the back surface along the side surface. Therefore, in the robot control device 20, it is possible to route all external wiring connected to the connection portions covered by the covers 230 and 231 from the front to the back. Further, since the external wiring is routed by the cover, the length of the external wiring is defined by the cover and does not become excessively long. Therefore, management of external wiring outside the robot control device 20 is facilitated.

  Furthermore, since the covers 230 and 231 are detachable from the front surface of the second unit 22, it is possible to connect external wiring to the front surface of the housing in a state where the covers 230 and 231 are detached from the housing, thereby facilitating connection work. . The cover 210 can be separated into a first member 210a and a second member 210b, and the cover 211 can be separated into a first member 211a and a second member 211b. Accordingly, if the first members 210a and 211a are removed while the second members 210b and 211b are attached to the side surfaces of the first unit 21, external wiring is disposed between the side surfaces of the first unit 21 and the covers 210 and 211. It is possible to perform the work to do very easily.

  Furthermore, in the present embodiment, the external wiring can be routed to the back side by the covers 210 and 211, and an excessively large space is not required for the external wiring on the side surface of the first unit 21. Therefore, in a configuration in which the length in the width direction can be defined, for example, in the robot control device 20 or the like that can be installed in a rack mount, an excessively wide space is secured for the external wiring on the side surface constituting the end surface in the width direction. There is no need. For this reason, even if it is the structure which can prescribe | regulate the length of the width direction, it is not necessary to make the width | variety of the robot control apparatus 20 too small, and the internal space of the robot control apparatus 20 can fully be enlarged.

  Further, the length of the covers 210 and 211 in the depth direction is shorter than the length of the first unit 21 in the depth direction. That is, the end surfaces on the back side of the covers 210 and 211 are located on the front side of the back surface of the housing. Therefore, like the external wiring I shown in FIGS. 5A and 5B, the external wiring can be routed from the side surface side to another part instead of the back surface side.

(2) Other embodiments:
The above embodiment is an example for carrying out the present invention, and various other embodiments can be adopted. For example, the aspect of the robot system 10 is not limited to the aspect illustrated in FIG. 1A, and may be any other robot such as a double-arm robot, a humanoid robot, or a scalar robot. Furthermore, the robot control device may be thin, and the drive substrate 221 may be thinned by a configuration in which the drive substrate 221 exists outside the range of the maximum height portion of the power supply substrate 220 in the height direction. That is, in the thickness direction of the power supply substrate 220, the distance between the surface of the power supply substrate provided with the power supply circuit and the surface of the drive substrate provided with the drive circuit 221 is the maximum height of the power supply substrate 220 (FIG. 2B). It may be shorter than R) shown in FIG.

  Furthermore, a configuration in which a part of the configuration of the robot control device 20 described above is omitted or replaced may be used. For example, at least a part of the covers 230 and 231 may be omitted, and the external wiring may be mainly routed to the back surface along the front and side surfaces of the housing by the side covers 210 and 211.

  Furthermore, another configuration may be added to the robot control device 20. For example, the second unit may be provided with a handle parallel to the bottom surface. FIG. 5C is a perspective view showing a part of the second unit 22a provided with the handle. In FIG. 5C, the second unit 22a has substantially the same configuration as the second unit 22, but is different in that a handle 22b is provided on the front surface thereof. The handle 22b is composed of a rod-shaped member, and includes two parts extending perpendicularly to the front surface of the second unit 22a and one part extending parallel to the front surface of the second unit 22a so as to connect the parts. It has.

  The direction in which each part extends is parallel to the bottom surface of the second unit 22a. In this sense, the handle 22b is parallel to the bottom surface. In the example shown in FIG. 5C, the handle 22b is attached to the lower part of the front surface of the second unit 22a, and thus is attached at a position close to the bottom surface of the second unit 22a existing on the back side of the front surface. According to the above configuration, the user can easily pull out the second unit 22 using the handle 22b. Further, the force acting on the second unit 22a by the handle 22b is more likely to act as a force for pulling out the bottom surface than bending the front surface of the second unit 22a. In this sense, the user can easily pull out the second unit 22. Is possible.

