KR20150109215A - Device for assembling robot - Google Patents

Abstract

According to one embodiment of the present invention, provided is a robot assembling device which comprises: a storage unit for storing a 3D image file about a plurality of components constituting a robot, IDs, location information, feature information, and required voltage information of robot modules for operating the component respectively or related to the component operation, electrical connection information between the robot modules, and electrical connection information between the robot modules and a controller for controlling the robot modules; and a robot assembling viewer for displaying a 3D image about the components and displaying information about at least one robot module connectable to the controller and information about the robot modules which are connectable to each other on an assembling screen window.

Description

{DEVICE FOR ASSEMBLING ROBOT}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a robot assembling apparatus, and more particularly, to a robot assembling apparatus capable of assembling a robot using electrical connection of components constituting the robot.

2. Description of the Related Art [0002] With the recent development of the robot technology field, robots are being used in various industries, and there is an increasing demand to produce robots with ease.

Generally, robots should be assembled by taking into account not only the mechanical connection of the robot but also the electrical connection.

However, conventionally, only the mechanical connection when assembling robots is limited to physical aspects after robot assembly.

Accordingly, there is an urgent need to consider the electrical connection between the robot module including the battery, the controller, the actuator module, the sensor module, the communication module, and the display module while considering the physical assembly of the robot .

SUMMARY OF THE INVENTION It is an object of the present invention to provide a robot assembling apparatus that can assemble a robot using electrical connection of components constituting the robot.

The objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood from the following description.

According to an aspect of the present invention, there is provided an image processing apparatus including a 3D image file for a plurality of components constituting a robot, an ID for a plurality of robot modules associated with the plurality of components, A storage unit for storing position information, characteristic information, required voltage information, electrical connection information between the robot modules, and electrical connection information between the robot module and a controller for controlling the robot module; And displaying information on the at least one robot module connectable to the controller using the electrical connection information and information about the robot modules connectable to each other on the assembly screen window by displaying the 3D image for the plurality of components A robot assembly device is provided, including a robot assembly viewer.

Wherein the storage further stores information about a port formed in any one of the plurality of robot modules, information about a connector coupled with the port, and electrical connection information between the connector and the controller, And a controller for checking the connection direction, the size, and the number of pins of the port by using the electrical connection information, determining whether the port and the connector are connectable, May be displayed on the assembly screen window and a connector connectable with the controller may be displayed on the assembly screen window.

Wherein the storage unit further stores electrical connection information between the robot module and a battery supplying electricity to the robot module, wherein the robot assembly viewer displays a voltage required for operation of the robot module and a voltage So that the at least one robot module connectable to the battery can be displayed on the assembly screen window.

Wherein the robot assembly viewer further displays a 3D image for each of the plurality of components displayed on the assembly screen window and displays an ID assigned to each of the plurality of robot modules in the assembly screen window, An interface for adjusting the angle of the selected robot module with respect to time is further displayed on the assembly screen window, and the storage unit may further store angle adjustment information according to time inputted through the interface.

The robot assembly viewer may further display a moving image on which the component operated by the selected robot module moves, using the angle adjustment information, on the assembly screen window.

According to an embodiment of the present invention, a controller or a robot module connectable with a battery is displayed on a screen, thereby obtaining a relationship between components of a robot connected to each other according to electrical characteristics as well as mechanical connection.

Also, according to an embodiment of the present invention, by providing an interface capable of adjusting the angle of the robot module with respect to time, a simulated moving image of the robot can be easily provided.

It should be understood that the effects of the present invention are not limited to the above effects and include all effects that can be deduced from the detailed description of the present invention or the configuration of the invention described in the claims.

1 is a block diagram showing a configuration of a robot assembling apparatus according to an embodiment of the present invention.
2 is a view illustrating an assembly screen window for displaying a robot according to an embodiment of the present invention.
3 is a view showing an assembly screen window for displaying components constituting a robot according to an embodiment of the present invention.
4 is a view showing an assembly screen window displaying a robot according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when a part is referred to as being "connected" to another part, it includes not only "directly connected" but also "indirectly connected" . Also, when an element is referred to as "comprising ", it means that it can include other elements, not excluding other elements unless specifically stated otherwise.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing a configuration of a robot assembling apparatus according to an embodiment of the present invention.

