Difference between revisions of "Projets:Lab:2015:SolderStation:ManuelEnglish"

From Electrolab
Jump to: navigation, search
m (MCU board)
(quick/incomplete proofreading of first part of page)
 
(15 intermediate revisions by 2 users not shown)
Line 1: Line 1:
 
[[File:Generale.JPG |600px|thumb|A soldering station for SMD components used to learn how to solder SMD component. Ain’t that recursive enough ?(click on the picture for higher def.)]]
 
[[File:Generale.JPG |600px|thumb|A soldering station for SMD components used to learn how to solder SMD component. Ain’t that recursive enough ?(click on the picture for higher def.)]]
 
 
 
 
 
  
 
=''' Assembly Manual'''=
 
=''' Assembly Manual'''=
  
 
<br style="clear: both" />
 
<br style="clear: both" />
   Six Wiki pages and two files are related to this manual:  
+
   Seven Wiki pages and two files are related to this project:  
 
    
 
    
   * [[Projets:Lab:2015:SolderStation:Firmware| Les instructions de chargement du firmware (version Française) ]]
+
   * [[Projets:Lab:2015:SolderStation:Firmware| Loading the firmware (Française release) ]]
   * [[Projets:SolderStationW| Une presentation générale de l'appareil (version Française)]]
+
   * [[Projets:SolderStationW| A quick general presentation of the solder station (French release)]]
   * [[Projets:Lab:2015:SolderStation:Manuel | Le guide de montage illustré (version Française) ]]   
+
   * [[Projets:Lab:2015:SolderStation:Manuel | Assembly Manual, illustrated (French release) ]]   
   * [[File:BOM_Station_CMS.xls]] The Bill of Material, xls format
+
   * [[File:BOM_Station_CMS.xls]] The Bill of Material, xls format
   * [[File:BOM_Montage.xls]] The Assembly BoM, xls format
+
   * [[File:BOM_Montage.xls]] The Assembly BoM, xls format
 
    
 
    
   * [[Projets:Lab:2015:SolderStation:FirmwareEnglish | '''Loading the firmware, (English version)''']]
+
   * [[Projets:Lab:2015:SolderStation:FirmwareEnglish | '''Loading the firmware (English release)''']]
   * [[Projets:Lab:2015:SolderStation:ManuelEnglish | '''Assembly Manual, (English version)''']]
+
   * [[Projets:Lab:2015:SolderStation:ManuelEnglish | '''Assembly Manual (English release)''']]
   * [[Projets:SolderStationWEnglish| A quick general presentation of the solder station(English version) ]]
+
   * [[Projets:SolderStationWEnglish| A quick general presentation of the solder station (English release) ]]
 
+
 
 
+
  * [[Projets:Lab:2015:SolderStation:ManualGerman | '''Assembly Manual, illustrated (German release)''']]
  
  
Line 27: Line 22:
  
 
==''' The tools you need '''==
 
==''' The tools you need '''==
 
  
 
* Soldering iron (with a fine “needle” tip)
 
* Soldering iron (with a fine “needle” tip)
* Solder wick (to correct bad solder points)
+
* Copper desoldering braid (also called "Solder wick", to correct bad solder points)
 
* Cutting pliers (“flush” cutting, not bevelled if possible)
 
* Cutting pliers (“flush” cutting, not bevelled if possible)
 
* Solder flux
 
* Solder flux
Line 36: Line 30:
 
* Toothbrush or Q-tip  
 
* Toothbrush or Q-tip  
 
* Jewelery tweezers or fine tip tweezers
 
* Jewelery tweezers or fine tip tweezers
* Solder wire (0.5mm max dia recommended, 0.3mm is better, tin-lead-silver or tin-lead-copper alloy. Try to avoid ROHS solder)
+
* Solder wire (0.5mm max recommended, 0.3mm is better, tin-lead-silver or tin-lead-copper alloy. Try to avoid ROHS solder)
* Components (see BoM of the “kit number 2”)
+
* Components (see BoM of “kit number 2”)
* 2.5 meter cable wire
+
* 2.5 meters of cabling wire
 
* Arduino Nano (NOT mini!)
 