Further, in the configuration shown in FIG. 5C, the end surface E ₂ of the handle 22b on the front side of the casing is on the back side of the end surface E ₁ of the casing on the front side. Therefore, in a state where the insertion of the second unit 22a to the first unit 21, the end face positioned closest to the front side is an end E ₁ of the housing, the end face E ₂ of the handle 22b is far from the end face E ₁ of the housing It is located on the side (back side). According to this configuration, the handle 22b does not protrude to the front side, and the handle 22b does not become an obstacle to the work of the user or the like when the user works on the covers 230, 231 and the like.

  The power supply board only needs to include a power supply circuit, and the power supply circuit only needs to be able to generate power to be supplied to another circuit (another board or robot). Such a power supply circuit, for example, receives power from an external power supply (for example, commercial power supply) supplied at a location where the robot controller is installed, and performs voltage conversion and frequency conversion (including DC / AC conversion). The circuit can be configured by a circuit that generates power to be supplied to other circuits.

  The drive board only needs to include a drive circuit that drives the robot with the electric power supplied from the power supply board, and the drive circuit only needs to be able to drive the robot. That is, the robot is configured to realize a predetermined function by driving at least one driving unit, and the driving circuit is configured by a circuit that drives the driving unit. The driving unit of the robot may be driven by various mechanisms. For example, a configuration in which the driving unit (joint or the like) of the robot is driven by operating a driving unit including a motor, a solenoid, or the like may be used.

  Note that, in a circuit arranged inside the robot control device, the volume of a power supply circuit that receives power from an external power supply and performs power conversion or the like is generally the largest. That is, in order to configure a power supply circuit, in many cases, it is necessary to mount a bulk component (such as a transformer) having a height larger than the substrate thickness in the height direction from the mounting surface of the substrate. On the other hand, since the drive board includes a drive circuit that uses power after the power supplied from the external power supply is converted by the power supply board, the drive circuit can generally be configured with a volume smaller than the volume of the power supply circuit.

  In such a case, since the maximum height of the power supply board> the maximum height of the drive board, the drive board is arranged within the range in the height direction of the maximum height portion of the power supply board. The height of the robot controller can be limited to a maximum height of the power supply board and is not affected by other boards. In the drive circuit provided in the drive board, a circuit that performs power conversion and power frequency conversion may be provided, but these circuits are not circuits that are directly supplied with power from an external power source. The components of the drive circuit are smaller than the components of the power supply circuit. For this reason, the state of the maximum height of the power supply substrate> the maximum height of the drive substrate can be realized.

  Various configurations can be adopted as the configuration for disposing the drive substrate within the range in the height direction of the maximum height portion of the power supply substrate. That is, the position of the upper end in the height direction of the drive board including the drive circuit is lower (or equal to) the position of the upper end in the height direction of the drive board including the power supply circuit, and the height of the drive board including the drive circuit is high. The position of the lower end in the vertical direction only needs to be above (or equal to) the position of the lower end in the height direction of the drive board including the power supply circuit, and within this range, the drive board can be arranged at any position. is there. The height direction may be a direction perpendicular to the mounting surface of the board. When the direction is the height direction, the width direction and the depth direction are perpendicular to the height direction and perpendicular to each other. Can be defined.

  In addition, since it is a power supply circuit that occupies the largest volume (having the highest part in the height direction) in the robot control device, the drive board is arranged in the height direction of the maximum height portion of the power supply board. By arranging within the range, the robot control device can be easily reduced in thickness. If the largest factor limiting the thinning inside the robot controller is the power supply board, the robot controller can be configured with a housing that can accommodate the maximum height of the power board. Is realized.

  Therefore, in the robot control apparatus thinned in this way, other parts may be incorporated in the housing as long as they are included in the height direction range of the maximum height portion of the power supply board. . In this case, the other component may be a bulk component or another substrate. The other substrate is preferably parallel to the power supply substrate and the drive substrate (there is no substrate perpendicular to the mounting surface of the power supply substrate), but is included within the range of the maximum height portion of the power supply substrate. In this case, the other board may be oriented perpendicular to the mounting surface of the power board.