Referring to FIG. 1, a robot assembling apparatus 100 according to an embodiment of the present invention may include a storage unit 110 and a robot assembly viewer 120.

The storage unit 110 may be configured as a memory of the robot assembling apparatus 100 including a program memory, a data memory, and the like.

Execution programs executed by the robot assembly viewer 120 may be stored in the program memory. For example, the storage unit 110 may store a first program capable of editing connection information between the robot modules, a second program capable of controlling the operation of each robot module, and the like in the program memory.

Data generated during the execution of the programs stored in the program memory by the robot assembly viewer 120 may be stored in the data memory. For example, the storage unit 110 stores electrical connection information between the robot module and the controller generated through the first program, electrical connection information between the robot module and the battery, electrical connection information between the robot modules, And a simulation video in which the robot generated through the second program moves can be stored.

The robot assembling apparatus 100 can execute the first program and the second program in association with each other and load the information generated through the first program in the second program. That is, the robot assembling apparatus 100 loads the information about the robot whose connection between the components of the robot is edited in the second program through the first program, and provides a simulation video in which the robot in which the operation of the robot is controlled moves can do.

The storage unit 110 may store 3D image files for various components of the robot. For example, the storage unit 110 may include a plurality of components constituting the robot, a plurality of robot modules associated with the components, a port formed on the robot module, and a connector coupled with the port, You can save the 3D image file to.

Here, the robot module may include an actuator module for operating a component, a communication module for communicating with an external device, a sensor module for sensing information by sensing a surrounding situation, and a display module for displaying information, but the present invention is not limited thereto , And various modules needed to configure the robot.

The storage unit 110 may store an ID assigned to each of the plurality of robot modules, position information of each of the robot modules, characteristic information of each of the robot modules, and voltage information necessary for operating each of the robot modules.

The storage unit 110 may store electrical connection information between the at least one robot module and the controller. Here, the electrical connection information indicates how the robot module and the controller are connected or can be connected, indicating how the controller is controlled by the controller for controlling the robot module and the robot module controlled by the controller, And may include electrical connection information between one controller and a plurality of robot modules, and may include electrical connection information between one controller and a plurality of robot modules.

The storage unit 110 may store electrical connection information between the at least one robot module and the battery. Here, the electrical connection information indicates how the robot module is connected between the battery supplying electricity to the robot module and the robot module receiving electricity from the battery, and is information indicating whether the robot module and the battery are connected or connectable. And may include electrical connection information between one battery and one or more robot modules.

The storage unit 110 may store electrical connection information between the plurality of robot modules. Here, the electrical connection information indicates how the plurality of robot modules are connected to each other, and is information indicating whether the robot modules are connected to each other or can be connected to each other. In this case, any one of the plurality of robot modules, Lt; / RTI >

The storage unit 110 may store information about a port formed in any one of the plurality of robot modules, information about a connector coupled to the port, and electrical connection information between the connector and the controller. Here, the electrical connection information indicates how the connector and the controller that transmits the control signal are connected through the connector, and is information indicating whether the connector and the controller are connected or connectable, and may include one controller and one or more connectors Lt; / RTI >

The storage unit 110 may store angle adjustment information according to time input through an interface for adjusting the angle of the robot module displayed by the robot assembly viewer 120 with time. In this regard, it will be described later with reference to Fig.

The robot assembly viewer 120 can display various information in an assembly screen window provided through the first program. At this time, the robot assembly viewer 120 can display information through one or more assembly screen windows. When information is displayed through a plurality of assembly screen windows, the robot assembly viewer 120 displays divided screen windows or superimposes the screen windows .

The robot assembly viewer 120 may display a 3D image file of various components of the robot stored in the storage unit 110 on the assembly screen window. At this time, the robot assembly viewer 120 can display the 3D image of each component separately on the assembly screen window, and display the 3D image of all or part of the robot combining the plurality of components on the assembly screen window It is possible.