* Arduino Nano (NOT mini!)
* Power supply 12 V (for testing)
+
* 12V Power supply (for testing)
 
* Protection goggles  
 
* Protection goggles  
  
The first part of this manual deals with the assembly of SMD and through-hole components to build the heart of the solder station. It does not address the mechanics (boxed layout, integration) of this equipment.
+
The first part of this manual deals with the assembly of SMD and through-hole components to build the core of the solder station. It does not address the mechanical parts (boxing, integration) of this equipment.
  
       Important note: each step requires you to remove one or many (up to 9) component out of the
+
       Important note: each step requires you to remove one or many (up to 9) components out of the
       kit. To avoid losing them, it is recommanded to put these devices in a small container (yogurt
+
       kit. To avoid losing them, it is recommended to put these devices in a small container (yogurt
 
       cup, plate etc).
 
       cup, plate etc).
       DO NOT extract the components from their storage tape more than one after the other
+
       DO NOT extract the components from their storage tape more than one by one
 
+
  
 
==''' Schematic diagram and PCB ayout '''==
 
==''' Schematic diagram and PCB ayout '''==
Line 59: Line 52:
 
The schematic is not very complex.
 
The schematic is not very complex.
  
The heart of the device is an Arduino (Nano in this case). Ports D2 to D13 and A2 to A4 are devoted to man to machine interface, which can be completely modified depending of the user’s choice. Some people in the Electrolab have prefered to use a color LCD rather than the basic set of 7-segment displays. The choice of temperature controls (buttons "up-down" or rotary encoder) depends on a simple selection in the configuration file (see the “firmware installation” chapter). Both possibilities (button or encoder) have been kept on the pcb
+
The core of the device is an Arduino (Nano in this case). Ports D2 to D13 and A2 to A4 are devoted to the man-machine interface, which can be completely modified on user’s choice, as it is independant from the core. Some people at Electrolab prefered to use a color LCD rather than the basic set of 7-segment displays. The choice of temperature controls ("up-down" buttons or rotary encoder) depends on a simple selection in the configuration file (see the “firmware installation” chapter). The two alternatives (button and encoder) are available on the same PCB
  
The soldering iron plugs into P1. On this connector, you will find a 12 V “power” output (pins 4 and 5) supplying heating resistor of the iron. This voltage is not a DC voltage but a PWM signal controlled by the Arduino (D3 port) via a power FET transistor Q1. The duty cycle decreases or increases the proportion of current sent to the iron, and hence its temperature.
+
The soldering iron plugs into P1. On this connector, you will find a 12 V “power” output (pins 4 and 5) powering the heating element of the iron. This voltage is not a DC voltage but a PWM signal controlled by the Arduino (on port D3) via a power FET transistor Q1. Variation of the duty cycle decreases or increases the amount of current sent to the iron, and hence its temperature.
  
Also on P1, pin 1, a very low and variable voltage is received from the temperature sensor hidden in the body of the Weller solder tip. This voltage is strongly amplified by the operational amplifier OPA336, and then injected on one of the analog inputs of the Arduino.  
+
Also on P1, pin 1, a very low and variable voltage is received from the temperature sensor embedded in the body of the Weller soldering tip. This voltage is strongly amplified by the operational amplifier OPA336, and then fed to one of the analog inputs of the Arduino.  
The value of this voltage gives a clear indication of the iron temperature to the microcontroller. The microcontroller then decides to increase or decrease the width of the PWM signal (port D3). This variations has for consequence the increase or decrease of the iron’s temperature as already mentioned.
+
Measuring this voltage provides the microcontroller with an accurate tip temperature information. The software control loop programmed in the microcontroller uses this temperature measure to adjust the width of the PWM signal (Port D3). The goal of the control loop is that the temperature of the tip remains, as far as possible, of constant value.
  
