Tag: tutorial

Programming the body interaction 2 (BI2) with Blynk part 1

This in an intro to using and programming the BI2 with the Blnyk app. Read here how to set up Arduino. For a more general basic intro (based on the body interaction 1 board) read here.

Pins

The communication between app and BI2 microcontroller is realized by pins. The idea is very easy: Each widget in the Blynk app is connected to a physical pin of the microcontroller. Every microcontroller has several pins where you can connect other electronic parts like a LED or a vibration motor. For each pin you have to configure if it is a output or input pin. Output pins are for controlling actuators, like LED, motor or display. Input pins are connected to sensors, like buttons, temperature sensors, acceleration sensor.  In addition each pin can be digital, analog or virtual.

Digital output pins can only set the actuator to on or off e.g. turning the LED on or off. Analog pins can set the actuator to a specific value in a given range. Usual this in done in the range [0..255] or [0..1023]. For a motor 0 will set the motor off, 50 may be make the motor move very slowly and 255 will be full speed. An analog output pin is sometimes called PWM. (PWM is a method to simulate an analog signal with a sequence of digital on/off signals.)

Digital input pins can read the position of a button (on/off). Analog input pins can read a value in a given range, e.g. the acceleration in the X-axis or the temperature.

So what you have to do to connect a widget to a pin? Just set the widget (e.g. on/off switch widget) to the pin you want to set on/off (e.g. a pin which is connected to a LED). That’s all. No programming required. All you need is this small program which must be uploaded to the microcontroller with the Arduino IDE.

The body interaction 2 use the ESP8266 microcontroller. There are 16 pins, all could be used as digital or analog, input or output. But only pin 12 and 13 are free to use (the rest if for internal communication). Pin 14 is connected to the LED WS2821B.

The Arduino sketch

The first 3 lines are for configuring Blynk and using two libraries. The 3 variables auth, ssid and pass are defined. (The variables are from thy type char (=character) and in this case it is not only one character but an array which you can see by the “[” and “]”. Here you have to add your AUTH token from the Blynk app, and SSID and password from your local WLAN/WIFI.

#define BLYNK_PRINT Serial 
#include <ESP8266WiFi.h> 
#include <BlynkSimpleEsp8266.h> 

char auth[] = "XXXXXXXXXXXXXXXXXXXXXXXXXXX"; 
char ssid[] = "XXXXXXXX"; 
char pass[] = "XXXXXXXX";

Each Arduino program consists of a setup and a loop procedure. The setup is called only one time when the microcontroller is started (or connected to a battery). It is used to initialize the microcontroller, in this case Blynk is started. The loop will be called indefinitely and all statements are executed in the given order. To get Blynk running you have to call Blynk again and again (“Blynk.run();”). According to the Blynk manual, you should not add a delay() function here, because this could disturb the communication between the app and the microcontroller.

void setup() { 
  Blynk.begin(auth, ssid, pass); 
} 

void loop() { 
  Blynk.run(); 
}

Virtual pins

So far communication is only possible with physical pins. But how can you exchange other information? Maybe you want to tell the microcontroller to “shut up immediately”,  or you want to play a given vibration pattern like a sinus curve. For this you can use “virtual pins”. (IMHO there is no reason to call this mean of data exchange “virtual” and it is has nothing to do with a pin. You can call it a variable or channel for data exchange.) The zeRGBa widget is a good example. The color of the LED is controlled by 3 values, the amount of red, green and blue color. This 3 values can be connected to one virtual pin (“V0”) and then they will be transmitted to the microcontroller. To change the color of the LED you have to program the microcontroller  to read out the amount of each color and set the LED to the appropriate value.

We will demonstrate virtual pins with the LED. The WS2821B LED is connected to pin 14, but you cannot control the LED directly by setting the pin to a given value. This is done by a library which controls the LED.

First we have to include the library, we use FastLED.

#include "FastLED.h"

Then  we have to tell how many LEDs we have (you can put several of them in a chain). The BI2 has only one on board (but you can add more).

#define NUM_LEDS 1 // number of LEDs

The you have to tell to which physical pin the LED is connected (14). Finally you have to set up a (instance of an) object “CRGB” for the LED where all relevant data is hidden.

#define DATA_PIN 14 // pin for LED 
CRGB leds[NUM_LEDS]; // define the array of leds

Now comes the more difficult part. The zeRGBa widget has 3 values (one for red, one for green, one for blue) and all are put in the virtual variable V0.

