Acrobatic Top Performance for Spherical Vehicle
Spherical Vehicle With Balancing Drive Module As Mechatronics Demonstrator
Project studies open up future perspectives and can also inspire people. Nowhere is this truer than in the field of mechatronics, which connects three highly dynamic and growing fields offering a vast range of new developments. For this reason, GIGATRONIK Group, a medium-sized company specializing in automotive, electronics and information technology, sponsored a mechatronics demonstrator as a Bachelor’s thesis. This serves for demonstration purposes at fairs and recruiting days. Complex position control in combination with fast mechanical implementation of the necessary commands, represented a challenge to both developers and the integrated components.
Quick Reflexes Necessary
Like a human on two legs, a spherical vehicle has an unstable “resting stance”. It requires continuously active readjustment in order to maintain a position in the room. The procedure must be carried out very quickly, even reflexively – for the faster the reaction, the more minor necessary corrections are and the better the stability of the device. In the case presented, a vehicle equipped with electronics, electric motors and rechargeable battery balances on a ball. The dimensions of the vehicle are approximately 30 cm x 30 cm x 15 cm, and it has a net weight of approximately 2.5 kg (5.5lbs). Shifts in the center of gravity of the vehicle allow the ball to easily roll along on the surface. Like an acrobat, the vehicle is forced to balance out these rolling movements through corresponding counter-movements. To this end, a seamlessly integrated inertial sensor measures acceleration, rotation rates, and the force of the Earth’s magnet field on the electronic circuit board of the prototype controller, referred to as, “GIGABOX gate”.
The actual control is modeled with Simulink, transferred via a Simulink target by means of autocode generation in C-code and integrated into the controller as a realtime task. From measured data, the software computes the actual status of the overall system. The system can be seen as a three-dimensional, inverse pendulum. The pitch and roll angle are determined by a position scanner. Two PD controllers provide the necessary pulses for the stabilizing drive. These pulses are then converted by three omnidirectional drive wheels, each offset at 120° in a circle, into mechanical motion relative to the spherical surface.
Highly Dynamic And Accurate
Only highly compact motor units can be used to drive the wheels. The required dynamics narrow the options to electronically commutated motors. The optimal choice proved to be 20 mm-diameter brushless DC servo motors with an integrated encoder. Diameter-compliant gearing with a speed reduction of 14:1 supplements the drive package. With it, the small 20-watt drive can supply up to 0.7 Nm for short periods in order to control the position. A toothed belt reduction further boosts the torque to the wheels. The high efficiency factor on the part of the motor (70%) and gearing (80%) enables the use of smaller rechargeable batteries. The smaller dimensions here improve the vehicle’s quick reactions to position commands. The three motor units are continuously deployed independently from one another, thus converting the control commands into mechanical propulsion.
A further advantage for fast, dynamic corrections is the fact that miniature motors, especially electronically commutated variants, are generally able to withstand considerable overload for short periods of time. Due to the low volume, the heat radiating to the surface is comparatively high; the thermal capacity of the materials offers a further thermal buffer. The high efficiency of the unit, e.g. comparatively low power dissipation, enables such a high level of energy transfer above the rated output. In connection with the low level of moving mass, this performance virtually predestines the use of EC drives for highly dynamic functions. This is particularly the case when small installation spaces and/or very low inertial masses, e.g. on the tip of cantilever arms or robotic arms, are necessary.
Even ostensibly playful functions can contribute to the solution of problems. Small prototypes that can complete complex tasks in real time, such as here the active balancing on a ball, are cost effective research objects. Miniature drives with auxiliary modules, such as encoders, gearing, and also integrated controllers, enable not only inexpensive implementations for experiments, but are also suitable for use in professional applications. The large combination variety in connection with individual case adaptation enables a customized solution for every motor task.