Différences entre versions de « Projets:Motorized head support »

Project overview

To manufacture a low-cost assistive device to support and allow the rotation of the head of a person whose muscular deficiency in the neck area does not allow them neither a natural support of their head nor a natural rotation from left to right (rotation of the head is impossible muscularly, only articularly). Mathilde does not wish to get yet another remote control button to make use of this functionality because she already has several of them and she cannot always access them depending on the situation.

Design brief

The device must :

• support the weight of the head,
• allow for 30° left rotation, 30° right rotation,
• be electronically controlled on demand,
• withstand daily use under all conditions (vibration, humidity, heat,...)
• be hermetic enough not to allow hair to get caught in the mechanism
• weatherproof
• take into account the fact that Mathilde is going to be equipped with a new chair

Existing prototype(s) analysis

This solution exists on the market but only as a non electrified version

The following solution has been tested and is suitable for Mathilde, except for the lack of electrical assistance. http://www.medifab.co.nz/products/wheelchair-seating/axion-rotary-interface-wheelchair-headrests

Example of a commercial rotary interface: https://media.wix.com/ugd/3c5a2b_070f4373519443e69189391e8c695b87.pdf

Details regarding the bearing mechanism: http://ot-sieber.ch/wp-content/uploads/2016/03/DSC_0052_3-180x180.jpg

Team (Project leader and contributors)

• Project leader(s) :

Mathilde Fuchs

• Designers/Contributors :

Philippe Pacotte, Stéphane Godin, André Bécot, Jean-Pierre Legrand, Yves Le Chevalier, Christian Fromentin, Danke, Francis Esnault, Jean-François Duguest, Brice Besançon, Yohann Véron,

• Animator (Project coordinator)

Delphine Bézier

• Referent fabmanager

Delphine Bézier

• Documentation manager

Required components

Required tools

Cost

Estimated timeframe

Source files

Download the code

Download the documents

Download the pictures

Download the 3D models(STL)

Step by step manufacturing process

Step 1 - Captioned view of the final prototype

Step 2 - Fabrication of the connecting piece between the rail and the adjustable support of the chair head restraint

The connecting piece between the rail and the adjustable support of the head restraint attached to the chair was made from three flat bars welded together. Refer to the file "support entre rail et fauteuil.stl".

Download the stl file support between rail and chair

Step 3 - Rail fabrication

To manufacture the rail, take the 4G aluminum plate (see picture for dimensions) and adjust the curvature of the bending machine as seen on STL file. It might be possible to make a cardboard or 3D printed installation template to check and adjust the curve. Watch how to proceed here :

https://youtu.be/oLzzKH7SkhM

https://youtu.be/36KCF7G6KE4

https://youtu.be/mCTa5f2ztH4

Then drill the holes and filter them for the end stop switches, the position of which is to be adjusted according to the desired degree of movement or the head rotation, which must remain comfortable for the user.

Download the stl rail file

Step 4 - Fabrication of the mounting ball

Depending on the person's head restraint, the dimensions of the mounting ball will need to be adjusted. If the model corresponds to this one, ask a machinist to manufacture it out of 4G aluminium according to the STL model (rotule.stl). It will then be necessary to drill and filter it (for a CHc-M5X15 screw) to attach it. Caution : add a steel locking pin to the baseplate of the ball joint parallel to the screw which also goes on the on the mounting ball support to avoid the rotation of the ball on itself.

Download the stl rotule model file

Step 5 - Fabrication of the ball mounting plate and rollers

Manufacture the ball mounting plate with a folding machine based on the plaquerotule.stl file.

Manufacture the four rollers (5mm sheave rollers inside groove width and 2.5mm shoulder sheave) Machine the four rollers in POM-C plastic material (Nylacast Polyacetal POM-C otherwise known as Acetal Copolymer is an engineered plastic) with an outer diameter of 15mm and inner diameter of 10mm. Bore them for the rollers that attach at the two extremities.

Download the stl file galet_perce

Download the stl file plaquerotule

Step 6 - 3D printing of the components (simulate printing time in Cura)

Print every component located in the " STL/A print " folder.

• Filament material: preferably ABS or PLA
• Cura configuration settings : Density: 90 % filling, quality 0.2.

Printout of end stops, motor mount, limit switch sensor lug as well as the protective cover.

