Difference between revisions of "Triskar2"
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== Components == | == Components == | ||
− | + | === Mechanics === | |
+ | The frame of the robot is based on [http://www.item24.com/ Item] mechanical elements Motor and transmission subsystems have been designed to minimize the number of mechanical elements that have to be especially built or customized for this application, thus reducing the time, tooling and skills required for modification, repair or construction. | ||
Triskar2 uses three identical motor+transmission modules. Each of these includes the following elements: | Triskar2 uses three identical motor+transmission modules. Each of these includes the following elements: | ||
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* an elastic joint (#0.0.628.83, made by [http://www.item24.com/ Item]), used to connect the transmission shaft to the wheel shaft to reduce the transmission of mechanical stresses. | * an elastic joint (#0.0.628.83, made by [http://www.item24.com/ Item]), used to connect the transmission shaft to the wheel shaft to reduce the transmission of mechanical stresses. | ||
− | + | === Electronics === | |
+ | Electronic elements (e.g., motor control) of Triskar2 are based [[Low-cost Robotics | R2P]], the modular robot architecture developed at AIRLab by [[User:MartinoMigliavacca | Martino Migliavacca]]. Independent, low-cost, HW modules implement the single functionalities (motor control, communication, sensor interfaces, ...) and it is connected to the others via a CAN bus, participating in a publish-subscribe architecture supported by the real-time operating system [http://chibios.org/dokuwiki/doku.php ChiBiOS]. This means that interaction among modules is implemented in real-time. Modules include an [http://www.st.com/ ST Microelectronics] ARM processor on which the basic functionalities of the module are implemented. Therefore, any robot HW can be implemented in hours. | ||
R2P exposes a [MicroROS] interface, enabling each R2P node to interact directly to any [http://www.ros.org/ ROS] node implemented on a connected computer or network. | R2P exposes a [MicroROS] interface, enabling each R2P node to interact directly to any [http://www.ros.org/ ROS] node implemented on a connected computer or network. | ||
− | + | === Computing === | |
The first instance of Triskar2 robot is fitted with a small-form-factor PC by [http://www.zotac.com/ Zotac]: model ID82, based on an Intel Core i3 2330M dual-core processor. The PC is mounted on a quick-release tray. | The first instance of Triskar2 robot is fitted with a small-form-factor PC by [http://www.zotac.com/ Zotac]: model ID82, based on an Intel Core i3 2330M dual-core processor. The PC is mounted on a quick-release tray. | ||
Operating system is Linux. All the software of Triskar2 has been developed by AIRLab, and is modular in its structure to allow easy modification. | Operating system is Linux. All the software of Triskar2 has been developed by AIRLab, and is modular in its structure to allow easy modification. | ||
− | + | === Power supplies === | |
Triskar2 uses a 24V DC power supply based on a couple of 12V sealed lead-acid batteries connected in series. | Triskar2 uses a 24V DC power supply based on a couple of 12V sealed lead-acid batteries connected in series. | ||
The onboard PC requires 19V DC, which are generated by a configurable board (model DCDC-USB) by [http://www.mini-box.com/DCDC-USB Mini-Box]. | The onboard PC requires 19V DC, which are generated by a configurable board (model DCDC-USB) by [http://www.mini-box.com/DCDC-USB Mini-Box]. |
Revision as of 11:51, 11 January 2013
Triskar2
| |
Short Description: | Highly modular omnidirectional robot base |
Coordinator: | AndreaBonarini (andrea.bonarini@polimi.it) |
Tutor: | |
Collaborator: | GiulioFontana (giulio.fontana@polimi.it), MartinoMigliavacca (migliavacca@elet.polimi.it) |
Students: | |
Research Area: | Robotics |
Research Topic: | Robot development |
Start: | 2012/10/01 |
End: | 2015/12/31 |
Status: | Active |
Contents
General features
Triskar2 is a highly modular omnidirectional robot base developed by AIRLab. Triskar2 benefits from some years of experience with the omnidirectional robot Triskar. Triskar was built by AIRLab for the Milan Robocup Team, which participated to the Robocup competition up to 2010.
Triskar2 is modular from the mechanical, the electronic, and the software points of view.
Any mechanical dimension can be changed within hours. Each arm holding the motor is independent and can be locked on the central pillar in seconds. This also allows easy transportation. On the central pillar different "bodies" can be locked.
The electronics of Triskar2 is based on R2P, which allows easy and quick modifications.
Data processing is done onboard by a small-form-factor PC running software developed by AIRLab.
Triskar2 is currently under development as a base for some Robogames, the most advanced of which is presently Alien-Bot.
Components
Mechanics
The frame of the robot is based on Item mechanical elements Motor and transmission subsystems have been designed to minimize the number of mechanical elements that have to be especially built or customized for this application, thus reducing the time, tooling and skills required for modification, repair or construction.
Triskar2 uses three identical motor+transmission modules. Each of these includes the following elements:
- a Maxon motor+transmission+encoder combination (code #220251, composed of: #118798 DC motor mod. RE36, graphite brushes, 70W, ball bearings, 2 shafts; #166158 2-stage planetary gearhead, 2.25Nm, ball bearings; #110513 encoder, 500 impulses/turn);
- two Koyo model UP000 small pillow block bearings (many thanks to the Italian distributor MCI for helping us in getting these!);
- an omnidirectional wheel (model #14054, with hub #18009 for 10mm shaft) made by Opteq;
- a short wheel shaft (aluminium, 10mm diameter);
- an elastic joint (#0.0.628.83, made by Item), used to connect the transmission shaft to the wheel shaft to reduce the transmission of mechanical stresses.
Electronics
Electronic elements (e.g., motor control) of Triskar2 are based R2P, the modular robot architecture developed at AIRLab by Martino Migliavacca. Independent, low-cost, HW modules implement the single functionalities (motor control, communication, sensor interfaces, ...) and it is connected to the others via a CAN bus, participating in a publish-subscribe architecture supported by the real-time operating system ChiBiOS. This means that interaction among modules is implemented in real-time. Modules include an ST Microelectronics ARM processor on which the basic functionalities of the module are implemented. Therefore, any robot HW can be implemented in hours.
R2P exposes a [MicroROS] interface, enabling each R2P node to interact directly to any ROS node implemented on a connected computer or network.
Computing
The first instance of Triskar2 robot is fitted with a small-form-factor PC by Zotac: model ID82, based on an Intel Core i3 2330M dual-core processor. The PC is mounted on a quick-release tray.
Operating system is Linux. All the software of Triskar2 has been developed by AIRLab, and is modular in its structure to allow easy modification.
Power supplies
Triskar2 uses a 24V DC power supply based on a couple of 12V sealed lead-acid batteries connected in series.
The onboard PC requires 19V DC, which are generated by a configurable board (model DCDC-USB) by Mini-Box.