The robot assembly viewer 120 displays a 3D image of various components of the robot on the assembly screen window and displays a screen change command (for example, move, enlarge, or reduce) A 3D image that changes according to the command can be further displayed in the assembly window.

The robot assembly viewer 120 displays one or more robot modules connected to the controller or one or more robot modules connectable to the controller on the assembly screen window using the electrical connection information between the robot module and the controller stored in the storage unit 110 .

That is, when the controller is selected according to the user's operation, the robot assembly viewer 120 may display one or more robot modules connected to the selected controller or one or more robot modules connectable to the controller, When selected, a controller connected to the selected robot module or a controller connectable to the robot module can be displayed.

The robot assembly viewer 120 may display one or more robot modules connected to the controller or a robot module connectable to the controller in a new assembly window, while displaying a 3D image of various components of the robot on the assembly window, One or more robotic modules associated with the controller may be highlighted (e.g., blinking or displaying the components in a different color).

The robot assembly viewer 120 can check the voltage of the robot module using the voltage information stored in the storage unit 110 and determine whether the robot module and the battery are connectable and display the connection availability on the assembly screen window. At this time, the robot assembly viewer 120 can compare the voltage required for the operation of the robot module with the voltage supplied by the battery, and determine whether the robot module and the battery are connectable.

In addition, the robot assembly viewer 120 may use at least one robot module connected to the battery or at least one robot module connectable to the battery, separately from the assembly screen window 120, using the electrical connection information between the robot module stored in the storage unit 110 and the battery And one or more robot modules connected to the battery can be highlighted and displayed.

The robot assembly viewer 120 can use one or more robot modules connected to a specific robot module or one or more robot modules connectable to a specific robot module by using the electrical connection information between the robot modules stored in the storage unit 110 Can be displayed.

For example, when the first robot module and the second robot module are set to be connectable, the robot assembly viewer 120 selects the first robot module according to an operation of the user, 2 robot module can be displayed. When the second robot module is selected according to the user's operation, the first robot module connectable to the second robot module can be displayed.

If the first robot module and the second robot module are connected to each other, the robot assembly viewer 120 can display the second robot module connected to the first robot module when the first robot module is selected If the second robot module is selected, the first robot module connected to the second robot module can be displayed.

The robot assembly viewer 120 may display a connector coupled to a port and a port formed in the robot module on the assembly screen window using information about the port stored in the storage unit 110 and information about the connector. At this time, the robot assembly viewer 120 displays a 3D image of various components of the robot on an assembly screen window, and can display an area where a port or a connector is displayed by a user's operation command or automatically enlarge and display.

When the port and the connector are displayed, the robot assembly viewer 120 checks the combining direction, the size, and the number of pins of the port using the information about the port. If it is determined that the port and the connector are connectable, The combined 3D image of the connector can be displayed in the assembly window. At this time, the robot assembly viewer 120 can compare the number of pins of the port with the number of pins of the connector to determine whether the port and the connector can be connected.

The robot assembly viewer 120 may display one or more connectors connected to the controller or one or more connectors connectable to the controller on the assembly screen window using the electrical connection information between the controller and the connector stored in the storage unit 110. [

The robot assembly viewer 120 can display the 3D images of the various components of the robot on the assembly screen window through the first program and display the IDs allocated to each of the plurality of robot modules stored in the storage unit 110 have.

When one or more robot modules among the plurality of robot modules are selected, the robot assembly viewer 120 may display the interface for adjusting the selected robot module through the second program on the assembly screen window by executing the second program, The moving image moving component operated by the robot module can be further displayed on the assembly screen window using the angle adjustment information stored in the storage unit 110. [ In this regard, it will be described later with reference to Fig.

2 is a view illustrating an assembly screen window for displaying a robot according to an embodiment of the present invention.

First, the robot assembly viewer 120 may display a 3D image of various components of the robot stored in the storage unit 110 on an assembly screen window.

2, the robot assembly viewer 120 can display the overall 3D image of the robot including the first robot module 201, the second robot module 202, the controller 203 and the battery 204 have. Here, the first robot module 201 and the second robot module 202 may be any one of various robot modules such as an actuator module, a communication module, a sensor module, and a display module.