We have add a new function called “BLYNK_WRITE(V0)”. To get the first value we have to read out “param[0]”, for the second “param[1]” etc. We want to store this first value in a variable “i” of the type integer. To assure that param[0] is also from the type integer we add “.asInt()”. The value for red is put in variable i, green in j and blue in k.

BLYNK_WRITE(V0) {
  int i = param[0].asInt();
  int j = param[1].asInt(); 
  int k = param[2].asInt();
}

Now we have to tell the function BLYNK_WRITE what to do with the values i, j an k. This is done by using the method setRGB which is attached to the LED (which is number 0)

leds[0].setRGB(j,i,k);

Now we can make changes to other LEDs (if we have more than one). If you are ready you have to tell the LED to show the new color.

FastLED.show();

In addition a new statement has to be added to setup the LED within the setup part.

void setup() { 
  FastLED.addLeds<WS2812B, DATA_PIN, RGB>(leds, NUM_LEDS);
  [...]

Now we can put everything together the script will look like this:

/*************************************************************
Controling the body interaction 2 board with the Blynk app
*/

#define BLYNK_PRINT Serial
#include <ESP8266WiFi.h>
#include <BlynkSimpleEsp8266.h>

// Auth Token infor the Blynk App.
char auth[] = "XXXXXXXXXXXXXXXXXXXXXXXXXXX";

// Your WiFi credentials.
char ssid[] = "XXXXXXXX";
char pass[] = "XXXXXXXX";

// Library for controlling the WS2821B (Neopixel) LED or LED strip
#include "FastLED.h"
#define NUM_LEDS 1 // number of LEDs
#define DATA_PIN 14 // pin for LED
CRGB leds[NUM_LEDS]; // define the array of leds

// This function set the LED color according to the selected RGB values in the app.
// RGB values are controlled in the app with zeRGBa widget
// values are stored in the virtual pin V0
// V0 consists of 3 values for Red, Green, Blue
BLYNK_WRITE(V0) // set LED RGB color values
{
  int i = param[0].asInt();
  int j = param[1].asInt();
  int k = param[2].asInt();
  leds[0].setRGB(j,i,k);
  FastLED.show();
}

void setup()
{
  // init LEDs
  FastLED.addLeds<WS2812B, DATA_PIN, RGB>(leds, NUM_LEDS);

  // connect to Blynk
  Blynk.begin(auth, ssid, pass);
}

void loop()
{
  Blynk.run();
}

Do you like this, do you need this, do you understand this? Tell me jacardano@gmail.com

Blynk: Controlling BI2 from the smartphone

Readers ask me for an easy way to control the body interaction vibrator development board. Without or with limited  programming knowledge, without complicated Internet of thing technology, like the visual programming tool NODERED or the MQTT protocol and server.

That’s what Blynk is for. Started in 2016 as a kickstarter  campaign, they have built a tool which hides a lot of the complexity of the Internet of Things. Blynk consists of the following parts:

Blynk app. With this app you can build a User Interface in just a few minutes. You have all the usual elements like switches, slider,  graphs and much more for controlling IOT devices.

Blynk Server / Cloud is responsible for the communications between the smart phone and IOT devices. There is nothing to do, everything works in the background

IOT devices library: So far everything is very simple. But at the end you have to program your IOT device – the body interaction 2 board for example. They support a great number of boards. For this they created the blynk  library – with the library you need only some lines of code which must be uploaded to the board. Even when you change the user interface the code can stay the same. At least for simple changes. They offer a code generator where you code for your board and use case is generated automatically.

You find a lot of information in the Internet about the pros and cons. In short: It is easy compared to other tools, but if you want to implement your own algorithms programming knowledge is needed. Blynk limits the number of free User Interface elements. If you need more you have to pay  a small fee.

 

Here is short tutorial to run you BI2 with Blynk. (takes 30 minutes)

Download the Blynk app (Android or iPhone).

Within the Blynk app: Register for Blynk and get AUTHenitfication code.

Upload Arduino

You can download Arduino from the Arduino Website or from the Microsoft Store (Windows only)

 

Add or update the following libraries with the library manager: FastLED and Blynk.

Select Include libraries -> library manager

Search for FastLED and install this library (press install button).

Now search for “Blynk” and install the Blynk software. However Blynk suggests to install the Blynk app manually.

