KR20090128637A - Educational frame robots - Google Patents

Abstract

PURPOSE: An assembly education robot is provided to form the frame of a mobile robot in a drawer structure, thereby expanding freely a controller and the user module of a circuit board without the shape change of the robot. CONSTITUTION: A driving unit(10) has a driving wheel and a shock reducing unit. The driving wheel is driven with the driving of a drive motor. A frame unit(20) comprises a plurality of expansion boards. A controller or a circuit board for robot control is installed in the expansion board. The expansion boards are inserted into a supporting frame in a drawer type. A sensor unit(30) has a plurality of sensors. The frame unit passes through the center of the sensor unit. The sensor unit is fixed to one side of the frame unit. A main control unit(40) is installed in the top of the frame unit.

Description

Prefab Educational Robots {Educational Frame robots}

The present invention relates to a prefabricated educational robot, wherein the robot is formed separately for each function and module, and the controller and the circuit board can be freely expanded, and the prefabricated educational robot has diversified the functions and shapes of the robot by the educator's assembly method. It is about.

The use of robots includes industrial robots used for production at industrial sites according to industrial needs and educational robots used for experiments in schools, etc., for the purpose of teaching students the principles of robot operation. In particular, the demand for non-industrial intelligent robots is increasing as much as industrial robots.

The robots used in the related art are designed to learn scientific principles through robots that are assembled and manufactured according to their functions. Since one robot covers only one principle, it is difficult to learn various robots and is in the form of a kit. Since the robot teaching materials are assembled by soldering or bonding by adhesive, they cannot be disassembled once assembled.

In addition, although modular assembly robots, which are widely used for educational purposes, can be modified or assembled in various shapes, the module itself is not deformable and provides a standardized assembly method. In addition, in order to implement separate functions intended by the students, it is difficult to produce more originality due to the difficulty of producing new connecting parts and fixed parts.

The present invention is to solve the above problems, the object is to configure the educational mobile robot into a plurality of modules, by assembling them in various forms assembled prefabricated educational robot that can change the shape of the robot according to the user's intention To provide.

Still another object of the present invention is to provide a prefabricated educational robot that can freely expand a user module such as a separate controller and a circuit board without changing the shape of the robot by forming a frame of the educational mobile robot in a drawer structure.

Another object of the present invention is to expand and install a separate controller and circuit board according to the user's intention, it is possible to easily understand the control and operation principle of the robot, and to plan the basic research of the robot that is the main axis of the future industrial site To provide a prefabricated educational robot.

Still another object of the present invention is to provide an educational robot having a complete appearance by covering its own circuits with an exterior of a modular robot even when a separate controller and circuit are inserted into the robot.

Another object of the present invention is to allow students who are new to the robot to experience the operation of the robot through direct manipulation, the prefabricated educational robot to enable students in the early stages of the robot feel interesting and develop creativity To provide.

Still another object of the present invention is to provide a prefabricated educational robot that can cope with various environments by adjusting the position of the sensor unit by using a robot frame and enabling sensor movement within the sensor unit.

Another object of the present invention is formed by vertically arranging the coupling holes on the side of the frame portion, and by installing a ball stopper coupled to the coupling hole in the sensor portion, prefabricated training for freely adjusting the height position of the sensor portion around the frame portion To provide a robot.

Still another object of the present invention is to provide a prefabricated educational robot that can facilitate the connection between the main board and each component by forming a cable passage for cable processing in the frame portion, and at the same time improve the assembly efficiency according to the narrow space. It is.

Another object of the present invention is to provide a prefabricated educational robot that can install a shock-absorbing unit in the robot drive unit, to mitigate the impact due to the mobility of the step rise and the vertical movement of the robot.

According to the present invention, a driving wheel is moved by driving of a driving motor, and a driving part provided with an impact mitigating part and a plurality of expansion boards installed vertically on the driving part and installed with a controller or a circuit board for controlling a robot are provided in a support type. The frame unit is inserted and coupled, and provided with a plurality of sensors, the frame portion penetrates the center so as to be located above the drive unit, the sensor unit is fixed to one side of the frame portion, and the main control unit is installed at the top of the frame portion It is configured to include.