The robot assembly viewer 120 may display a 3D image that is a part of the robot in addition to the overall 3D image of the robot and separately display the 3D image of one of the various components of the robot.

For example, the robot assembly viewer 120 displays an overall 3D image of the robot. When a command to enlarge the leg of the robot is inputted, only a leg portion of the robot can be enlarged to display a portion of the robot. The robot assembly viewer 120 displays detailed information on the controller 203 (controlled by the controller 203) while separately displaying the 3D image of the controller 203, when the controller 203 among the various components of the robot is selected And the detailed information about the battery 204 (connected to the battery 204) while displaying the 3D image of the battery 204 separately when the battery 204 is selected The robot module information, the voltage information of the electricity supplied by the battery 204, and the like).

The controller 203 and the battery 204 may be connected to one or more robot modules in which the controller 203 and the first robot module 201 and the second robot module 202 may be connected and the battery 204 And the first robot module 201 and the second robot module 202 can be connected to each other.

The storage unit 110 may store location information of the first robot module 201 and the second robot module 202. For example, the storage unit 110 may be configured such that the first robot module 201 is located in the left portion of the controller 203, the second robot module 202 is located in the right portion of the controller 203, May be stored in the lower portion of the controller 203. [0050]

2, the robot assembly viewer 120 displays an overall 3D image of the robot stored in the storage unit 110. When the controller 203 is selected according to a user operation, the controller 203 is highlighted and displayed The first robot module 201 and the second robot module 202 that can be connected to the controller 203 can also be emphasized and displayed. At this time, the robot assembly viewer 120 may display the controller 203, the first robot module 201 and the second robot module 202 by blinking or displaying colors different from those of other components Can be highlighted and displayed.

When a connection command between the controller 203 and the first robot module 201 is input according to a user's operation, the robot assembly viewer 120 receives the connection command between the controller 203 and the first robot module 201 stored in the storage unit 110, It is possible to determine whether the controller 203 and the first robot module 201 can be connected to each other, and display the determination result on the assembly screen window. At this time, a connection command between the plurality of robot modules including the first robot module 201 and the second robot module 202 and the controller 203 can be input according to a user operation, and the robot assembly viewer 120 Using the electrical connection information between the controller 203 and the plurality of robot modules stored in the storage unit 110, determines whether or not the controller 203 can connect to the plurality of robot modules, and displays the determination result on the assembly screen window can do.

The storage unit 110 may change the electrical connection information of the controller 203 and the first robot module 201 when it is determined that the determination result of the connection of the controller 203 and the first robot module 201 is connectable, . That is, the storage unit 110 may change the electrical connection information between the controller 203 and the first robot module 201 from "connectable" to "connection completed ".

The robot assembly viewer 120 emphasizes one or more robot modules connected to the controller 203 and the controller 203 by using the same color or the like by using the electrical connection information between the controller 203 and the robot module Can be displayed. Thereby, the controller 203 and one or more robotic modules can be connected to inform the robot module that is substantially controlled by the controller 203,

For example, when the connection between the controller 203 and the first robot module 201 and the second robot module 202 is completed, the storage unit 110 stores the controller 203, the first robot module 201, The robot assembly viewer 120 can change the electrical connection information between the robot module 202 and the robot module 202 to be "connected" and store the electrical connection information. The robot assembly viewer 120, when the controller 203 is selected according to a user operation, The robot module 201 and the second robot module 202 can be displayed in the same color as the controller 203. When the first robot module 201 is selected, 203 and the second robot module 202, which is another robot module connected to the controller 203, in the same color as that of the first robot module 201.

The storage unit 110 stores the voltage information of the electric power supplied by the battery 204, the voltage information required by the first robot module 201 to operate the component, the voltage information required by the second robot module 202 to operate the component And voltage information for each component such as required voltage information.

As shown in FIG. 2, the robot assembly viewer 120 displays the entire 3D image of the robot. When the battery 204 is selected according to a user's operation, the robot 204 can be connected to the battery 204 while highlighting and displaying the battery 204 The first robot module 201 and the second robot module 202, which are provided in the first robot module 201, can be emphasized and displayed.