 

Add board definition for the ESP8266

Select Tools -> Board -> Board management

Search for ESP and install “esp8266”

Select Board -> Adafruit Feather

Build a connection between BI2 and your computer.

First download the USB driver from here and install the driver. Connect the BI2 with your computer. After some while windows will notice a new device. Windows will communicate with the board over a COM port (e.g. COM3). If you have any problemes check your USB wire. It must support all lines, not only + and – for charging.

Now go back to Arduino and select Tools -> Port. Select the new COM portcom port arduino

Compile and upload the code to BI2 board

Now copy and paste the following code in a Arduino sketch (use File -> new). Then press the Upload button.

/*************************************************************
Controling the body interaction 2 board with the Blynk app
*/

#define BLYNK_PRINT Serial
#include <ESP8266WiFi.h>
#include <BlynkSimpleEsp8266.h>

// Auth Token infor the Blynk App.
char auth[] = "XXXXXXXXXXXXXXXXXXXXXXXXXXX";

// Your WiFi credentials.
char ssid[] = "XXXXXXXX";
char pass[] = "XXXXXXXX";

// Library for controlling the WS2821B (Neopixel) LED or LED strip
#include "FastLED.h"
#define NUM_LEDS 1 // number of LEDs
#define DATA_PIN 14 // pin for LED
CRGB leds[NUM_LEDS]; // define the array of leds

// This function set the LED color according to the selected RGB values in the app.
// RGB values are controlled in the app with zeRGBa widget
// values are stored in the virtual pin V0
// V0 consists of 3 values for Red, Green, Blue
BLYNK_WRITE(V0) // set LED RGB color values
{
  int i = param[0].asInt();
  int j = param[1].asInt();
  int k = param[2].asInt();
  leds[0].setRGB(j,i,k);
  FastLED.show();
}

void setup()
{
  // init LEDs
  FastLED.addLeds<WS2812B, DATA_PIN, RGB>(leds, NUM_LEDS);

  // connect to Blynk
  Blynk.begin(auth, ssid, pass);
}

void loop()
{
  Blynk.run();
}

You have to change AUTH. Use the AUTH code / token that was sent to you during Blynk registration. Then you have to change the WLAN credentials. Use the name of your network (SSID) and its password. (Depending on the maximum voltage of the vibration motor you have to adjust i, j and k e.g. for a 1.5V motor divide the variables by 3.

Configure the Blynk app

Create a new project and choose this device: ESP8266. Now add user interface elements – they are called widgets -to control the BI2. You can move and resize, add and delete each widget. Press on the widget to enter parameters like GPIO port etc. The app could look like that but you may position the widgets as you like. [The pitch, roll, yaw text fields can be omitted. They are introduced later.]

Add the following Widgets

Press the “+” button and add this widget:

zeRGBA: With this tool you can control the WS2821B LED

Choose select pin V0 = Virtual Pin 0.

Choose Merge.

Send on release: off

Add Sliders

Press the “+” button and add two sliders, one for each motor.

1st silder: Select Digital Pin 12 (PWM)

2nd slider:  Select Digital Pin 13 (PWM)

Add Button

Press the “+” button and add the button widget. Select pin digital – gp0. Set mode to “switch”.

Start the app

Therefore press the Run (or play) button (top left).

 

Done!

Questions? Reply to this post, via wordpress or to jacardano@gmail.co

 

BI2 – building a silicone sex toy

Now let’s build the first ESP8266 vibrator. I use the reliable design from this blog post and the new BI2 board. The new BI2 board can be controlled from any smart phone or computer.

As the BI2 board is round there is no need to build a case for the PCB and the LiPo. The easist way is to glue the battery directly on the ESP8266. Connect the battery and one or more vibration motors with the BI2 board.

 

The form consists of two parts which are fastened together with tinker wire. Before you have to insert the board with the vibration motor(s) and the battery. Therefore I used a handle. The handle could be put on top of the form. Then fix a USB connector to the handle. Plug in the BI2 board. Fasten the second half of the form.

Very important: The USB micro connector on the board must be protected from the silicone. When silicone flow between USB plug and connector it will be impossible to pull out the plug. I use wax to seal the USB micro connector. Read more here.

 

Now pour in the silicone, wait for some hours. And open softely the form.

 

Remove the overhanging silicone.