The shock absorbing part is composed of a front caster part positioned at the front end of the driving body body based on the moving direction of the robot, and a rear caster part which is installed at the rear end of the driving body base so as to be positioned on the same line as the front caster part and is buffered up and down,

The tip caster is composed of a caster holder installed on the upper surface of the body base and having an installation groove therein, and a rotatable caster inserted into the installation groove of the caster holder.

The rear end caster is fixedly installed at the lower portion of the drive body base and the upper and lower portions are opened, the piston guide is integrally fixed to the upper portion of the cylinder and formed with a guide hole in the center, and the rod passes through the guide hole of the piston guide. Is installed and the flange which is moved in the cylinder is integrally formed in the lower part of the rod, the compression spring is installed in the cylinder so as to be located between the piston guide and the flange of the piston, and the integrally installed on the lower surface of the flange of the piston It is intended to include a typical caster.

As such, the present invention includes a driving unit, a frame unit, a main control unit, and a sensor unit, respectively, and can be assembled in various forms by a combination thereof.

In addition, the present invention frame structure is made of a drawer type, it is possible to freely expand the various controllers and circuit boards, through which it is possible to configure a robot of various functions according to the user's intention.

In addition, the present invention by installing the intermediate support in the frame portion, and protruding the fasteners formed on the intermediate support, by supporting one side of the expansion board to be slidingly coupled, while preventing the lifting phenomenon of the expansion beam, and at the correct position Can be assembled.

In addition, in the present invention, the cable passage is formed in the frame portion, it is possible to facilitate the processing of the cable for connection between each component.

In addition, the present invention can confirm the actual operation of each component, while confirming the structure of each of the robot components using the expansion of the separate controller and the circuit board of the user, through which students in the initial introduction stage of the robot Can inspire interest and develop creativity.

In addition, the present invention is formed integrally with the sound portion and the cover portion, to solve the spatial constraints.

In addition, the present invention can visually check the structure or operation principle of the components of the actual robot, not just the theory, trained and practiced on the structure, operation principle and control of the intelligent robot.

In addition, the present invention can be freely fixed to the position of the sensor portion by the ball stopper frame, it is easy to adjust the height of the sensor, through which the shape of the sensor module according to various environments can be freely changed according to the research purpose of the robot Can be.

In addition, the present invention by modifying the shape of the sensor body, the educator can adjust the installation position and angle of the sensor, thereby improving the detection efficiency according to the application target.

In addition, the present invention has a shock absorbing portion is installed in the lower portion of the drive, it is easy to climb the step when moving the robot, to prevent the fall, and to reduce the impact generated up and down there are many effects.

1 is an exemplary view showing a configuration according to the present invention, Figure 2 is an exemplary view showing a configuration of the drive unit according to the invention, Figure 3 is an exemplary view showing an internal configuration of the drive unit of the present invention, Figure 4 is a present invention Exemplary view showing the configuration of the shock absorber according to Figure 5 is an exemplary view showing the operating state of the shock absorber according to the present invention, Figure 6 is an exemplary view showing the configuration of the frame unit according to the present invention, Figure 7 8 is an exemplary view showing a configuration of the sensor unit according to the invention, Figure 8 is an embodiment showing a modified configuration of the sensor unit according to the present invention, Figure 9 is an illustration showing a coupling relationship between the frame unit and the sensor unit according to the present invention. 10 is an exemplary view showing a configuration of a cover unit and a sound unit according to the present invention, FIG. 11 is an exemplary view showing a configuration of a main control unit according to the present invention, and FIG. 12 is a configuration of a main control unit according to the present invention. It shows a block example,

According to the present invention, the driving wheel 12 is moved by the driving of the driving motor 11 and the driving unit 10 in which the impact mitigating unit 80 is installed, and the controller for controlling the robot and installed vertically above the driving unit 10. Alternatively, a plurality of expansion boards 21 on which circuit boards are installed are provided with a frame portion 20 into which a drawer type is inserted into the support 22 and a plurality of sensors 31, and further positioned to be positioned above the driving portion. 20 is installed so as to pass through the center, and comprises a sensor unit 30 fixed to one side of the frame portion 20, and the main control unit 40 is installed on the top of the frame portion 20 have.

In addition, the present invention is a cover portion 50 is installed on the exposed side of the frame portion 20, the sensor unit 30 is not installed, and the sound unit 60 is connected to the cover unit 50 is installed It includes more. In addition, the present invention is further provided with a camera unit 70 for image processing.