  As a configuration example in which the drive substrate is arranged so as to be included in the range in the height direction of the maximum height portion of the power supply substrate, a configuration in which the drive substrate is arranged on the same plane as the power supply substrate may be adopted. . With this configuration, it is possible to easily dispose the drive substrate within the range in the height direction of the maximum height portion of the power supply substrate. In addition, according to the above configuration, the visibility of each substrate, the circuit on the substrate, the mounted component, etc. is improved compared to a configuration in which each substrate is not arranged on the same plane, and the work related to the component is also easy. become. Of course, in a configuration in which the robot control apparatus includes another substrate, for example, a control substrate including a control circuit for controlling the robot, the other substrate may be disposed on the same plane as the power supply substrate. .

  In order to arrange the substrates on the same plane, it is only necessary that the circuit design has a high degree of freedom. For example, in a configuration in which the substrates are not arranged on the same plane, the terminals of the internal wirings connected between the substrates (the internal wiring of the robot controller is referred to as internal wiring and the external wiring is referred to as external wiring) If it is arranged at the edge, the workability is lowered, and the position of the terminal is easily restricted. However, if the substrates are arranged on the same plane, the internal wiring can be connected even if the terminals are arranged on the edge of the substrate, and the degree of freedom in circuit design is increased. The state in which the substrates are arranged on the same plane is realized by arranging the reference positions of the respective substrates (for example, the bottom surface of the substrate and the mounting surface of the substrate) on substantially the same plane. Even if there are some errors (for example, a difference in mounting position of about ± 10 mm, warpage of the substrate, etc.), it is considered that each substrate exists on the same plane.

  In a configuration including a substrate in a housing, power and signals are supplied to the substrate in the housing via various terminals and internal wiring, and the power and signals are sent to the outside. For this reason, it is necessary to provide the connection part to external wiring in the outer surface of a housing | casing. In addition, it is preferable that a connection part is comprised by the connector etc., and is gathered in few places (preferably one place (if a polyhedral housing is a specific surface)). In other words, if the connecting portions are dispersed in a large number of locations, maintenance becomes difficult. For example, the connection work of the external wiring to the connection part becomes complicated, and the management of the extra length becomes difficult.

  Therefore, the board having the largest interface to the external wiring among the plurality of boards is arranged closer to the front of the casing inside the casing than the board having the least interface to the external wiring among the plurality of boards. With this configuration, it becomes easy to collect most of the internal wiring in the housing on the front surface of the housing. Note that if the connection parts (connectors, etc.) to the external wiring are concentrated on the front surface of the housing, the user of the robot control device only needs to connect the external wiring on the front surface of the robot control device. Work becomes extremely easy. The front surface of the housing may be a surface in a direction in which an operator is present when viewed from the housing in a state where the robot control device is installed in an installation unit (cell or the like) and operates. In this case, the side opposite to the direction in which the worker is present when viewed from the housing is the back side. Except for the front and back, it can change in the direction of installation to the robot controller's installation, but when the robot controller is a cuboid and a thin box-shaped housing, the surface sandwiched between the front and back One of the two large surfaces can be regarded as the top surface, the other as the bottom surface, and the remaining surfaces as the side surfaces.

  Generally, a robot is multi-joint and includes a plurality of individual drive units (motors, solenoids, etc.) for individually driving each joint. Since the drive substrate includes a drive circuit for driving the robot, the drive substrate often includes individual circuits (for example, a power conversion unit) for driving a plurality of drive units. Therefore, there are many cases where a plurality of heating elements (circuits) exist in the drive circuit provided in the drive substrate. For this reason, if it is a structure provided with the fan arrange | positioned in the position near a drive board | substrate rather than a power supply board | substrate, it will become possible to cool the drive circuit of a drive board | substrate efficiently. Of course, when a substrate other than the power supply substrate and the drive substrate exists in the housing, it is preferable to dispose the drive substrate at a position closest to the fan.

  In a configuration in which the fan is located on a surface different from the front surface of the housing, the surface different from the front surface may be any of the side surface, the back surface, the top surface, and the bottom surface, but the fan is provided on the back surface that is the farthest from the user. If so, the noise reduction effect is higher and preferable.

