Christian Doeller: Conceptual Sensor: Difference between revisions

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For a restart both balls need to be removed and the reset-button on the circuit board is to be pushed.<br>
For a restart both balls need to be removed and the reset-button on the circuit board is to be pushed.<br>
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WORK IN PROGRESS<br><br>
WORK IN PROGRESS<br><br>
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[[File:MazeBoard.jpg]]<br><br>
[[File:MazeBoard.jpg]]<br><br>
Circuit borad with reset switch.<br><br>
Circuit borad with reset switch.<br><br>


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[[File:MazeSetup.jpg]]<br><br><br>
[[File:MazeSetup.jpg]]<br><br><br>
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== Variable Resistance ==   
== Variable Resistance ==   
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This tone range can be adjusted by turning a potentiometer (between pin 7 and 8) and by trying out different capacitors (between pin 1 and 2).<br>
This tone range can be adjusted by turning a potentiometer (between pin 7 and 8) and by trying out different capacitors (between pin 1 and 2).<br>
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WORK IN PROGRESS<br><br>
WORK IN PROGRESS<br><br>
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Testing aluminium parts in the circuit.<br><br>
Testing aluminium parts in the circuit.<br><br>
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RESULT<br><br>
RESULT<br><br>
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[https://www.dropbox.com/s/oxo8mfdqxbg4c8j/Tafel.mp4?dl=0 Video]<br><br><br>
[https://www.dropbox.com/s/oxo8mfdqxbg4c8j/Tafel.mp4?dl=0 Video]<br><br><br>
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== Final Work: The Reexperiventer ==   
== Final Work: The Reexperiventer ==   
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WORK IN PROGRESS<br><br>
WORK IN PROGRESS<br><br>
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[[File:cutting2.jpg]]<br><br>
[[File:cutting2.jpg]]<br><br>
The upper arm needs a „Slider“ - Something that is glued to one part of the arm holding the other (movable)<br> part of it in place. <br> It is important that the „Slider“ is not too tight nor too lose. <br> It should not be too hard to push the flexible part in and it should not have too much space to the <br>left and right at the same time. <br><br><br>
The upper arm needs a „Slider“ - Something that is glued to one part of the arm holding the other <br>(movable) part of it in place. <br> It is important that the „Slider“ is not too tight nor too lose. <br> It should not be too hard to push the flexible part in and it should not have too much space to the <br>left and right at the same time. <br><br><br>


[[File:cutting3.jpg]]<br><br>
[[File:cutting3.jpg]]<br><br>
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[[File:ReexHbridge.jpg]]<br><br>
[[File:ReexHbridge.jpg]]<br><br>
Bringing the parts together with a threaded rod and nutsH-Bridges for spinning each<br> DC-motor back and forth.<br><br><br>
H-Bridges for spinning each<br> DC-motor back and forth.<br><br><br>


[[File:ReexHbridgeCase.jpg]]<br><br>
[[File:ReexHbridgeCase.jpg]]<br><br>
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RESULT<br><br>
RESULT<br><br>

Latest revision as of 08:22, 17 December 2015


The Improbable Switch



MazeModule.jpg

The Improbable Switch, maze module


For the first assignment I built a switch that needs a (playful) effort to be operated.
It should stretch the time between the different states of change - and it should be allowed to „revolt".

I decided to design a little maze.
In the beginning two little metal balls are positioned at the starting point of the maze.
By that time no current flows through the circuit.
The goal is to make one of the balls fall into the „on-hole“ before the other ball reaches the „off-hole“.
The game is over as soon as one of the balls gets trapped in „hell“.

By activating the „on-hole“ a heart beat sound is turned on.
This sound continues until it is turned off by reaching the „off-hole“.
A loud noise starts buzzing for three seconds when one of the balls is trapped in „hell“.

For a restart both balls need to be removed and the reset-button on the circuit board is to be pushed.


WORK IN PROGRESS

GridSketch.jpg

Sketch for the frame of the maze (10 cm x 10 cm).
Each corridor should have a width of at least 1 cm.


GridSketch1.jpg

Final sketch for the two dimesnional structure of the maze.
Defining pins for connecting the „on“ / „off“ circuit.


Underneath.jpg

Setting up the switch structure with wire and tape.
Adding a connection for the „hell“ - circuit (red).


Paperwalls.jpg

Building the three dimensional wall structure of the maze.
The paper walls are jammed into the sliced Kappafix.


MazeSchematic.jpg

Schematic for the electronics with four 555 Timers:
- monostable mode (trigger) for „on“ and „off“
- astable mode for heart beat sound
- monostable mode (trigger) for „hell“ sound
- astable mode for „hell“ sound (using the same speaker)


MazeBoard.jpg

Circuit borad with reset switch.



RESULT

MazeSetup.jpg



Variable Resistance



SchwammCloseup.jpg

Variable Resistance, modified chalk board


The biggest challenge of Variable Resistance was to find materials that are flexible in terms of the current flowing though them.