The A5 port of the Arduino, named "STDBY SW" (standby switch) puts the iron in a "cold" standby position when this pin is grounded. Its activation may depend on of a magnetic switch (reed contact) hidden in the handle or the support of the soldering iron (the state of this switch is triggered by a magnet hidden in the support or the handle).
+
Port A5 of the Arduino, labelled "STDBY SW" (standby switch) puts the iron in a "cold" standby state when this pin is grounded. Its activation may be triggered by a magnetic switch (reed switch) located in the soldering iron's handle (activated by a small magnet you have to embed in the soldering iron cradle) or a sensitive mechanical switch mounted on the support of the soldering iron.
 
[[File:Implantation.PNG|900px|center|]]
 
[[File:Implantation.PNG|900px|center|]]
  
The entire station stands on two separate circuit boards. On the left of the schematic, the microcontroller card which supports both the Arduino Nano and components of the measuring loop (measuring amplifier, power supply transistor of the resistance of iron). On the left, a large 5x10cm PCB the man-machine interface (buttons/ temperature control encoder, digital display). This displays as two functions: it shows the iron’s temperature and the PWM duty cycle (decimal points: the more “dot point” you have, the wider the pwm is). An LED, located in the left lower corner of the display, will also light on when the iron is "heating".
+
The entire soldering station stands on two separate circuit boards. On the left side of the schematic, the microcontroller assembly which supports both the Arduino Nano and the components required for the measuring loop (measuring amplifier, transistor driving the power supply of the heating element). On the right side, a large 5x10cm PCB dedicated to the man-machine interface (temperature control buttons or encoder, digital display). This display has two functions: showing the iron’s temperature and the PWM duty cycle (through the decimal points: the more “dot point” shown, the higher the duty-cycle of the PWM signal). A LED, located in the lower left corner of the 7 segment display, will also light on when the iron is "heating".
  
The flat “shoulder” of the encoder is at the very same level as the 7 seg. display. This way, the displays and the “Temp” encoder will flush with the the front panel of the station.
+
The flat side of the encoder should be on the same height level than the 7-segment display. This way, display and rotary encoder will just be level with the front panel.
 +
 
 +
Use this layout diagram to identify the location of components during assembly.
  
Use this layout diagram to identify the location of components during the assembly
 
 
==''' The display board '''==
 
==''' The display board '''==
  
Line 99: Line 93:
 
<br style="clear: both" />
 
<br style="clear: both" />
  
Take 9x 220 Ohm resistors (R14 to R21 and R8), and repeat the operation for the next 9 resitor’s locations.
+
Take 9x 220 Ohm resistors (R14 to R21 and R8), and repeat the operation for the next 9 resistor’s locations.
  
 
{{Boite|titre=''' tips ‘n tricks '''|arrondi=5px|bordure=indianred|fond=lavenderblush|flotte=left|couleurTitre=lightcoral|largeur=39%}}
 
{{Boite|titre=''' tips ‘n tricks '''|arrondi=5px|bordure=indianred|fond=lavenderblush|flotte=left|couleurTitre=lightcoral|largeur=39%}}
Line 116: Line 110:
  
 
{{Boite|titre=''' tips ‘n tricks '''|arrondi=5px|bordure=indianred|fond=lavenderblush|flotte=left|couleurTitre=lightcoral|largeur=39%}}
 
{{Boite|titre=''' tips ‘n tricks '''|arrondi=5px|bordure=indianred|fond=lavenderblush|flotte=left|couleurTitre=lightcoral|largeur=39%}}
DO NOT over tighten the tweezers. By clenching too much, you may see your component literally “catapult” out of your tweezers, due to the elasticity of steel.Thus catapulted, the component status changes and turns into “meat for vacuum cleaner” ... you’ll have to take another transistor because the chances of retrieving it are inversely proportional to the importance of the said component.
+
Don't hold the parts too tight with the tweezers. By too much clenching, you may see your component literally jump out of your tweezers, due to the elasticity of the steel tips. Thus catapulted, the component status changes and turns into “meat for vacuum cleaner” ... you’ll have to take another transistor because the chances of retrieving it are inversely proportional to the importance of the said component.
 