  The configuration in which the height of the robot control device is 30 mm or more and 89 mm or less can be easily realized by arranging the drive substrate within the range in the height direction of the maximum height portion of the power supply substrate. Various values can be adopted for the height range, and if the height is 1.75 inches (about 44.45 mm) or less, a robot control device that can be installed in a range of 1U can be provided. Is possible.

  In a configuration in which at least a part of the external wiring connected to the robot controller is routed by the cover along the front and side surfaces, all the external wiring connected to the connection portion covered by the cover is routed. It can be routed from the front to the back. Further, since the external wiring is routed by the cover, the length of the external wiring is defined by the cover and does not become excessively long. Therefore, management of external wiring outside the robot control device is facilitated.

  The cover may be any member that forms a path for external wiring when attached to the housing, and is configured so that the direction in which the external wiring is routed is specified by forming the path. Just do it. For example, if a cover having a surface facing the surface (front surface or side surface) of the housing is configured, a cover in which the space between the facing surface and the surface of the housing serves as a path for external wiring can be configured. The cover only needs to form a passage for external wiring, and the shape is not limited. Further, the shape may be determined according to the number of external wirings provided in the robot control device. Furthermore, the cover may be attached to the second unit or may be attached to the first unit.

  In the configuration where the external wiring connection is provided only on the front of the housing on the outer surface of the housing, it is not necessary to connect the external wiring to the connection in advance before installing the robot controller in the installation. Even if the length and route of the external wiring in the installation section are fixed to a predetermined state, the external wiring can be connected to the robot control device. Therefore, management of external wiring becomes easy. Also, if the external wiring is removed from the connection portion, the robot control device installed in the installation portion can be easily removed without applying a load to the external wiring.

  In a configuration in which at least a part of the cover is removable, the removable portion of the cover may be any shape and size that facilitates the external wiring connection work, even if the entire cover is removable. good. Further, in a configuration in which a plurality of covers are attached to the housing, some of them may be removable.

  In a configuration in which the length in the width direction can be defined, for example, in a robot control device that can be installed in a rack mount, the external wiring is routed along the side surface of the housing to the back side of the housing. For example, it is not necessary to secure an excessively large space for the external wiring on the side surface constituting the end surface in the width direction, and a wide space can be secured as a space that can be used as the robot control device.

  In a configuration in which the second unit can be separated from the first unit by pulling out the first unit, the second unit can be separated from the first unit. There is no need for wide spaces on the left and right sides of the control unit. Therefore, it is possible to provide a robot controller that can be easily maintained.

  The casing only needs to have the first unit and the second unit, and the casing including the first unit and the second unit forms the casing by constituting the outer surface of the robot control device. To do. When the robot control unit is installed in the installation unit, it is preferable that a part of the housing, for example, the first unit is fixed to the installation unit.

  The robot control unit includes a circuit for controlling the robot, and may be configured by one or more substrates including the circuit. Of course, it may be constituted by circuits, parts, etc. other than the substrate-like circuit. The circuit may be composed of circuits having various functions, for example, to supply power from an external power source to perform voltage conversion or frequency conversion, or to drive a robot drive unit (motor, actuator, etc.). And a circuit for controlling the operation of the movable part of the robot.

  The second unit only needs to be separable from the first unit by being pulled out from the first unit. Therefore, the second unit can be moved in at least one direction with respect to the first unit. By moving the second unit until the second unit and the first unit are not in contact with each other, the second unit can be moved. What is necessary is just to be comprised so that it can isolate | separate from a 1st unit.

  Various configurations can be adopted as the configuration for pulling out the second unit from the first unit, as long as the second unit can be moved relative to the first unit in at least one direction. For example, a configuration in which the contact portion between the first unit and the second unit is shaped to move the second unit in one direction can be employed. The contact part may be a rail or the like that regulates the moving direction of the second unit, or the shape of the contact part itself may be a shape that regulates the moving direction of the second unit. Examples of the latter include a configuration in which a recess capable of fitting the second unit into the first unit is formed, and a configuration in which the first unit has a shape into which the second unit can be inserted.

  Various configurations can be adopted as the configuration of the restricting portion, and it can be configured by a stopper or the like that regulates the movement of the second unit by contacting a predetermined portion such as an end surface of the second unit. Of course, the second unit may be fixable to the first unit in a state where movement is restricted.