Here ist the Link to Tinkercad where you can edit the form and download STL files for your 3D printer: Download from Tinkercad: formhandle. Download ready to print zipped STL files.

Now build YOUR personal sex toy. Here you find the code for the ESP8266 as well as an IOT server application for quantifying your sex and remote control.

BI2: ESP8266 Vibrator Development Board – becoming colourful

The second version of the development board – I will call it BI2 from now on –  has some improvements:

  • I used more components of the original design (Adafruit Feather Huzzah) instead of comparable (and cheaper) Seeedstudio Open Part Library components. The reason for this is easy. The Adafruit design is reliable and approved. No need for designing your own circuits, no risk to fail. (But also no fun in inventing new circuits.)
  • I added LED light – the WS2812B – which is a  colourful LED (16 Mill. colours). They are commonly known as Adafruit Neopixel – a strip or a ring of individual programmable LEDs.
  • The diameter is smaller the first version.
  • It can drive three motors. (When you use the LED then only two motors can be driven.)

Here are some impressions of the board:

 

As you can see I had to wire the LED by hand. The reason for this is that I used GPIO16 which does not work at all. So I wired the LED to GPIO0 which can be used for testing only. The only free GPIOs are 12, 13 and 14.

 

 

 

 

 

 

 

Basic Node for the Internet of Sex Toys – part 3: software

This the third part of the tutorial which has the following parts:

part 1: Basic Node for the Internet of Sex Toys

part 2: Molding the Basic Node

part 3: Software for the Basic Node

For the basic node a simple software realizes all features like Mqtt communication, Web server, basic web user interface, reading data from the accelerometer. Please use the code at github and send request over github. Now the imported parts of the code are explained.

To communicate with the IOT Mqtt is used (read more here). This is a fast protocol for data transmission. Therefore we need a Mqtt server. You can install one on your local computer or use a cloud-based Mqtt server. We use the free CloudMqtt. The following variables must be initiated with the data  of your server. Please get your own account at CloudMqtt or use my server (but don’t spam it, please). Please remember: Transmission is not encrypted, everybody can read it.

const char* mqtt_server = "m12.cloudmqtt.com";
uint16_t mqtt_port = 15376;
const char* mqtt_user = "nvcuumkf";
const char* mqtt_password = "C-X6glwisHOP";

We have now  7 different modes. In each mode the basic node behaves different.

const int offMode = 0;
const int maxMode = 1;
const int sinusMode = 2;
const int motionMode = 3;
const int constantMode = 4;
const int listenMode = 5;
const int listenAndMotionMode = 6;

In off mode the basic node is off, in max mode the vibration is maximum. In sinus mode the vibration speed is altered according to a sinus curve.

Web user interface of the basic node

In motion mode the vibration changes according to the movement of the basic node. When moved fast the speed goes up, when moved slowly or movement stops, the speed goes down. In constant mode any vibration speed can be set to any strength. This feature is only available by Mqtt messages eg. from the IOT node-RED user interface. The listen mode is still experimental. In this mode the speed will be changed by OTHER basic nodes. Finally in the listenAndMotionMode the speed is changed by movements of the basic node and by other nodes. This feature was already available with the body interaction 1 development board as standard mode!

The basic node starts a web server (see image). A web page is generated which build up the user interface. There are buttons for every mode. In addition the speed and the battery power is displayed. This is done in this function:

void generateWebpage() {

The next lengthy procedure is this:

void mqttCallback(char* topic, byte* payload, unsigned int length) {

This is a call back function which is executed whenever a Mqtt message comes in. It parses the Mqtt message which is in the popular JSON format. The commands which are communicated within JSON are explained here. In principle there is a command for every mode, when the command “set mode to off” is send the mode is set to offMode.

In the setup() part of the code you will find a lot of lines like that:

httpServer.on("/MOTOR=MAX", []() {

They corresponds to the generateWebpage() function. When say the max button on the web page is pressed than the affiliated httpServer function is executed. So for every button on the webpage you need a corresponding httpServer function to implement the functionality. In this case (MOTOR=MAX) the mode is set to the constant speed maxMode.

Finally in the loop section of the code the following functions are implemented:

  • reading the accelerometer data
  • change the vibration motor speed according to the mode
  • generate a new JSON message which is send out via Mqtt
  • do the timing

Not mentioned is the OTA (over the air update) function, which is integrated in the code.