{{BoiteFin}}
 
{{BoiteFin}}
  
Line 130: Line 124:
 
<br style="clear: both" />
 
<br style="clear: both" />
  
Soldering this component should not be a problem. Except perhaps a lowering of the temperature of the tip of your iron when attempting to solder the two metallic side tabs. If you have a second soldering iron, use a larger solder tip and a thicker solder wire of 0.5 mm
+
Soldering the rotary encoder should not be a problem. You might perhaps lower the temperature of the tip of your iron when attempting to solder the two metallic side tabs. If you have a second soldering iron, use a larger solder tip and a thicker solder wire of 0.5 mm
 
[[File:Etape 6.JPG |400px|left|]]
 
[[File:Etape 6.JPG |400px|left|]]
 
<br style="clear: both" />
 
<br style="clear: both" />
Line 142: Line 136:
 
Install
 
Install
  
* either a Molex kk 15 contacts connector (optional) on the opposite side of the components and board (see picture)
+
* either a [http://www.usefulcomponents.com/ebay/pictures/connectors/molex/kk_6471/kk_conns_group_s.jpg Molex kk 15 pins connector] (optional) on the opposite side of the components and board (see picture)
  
 
* Or 15 pieces of wire, 15 cm each (approx. 6 inches). Strip each end over 4mm, tin with a solder drop, and insert and solder these wires one by one in the holes provided for this purpose.
 
* Or 15 pieces of wire, 15 cm each (approx. 6 inches). Strip each end over 4mm, tin with a solder drop, and insert and solder these wires one by one in the holes provided for this purpose.
Line 156: Line 150:
 
<br style="clear: both" />
 
<br style="clear: both" />
  
Using "kk" Molex connectors (optional) may seem attractive. In fact, it’s just a bad idea: the wiring of the cable itself with it’s two “housing” is long and tedious (especially for those not accustomed to this kind of sport) and insertion force needed to connect the whole 15 pins connectors is really high.
+
Using [http://spellfoundry.rivendelltechltd.netdna-cdn.com/wp/wp-content/uploads/2013/04/Crimped-plug-500.jpg "kk" Molex] connectors (optional) may seem attractive. In fact, it’s just a bad idea: the wiring of the cable itself with it’s two “housing” is long and tedious (especially for those that not are not accustomed to this kind of sport) and a significant insertion force is needed to connect the whole 15 pins connectors.
  
  
Line 299: Line 293:
  
 
The electronic part is completed. It remains to be tested, after connecting the iron (see diagram) and loading the Arduino with it’s code (see the section “Programming Manual”). Once the tests are successful, put the project in a dedicated enclosure.
 
The electronic part is completed. It remains to be tested, after connecting the iron (see diagram) and loading the Arduino with it’s code (see the section “Programming Manual”). Once the tests are successful, put the project in a dedicated enclosure.
 +
 +
 +
 +
 +
==''' Arduino's modification '''==
 +
 +
One last hack must be completed before loading the firmware :  the LEDoctomy (without anesthesia) of the diode marked "L" on the Arduino (the one driven by the D13 output). This is mandatory because D13 is used by one of the pins of the rotary encoder (or a button "up-down" temperature adjustment). Without such a surgical operation, the D13 port cannot reach a clean 0/5V level.
 +
 +
To unsolder this diode, use you tweezer and gently try to pick-up the component while heating each solder spot one after another.
 +
 +
DO NOT touch the other LED marked "PWR", "TX" and "RX".
 +
 +
 +
[[File:Ledoctomie fer.jpg|500px|left|]]
 +
<br style="clear: both" />
 +
 +
  
 
==''' Loading the firmware'''==
 
==''' Loading the firmware'''==
  
 
  [[Projets:Lab:2015:SolderStation:FirmwareEnglish | see the dedicated chapter]]
 
  [[Projets:Lab:2015:SolderStation:FirmwareEnglish | see the dedicated chapter]]

Latest revision as of 15:42, 6 August 2015

A soldering station for SMD components used to learn how to solder SMD component. Ain’t that recursive enough ?(click on the picture for higher def.)

