Showing posts with label conductive filament. Show all posts
Showing posts with label conductive filament. Show all posts

Wednesday, June 23, 2021

555 Timer - LED Flasher with conductive 3D Filament - Astable Mode

555 Timer - LED Flasher with conductive 3D Filament

Written by Larsha Johnson

Bits4Bots, LLC

 Rapid circuit prototype with a 3D printer and conductive filament. This project features a simple circuit designed to explain the working and use of a 555 timer IC. The connection used is credited to this blog LED Flasher Circuit 
 The 555 timer was one of the first IC chips I learned to use in a project back when I attended community college. I learned to read the datasheet and create my first flashing LED! This is a good place to start for those new to electronics. *I recommend reading the 555 timer datasheet to learn more!


3D printer
Proto-Pasta filament
eSun PLA filament
555 timer IC
5mm LED or similar i.e 3mm, 10mm
1uF capacitor - C1 * Can be SAT (selected at testing)
x2 resistors (1K) - R1 & R3
1 resistor (100K) - R2 *Can be SAT (selected at testing)
9V battery
9V snap connector

Download and print the 3D file(s) here or from Thingiverse I designed the assembly for one single print

(1hr 30min) or in two parts 45min each:

Base 30mm x 30mm
Traces for testing purposes (different Z-axis height layers for various conductivity)
For TinkerCad users see link: Tinkercad

Note: When the print is 7% to 8% complete, the conductive filament should follow. Here is a great Instructable for welding 3D filament Filament Fuser.

*I simply snipped off the colored PLA with a wire cutter, then guided the conductive filament into the 3D printer until the extruder accepted (grabbed) it.

After the print is complete the top layers of the board should have 3mm+ conductive filament.

Pin 2 and 6 are connected. All other pin connections will need to be made manually.

Place 555 timer onto 3D printed board and press firmly to make a strong connection. Careful not to bend the legs!

1. Connect pin 4 and 8 together with a male to male jumper or wire. *tinned wire for optimization
2. Connect LED ground leg to pin one.
3. Connect R3 (1K ohm) to +itive lead of LED, and then to pin 3.
4. Connect R1 between pin 6 and 7
5. Connect R2 between pin 7 and 8
6. Place C1 between pin 1 and 2 *-itive lead to pin 1 (for polarized capacitors)
7. Note: Pin 5 will not be connected (this is also called floating)

The last step is to power the circuit. 5V-9V is a good value to use for the power supply. Here I used a 9V battery and snap connector.

Connect negative lead to pin 1. Connect positive lead to pin 8

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**Did we make a mistake? Let us know :)

Before we designed our 555 timer circuit we conducted a search for conductive 3D filament. There are several companies that you can choose from. We decided to go with Proto Pasta. The details for conductivity are below:

Volume resistivity of molded resin (not 3D Printed): 15 ohm-cm
Volume resistivity of 3D printed parts perpendicular to layers: 30 ohm-cm
Volume resistivity of 3D printed parts through layers (along Z axis): 115 ohm-cm
Resistance of a 10cm length of 1.75mm filament: 2-3kohm
Resistance of a 10cm length of 2.85mm filament: 800-1200ohm


Now that the resistivity is known the next challenge is to calculate the resistance in each trace used.

I measured 2k Ohms in the curved traces on pin 1 and on pin 8. These are the traces that connect the power supply.

The shortest traces measure 1k Ohms. Pin 4 and pin 5.

The trace from pin 2 to pin 6 is 1.5k Ohms.

The T-shaped trace, pin 3 (trigger) and pin 7 around 1.5k Ohms.

***Increased layers on the Z-axis = increase the resistance. Less layers can be used to best resemble standard wires such a copper or other metals presented in general printed circuit boards. This portion of the 3D PCB is a work in progress.

In addition, advanced users can accurately determine exact wire (3D trace) resistance via circuit simulation software that can perform line calculations i.e. NI Multisim, ADS (Keysight), and others.

Calculate LED Flash Time

For the 555 Timer IC you, the designer, will calculate on/off flash time. The link below is a great way to calculate your design or check your math work. 555 Astable Circuit Calculator


Increasing C will increase the cycle time (and hence, reduce the frequency).
Increasing R1 will increase Time High (T1), but will leave Time Low (T0) unaffected.
Increasing R2 will increase Time High (T1), increase Time Low (T0) and decrease the duty cycle (down to a minimum of 50%)
By hand you can use these formulas to calculate the LED time on/off in seconds.

Time high (on) = 0.7 * (R1 + R2) * C1

Time low (off) = 0.7 * R2 * C1

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