As shown in FIGS. 1 to 3, the driving unit 10 is driven by the driving motors 11 installed at the left and right sides of the body 13, respectively, to drive the left and right driving wheels 12. Obstacles are contacted and sensed by a plurality of sensors 14 installed to protrude, and a shock absorbing unit 80 is installed below.

That is, the drive unit 10 is connected to the drive motor 11 and the drive motor 11, which is fixed to the body 13, the body base 15 located at the lower end of the body 13, the drive motor 11 is driven The driving wheel 12 is to be installed, the sensor 14 is installed to protrude outside the body to detect the obstacle by the contact, the shock absorbing unit 80 is installed to be located at the front and rear ends of the body base 15 It is intended to include.

The sensor 14 for detecting the obstacle is a contact sensor such as a bumper sensor installed in the educational mobile robot 100. The installation and operation principle of the sensor is a well-known technique, and the applicant of the present invention Since the configuration of the contact sensor is also described in detail in Patent Registration No. 0799947, etc., the detailed description thereof will be omitted.

As shown in FIGS. 2 to 5, the impact alleviating unit 80 includes a front caster unit 81 and a front caster unit 81 positioned at the front end of the driving unit body base 15 based on the moving direction of the robot. It is composed of a rear end caster portion 82 which is installed at the rear end of the drive body base 15 so as to be located on the same line as the.

The tip caster 81 is installed on the upper surface of the body base and the caster holder 811 having an installation groove 812 therein, and the rotary type inserted into the installation groove 812 of the caster holder 811 It consists of the caster 813. The rotatable caster 813 is to be free to rotate, the configuration of such a rotatable caster is well known technology, a detailed description thereof will be omitted. In addition, the rotatable caster 813 and the caster holder 811 are integrally coupled by a known technique such as bolt coupling.

The rear end caster 82 has a cylinder 821 having a lower portion fixedly installed at a driving unit body base 15 and an upper and lower portions thereof open, and a piston having a fixedly installed upper portion of the cylinder and a guide hole 822 formed at the center thereof. A piston 824 integrally formed at a lower portion of the lower portion of the rod with a guide 823, a rod 824a installed through the guide hole 822 of the piston guide, and moving in the cylinder; A compression spring 825 installed in the cylinder 821 so as to be located between the 823 and the flange 824b of the piston, and a rotatable caster 826 integrally installed on the lower surface of the flange of the piston 824. It is supposed to.

At this time, the diameter of the lower end of the cylinder 821 is to be smaller than the diameter of the flange 824b of the piston, when the piston guide is installed on the top of the cylinder, the rod end of the piston passes through the guide hole of the piston guide The flange of the piston will be moved in and out of the cylinder.

The rear caster portion 82 configured as described above is connected to the flange of the piston rather than being fixed to the rotatable caster, so that when an obstacle is in contact with the front caster portion or the left / right driving wheel, When an obstacle comes into contact with the rear caster, the piston connected to the rotary caster compresses the compression spring and moves in the cylinder to mitigate the impact transmitted to the robot. That is, the shock absorber according to the present invention is provided with the same function as the shock absorber.

The frame part 20 is connected to the upper end of the driving part and is fixedly installed. As shown in FIG. 6, a plurality of expansion boards 21 are inserted into the support 22 in a drawer type.

That is, the frame part 20 has a plurality of expansion boards 21 on which a controller or a circuit board is installed, which is slidably inserted into the support 22 to form a bolt, and the support 22 has a lower portion of the driving part 10. It is fixedly installed on the upper side of the support, the upper surface of the support 22 is formed on the cable passage 23 for the connection between the controller and circuit board and the main control unit 40 is installed on the expansion board, the sensor unit 30 on the side ) A plurality of coupling holes 24 for coupling with each other are formed in the vertical direction.

In this case, a plurality of intermediate supports 25 for inserting the expansion board 21 are installed in the support 22, and the intermediate supports 25 support the positions of the expansion board 21 to be inserted. The fastening table 26 is formed. That is, the fastening stand 26 is formed in a ring shape, the fastening hole 27 is formed in the expansion board 21, the support stand into the fastening hole 27 of the expansion board is inserted into the support 22 sliding Since the fastening table 26 is inserted so that one end of the expansion board 21 is caught by one side of the fastening table 26, the lifting phenomenon of the expansion board 21 is prevented.