Assembly Manual


  Seven Wiki pages and two files are related to this project: 
 
 *  Loading the firmware (Française release) 
 *  A quick general presentation of the solder station (French release)
 *  Assembly Manual, illustrated (French release)    
 *  File:BOM Station CMS.xls The Bill of Material, xls format
 *  File:BOM Montage.xls The Assembly BoM, xls format
 
 *  Loading the firmware (English release)
 *  Assembly Manual (English release)
 *  A quick general presentation of the solder station (English release) 
 
 *  Assembly Manual, illustrated (German release)



The tools you need

  • Soldering iron (with a fine “needle” tip)
  • Copper desoldering braid (also called "Solder wick", to correct bad solder points)
  • Cutting pliers (“flush” cutting, not bevelled if possible)
  • Solder flux
  • Isopropyl Alcohol (small bottle)
  • Toothbrush or Q-tip
  • Jewelery tweezers or fine tip tweezers
  • Solder wire (0.5mm max recommended, 0.3mm is better, tin-lead-silver or tin-lead-copper alloy. Try to avoid ROHS solder)
  • Components (see BoM of “kit number 2”)
  • 2.5 meters of cabling wire
  • Arduino Nano (NOT mini!)
  • 12V Power supply (for testing)
  • Protection goggles

The first part of this manual deals with the assembly of SMD and through-hole components to build the core of the solder station. It does not address the mechanical parts (boxing, integration) of this equipment.

      Important note: each step requires you to remove one or many (up to 9) components out of the
      kit. To avoid losing them, it is recommended to put these devices in a small container (yogurt
      cup, plate etc).
      DO NOT extract the components from their storage tape more than one by one

Schematic diagram and PCB ayout

Schema.PNG

Click on the picture to get a high definition version

The schematic is not very complex.

The core of the device is an Arduino (Nano in this case). Ports D2 to D13 and A2 to A4 are devoted to the man-machine interface, which can be completely modified on user’s choice, as it is independant from the core. Some people at Electrolab prefered to use a color LCD rather than the basic set of 7-segment displays. The choice of temperature controls ("up-down" buttons or rotary encoder) depends on a simple selection in the configuration file (see the “firmware installation” chapter). The two alternatives (button and encoder) are available on the same PCB

The soldering iron plugs into P1. On this connector, you will find a 12 V “power” output (pins 4 and 5) powering the heating element of the iron. This voltage is not a DC voltage but a PWM signal controlled by the Arduino (on port D3) via a power FET transistor Q1. Variation of the duty cycle decreases or increases the amount of current sent to the iron, and hence its temperature.

Also on P1, pin 1, a very low and variable voltage is received from the temperature sensor embedded in the body of the Weller soldering tip. This voltage is strongly amplified by the operational amplifier OPA336, and then fed to one of the analog inputs of the Arduino. Measuring this voltage provides the microcontroller with an accurate tip temperature information. The software control loop programmed in the microcontroller uses this temperature measure to adjust the width of the PWM signal (Port D3). The goal of the control loop is that the temperature of the tip remains, as far as possible, of constant value.

Port A5 of the Arduino, labelled "STDBY SW" (standby switch) puts the iron in a "cold" standby state when this pin is grounded. Its activation may be triggered by a magnetic switch (reed switch) located in the soldering iron's handle (activated by a small magnet you have to embed in the soldering iron cradle) or a sensitive mechanical switch mounted on the support of the soldering iron.

