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Autonomous Silicon Microrobots

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Presentation on theme: "Autonomous Silicon Microrobots"— Presentation transcript:

1 Autonomous Silicon Microrobots
Sarah Bergbreiter Prof. Kris Pister Berkeley Sensor and Actuator Center UC Berkeley ICAT 47th International Smart Actuator Symposium October 3, 2006

2 What is an Autonomous Silicon Microrobot?
Size Total size on order of millimeters Mobility Should be able to move around a given environment Speeds of mm/sec Manufacture MEMS techniques used for batch fabrication Autonomous Power and control on-board Communication between robots (?) Size Target Space Input Power Size ~ mm Input Power ~ 10s mW Speed ~ 10 sec / jump Speed

3 Applications for Autonomous Silicon Microrobots
Mobile Sensor Networks Search and Surveillance Cooperative Construction Planetary Exploration Key Technologies Large force, large displacement actuators Mechanisms (transmission/linkages) Energy storage for “High output power for short time” actuators

4 Actuator Requirements for Autonomous Microrobots
Low Input Power Small Size Force/Displacement Efficient Simple Fabrication and Integration Power Supply Compatibility Robust Yeh, 2001 Lindsay, 2001 Kladitis, 2000 Pelrine, 2002 Wood, 2005 Lu, 2003

5 Electrostatic Gap Closing Actuators (GCAs)
High force at low input power and moderate voltage Fabricated in single mask process l + - V d t k F

6 Electrostatic Inchworm Motor Operation

7 Electrostatic Inchworm Motor Operation

8 Electrostatic Inchworm Motor Operation

9 Electrostatic Inchworm Motor Operation

10 Electrostatic Inchworm Motor Operation

11 Electrostatic Inchworm Motor Operation

12 Electrostatic Inchworm Motor Operation

13 Electrostatic Inchworm Motor Operation

14 Electrostatic Inchworm Motor Operation

15 Electrostatic Inchworm Motor Operation

16 Electrostatic Inchworm Motor Operation

17 Solar Powered 10mg Silicon Robot Inchworm Motors
Designed 400mN 50V in 2.8 mm2 silicon area Demonstrated 6.8 mm/s shuttle speed Demonstrated 400 mm shuttle travel Demonstrated 60 mN force at foot

18 Solar Powered 10mg Silicon Robot

19 Why Was This So Difficult?
Failure in motors due to load forces and/or teeth slipping Complex process to integrate hinges and motors together Two 1-DOF legs dragging robot not very robust or adaptable to different surfaces

20 Try Jumping Instead Improve Mobility Improve Efficiency
Obstacles are large! Improve Efficiency What time and energy is required to move a microrobot 1 m and what size obstacles can these robots overcome? Ant (Walking) Proposed (Jumping) Hollar (Walking) Ebefors (Walking) Mass 11.9 mg 10 mg 80 mg Time 15 sec 1 min 417 min 2.8 min Energy 1.5 mJ 5 mJ 130 mJ 180 J Obstacle Size ** 1 cm 50 m 100 m

21 Building a Jumping Microrobot
Spring for energy storage short legs imply short acceleration times Higher force, larger displacement motor Power for motors and control Controller to direct motors Landing and resetting for next jump are NOT discussed From what we’ve already shown, the robot is going to require. Emphasize that landing and resetting for next jump are not discussed.

22 Demonstrated Energy Storage
20 mJ of energy stored corresponds to 20 cm jump straight up for 10 mg robot

23 Building a Jumping Microrobot
Spring for energy storage short legs imply short acceleration times Higher force, larger displacement motor Power for motors and control Controller to direct motors Landing and resetting for next jump are NOT discussed From what we’ve already shown, the robot is going to require. Emphasize that landing and resetting for next jump are not discussed.