The expansion board 21 includes a board panel 211 to which a controller or a circuit board is fixed and an assembly table 212 integrally formed on the board panel 211 and bolted to the support 22.

The expansion board 21 of the present invention frame unit configured as described above is more preferably to be inserted in the front direction from the rear of the robot rather than inserted into the rear direction from the front of the educational mobile robot.

In addition, the side of the support 22 is a plurality of coupling holes 24 are arranged vertically at equal intervals, and the upper surface and the intermediate support of the support and the controller and circuit boards installed in the frame portion and the main control unit For the connection, cable passages 23, 23 'into which cables are inserted are formed.

Frame portion of the present invention configured as described above is to be installed in a plurality of expansion boards are installed in a separate controller or circuit board 90 is a drawer type, it is easy to expand the various modules according to the needs of the user. .

As shown in FIGS. 7 and 9, the sensor unit 30 includes a central hole 32 into which the frame unit 20 is inserted in the center of the body portion, and the outer surface 34 of the body 33. Accordingly, a plurality of sensors 31 are installed therein to be exposed to the outside, and a plurality of ball stoppers 35 contacted with and coupled to the frame part 20 inside the body 33 to protrude in the direction of the central hole 32. ) Is installed. The sensor 31 is a non-contact sensor to install an ultrasonic sensor or an infrared sensor.

As shown in FIG. 9, the ball stopper 35 is located in the body 33 and has a groove 36 open at one side in the direction of the central hole 32, and a central portion through the open side of the groove 36. The ball 37 is provided to protrude into the hole 32 and the spring 38 is located in the groove 36 and installed to contact the ball 37 to push the ball in one direction, the ball by the elasticity of the spring Is pushed in the direction of the center hole to insert the ball into the coupling hole of the frame support, thereby fixing the position of the sensor portion. At this time, the ball is to protrude only a portion in the direction of the central hole through the open one side of the groove 36, so as not to be separated to the outside.

In addition, as shown in FIG. 8, the sensor unit may be configured as a movable type instead of a fixed type. That is, the sensor unit may adjust the position and number of the plurality of sensors by sliding the deformation of the shape of the body.

That is, the sensor unit is formed in the body along the outer surface of the body to communicate with the opening hole 33a formed along the outer circumferential surface of the sensor unit body, the opening hole 33a, the guide groove 33b for sliding the sensor is inserted; The angle display part 33c formed on the outer surface of the body to be positioned above and below the opening hole 33a may be further provided to adjust the number and position of sensors installed inside the sensor part.

At this time, the sensor slidingly inserted into the guide groove is exposed to the outside through the opening hole. That is, the deformed sensor unit as described above is modified in the shape of the sensor unit body, the configuration of the central hole, ball stopper and the like is the same.

In addition, the present invention may be further installed by connecting the camera unit 70 installed therein to the main controller 40 for image processing. The camera unit 70 may be installed by being connected to the main control unit, the frame unit, the driving unit, and the like, and the position thereof is not particularly limited, and the camera in the camera may be tilted by the tilt motor 71 or the like. desirable. In addition, the camera unit is preferably connected to the main control unit and USB.

11 and 12, the main controller 40, the main board 41 including a central processing unit for managing the entire system, and connected to the main board to control the sensor installed in the robot A sensor controller 42 for connecting to the main board, a motion controller 43 for controlling various motors installed in the robot, and a main controller for transmitting images and signals to a remote site and receiving command signals from the remote site. It includes a wireless network section 44 for receiving. In this case, the wireless network unit uses a transmission and reception module for transmitting and receiving wireless signals.

In addition, the main control unit 40 has a camera installation hole 40` for installing the camera unit 70 or the position recognition camera 112, the touch screen connected to the main board 41 on one side 45 is provided. The touch screen 45 serves as an operation panel for the educator to directly control the robot.

The cover part 50 is installed on the exposed outer surface of the frame part, and as shown in FIG. 1, the cover part 50 is installed on the remaining part where the sensor part is not located to protect the circuit board and the controller installed in the frame part. That is, the shape of the cover portion is not specified, but is attached to the exposed surface of the frame portion.

Although the sound unit 60 may be formed separately from the cover unit, as illustrated in FIGS. 1 and 10, when considering the efficiency of the installation space, the sound unit 60 may be integrally formed with the cover unit.