Implantation.PNG

The entire soldering station stands on two separate circuit boards. On the left side of the schematic, the microcontroller assembly which supports both the Arduino Nano and the components required for the measuring loop (measuring amplifier, transistor driving the power supply of the heating element). On the right side, a large 5x10cm PCB dedicated to the man-machine interface (temperature control buttons or encoder, digital display). This display has two functions: showing the iron’s temperature and the PWM duty cycle (through the decimal points: the more “dot point” shown, the higher the duty-cycle of the PWM signal). A LED, located in the lower left corner of the 7 segment display, will also light on when the iron is "heating".

The flat side of the encoder should be on the same height level than the 7-segment display. This way, display and rotary encoder will just be level with the front panel.

Use this layout diagram to identify the location of components during assembly.

The display board

Etape 1.JPG


Put three small blobs of solder on the three upper left footprints R11, R12 and R13 of the display card (one side only, NOT the two solderpads). Use the tweezers to take 3x 1 kOhm resistors, gently slide each resistor in position while heating the solder blob with your soldering iron. Do not try to heath the component itself, just the pad. The metal will flow and “wet” the resistors. If the solderpoint is not shiny anymore or refuse to spread (by capillarity) on the resistor’s side, just add some solder flux. Once the metallized part of the resistance is "wet" by the solder, remove the iron while maintaining the tweezer ... without moving. That’s fine, you’ve made your first SMD solder point.

It is not advisable to leave the iron tip in contact with the printed circuit during a long period of time (5 seconds maximum).

tips ‘n tricks

Solder drop must spread on the end of the component by capillary. If this is not the case, either the soldering iron is not enough clean (wipe it with a sponge or bronze wool) or the solder itself is oxidized (in this case, add a drop of flux).


Repeat the operation for the second 1 kOhm resistors… and so on. The three resistors once maintained by the solder on the board, solder the other side of each resistor.

At the end of this operation, you still have one 1k resistor left in its protective tape. Take it preciously apart. You’ll need it when building the MCU board.


Etape 2.JPG


Take 9x 220 Ohm resistors (R14 to R21 and R8), and repeat the operation for the next 9 resistor’s locations.

tips ‘n tricks

Beware not to "overload" the solder pads. Too much solder could provoke bad electrical contacts


Etape 3.JPG


Take 3 x BSN20 FETs (Q3, Q4, Q5). Put a drop of solder to only one of the three pads (the one located in the middle is the most convenient). Then hold the transistor by the sides with your tweezers and slide it into the drop of molten solder (well… not the component itself, just the pin ;- ) ). Take off the board the tip of your soldering iron when your transistor is in the right position. All the three pads must be aligned with the corresponding pins of the device. Wait two or three seconds until the solder is cold and solid. Make sure the transistor is centered and all it’s pin on a solder pad. If this is not the case, correct its position again by heating the solder bump and try to adjust the position of the transistor again. . Repeat this for all three transistors located on the upper edge of the plate

tips ‘n tricks

Don't hold the parts too tight with the tweezers. By too much clenching, you may see your component literally jump out of your tweezers, due to the elasticity of the steel tips. Thus catapulted, the component status changes and turns into “meat for vacuum cleaner” ... you’ll have to take another transistor because the chances of retrieving it are inversely proportional to the importance of the said component.

At the end of this operation, you have one BSN20 transistor left on its protective strip. Take it apart too, with the 1k resistor (see first chapter above)

Etape 4.JPG


Put the SW3 rotary encoder in it’s place, on the right side of the pcb. The case must firmly rest on the surface of the pcb. If not, the upper surface of the display won’t flush with the surface of the front plate of your enclosure.