File:butees.stl

File:capot.stl

File:support_capteurs_fin_course.stl

File:support_moteur.stl

Step 7 - Fabrication of the electronic circuit

Required components:

• Arduino-NANO
• resistor-1K
• micro-switch
• nema17-42SHD0228
• veroboard
• battery-12V
• big-easy-driver card

___________________________________

• PCB (to which the on/off circuit must be added)
• Arduino file (code)

Download the code

Manufacture or have the printed circuit board made by referring to the schematic and PCB below (Headrestschemav1.2.jpg, headrests-PCBv1.2.png).

Upload the code to the Arduino board.

#include "cli.h"
#include "config.h"


#include "command.h"


// task definition for periodic scheduling 1ms
//void motorControl(Task* me);
//Task schedule (1, motorControl);



void setup() {

  // intialize command
  cli_open ();
  
  // initialize motor
  load_config ();
  get_stepper()->setMaxSpeed (get_speed());
  get_stepper()->setAcceleration (get_accel());
  // initialize led
  pinMode(LED, OUTPUT);
  digitalWrite (LED, LOW);

  // initialize buttons
  pinMode(BTN_RIGHT, INPUT);
  pinMode(BTN_LEFT, INPUT);

  // stepper microstep
  pinMode (MOTOR_MS1, OUTPUT),
  pinMode (MOTOR_MS2, OUTPUT);
  digitalWrite (MOTOR_MS1, LOW); // todo place config in config.h
  digitalWrite (MOTOR_MS2, LOW);

  //endstop
  pinMode (ENDSTOP_LEFT, INPUT),
  pinMode (ENDSTOP_RIGHT, INPUT);
  
  
  // run scheduler
  //SoftTimer.add(&schedule);

}

// function :SensorLeft
//
// Description :
// return te logic state of the left sensor
//
// Return :
// true if the left sensor is active. Otherwise false
boolean SensorLeft ()
{
  if (get_force_left () > 0)
    return (true);
  return (digitalRead (BTN_LEFT)== BTN_LEFT_ACTIVE_STATE ? true : false);
}

// function :SensorRight
//
// Description :
// return te logic state of the right sensor
//
// Return :
// true if the right sensor is active. Otherwise false
boolean SensorRight()
{
  if (get_force_right () > 0)
    return (true);
  return (digitalRead (BTN_RIGHT) == BTN_RIGHT_ACTIVE_STATE ? true : false);
}

// function :EndStopLeft
//
// Description :
// return the logic state of the left endstop sensor
//
// Return :
// true if the left endstop is active. Otherwise false
boolean EndStopLeft ()
{
  return (digitalRead (ENDSTOP_LEFT) == ENDSTOP_LEFT_STATE ? true : false); 
}

// function :EndStopRight
//
// Description :
// return the logic state of the right endstop sensor
//
// Return :
// true if the right endstop is active. Otherwise false
boolean EndStopRight ()
{
  return (digitalRead (ENDSTOP_RIGHT) == ENDSTOP_RIGHT_STATE ?  true : false); 
}

int RIGHT_MOVE = 1;
int LEFT_MOVE = -1;
int STOP_MOVE = 0;

//void turnOn(Task* me)
//{

//}


// Function: motorControl
//
// Description :
// The function is called every 1 ms. check command sensor and enstop and control the motor
//
// 
//void motorControl(Task* me)
void loop ()
{
  AccelStepper *pstepper = get_stepper ();
  
  // put your main code here, to run repeatedly:

  int step = 0;
  // decide move
  int move = STOP_MOVE;

  boolean right = SensorRight ();
  boolean left = SensorLeft ();
  
  boolean endl = EndStopLeft ();
  boolean endr = EndStopRight ();

 
  
 if (endr || endl)
  digitalWrite (LED, HIGH);
  else
  digitalWrite (LED,LOW);
 
 //endr = false;
 //endl=false;
  if (right == left)
  {
    move = STOP_MOVE;
    
    //digitalWrite(LED, LOW);
  }
  else if (right==true)
  {
    if (endr)
    {
      move=STOP_MOVE;
    }
    else
    {
      move = RIGHT_MOVE;
      pstepper->move (20000);
      //digitalWrite(LED, HIGH);
    }
  }
  else if (left == true)
  {
    if (endl)
    {
      move=STOP_MOVE;
    }
    else
    {
      move = LEFT_MOVE;
      pstepper->move(-20000);
      //digitalWrite(LED, HIGH);
    }
  }

  // motor control
  if (move != STOP_MOVE)
  {
    pstepper->run();
  }
  else
  {
    //stepper1.disableOutputs();
    pstepper->setSpeed(0);
    pstepper->setCurrentPosition (0);
  }

  // process command
   CLI.process();
}

The arduino card is powered with 5V from the 5V output of the easy driver card. Connect the 24V from the PCB to the chair batteries (see Schema_batterie.jpg).