Node-RED

For controlling the toy via the internet you can use node-Red. You can find the code at github via this link.

The flow is explained here and here.

 

OpenSCAD as silicone molding form generator


scadmoldform1tryballs_revisited_3_finalAn alternative to 3d-printed sex toys are silicone toys. For making such a sex toy you need a molding form, where you pour in the silicone. If you use Tinkercad to build the form for the balls motive, you may need more than one hour. If you are not experienced in 3d constrcution it may take days. That’s ok and can be fun as you can realize your fantasies step by step.

 

 

molded-with-ueberh-querBut if you want to change a detail or want to resize some parts of it, it will take a long time as you have to unbuilt parts of the form, make changes and then reassemble. Sometimes building from scratch is faster.

In the last blog post we have introduced OpenSCAD to construct a sex toy form. Now we want to build a hull for the sex toy for overmolding.

The basic idea is very simple:

  • Generate two forms. The smaller one has the size of the sex toy you want to make. The larger one will be the form where you pour in the silicone.
  • Than use the OpenSCAD difference command which “subtracts” or cuts out the smaller form from the larger form.

But it is more complicated:

  • You have to include a frame otherwise the form would fall over.
  • You need two forms (A and b) so you could open the form after molding.
  • Both forms must be fastened together when molding. Therefore you need holes for tinkering wire.

bi-round-12-scadWe have created a solution for molding form generation which is as flexible as our OpenSCAD sex toy generator. In addition you can change the thickness of the frame. Therefore you have to change the variable frame_thickness.

The SCAD script uses the module base which is already introduced. The generation of the frame is done in the module frame. The frame consists of a base plate and two supporting frames which stabilize the whole form. In addition there are extensions to the frame in the upper part of the form. These extensions will provide holes for fastening both forms.

The module complete_form constructs the form which is tricky. The union command is used to join the complete outer form and the frame. Now we have a filled form and have to remove the inner part. This is done by subtracting another complete form which is a bit smaller than the outer form. This is done with the difference command.

Another module hole provides all holes for the tinkering wire. At last we construct part A and part B of the molding form. Again the difference command is used to cut out one half of the form. This is done by subtracting a cube which is placed in the middle of the complete form. In addition the holes must be subtracted from the complete form.

You can build in the body interaction vibrator development board to make a vibrating dildo, controlled by motion or by another body interaction vibrator development board. Read more here.

Try out with the Thingiverse customizer.

Download the zipped SCAD file here: bi1-round12

Or copy and paste the source code to the SCAD software:

// bodyinteraction toy form and mold form generator
// radius of bottom part
r_bottom=25; // [15:5:80] 
// height of bottom part
h_bottom=30; // [10:5:80] 
// top rounding of bottom part
rounding=10; // [10:5:20]
// radius of ball 1 
r_ball1=21; // [15:5:50] 
// radius of ball 2
r_ball2=15; // [15:5:50] 
//radius of ball 3 
r_ball3=11; // [15:5:50] 
// radius of connecting cylinders
connector_radius=8; // [10:2:20]
// distance between balls and bottom part
ball_distance=15; // [10:2:40]
// offset (thickness of hull)
o=2; 
// thickness of frame
frame_thickness=4; 

height=h_bottom+3*ball_distance+r_ball1*2+r_ball2*2+r_ball3*2; echo(height);


// form part A
translate([0,0,height+frame_thickness])rotate([0,180,0])
difference() {
 complete_form(r_bottom,h_bottom,rounding,r_ball1,r_ball2,r_ball3,connector_radius,ball_distance,o,frame_thickness,height);
union(){
 translate([-r_bottom-o-10,0,-5])
 color("red")cube([2*r_bottom+2*o+20,r_bottom+2*o,height+frame_thickness+5]);
 holes(height,h_bottom);
 }
}
//form part B
translate([90,0,height+frame_thickness])rotate([0,180,0])
difference() {
 complete_form(r_bottom,h_bottom,rounding,r_ball1,r_ball2,r_ball3,connector_radius,ball_distance,o,frame_thickness,height);
union(){
 translate([-r_bottom-o-10,-r_bottom-o-2-10,-5])
 color("red")cube([2*r_bottom+2*o+20,r_bottom+2*o+10,height+frame_thickness+5]);
 holes(height,h_bottom);
 }
}

