Maybe 20 minutes with some cardboard for a mock-up to get a feel for proportions, another 20 minutes with #Tinkercad, snacks, and over to the printer for a 25% print. At 3mm thickness I forgot that the 25% was going to be less than a millimeter thick, but no issues getting it off the base as long as I let it cool down all the way.

No "floppy drive" slot. Going for the feel more than accuracy. Also thinking of a low and wide version that looks more like the Lisa.

I should have printed something for the temporary computer screen.

I'm thinking of finishing the design with no mounting hardware. I built the North Pi case and thought there were some pieces that could have skipped the hardware, and I should put my money where my mouth is, even though I'm clearly no designer.

#DuskOS #RaspberryPi #LetsGoRetro

A wafer thin bend of plastic about 5cm tall with the rake of a modernistic photo frame holds a handwritten piece of paper as a mock computer screen. The paper simply says "ok" in homage to the traditional FORTH programming environment prompt.

**Elod Pal Csirmaz** @csirmaz@fosstodon.org · Mar 24

Mar 24

Elod Pal Csirmaz @csirmaz@fosstodon.org

I've started using @Vivaldi but am encountering some issues. I cannot type into the microsoft/ #outlook login page, and it seems to me that repeated downloads of the same name don't happen.

For example, on #tinkercad, exporting repeatedly from the same project creates a download of the same name. #Vivaldi opens the download dialog, but the file doesn't appear.

Anyone noticed anything like this?
And can one submit bug reports without going through the forum?

**Gabriel Pettier** @tshirtman@mas.to · Feb 25

Feb 25

Gabriel Pettier @tshirtman@mas.to

So, took me a lot of design, iteration, a few failed prints and facepalms, and some help from the solder iron in the end, but my bike phone support for my Ulefone 27T pro (a bulky and heavy rugged phone), might be ready for real world testing (and hopefully won't explode on the first bump ).

First project of this complexity on the 3D printer, not perfect, surely a simpler design exist, but this is what i got for now.

3D view of modeled parts on a plane, for 3D printing, there is a structure in two parts to hold a phone, a layer where two parts can be pulled together to drive the two sides, flat springs, a support to attach to the bike, and various small parts to hold everything together.

Side view of the printed and assembled bike phone stand, it's blue colored, at the top we see the parts meant to grab the phone, with a small lever to close the mechanism, under it a layer of 6 short springs connect that part to a second layer, where 2 circle attachments can be seen on one side to connect to the handlebar, and a long one connected to a vertical spring, on the other, to connect to the head tube.

Front view of the final print, the split bad for the phone is visible, with a lever on the side to close them together and hold the phone in place.

#TinkerCad #3dPrinting #bamboulab

**Ana Cardamine** @cardamine@piaille.fr · Feb 17 *

Feb 17 *

Ana Cardamine @cardamine@piaille.fr

#introduction #introductionfr

À la recherche d'un coin de net où trainer pendant les réunions trop longues, les pauses déj', les insomnies, et en essayant de se libérer des Gafam.

Ici, je n'ai pas tout compris et déjà changé 3 fois d'instance, retrouvé seulement 3 contacts de la vraie vie... Mais aussi plein de comptes de l'époque où twitter était fréquentable. Et j'aime bien le système de liste... C'est prometteur !

Et donc la présentation : J'aime lire des bd (et +), je dessine (parfois), j'aime la culture diy ... Ma dernière lubie c'est l'impression 3d (#tinkercad ).

Anxieuse, je vis actuellement en dissonance cognitive. #LeFuturCÉtaitMieuxAvant

Photo d'un dessin punaisé représentant un personnage assis au sol, on ne voit pas la tête , les détails sont portés sur une main et un pied. Le dessin est réalisé au crayon de couleur avec un trait dynamique et raturé. ( Pas facile l'exercice du alt !)

**mirobo Technology** @mirobotech@techhub.social · Feb 7

Feb 7

mirobo Technology @mirobotech@techhub.social

It's freebie Friday!

Hey #STEM teachers, we just finished updating our free #Tinkercad lesson activities created to help you teach #electronics and #Arduino #programming – now for both ARPS and ARPS2!

Find them all here: https://mirobo.tech/electronics

Start learning: https://www.tinkercad.com/things/0A7EIOHHtCo-arps2-introductory-activity-1

A blue ARPS2 circuit prototype is sitting on a laptop's palm rest and the Arduino UNO R4 circuit underneath the ARPS2 is connected to the laptop with a USB cable. The laptop screen shows a part of the ARPS2 circuit re-created on a breadboard in Tinkercad, and the code window shows a beginner learning activity. The laptop is sitting on a table top along with a SONAR module, a screwdriver, a black pen, and a classroom Sumo robot controlled by the original ARPS circuit.

The Educational Starter configuration of an ARPS2 circuit is built on a breadboard in Tinkercad. The program code window is open at the right side of the screen showing the loop function of a beginner program as well as the first program analysis activity.