Add the LED ON/OFF switch circuit (presented on the provided picture) to be able to switch off the device and not use battery power for nothing. :)

Step 8 - Installation of the circuit in the electronic circuit box

Required component:

• electrical junction box

Place the circuit in the waterproof electrical junction box. Waterproof electrical junction box reference: https://www.leroymerlin.fr/v3/p/produits/boite-de-derivation-etanche-en-saillie-debflex-8-entrees-e29160

The box will be mounted to the rear of the chair.

Step 9 - Assembly of the button or system, chosen to control the rotary head restraint

Assemble the button according to the following diagram. Prepare the cable length in advance to connect the cable to the PCB located in the housing that has been mounted to the rear of the chair.

Step 10 - Mounting of the GT2 bore 5 pulley to the NEMA17 stepper motor

Required components:

• pulley-GT2-bore5-20toothed
• nema17

Thread the GT2 bore 5 20toothed pulley on the shaft of the Nema17 motor. Then attach it with two screws with no locking head of the pulley.

Refer to the picture of the global diagram.

Step 11 - Attaching the motor + pulley, to the motor support

Required component:

• screw-M3-12

Attach the set motor + pulley on the motor support using two M3x12 screws.

Étape 12 - Mounting the bearings to run the strap

Required components:

• bearings-F624ZZ
• rings

Attach the four ball bearings F624ZZ placed in mirror pairs with the outer pointed shoulder, with the rings placed between the screw and the bearing, to avoid compressing the outer part of the bearing. And on the other side of the motor support plate, place the M4x20 (or 25) screw with a nylstop nut.

Step 13 - Wiring of the end-stop switch sensors

Required components:

• micro-switch
• monofilament-0.2

Weld the wires to the end-stop switches (also called microswitches). Prepare sufficient wire length to reach the housing where the electronic circuit is located.

Step 14 - Mounting end stop switches on their support

Required components:

• screw CHc-M2X16
• M2 nuts

Assemble the end stop switches (microswitches) to their supports with 2 screws CHc-M2X16 each and their respective nut.

Step 15 - Installation of the end stop switches support on the motor support

Required components:

• screw CHc-M3x14
• nylstop nut M3

Attach the end stop switch sensor brackets to the motor support with 2 screws CHc-M3x14 which are mounted to the Nema 17.

Step 16 - Preparation of the rollers

Insert an MR84ZZ bearing on both sides of each roller. Forcibly insert the bearings (two per roller) in the rollers.

Step 17 - Installation of the rollers on the baseplate of the mounting ball

Required components:

• screw-CHc-M5X35
• nylstop nut

Attach the rollers on the baseplate of the mounting ball with the CHc-M4X35 screws and M4 nylstop nuts. Do not tighten the screws all the way and leave some looseness for the installation on the rail.

Step 17 - Assembly of the rollers on the baseplate of the mounting ball

Required components:

• screw-CHc-M5X35
• nylstop nut

Place the rollers on the installation plate of the mounting ball with the CHc-M4X35 screws and M4 nylstop nuts. Do not tighten the screws all the way and leave some looseness for assembly on the rail.

https://youtu.be/SlecIxJOSQ0

Step 19 - Installation of the mounting ball baseplate on the guide rail

Thread the mounting ball baseplate on the guide rail.

Tighten the fixing nuts securing the rollers. Do not tighten them too much to ensure correct sliding.

Step 20 - Installation of the aluminium angle on the mounting ball support baseplate

Required components:

• screw-M3
• nylstop nut-M3

Attach the angle iron to the mounting ball support baseplate. The angle iron is 20x20, 31 mm length + 2 M3 screws with nylstop nuts + 2 screws

Step 21 - Set up, tensioning and fastening of the strap

Set up, tensioning and fastening of the strap GT2, 6 mm width, 2 mm pitch and approximately 35mm in length or adjust the length according to the pathing of the rail. Fasten the strap to each extremity by making it go through the specified opening on the end stop switch, then secure it with a serflex on the outer side. The notches of strap must be pointed towards the rail.

Installation of the head restraint : https://urlz.fr/bjPY

Fastening of the strap : https://youtu.be/NXCGfeGCh6I

Step 22 - Assembly video

https://urlz.fr/bjPs

Final prototype fabrication time

Logbook

Date: xx/xx/2020