The robot assembly viewer 120 receives the connection command between the battery 204 and the first robot module 201 according to a user's operation and stores the battery 204 stored in the storage unit 110 and the first robot module 201, It is determined whether the battery 204 and the first robot module 201 can be connected to each other according to the voltage of the battery 204 and the first robot module 201 using the electrical connection information between the battery 204 and the first robot module 201, Can be displayed. At this time, a connection command between the plurality of robot modules including the first robot module 201 and the second robot module 202 and the battery 204 may be inputted according to a user's operation. In the robot assembly viewer 120, It is possible to check the voltage of the battery 204 and the plurality of robot modules, and determine whether the battery 204 and each robot module are connectable, thereby displaying the connection availability.

For example, the storage unit 110 may store battery information in which the voltage of the battery 204 is 5V, the voltage of the first robot module 201 is 5V, and the voltage of the second robot module 202 is 10V. At this time, when a connection command between the battery 204 and the first robot module 201 and the second robot module 202 is input according to a user's operation, the robot assembly viewer 120 generates a battery 204 and the first robot module 201 can be connected to each other so that the first robot module 201 can be displayed in the same color as the battery 204 and the second robot module 202 can be displayed with a voltage difference A non-connectable message may be displayed.

When the battery 204 and the first robot module 201 are connected, the storage unit 110 stores the electrical connection information between the battery 204 and the first robot module 201 as "connection completion" Can be changed and stored.

The first robot module 201 and the second robot module 202 may be connected to each other and the first robot module 201 and the second robot module 202 may be connected to each other. 3 robot module and the first robot module 201 can not be connected.

When the first robot module 201 is selected according to a user operation, the robot assembly viewer 120 displays a second robot module 201 that can be connected to the first robot module 201 while highlighting and displaying the first robot module 201 202) can be emphasized and displayed further. At this time, the robot assembly viewer 120 displays the third robot module, which can not be connected to the first robot module 201, with colors different from those of the first robot module 201 and the second robot module 202, 3 robot module can not be connected to the first robot module 201.

When the connection command between the first robot module 201 and the third robot module is input according to a user operation, the robot assembly viewer 120 generates a connection command between the first robot module 201 and the third robot module stored in the storage unit 110, It is possible to determine whether the first robot module 201 and the third robot module can be connected to each other, and display the determination result on the assembly screen window. At this time, since the first robot module 201 and the third robot module can not be connected, the robot assembly viewer 120 displays the second robot module 202, which is a robot module connectable with the determination result, A robot module that can be connected to the robot module 201 can be recommended.

When a connection command between the first robot module 201 and the second robot module 202 is input according to a user operation, the storage unit 110 stores the electrical connection between the first robot module 201 and the second robot module 202 The connection information can be changed from "connectable" to "connection completed"

Thus, according to the embodiment of the present invention, by displaying the robot module connected to the controller 203 or the battery 204 on the screen, not only the mechanical connection but also the relationship between the components connected to each other according to the electrical characteristics can be grasped There is an effect that can be.

3 is a view showing an assembly screen window for displaying components constituting a robot according to an embodiment of the present invention.

2, the robot assembly viewer 120 displays a 3D image of the robot as a whole. When a screen enlargement command is input or a specific component is selected according to a user's operation, a 3D image, which is a part of the robot, is displayed can do.

Referring to FIG. 3, the robot assembly viewer 120 may display a 3D image of a component that is part of a robot that includes a first port 301 and a first connector 302 coupled with a second port. Here, the first port 301 and the second port may be included in the same robot module, and each may be included in another robot module. The first port 301 may be unconnected to the connector and the second port may be included in the first connector 302 in combination with the first connector 302 shown in FIG.

The connector can be coupled with the port for electrical signal transmission and external power supply between the robot modules. The first connector 302 shown in FIG. 3 includes a robot module including a second port, And transmits the information between the robot modules including the port.

The storage unit 110 may store information about the first port 301 formed in the robot module and the first connector 302 coupled to the second port. The robot assembly viewer 120 may include a storage unit 110, And the first connector 302 coupled with the first port 301 and the second port using the electrical connection information stored in the first port 301. [

Specifically, if the first port 301 is included in the robot module while displaying the robot module constituting the robot, the robot assembly viewer 120 can further display the first port 301 included in the robot module have.