Etape 5.JPG


Soldering the rotary encoder should not be a problem. You might perhaps lower the temperature of the tip of your iron when attempting to solder the two metallic side tabs. If you have a second soldering iron, use a larger solder tip and a thicker solder wire of 0.5 mm

Etape 6.JPG


Position the three 7 segments displays AFF2, AFF3, and AFF4. They can only be installed in one only one position/orientation. Be careful not to bend one of the pin when inserting each display unit.

Etape 7.JPG


Solder each pins after returning the board. Take care that the base of the component remains in contact with the pcb. Again, a large iron tip and a solder wire of 0.5 or 1mm is appreciable

Install

  • Or 15 pieces of wire, 15 cm each (approx. 6 inches). Strip each end over 4mm, tin with a solder drop, and insert and solder these wires one by one in the holes provided for this purpose.

Trim each wire with a cutter plier.

Warning: the last two holes located on the bottom of the row must stay free of any wire. They are reserved for possible extensions between the interface and a gpio Arduino (one GND and one "free" wire).

Etape 8bis.JPG


Picture above : the wiring once finished (click on the picture if you want a higher resolution)

Etape 8.JPG


Using "kk" Molex connectors (optional) may seem attractive. In fact, it’s just a bad idea: the wiring of the cable itself with it’s two “housing” is long and tedious (especially for those that not are not accustomed to this kind of sport) and a significant insertion force is needed to connect the whole 15 pins connectors.


Etape 9.JPG


Solder the D1 Led located at the left hand side of the pcb. The longer wire goes on the upper hole, the shorter in the lower (grounded) hole. The top of the LED should slightly protruding above the level of the 7 segment display.


Etape 9bis.JPG


With cutting pliers, cut/trim protruding pin and wires

tips ‘n tricks

Always keep a finger on top of the pin being cut (see photo). Metal shrapnel could be thrown when cutting the pin causing potential serious injuries. Protective eyewear is strongly recommended

Etape 10.JPG


This conclude the assembly of the first pcb

Clean flux residues with a toothbrush or Q-tip soaked in isopropyl alcohol (isopropanol or rubbing alcohol). Put the diplay board apart.

tips ‘n tricks

Cleaning is not just to have "beautiful" circuits. The solder flux is relatively acidic and over time could attack the copper tracks and contacts, causing outages and poor contacts.


MCU board

Remembrer, when assembling the display board. Two component have been take apart: a 1k resistor (R3) and a BSN20 transistor (Q2). It is wise to solder them immediately to avoid losing them, particularly if they have been removed from their protective tape.

Place the remaining transistor in the same way that you have already soldered the other (location of Q2 is between the two rows of HE10 female contacts of the Arduino Nano board)

Etape 10 bis.JPG


Then the 1kOhm resistor

Etape 10 ter.JPG


Now it's time to get serious and solder the first SOIC component


Etape 11.png


tips ‘n tricks

Active components in SOIC packages have an orientation. The number 1 pin is marked by a small laser etched “dot”, and/or a biased edge to 45 ° (see above picture)

Etape 12.JPG


Take the "MCU" board, the Q1 transistor (FET IRF7416). Important Warning : the kit includes two circuits with the same kind of packaging. Check the reference before soldering.

Etape 13.JPG


Proceed exactly as for the transistors by depositing a drop of solder on one pad only. slide the component in position using the tweezers; while heating the solder drop with your soldering iron. When the component is correctly aligned (all pins and pads) remove the tip of the iron so that the solder solidifies. Attention, an 8-pin SOIC case is a little bit more difficult to align than a transistor. The 8 component’s pins must be centered on each solder pad. One the first pin is soldered, take the opportunity to check again the orientation of the IC ... spotting the beveled side of the circuit is not obvious.