24 Actuator Challenges for Jumping Microrobots
Motor work  kinetic energy for jump Drag is not large effect at smaller energies Actuator requirements High energy density Large deflection (5mm) Large forces (10mN) Simple process integration Previous inchworm motor specs could only store 8 nJ

25 Increase Displacements
Remove silicon springs used to keep the shuttle in-plane Use micro rubber band to return shuttle to original position Assembled clips demonstrated without complex processing Subramaniam Venkatraman, 2006

26 Higher Forces Decrease Gap k Increase Voltage V d Increase Area -
Disadvantage: new clutch design and lithography limits Increase Voltage Disadvantage: power and electronics Increase Area Disadvantage: greater area implies greater mass Increase dielectric constant Disadvantage: processing and small displacements l + - V d t k F

27 Reduce Gaps Use insulating stops integrated in fingers of gap closers to determine final gap Initial gap = g2 Final gap = g2 – g1 Charging issues minimized if insulator area is kept small For example: g1 g2 g1 2 mm g2 2.5 mm Nitride Insulator Silicon Plate E. Sarajlic, E. Berenschot, G. Krijnen, and M. Elwenspoek, "Versatile trench isolation technology for the fabrication of microactuators," Microlectronic Engineering, vol , pp , 2003.

28 Reduce Initial Gap 0V Drive Actuator Transmission
Drive force dependent on initial gap of the drive actuator Add a transmission to reduce initial gap beyond lithographic limits Provide an additional mechanical stop to limit return motion of drive frame Force required minimized to just the restoring force of springs on drive frame Reduces force density of actuator, but effect minimal + - 0V Drive Actuator Transmission

29 Reduce Initial Gap 0V 50V Drive Actuator Transmission
Drive force dependent on initial gap of the drive actuator Add a transmission to reduce initial gap beyond lithographic limits Provide an additional mechanical stop to limit return motion of drive frame Force required minimized to just the restoring force of springs on drive frame Reduces force density of actuator, but effect minimal + - 50V Drive Actuator 0V Transmission

30 Reduce Initial Gap 50V Drive Actuator Transmission
Drive force dependent on initial gap of the drive actuator Add a transmission to reduce initial gap beyond lithographic limits Provide an additional mechanical stop to limit return motion of drive frame Force required minimized to just the restoring force of springs on drive frame Reduces force density of actuator, but effect minimal + - 50V Drive Actuator Transmission

31 Reduce Initial Gap 50V 0V Drive Actuator Transmission gnew
Drive force dependent on initial gap of the drive actuator Add a transmission to reduce initial gap beyond lithographic limits Provide an additional mechanical stop to limit return motion of drive frame Force required minimized to just the restoring force of springs on drive frame Reduces force density of actuator, but effect minimal + - 0V Drive Actuator 50V Transmission gnew

32 Fabricated Transmission
4mm to 3mm initial gap demonstrated Suspension problems prevented proper clutch operation

33 New Clutch Design Need to effectively transmit drive force to the shuttle If gear teeth are used on the shuttle, reducing step size impacts drive actuators required If one drive actuator used: Step size limited to 4 mm Solution: Remove teeth Coefficient of friction of ~1 observed Clutch force dependent on final gap so area does not explode

34 How Much Does This Help? g g g g W All numbers calculated at 50V
Previous Designs (demonstrated) Current Designs (proposed) Theory Force Density (mN/mm2) 0.14 1.6 ~50 Power Density (W/g) 0.01 ~600 g g g W All numbers calculated at 50V Multiply by 10 to get approximate numbers at 150V Theory assumptions AR = 25:1, g = 1 m Spring constant based on given force Spring constant much higher than could be used in practice due to damping and clocking

35 Conclusions and Future Work
Silicon inchworm motors provide high forces and displacements at low input powers for autonomous silicon microrobots Assembled clips provide higher linear displacements Nitride isolation structures and transmission provide smaller gaps for increased forces Demonstrate a silicon inchworm motor with > 1mN force and > 1 mm displacement (in progress) Add with energy storage system to build fully functional autonomous jumping microrobot


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