**mirobo Technology** @mirobotech@techhub.social · Feb 5

Feb 5

mirobo Technology @mirobotech@techhub.social

Wanna play with my new, prototype ARPS2 (Arduino Robot Project Shield, v. 2) circuit in #Tinkercad? Try it here: https://www.tinkercad.com/things/86ZfsS56ZBk-arps2-full-robot-circuit

ARPS2 is designed to make it easy for beginners to learn #Arduino programming quickly (no breadboarding), and to help them build simple #robots!

An ARPS2 (Arduino Robot Project Shield, version 2) circuit with an HC-SR04 ultrasonic SONAR distance sensing module installed in its expansion header is attached to an Arduino UNO R4 Minima sitting on top of a laptop's trackpad. The laptop screen behind ARPS2 shows the ARPS2 circuit built in the Tinkercad simulator including an attached SONAR module, two servos, and two DC motors. The code window is open showing a demonstration C language program for the ARPS2 circuit.

An ARPS2 (Arduino Robot Project Shield, version 2) built on a breadboard attached to a virtual Arduino UNO R3 in the Tinkercad simulator. The ARPS2 circuit includes 4 user pushbuttons, 4 user LEDs, a piezo beeper, an IR demodulator, a temperature sensor, a battery voltage divider circuit, two IR LEDs and phototransistors, a motor driver with two attached motors, two servos, and an ultrasonic SONAR distance sensor module. The code window is open showing the ARPS2 robot starter program running. The Serial monitor shows the current values returned by the phototransistors, temperature sensor, and voltage divider.

#STEM #STEMeducation #robotics

**LED Patrick** @pbl0m@phpc.social · Feb 2

Feb 2

LED Patrick @pbl0m@phpc.social

What Makes a Designer a Designer?

Recently, I had a conversation with some creatives about #3DModels and the process of designing them. When I mentioned that I use #Tinkercad for most of my designs, they laughed and suggested I switch to a "real" CAD program or Blender, claiming Tinkercad is too basic.

It got me thinking—does being a designer depend on the tools you use , or is it about the creative skill and vision you bring to the table?

What's your opinion on this?

**mirobo Technology** @mirobotech@techhub.social · Jan 19

Jan 19

mirobo Technology @mirobotech@techhub.social

Do you know anyone who wants to build a simple 3D-printable robot?

I just shared all of the parts of the BEAPER Bot robot chassis (so far) on the @PCBWay site: https://www.pcbway.com/project/shareproject/BEAPER_Bot_Robot_Chassis_d369f8bb.html

It includes all of the links to the #Tinkercad part designs too!!

A red, 3D-printed BEAPER Bot robot controlled by a BEAPER Pico circuit with an on-board Raspberry Pi Pico microcontroller (green PCB), full-colour graphical LCD (black rectangle), and an ultrasonic SONAR distance sensor module (left). Two optical line sensor modules in dove-tail mounts are attached on opposite sides at the front of the robot, which has been assembled in a rear-drive configuration.

The parts to build a BEAPER Bot robot spread out on a wooden table top. Clockwise from left is a BEAPER Pico PCB with an installed Raspberry Pi Pico 2 W microcontroller (green) above an optional LCD display (black rectangle), two N20 DC gear motors (top) above a steel roller ball assembly, two white, 3-spoke wheels with rubber tires, a black 4AA battery holder, a red, 3D-printed BEAPER Bot chassis, and two optical floor sensor modules (bottom) consisting of floor sensor PCBs (snapped away from the BEAPER Pico PCB) installed in red, 3D-printed floor module mounts.

#STEM #STEMeducation #robots

**Virgil Tibbs** @virgil_tibbs@norden.social · Jan 8

Jan 8

Virgil Tibbs @virgil_tibbs@norden.social

@kuketzblog

Moin!
Haben Sie zufällig schon mal was von der #Schulsoftware #TinkerCAD gehört?
Ich soll für meinen Sohn ein Einverständnis unterschrieben und Daten gehen an Drittparteien.
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**Giacomo Alessandroni** @Galessandroni@wikis.world · Dec 14, 2024 *

Dec 14, 2024 *

Giacomo Alessandroni @Galessandroni@wikis.world

Christmas time, time to fly with fantasy: this is XB (X-mas Bot).
We have used #Tinkercad to draw it and for the drawing we have used the free hand tool.
So, this activity can be replicated also in primary schools, like first approach to #3Dprinter.
--
#STEM #Robotics #STEMeducation

An X-mas Bot (XB) designed by the imagination of my robotics pupils'. It was made with Tinkercad and drawn freehand. It has movable hands, arms and legs. Eventually, in the heart a LED with a battery.

**mirobo Technology** @mirobotech@techhub.social · Dec 6, 2024

Dec 6, 2024

mirobo Technology @mirobotech@techhub.social

It's freebie Friday!!