Various controllers and circuit boards installed in the sensor unit, the camera unit, the driver unit, the sound unit, and the frame unit according to the present invention configured as described above are all connected to the main controller by a cable or a USB port.

In addition, the present invention configured as described above may be assembled by installing all of the cover portion, the main control unit, the sensor unit and the camera unit provided with a frame unit, a sound unit installed on the upper side of the drive unit, one or more of them can be selected and assembled.

That is, the present invention consists of an educational robot including a main control unit and a driving unit in which a driving motor is controlled by the main control unit, and a plurality of expansion boards are supported on the top of the driving unit so as to be located between the driving unit and the main control unit. The frame unit is inserted into and coupled to, or a plurality of sensors are installed therein, the sensor unit having a central hole into which the frame unit is inserted, or one or more camera units provided with a camera therein is mounted and assembled. In addition, the frame portion may be further provided with a cover portion provided with a sound portion.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

1 is an exemplary view showing a configuration according to the present invention

2 is an exemplary view showing a configuration of a driving unit according to the present invention

Figure 3 is an exemplary view showing the internal configuration of the drive unit of the present invention

Figure 4 is an exemplary view showing the configuration of the shock absorber according to the present invention

5 is an exemplary view showing an operating state of the shock absorber according to the present invention.

6 is an exemplary view showing a configuration of a frame unit according to the present invention

7 is an exemplary view showing a configuration of a sensor unit according to the present invention

Figure 8 is an embodiment showing a modified configuration of the sensor unit according to the present invention

9 is an exemplary view showing a coupling relationship between the frame unit and the sensor unit according to the present invention.

10 is an exemplary view showing a configuration of a cover unit and a sound unit according to the present invention

11 is an exemplary view showing the configuration of the main control unit according to the present invention;

12 is an exemplary block diagram showing the configuration of the main control unit according to the present invention.

* Explanation of symbols for main parts of the drawings

10: drive unit 11: drive motor

(12): drive wheel (13): body

14: sensor 15: body base

20: frame portion 21: expansion board

(22): Support (23): Cable passage

(24): coupling hole (25): intermediate support

(26): fasteners (27): fastening holes

30: sensor unit 31: sensor

(32): Central hole 33: Body

(33a): Opening hole (33b): Guide groove

(33c): Angle display part 34: Body outer surface

35: ball stopper 36: home

37: ball 38: spring

(40): main control unit (40`): camera mounting hole

(41): Motherboard (42): Sensor Controller

(43): motion controller (44): wireless network

(45): touch screen (50): cover

60: sound unit 70: camera unit

(71): Tilt motor 80: Impact buffer

(81): front end caster part (82): rear end caster part

(90): controller or circuit board (100): educational mobile robot

101: amplifier 102: home appliance control transceiver

(103): LCD 104: Frame Grabber

(105): power controller 106: I / O

107: Speaker 108: Microphone

(109): Gyro sensor (110): Fall detection sensor

(111): LED (112): position recognition camera

(113): landmark device 114: battery

(115): RS232 (116): USB

200: Obstacle 211 Board Board

212: assembly rack 811: caster holder

(812): Mounting Groove (813): Rotary Caster

821: Cylinder 822: Guide Hole

(823): piston guide 824: piston

824a: rod 824b: flange

(825): compression spring (826): rotatable caster

Claims (14)