module holes (height,h_bottom){
for (i=[h_bottom+30:10:height])
 translate([r_bottom-1,5,i])rotate([90,90,0])
 color("green")cylinder(h=15,r=1,$fn=20);

for (i=[0:10:h_bottom+20])
 translate([r_bottom-3+10,5,i])rotate([90,90,0])
 color("blue")cylinder(h=15,r=1,$fn=20);

for (i=[h_bottom+30:10:height])
 translate([-r_bottom+1,5,i])rotate([90,90,0])
 color("green")cylinder(h=15,r=1,$fn=20);
for (i=[0:10:h_bottom+20])
 translate([-r_bottom-6,5,i])rotate([90,90,0])
 color("blue")cylinder(h=15,r=1,$fn=20);
}

module complete_form (r_bottom,h_bottom,rounding,r_ball1,r_ball2,r_ball3,connector_radius,ball_distance,o,frame_thickness,height) {
 difference() {
 union() {
 base(r_bottom+o,h_bottom+o,rounding,connector_radius+o,ball_distance-2*o,r_ball1+o,r_ball2+o,r_ball3+o);
 //complete frame
 frame(2*r_bottom+2*o,o,height,frame_thickness,r_bottom,h_bottom,rounding);
 };
 base(r_bottom,h_bottom,rounding,connector_radius,ball_distance,r_ball1,r_ball2,r_ball3);
 
 
};
}

module frame(width,o,height,frame_thickness,r_bottom,h_bottom,rounding) {
 //plate
 translate([-width/2,-width/2-2*o,height]) cube(size=[width,width+2*o,frame_thickness]);
 //frame1
 translate([-width/2,-frame_thickness/2,0]) cube(size=[width,frame_thickness,height]);
 //frame 1 extensions
 translate([-width/2-010,-frame_thickness/2,-5]) color("blue")cube(size=[12,frame_thickness,60]);
 translate([-width/2-10,-frame_thickness/2,55]) color("red")rotate([0,45,0]) cube(size=[12,frame_thickness,20]);
 
 translate([+width/2-2,-frame_thickness/2,-5]) color("green")cube(size=[12,frame_thickness,60]);
 translate([+width/2+01,-frame_thickness/2,47]) color("green")rotate([0,-45,0]) cube(size=[12,frame_thickness,20]);
 //frame2
 translate([-frame_thickness/2,-width/2,0]) cube(size=[frame_thickness,width, ,
 height]);
 // stabilize bottom with cylinder
 color("green")translate([0,0,h_bottom])rotate([00,0,0180])
 cylinder(h=r_bottom*2-rounding*.5, r1= r_bottom-rounding, r2=0);

}

module base (r_bottom,height,rounding,connector_radius,ball_distance, c1,c2,c3) {
 union () {
 // connector
 color("white")cylinder(h=height+2*ball_distance+c1*2+c2*2+c3*2,r=connector_radius,$fn=60);
 //base
 color("DarkSlateBlue") cylinder (h=height-0,r=r_bottom-rounding,$fn=60);
 color("MediumSlateBlue")cylinder (h=height-rounding,r=r_bottom,$fn=60);
 translate([0,0,height-rounding]) color("SlateBlue") rotate_extrude() 
 translate([r_bottom-rounding,0,0]) circle(r=rounding,$fn=120);
 // circle (ball) 1, 2 and 3
 translate([0,0,height+ball_distance+c1]) color("Indigo")sphere(r=c1,center=true,$fn=60);
 translate([0,0,height+2*ball_distance+2*c1+c2]) color("Violet")sphere(r=c2,center=true,$fn=60);
 translate([0,0,height+3*ball_distance+2*c1+2*c2+c3]) color("Purple")sphere(r=c3,center=true,$fn=60);
 }
}

 

Go to the first part of the SCAD tutorial

OpenSCAD as sex toy generator

balls_scadOpenSCAD is a free software tool for creating 3d objects. But it is different from other CAD tools like Tinkercad or Freecad. Instead of using the mouse to select and modify 3d objects you have to use a description language. Making a 3d object in OpenSCAD is a bit like programming. For creating a sphere you just have to type sphere(r=10); where r is the radius of the sphere. For creating a cube or a cylinder just type in the appropriate command. When done select compile from the menu and you’re object will be displayed.

Just download the OpenSCAD software, install the tool and try out a command. You can copy and paste the dildo generator source code (at the end of this blog post) and try to change the parameters. Another option is to use the customizer module of the Thingiverse platform.