We tested things by including them into the circuit of a 555 timers astable mode.

After trying out things that I carried to the classroom I had the idea to connect something to the circuit that was already there.
The chalk board was a good example: by connecting a humid rag (to pin 6) and a piece of wet aluminium foil sticking to the board (to pin 7) I could draw sounds by wiping the surface.

Thereby I found out that it is very important to „calibrate“ the used material: a very high and still hearable tone should sound when the rag is put directly onto the aluminium connector.
By moving the rag further away, the tone will become deeper and deeper (as the resistance rises).
This tone range can be adjusted by turning a potentiometer (between pin 7 and 8) and by trying out different capacitors (between pin 1 and 2).


WORK IN PROGRESS

BycicleTyre.jpg

Trying out a bicycle tire filled with water and wire as a variable resistor for a 555 Timer astable mode.
(failed)


OnTop.jpg

Circuit board with 555 Timer astable mode and speaker on top of the chalk board..


AluFoilFirst.jpg

Connecting one side of the resistor to the chalk board via aluminium foil.
The foil sticks automatically to the wet spots on the board.
A sponge was used to draw temporary traces that conduct electricity and therefore
can function as parts of the resistor.


AluModules.jpg

Squares and rectangles of aluminium foil with parallels to different electrical parts.
They can be included in the chalk board circuit.


TestingAlu.jpg

Testing aluminium parts in the circuit.




RESULT

ChalkBoard.jpg

Video



Final Work: The Reexperiventer



ReexSketch.jpg
Reexperiventer, Sketch


Manual:

1. Select an image you want to reexperivent (online, in a book, in a magazine, …)

2. Print it out (7 cm width max.) and put it underneath the tip of the pen so that it is located at the pictures center.

3. Cover the image with a sheet of transparent paper.

4. If you chose a totalitarian, evil, dangerous or seemingly untouchable image: put on rubber gloves.

5. Check out the switches and their effects on the movement of the device.

6. Rotate the device to the starting position. Move down the pen until it touches the paper.

7. Take a deep breath and start drawing. Only draw with maximum awareness and get yourself into every single movement.

8. Rotate the device to the very right or left once you finished reexperiventing.

9. Enjoy the result and be anxious to extend your repertory of reexperiventions!



WORK IN PROGRESS

FirstPrinter.jpg

Salvaged printer parts:
A metal case, rails, transport systems for paper and printer head, two DC motors
and light gate for control of motor movement.


HbridgeSwitches.jpg

Experimenting with two switches (H-bridge) for the horizontal movement of the DC motor.


PrinterVid.jpg

The printer as a drawer.
Manual control of the movements with switches and H - bridge (Video)


Reexsketch.jpg

Idea: A movable „arm“ that allows going back, forth, left and right (movement in x and y direction)
with a changeable „nose“.
Make the printers inner movements visible outside of the casing.


Cutting1.jpg

Cutting the „arm“ pieces out of Kappafix (accessible, easy to work with, strong enaugh and flexible
at the same time).
Gluing them together (sandwiching) for a better stability.


Cutting2.jpg

The upper arm needs a „Slider“ - Something that is glued to one part of the arm holding the other
(movable) part of it in place.
It is important that the „Slider“ is not too tight nor too lose.
It should not be too hard to push the flexible part in and it should not have too much space to the
left and right at the same time.


Cutting3.jpg

The „Slider“ made of papercard glued to the longer side of the upper arm.


ReexWheel1.jpg

The lower (static) arm did not move back and forth - the pressure from the wheels of the printer
was too low.
Another single wheel had to be installed that allows the back wheels to apply more pressure on the arm.
The same thing has been done in the front later on.


3erWheel.jpg

How can the „joint“ of the two arms move to any x/y direction?
It needs wheels that are like rolling spheres.
This prblem has been solved with wheels from the hardware store:
they contain axle bearings that allow them to circle around their own case.
Three of these wheels are enough for a stable platform.


ReexAllParts.jpg

Bringing the parts together with a threaded rod and nuts.


ReexCallibration.jpg

Defining the reachable area by pushing the arms to their maximum position.


ReexPWM.jpg

The PWM Schematic for controlling the speed of the DC motors.


ReexPWMcase.jpg

The PWM module in its case with a knob to control the motor speed and a connector for a
9V DC power supply that works with 220V AC from a common power plug.


ReexHbridge.jpg

H-Bridges for spinning each
DC-motor back and forth.


ReexHbridgeCase.jpg

The „Game Pad“ in a Kappafix case.


ReexWired.jpg

Everything brought together and wired up.


Reexfirst.jpg

The first drawing..


ReexSelfie.jpg

„Self Portrait“ with and without additional stabilisation.


ReexSelfieMe.jpg

„Self Portrait“ # 2




RESULT

ReexVideo.jpg

Video