In the prefabricated educational mobile robot; A driving part 10 driven by the driving motor 11 and having a shock absorbing part 80 at a lower part thereof; A frame part 20 in which a plurality of expansion boards 21 installed vertically on the driving part 10 and installed with a controller or a circuit board for controlling a robot are inserted into the support 22 in a drawer type; The sensor unit 30 is provided with a plurality of sensors 31, the frame unit 20 is installed so as to be positioned above the drive unit, the frame unit 20 is fixed to one side of the frame unit 20, Prefabricated educational robot, characterized in that it comprises a main control unit 40 is installed on the top of the frame portion 20. The method according to claim 1; The drive unit 10 is a drive motor 11 is fixedly installed on the body 13, the body base 15 located at the lower end in the body 13, and the drive is connected to the drive motor 11 and driven And a wheel 12, a sensor 14 installed to protrude outside the body to detect an obstacle by contact, and an impact alleviating unit 80 installed to be positioned at the front and rear ends of the body base 15. Prefabricated educational robot, characterized in that. The method according to claim 1 or 2; The shock absorbing part is a front caster part positioned at the front end of the driving body base based on the moving direction of the robot, and a rear end caster installed at the rear end of the driving body base so as to be in the same line as the front caster part and buffered up and down by a compression spring. Prefabricated educational robot comprising a. The method according to claim 3; The tip caster is composed of a caster holder installed on the top surface of the body base and having an installation groove therein, and a rotatable caster inserted into the installation groove of the caster holder. The rear end caster is fixedly installed at the lower portion of the drive body base and the upper and lower portions are opened, the piston guide is integrally fixed to the upper portion of the cylinder and formed with a guide hole in the center, and the rod passes through the guide hole of the piston guide. Is installed and the flange which is moved in the cylinder is integrally formed in the lower part of the rod, the compression spring is installed in the cylinder so as to be located between the piston guide and the flange of the piston, and the integrally installed on the lower surface of the flange of the piston Prefabricated educational robot comprising a typical caster. The method according to claim 1; The frame part 20 has a plurality of expansion boards 21 on which a controller or a circuit board is installed, which is bolted to the support 22 by sliding in layers, and the support 22 has a lower portion of the driving part 10. Is fixedly installed on the upper side, the upper surface of the support 22 is formed on the cable board 23 for connecting the controller and circuit board and the main control unit 40 is installed on the expansion board, the side with the sensor unit 30 Prefabricated educational robot, characterized in that formed in the vertical direction a plurality of coupling holes 24 for coupling. The method according to claim 5; Inside the support 22, a plurality of intermediate supports 25 are installed for insertion of the extension board 21, and the intermediate supports 25 are annular to support the position of the extension board 21 to be inserted. Prefabricated educational robot, characterized in that the fastening table 26 is formed. The method according to claim 1; The sensor unit 30 has a central hole 32 into which the frame unit 20 is inserted in the center of the body, and a plurality of sensors 31 therein to be exposed to the outside along the outer surface 34 of the body 33. ) Is installed, and a plurality of ball stopper 35 is installed in contact with the frame portion 20 in the body 33 so as to protrude in the direction of the central hole 32, prefabricated educational robot. The method of claim 7; The ball stopper 35 is positioned in the body 33 so as to protrude into the central hole 32 through a groove 36 open at one side in the direction of the central hole 32 and one side located in the groove 36. Prefabricated educational robot, characterized in that it comprises a ball (37) to be installed, and a spring (38) located in the groove (36) and installed to contact the ball (37) to push the ball in one direction. The method of claim 7; The sensor unit body has an opening (33a) formed along the outer circumferential surface, A guide groove 33b formed in the body along the outer surface of the body so as to communicate with the opening hole 33a and sliding of the sensor; Prefabricated, characterized in that the number and position of the sensor installed in the sensor unit is further adjusted to further include an angle display portion (33c) formed on the outer surface of the body to be located on the upper / lower portion of the opening hole (33a) Educational Robot. The method according to claim 1; The main controller is connected to the main board 41 and the main board 41 including a central processing unit for managing the entire system, a sensor controller 42 for controlling the sensor installed in the robot connected to the main board, Motion controller 43 for controlling various motors installed in the robot, and a wireless network unit 44 is connected to the main board to transmit images and signals to a remote site and receive command signals from a remote site Prefabricated educational robot. The method according to claim 1; The cover unit 50 is installed on the exposed side of the frame unit 20, the sensor unit 30 is not installed, and the sound unit 60 is connected to the cover unit 50 is integrally installed Prefabricated educational robot, characterized in that. The method according to claim 1; Prefabricated educational robot, characterized in that the camera unit 70 is further installed for image processing. It consists of an educational robot including a main control unit and a driving unit for controlling the driving motor by the main control unit, On the top of the drive unit to be located between the drive unit and the main control unit, A frame portion in which a plurality of expansion boards are inserted into the support in a drawer type; Alternatively, a sensor unit having a plurality of sensors installed therein and having a central hole into which the frame unit is inserted; Or, prefabricated educational robot, characterized in that the one or more cameras installed inside the camera is mounted and assembled. The method of claim 13; Prefabricated educational robot, characterized in that the frame portion is further provided with a cover portion provided with a sound portion.

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