Brief Intro to OpenSCAD

openscadintro If you want to create a sphere not in the origin but somewhere else you have to shift the object using the translate command. For creating the second smaller sphere use

translate([30,0,0]) sphere(r=10);

The translate command moves the sphere objects on the x-axis by 30 points.

To visualize the form use the design menu and select “compile” or “compile and render”. Rendering takes some time (up to some minutes) but it will give you a correct preview of your form.

To build more complex objects you have to use the union or difference command. The union command puts simple objects together. With the difference command you can cut out something e.g. to make a ring. openscadintro2 You can download a STL-file (select “export STL” from the menu) and print out the form with a 3d printer.

OpenScad can be used to create sex toys as shown by Mr O. He used OpenScad to create basic building blocks for sex toys which can be combined and changed in size. Moreover with OpenScad you can make generative designs. For example you can make a generative dildo which can be individualized by changing parameters like height, length etc.

Generative Dildo Project

Let us create the “balls” dildo which is introduced in Silicone overmolded vibrator – balls revisited and Update for “balls revisted” – silicone molded vibrator.

molded-querThe dildo consists of 6 forms:

  • three spheres with individual radius
  • a base which is made of cylinders
  • and an iterative use of circles to make the upper top of the base to be round

We use the module command to encapsulate the commands for creating the dildo. A module is very similar to functions or procedures in other programming languages, but they do not return a value. They just execute the commands in the module. The definition of the module starts with its parameters.

module base (r_bottom,height,rounding,connector_radius,ball_distance, c1,c2,c3) {
  ...commands for creating the dildo...
}

c1, c2 and c3 are the radius of the spheres. r_bottom is the radius of the base part and height the height if the base parts.

balls_scad

Now you can produce different versions of the ball motive by entering different parameters when you call the module base. With the following parameters the form at the left side will be generated:

base(50,60,10,10,30,15,25,35);

 

 

ball_scad_alt_parametersThis form will be made when using the following parameters:

base(60,30,10,10,30,20,35,45);

 

 

 

Make your own generative sex toy design and publish it

The Thingiverse platform is able to create objects made with OpenSCAD. Just upload the SCAD-file to Thingiverse using the customizer option. Now you can change the parameters within Thingiverse and generate a customized STL-file for 3d printing. Try it out with the Thingiverse customizer (as long as nobody complains…).

Download the SCAD file source code here: form_only

Or copy & paste the following SCAD code to generate the “balls” sex toy:

// bodyinteraction toy form

// radius of bottom part
r_bottom=50; // [50:5:80] 
// height of bottom part
h_bottom=60; // [10:5:80] 
// top rounding of bottom part
rounding=10; // [10:5:20]
// radius of ball 1 
r_ball1=35; // [15:5:50] 
// radius of ball 2
r_ball2=25; // [15:5:50] 
//radius of ball 3 
r_ball3=20; // [15:5:50] 
// radius of connecting cylinders
connector_radius=10; // [10:2:20]
// distance between balls and bottom part
ball_distance=30; // [10:2:40]


base(r_bottom,h_bottom,rounding,connector_radius,ball_distance,r_ball1,r_ball2,r_ball3);

module base (r_bottom,height,rounding,connector_radius,ball_distance, c1,c2,c3) {
 union () {
 // connector
 color("white")cylinder(h=height+2*ball_distance+c1*2+c2*2+c3*2,r=connector_radius,$fn=60);
 //base
 color("DarkSlateBlue") cylinder (h=height-0,r=r_bottom-rounding,$fn=60);
 color("MediumSlateBlue")cylinder (h=height-rounding,r=r_bottom,$fn=60);
 translate([0,0,height-rounding]) color("SlateBlue") rotate_extrude() 
 translate([r_bottom-rounding,0,0]) circle(r=rounding,$fn=120);
 // circle (ball) 1, 2 and 3
 translate([0,0,height+ball_distance+c1]) color("Indigo")sphere(r=c1,center=true,$fn=60);
 translate([0,0,height+2*ball_distance+2*c1+c2]) color("Violet")sphere(r=c2,center=true,$fn=60);
 translate([0,0,height+3*ball_distance+2*c1+2*c2+c3]) color("Purple")sphere(r=c3,center=true,$fn=60);
 }
}

 

Next part: Silicone sex toy mold generator with OpenSCAD

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