As described above, when the second port is included in the component, the robot assembly viewer 120 displays the second port and determines whether the second port and the first connector 302 can be coupled using the electrical connection information And if it is determined to be connectable, the first connector 302 may be coupled to the second port to display a 3D image.

At this time, the robot assembly viewer 120 can check the number of the pins of the second port and the number of the pins of the first connector 302 to determine whether the second port and the first connector 302 can be coupled. For example, the storage unit 110 may store electrical connection information in which the number of pins of the second port is 5, and the number of pins of the first connector 302 is 5. Accordingly, the robot assembly viewer 120 checks the number of the pins of the second port and the number of the pins of the first connector 302 using the electrical connection information, 2 port and the first connector 302 may be combined to display a 3D image. The robot assembly viewer 120 can determine whether the port and the connector can be coupled by checking the size of the port and the direction of connection of the ports in addition to the number of pins of the port.

When the first connector 302 is selected, the robot assembly viewer 120 may further display another port connectable to the first connector 302. For example, if the first port 301 and the first connector 302 have the same number of pins, the robot assembly viewer 120 displays the first connector 302 and the first port 301 in the same color So that they can be connected to each other.

On the other hand, it is assumed that the controller 203 can be connected to one or more connectors, in which the controller 203 and the first connector 302 and the second connector can be connected.

When the controller 203 is selected in response to a user's operation, the robot assembly viewer 120 can display a list of connectors including the first connector 302 and the second connector connectable to the controller 203 on the screen.

When the first connector 302 of the connector list is selected, the storage unit 110 recognizes that the connection command of the controller 203 and the first connector 302 is input, ) Can be changed from "connectable" to "connection completed" to store the electrical connection information.

When the controller 203 is selected, the robot assembly viewer 120 displays the first connector 302 connected to the controller 203 and the controller 203 using the electrical connection information in the same color, It is possible to notify that the controller 203 and the first connector 302 are connected.

In addition, when the controller 203 is selected, the robot assembly viewer 120 notifies the controller 203 that the second connector can be connected through a method of displaying the second connector in a different color from the other components .

Meanwhile, the storage unit 110 may store information about the robot module connected to the ID and the port allocated to each port.

For example, the robot assembly viewer 120 can display a port list including the first port 301 and the second port on the assembly window, and when the first port 301 is selected in the port list, The robot module connected to the first port 301 can be displayed on the assembly screen window.

As described above, according to the embodiment of the present invention, by displaying the components including the port and the connector on the screen, it is possible to easily grasp the relationship between the components connected to each other according to the electrical characteristics.

4 is a view showing an assembly screen window displaying a robot according to another embodiment of the present invention.

The storage unit 110 may store a 3D image file for various components of the robot, and may further store IDs assigned to the robot modules of the components. Here, the ID may be allocated according to a user's operation command, and may be arbitrarily assigned by the robot assembling apparatus 100.

4, the robot assembly viewer 120 may display a 3D image of various components of the robot stored in the storage unit 110 on the assembly screen window, and further display the IDs allocated to the robot modules .

When at least one of the IDs displayed on the assembly window is selected according to the user's operation, the robot assembly viewer 120 may display an interface for adjusting the angle of the selected robot module with respect to time, May store angle adjustment information according to time inputted through the corresponding interface. Here, the angle adjustment information is information indicating how much time and angle of the robot module selected through the interface is to be adjusted.

For example, when the user selects the robot module corresponding to the ID 15 through the interface and inputs the angle adjustment information for changing the angle of the robot module by 30 degrees two seconds later, the storage unit 110 stores the angle adjustment information Can be stored. At this time, the user can set the angle adjustment separately for each robot module, and the angle adjustment can be set for the robot module set as a group by setting a plurality of robot modules as a group.

The storage unit 110 may store characteristic information of the robot module. Here, the characteristic information of the robot module may be information on an angle range in which the robot module can be adjusted.

