User:Mike Barnkob/Projects/Liquid handling robot: Difference between revisions
Mike Barnkob (talk | contribs) (→Week 1) |
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Programmed two aspiration and dispensing programs, called 'asp & disp 1 and 2 (16-03-10).c'. The code for asp & disp 2 is: | Programmed two aspiration and dispensing programs, called 'asp & disp 1 and 2 (16-03-10).c'. The code for asp & disp 2 is: | ||
< | <pre> | ||
#pragma config(Motor, motorA, motor_A, tmotorNormal, PIDControl, encoder) | |||
#pragma config(Motor, motorB, motor_B, tmotorNormal, PIDControl, encoder) | #pragma config(Motor, motorB, motor_B, tmotorNormal, PIDControl, encoder) | ||
//*!!Code automatically generated by 'ROBOTC' configuration wizard !!*// | //*!!Code automatically generated by 'ROBOTC' configuration wizard !!*// | ||
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DispensControl(-15, 0, 250); | DispensControl(-15, 0, 250); | ||
}</ | } | ||
</pre> |
Revision as of 02:48, 17 March 2010
Liquid handling robot
Introduction
Background
Ressources
Software
Hardware
- Articles on construction of trusses by TJ Avery.
- Linear actuator by Xander Soldaat
- Aluminium beams
- Firgelli Linear actuators
Knowledge
- Introduction to the RobotC programming language by Albert W. Schueller.
- Creating own functions in RobotC By Albert W. Schueller.
- Robot C Functions help
- Introduction to robotics at Stanford Engineering.
Ideas
Notebook
Week 1
Monday: Worked on the primary handling operation with a very simpel design and set up the lab space.
The linear actuator works up to aboout 1,6 cm, putting a limit on how much the pipet can be pushed down. Solutions might be: using two actuators, using a rail-design instead or adding more power to the actuator.
The design is becoming quite big. Solution might be to use the power function powers, which are smaller.
The pipet needs to be tested for accuracy.
Tuesday: Continued working on the dispensing handling. Created a successful design with two motors that press down on the pipet. I'm a bit nervous about the stress on the motor, but for now they seem to do fine.
The battery in one of the NTX bricks already ran out. I've ordered a rechargeable battery - but no transformer, since they are not sold here. Hopefully the inlet will accepts other transformers as well.
Programmed two aspiration and dispensing programs, called 'asp & disp 1 and 2 (16-03-10).c'. The code for asp & disp 2 is:
#pragma config(Motor, motorA, motor_A, tmotorNormal, PIDControl, encoder) #pragma config(Motor, motorB, motor_B, tmotorNormal, PIDControl, encoder) //*!!Code automatically generated by 'ROBOTC' configuration wizard !!*// //DECLARING FUNCTIONS //Control of the dispenser void DispensControl (int DCmotor, int DCencode, int DCpause) { //Syncronizing motors nSyncedMotors = synchAB; nSyncedTurnRatio = +100; // Left motor turns 100% of right motor //Power up while( !(nMotorEncoder[motor_A]==DCencode) ) { motor[motor_A]=DCmotor; nxtDisplayClearTextLine(5); nxtDisplayClearTextLine(6); nxtDisplayString (5,"%d, %d", nMotorEncoder[motorA],nMotorEncoder[motorB]); nxtDisplayString (6,"%d, %d", DCencode, DCmotor); wait1Msec (1); } motor [motorA] = 0; //End pause if any wait10Msec(DCpause); } //MAIN TASK task main () { nxtDisplayString (1,"DISPENSING 2"); nMotorEncoder [motor_A] = 0; //Air-out nxtDisplayClearTextLine(3); nxtDisplayString (3,"Air-out"); DispensControl(30, 30, 0); DispensControl(70, 60, 250); //Aspiring nxtDisplayClearTextLine(3); nxtDisplayString (3,"Aspiring"); DispensControl(-15, 0, 250); //Dispensing nxtDisplayClearTextLine(3); nxtDisplayString (3,"Dispensing"); DispensControl(30, 40, 0); DispensControl(70, 80, 250); //Resetting nxtDisplayClearTextLine(3); nxtDisplayString (3,"Resetting"); DispensControl(-15, 0, 250); }