Do you need a component lead bender for through-hole resistors or diodes? 3D-print or modify your own with this model in #Tinkercad: https://www.tinkercad.com/things/gxNAhfW3YLA-component-lead-bender

A red, 3d-printed component lead bender with three labelled sizes sitting on a blue solder mat with a group of 1/4W resistors and a blue PCB. Two of the resistors have had their leads bent.

#STEMeducation #electronics

**Tomi** @tomi@blog.rozman.info · Nov 26, 2024 *

Nov 26, 2024 *

Tomi @tomi@blog.rozman.info

If you’re reading this on fediverse and the layout (embedded pics) is off, here’s the link to the original blog post.

The problem:

My ceramic pot planted with basil had no stand and the water was flowing everywhere after the watering. Some mold grew under the pot because of that.

I had some old #TPU lying around and an afternoon of spare time so I designed and 3D printed the stand.

I’ll describe step-by-step process with all the tools that I use.

1. step: redrawing the pot bottom and measuring

I’ve put a sheet of paper under the pot and sketched it with pencil. Then I measured the radius of circular parts.

2. step: making 3 cylinders in TinkerCad’s Codeblocks

I couldn’t figure out how to make 3 cylinders equally distributed from the center in TinkerCad (manually). Then I found ‘Tinekrcad Codeblocks’ that allows constructing 3D objects using the code (similar to OpensCad).

I reused built-in example, modify it a bit to draw 3 cylinders on the spokes of a 3-sided star (invisible, just a helper):

3. step: exporting from Codeblocks and importing to TinkerCad

I’ve exported generated shape to .stl and imported it to TinkerCad. Maybe there is a more direct way to transfer the shape from CodeBlocks to TinkerCad, but I couldn’t find it.

4. Adding the missing parts in the centre

There is something missing between the circles, right?

I’ve designed the missing center part in TinkerCad: I added a bigger shallow cylinder to the middle (orange – see the pic below) and cut out the edges (gray). The blue parts are imported from Codeblocks.

The remaining part filled the empty space between the displaced blue cylinders.

5. Cuting out

I designed a similar shape (steps 1-4) for a cutout:

6. The final shape

The final shape is 8mm high and the cutout is 6mm deep – the botton is 2mm thick.

7. Slicing

I’ve used the following setting for 3D printing:

printer: Sovol SV06 with Marlin and Octoprint on separate server connected via USB)
sliced with: Sovol Cura 1.5.4 (old, but still works better for me than the latest version)
material set in slicer: Generic TPU 95A
bed temp.: 60C
nozzle temp.: 220C (230C later)
fan speed: 5% (later changed to 0%)
nozzle size: 0.4mm
layer height: normal – 0.15mm
speed: 40mm/s
infill: 10% (but it’s not needed here)
other settings: ‘arc welder’, ‘dynamic precision’ and ‘use adaptive layers’ turned on in Sovol Cura
hardware settings: I’ve loosened down the screw (spring) that pushes against the filament at the extruder entry. Otherwise, the filament will get stuck in the extruder gears.

I had some problems placing the object correctly on the printing bed. The object is so big it covers the whole printing bed. After some retries (rotating, moving it around, reducing the size to 98%) I found almost perfect position, but not quite.

8. 3D printing with TPU

I also used the filament directly from the filament drying chamber (#Sovol), set firstly to 40C and after the 1st layer to 50C. I’ve noticed the filament was a bit wet (I heard pops and crackles at the beginning of printing).

The first layer was perfect, almost fits to the category ‘1st layer porn’:

… but the second layer was crap (sorry, no picture). It was underextruded with long gaps of missing filament.

I changed the settings mid-print to:

fan speed: 0%
Extrusion rate: 110%
Temperature: 230C

After this change, it printed better.

I used #Octoprint and #ESP32 cam to record the timelapse. I know, I should move the camera somewhere closer to the printing bed to get a better timelapse.

https://youtu.be/g2iOPVEEl1g

I’m also using Octoprint’s PrettyGCode viewer to monitor the progress:

To monitor the print in realtime from my living room (the printer is located in a workshop), I’m using #HomeAssistant with the ESP32 camera video feed embedded and the automation that notifies me when the printing is done.

The final result after 14hrs of printing and 83g (28m) of spent filament:

I’m quite satisfied with the final result. It’s flexible and no strings, blobs or similar. The flat/cut area at the top left corner is because the size of the object is too big for my printer (23.5 x 23.5cm). I tried to fit it on the plate by rotating it and scaling it to 98%, but that was the best fit I could do. It’s not an issue, because the material is flexible and wraps around the pot.

The pot fits perfectly: Now the water will not flow everywhere.

Despite numerous fails (all my fault), I still love #tpu.

It’s finnicky, but the results are good looking, flexible and durable.

For more examples of TPU 3D prints see my previous post.

https://blog.rozman.info/3d-design-and-printing-with-tpu-plant-pot-stand/