For example, the storage unit 110 may store information on an angular range from 0 degrees to 90 degrees with the characteristic information of the robot module corresponding to the ID 11, and the robot assembly viewer 120 may store information about angles ranging from 0 degrees to 90 degrees. You can display adjustable interfaces up to degrees. This is because, since the angle that can be adjusted for each robot module is different (for example, the range of the movable angle of the arm portion and the leg portion is different), the characteristic for the angular range is preset for each robot module, This is to limit the range that can be moved.

The storage unit 110 may store the angle adjustment information after confirming that the angle adjustment information according to the time inputted through the interface is appropriate by using the characteristic information of the robot module. For example, if the characteristic information of the robot module corresponding to the ID 11 is information on the angular range from 0 to 90 degrees, the storage unit 110 stores the angle adjustment information of the robot module corresponding to the ID 11 at 0 degree After confirming that the angle is within 90 degrees, the angle adjustment information can be stored.

The robot assembly viewer 120 can generate a moving image of a component operated by the robot module, that is, a simulation moving image in which the robot moves, using the angle adjustment information stored in the storage unit 110, and display the generated moving image on the assembly screen window.

For example, when the user inputs angle adjustment information for changing the angle of the robot module corresponding to IDs 3 and 4 to 90 degrees after 2 seconds via the interface, the robot assembly viewer 120 displays IDs 3 and 4 after 2 seconds By moving the component operated by the robot module corresponding to the IDs 3 and 4 by adjusting the angle of the corresponding robot module to 90 degrees, it is possible to display a moving image in which both arms of the robot are moved up on the assembly screen window.

The operation control of each robot module described with reference to FIG. 4 can be performed by the second program, and the connection between the respective components described with reference to FIGS. 2 and 3 and the storage of the corresponding information are performed by the first program .

That is, the storage unit 110 may store the electrical connection information and the like among the components generated through the first program as a specific file (for example, an XML file), and the robot assembly viewer 120 2 program, and the robot set through the first program is operated and controlled through the second program to provide a simulation video of the robot.

As described above, according to the embodiment of the present invention, by providing an interface capable of adjusting the angle of the robot module with time, it is possible to easily provide a simulation video in which the robot moves.

It will be understood by those skilled in the art that the foregoing description of the present invention is for illustrative purposes only and that those of ordinary skill in the art can readily understand that various changes and modifications may be made without departing from the spirit or essential characteristics of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included within the scope of the present invention.

100: Robot assembly device
110:
120: Robot assembly viewer
201: first robot module
202: second robot module
203:
204: Battery
301: First port
302: first connector

Claims (5)

A 3D image file for a plurality of components constituting the robot, IDs, position information, characteristic information, required voltage information for a plurality of robot modules associated with or operating the plurality of components, A storage unit for storing electrical connection information and electrical connection information between the robot module and a controller for controlling the robot module; And
A robot for displaying a 3D image of the plurality of components, information about the at least one robot module connectable with the controller using the electrical connection information, information about the robot modules connectable to each other, And an assembly viewer. The method according to claim 1,
Wherein,
Information about a port formed in any one of the plurality of robot modules, information about a connector coupled with the port, and electrical connection information between the connector and the controller,
The robot assembly viewer includes:
The controller determines whether the port and the connector can be coupled to each other by using the information about the port to check the coupling direction, size, and number of pins of the port, Is displayed on the assembly screen window and a connector connectable with the controller is displayed on the assembly screen window. The method according to claim 1,
Wherein,
Further storing electrical connection information between the robot module and a battery supplying electricity to the robot module,
The robot assembly viewer includes:
And compares the voltage required for the operation of the robot module with the voltage supplied by the battery and displays the at least one robot module connectable with the battery on the assembly screen window. The method according to claim 1,
The robot assembly viewer includes:
And displays a 3D image of each of the plurality of components displayed on the assembly screen window, displays an ID assigned to each of the plurality of robot modules in the assembly screen window, and, when one or more robot modules are selected, An interface for adjusting the angle of the display screen with respect to time is further displayed on the assembly screen window,
Wherein,
And further stores angle adjustment information according to time inputted through the interface. 5. The method of claim 4,
The robot assembly viewer includes:
And further displays, in the assembly screen window, moving images in which the components operated by the selected robot module move, using the angle adjustment information.

Images