Etape 14.JPG


If everything is ok, solder the diametrically opposite pin of the component. Check centering legs and pads, adjust slightly if necessary. Then solder the other remaining six pins

tips ‘n tricks

It is common for beginners to create "bridges" between IC’s pins, bringing too much solder metal. Do not try to immediately eliminate the short circuit. Finish all the soldering of the other pins. Once this work is completed, put a drop flux over the bridge (a bridge is always a sign of poor "wettability" of the eutectic), carefully clean the tip of your iron and melt the solder overflow with the tip of the iron and some solder wick. The bridge will be literally sucked by the wick. Put some new and fresh solder if the braid has done his job too well. Go to the next solder bridge if there is one.


The next picture shows the IRF7416 soldered Do not pay attention of the transistor located close to Q1. This is Q2, BSN20, in prototype version of the pcb. Q2 is now placed between between the two pinout rows of the Arduino and has already been soldered (see beginning of this chapter).

Etape 16.jpg


Take the second integrated circuit U1 (OPA336), check its orientation (use orientation’s marks on the silk mask), then solder it as explained before.

Etape 17.JPG



Solder the 3 ceramic capacitors the same way you did with the resistors. Begin with the 100nF C1, then the two 10nF C2 and C3. Attention ! unlike resistors whose value is printed on the body of the component, capacitors are not "marked". Do not mix the values during assembly.

Etape 18.JPG


Do the same with the resistors R2 and R7 (5.6 kOhm), R4 (100 kOhm), R5 (100 Ohm), R6 (68 kOhm) located around the OPA336 operational amplifier. Then solder R1 (10 kOhm, near the IRF7416). R3 resistance (1 kOhm) close to Q2, under the Arduino Nano, has already been soldered.

Etape 19.jpg


Prepare the two “15 contacts” Arduino support (female HE10)

Etape 20.JPG


Insert each row on Arduino’s pins. Make sure the connectors are fully inserted.

Etape 21.JPG


Insert the two strips maintained by the Arduino on the pcb.

Etape 22.JPG


Solder the first pad, make sure the contact strip is resting on the “components side” of the pcb. Solder the pin located in the opposite corner.Make a final visual check, adjust if necessary, then solder all the pins.

Etape 23.JPG


This method guarantees a perfect alignment of pins. Do not try to solder the 15 pin connector without an Arduino that could be used as a “jig”

Optionally, it is possible to add two KK Molex connectors one of 15 (or 17) pins to connect the display unite, the other one with 5 pins to plug the output/soldering tip/temp. sensor connector.


Etape 24.JPG



Etape 23 bis.JPG




By default, these two connectors are NOT provided in the kit. It is easier to connect the Microcontroller, output connector and the display unit with simple cabling wires. (see picture above)

As for the display board, the two bottom holes are not used and therefore are not wired.

No wires should be crossed, the wiring is "straight, pin to pin." An exception: the two wires located at the top of the row (gpio 12 and 13). This two wire can be twisted so that the temperature increase is done by turning the encoder’s button clockwise. (with a “straight” cabling, increase of the temperature is set counterclockwise).

Etape 24bis .JPG


Flip the MCU board upside down and solder D2, a large CMS Schottky diode, taking care of the orientation. The cathode –marked with a bar on one end of the component- is oriented toward the Arduino side. The anode, the other side, is facing the 12 V pad and the pcb edge (in case of doubt, refer to the picture).

Etape 25.JPG


The electronic part is completed. It remains to be tested, after connecting the iron (see diagram) and loading the Arduino with it’s code (see the section “Programming Manual”). Once the tests are successful, put the project in a dedicated enclosure.



Arduino's modification

One last hack must be completed before loading the firmware : the LEDoctomy (without anesthesia) of the diode marked "L" on the Arduino (the one driven by the D13 output). This is mandatory because D13 is used by one of the pins of the rotary encoder (or a button "up-down" temperature adjustment). Without such a surgical operation, the D13 port cannot reach a clean 0/5V level.

To unsolder this diode, use you tweezer and gently try to pick-up the component while heating each solder spot one after another.

DO NOT touch the other LED marked "PWR", "TX" and "RX".


Ledoctomie fer.jpg



Loading the firmware

 see the dedicated chapter