  The casing may have any shape, but the casing has a rectangular parallelepiped portion, the first unit constitutes the top, bottom, and side surfaces of the rectangular parallelepiped portion of the casing, and the second unit is the casing. You may comprise the front of a rectangular parallelepiped part, a back surface, and a bottom face. That is, when the first unit constitutes the top surface, the bottom surface, and the side surface of the rectangular parallelepiped and the second unit constitutes the front surface, the back surface, and the bottom surface of the rectangular parallelepiped, the bottom surface of the second unit is disposed on the bottom surface of the first unit. However, if it is configured to be movable back and forth (perpendicular to the front and back surfaces), a second unit that can be pulled out from the first unit in a rectangular parallelepiped housing can be configured. In this case, the 2nd unit should just be a magnitude | size which can be inserted inside each surface with which a 1st unit is equipped.

  Note that the side surface of the first unit may be two surfaces or one surface. That is, if the side surface is two surfaces, the first unit is constituted by a cylindrical body having a rectangular opening, and if the side surface is one surface, there is no one surface of the cylindrical body having a rectangular opening. The first unit is composed of the structure.

  In a configuration in which the fan is located on a surface different from the front surface of the housing, the surface different from the front surface may be any of the side surface, the back surface, the top surface, and the bottom surface, but the fan is provided on the back surface that is the farthest from the user. If so, the noise reduction effect is higher and preferable. Furthermore, if the fan is located on the back side, the second unit can be separated from the first unit together with the fan by pulling out the second unit from the first unit, and the fan can be easily maintained. Is possible.

  In the configuration in which the connection portion of the external wiring is provided only on the front surface of the housing, the external wiring may be attached to and detached from the connection portion after the second unit is inserted into the first unit installed in the installation portion. Therefore, it is not necessary to connect the external wiring to the connection portion in a state where the second unit and the first unit are separated, and even if the length or route of the external wiring in the installation portion is fixed to a predetermined state, the connection portion External wiring can be connected to. Therefore, management of external wiring becomes easy. If the external wiring is removed from the connection portion, the second unit installed in the installation portion can be easily pulled out without applying a load to the external wiring.

DESCRIPTION OF SYMBOLS 10 ... Robot system, 20 ... Robot control apparatus, 21 ... 1st unit, 22 ... 2nd unit, 22a ... Unit, 22b ... Handle, 30 ... Robot, 40 ... Cell, 220 ... Power supply board, 220a ... Mounting component, 221 ... Drive board, 221g ... Fan, 222 ... Control board, 222a ... Control unit, 230, 231, 210, 211 ... Cover

Claims (11)

A power supply board including a power supply circuit;
A drive board including a drive circuit for driving the robot by the electric power supplied from the power supply board,
In the thickness direction of the power supply substrate, the distance between the surface of the power supply substrate provided with the power supply circuit and the surface of the drive substrate provided with the drive circuit is shorter than the maximum height of the power supply substrate. , Robot controller. The drive board is disposed within a range in the height direction of the maximum height portion of the power supply board,
The robot control apparatus according to claim 1. The drive board is disposed on the same plane as the power supply board,
The robot control apparatus according to claim 1 or 2. A plurality of substrate housings including the power supply substrate and the drive substrate;
The board having the largest interface to the external wiring among the plurality of boards is arranged closer to the front of the casing inside the casing than the board having the least interface to the external wiring among the plurality of boards. Being
The robot control apparatus according to any one of claims 1 to 3. A fan disposed at a position closer to the drive board than the power supply board;
The robot control device according to any one of claims 1 to 4. The fan is located on a different surface from the front of the housing;
The robot control apparatus according to any one of claims 1 to 5. The height is 30 mm or more and 89 mm or less,
The robot control device according to any one of claims 1 to 6. A control board including a control circuit for controlling the robot;
The control board is disposed on the same plane as the power supply board,
The robot control apparatus according to any one of claims 1 to 7. The robot includes a plurality of driving units,
The plurality of driving units are driven by the same driving substrate.
The robot control apparatus according to any one of claims 1 to 8.   A robot controlled by the robot control device according to claim 1. The robot controller according to any one of claims 1 to 10,
A robot controlled by the robot control device,
Robot system.

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