Difference between revisions of "Assembly"

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__FORCETOC__
__FORCETOC__
== Overview of parts ==
 
[[File:Overview.jpg|500px|left]]<br clear=all>
{{#ev: vimeo | 684373327 | 1000px }}
 
== Overview of parts / Assembly ==


'''Requirements:
'''Requirements:
Line 9: Line 11:
#  Flux  
#  Flux  
#  3D Printer / 3d printing service
#  3D Printer / 3d printing service
#  [[bcMeter Parts]]


== Walkthrough ==
<vimeo>568114940</vimeo> Time lapse of assembly


'''This guide is for the general purpose 12V PCB which was designed for simplicity so as little as possible SMD components and parts with large footprints are used. '''


<br><br>
LED and sensor brackets
[[File:Image_001.png|thumb|none]]


1. Start assembling by soldering the smallest parts first (MMBT3904 + MCP3426).  
The orientation of both the 3D printed infrared LED and sensor assemblies have been simplified to reduce orientation mismatches.
The infrared LEDs come in a clear looking part while the infrared sensors are dark parts.
Each part needs to be correctly oriented; they have an spherical shaped part (lenses) which needs to point to the shorter end of the 3D printed brackets in
a way that they both point to the filter paper.


<gallery>
Insert LED and sensor bracket assembly to the case
BcMeter-assembly0000.jpg
[[File:Image_002.png|thumb|none]]
BcMeter-assembly0001.jpg
</gallery>
<br>
2. Then add THT passive parts piece by piece, the Pi Header (or connector) according to description on the PCB and the BOM.


<gallery>
Prepare both the counterparts for the LED and sensor bracket assemblies with superglue or hot glue before insertion to create airtight channels. Make sure to also completely cover the middle part between sample and sensor area with glue. This is absolutely crucial to avoid air leakage.
BcMeter-assembly0002.jpg
Before inserting the brackets into the case, use superglue to fix the LEDs and sensors in place (avoid tilting and
BcMeter-assembly0003.jpg
[[File:Image_003.png|thumb|none]]
BcMeter-assembly0004.jpg
BcMeter-assembly0005.jpg


</gallery>
check orientation).
Mount the brackets to the case and check that the lenses of are centered in the holes by looking straight from above; same goes for the dark infrared sensors in their bracket to be inserted in the bottom case.
You have a little while to adjust with superglue; using hot glue, reheat the area as needed:
Clean possible residue of glue with acetone as it affects the clarity of the LEDs.
Reference & Sample parts
[[File:Image_004.png|thumb|none]]


In this area on the circuit board, the LEDs have to be connected in series, so the negative pin of the first LED is the positive pin of the second LED. Using a standard 4 pin 2.54mm JST connector and cable, solder the connections in the order red- black-yellow-white.


3. Put IRL81A (IR Emitter) and LPT80A (Sensor) in brackets D and E - refer to overview above -  seal with hot glue and solder wires to the corresponding vias on the PCB. Long leg is anode (positive).
[[File:Image_005.png|thumb|none]]


<gallery>
Here, the infrared sensors for measuring the attenuation are connected parallel. Thus, they have to be connected in a different order than the LEDS: black-red-white-yellow.
BcMeter-assembly0006.jpg
Now, you have completed the most crucial part of the bcMeter assembly. The orientation of the LEDs to the sensors and the air leakage have a huge influence on the later accuracy of the device. Smaller isalignments can't be avoided and compensated by the "Calibration" function from the interface.
BcMeter-assembly0007.jpg
Sealing
BcMeter-assembly0008.jpg
[[File:Image_006.jpg|thumb|none]]
Sensor-emitter-brackets.jpg
BcMeter-assembly0009.jpg
</gallery>


4. Place adapters D and E (refer to overview above) in the case A and B. Emitter to top case. Seal with (hot) glue or tape. <br clear=all>
Now we can continue assembling the case itself by adding the rubber seal onto the bottom part. Make sure that the diameter is very well known as this is a crucial parameter for accuracy.
<gallery>
Check for air leakage and if needed, add a second seal on the top part as well. Make sure that the holes a overlapping.
BcMeter-assembly0016.jpg
To verify the diameter, you can just let the paper run black and then check the form and size of the sample spot.
Brackets-in-lower-case.jpg
Also add the M3 screw threads to the poles and use superglue to make a solid connection.
</gallery>


‌Pump control circuit


5. Put pump in place and do a test run for leakage.  
[[File:Image_007.jpg|thumb|none]]


<gallery>
pump.jpg
BcMeter-assembly0015.jpg
</gallery>


The bcMeter is very forgiving in choosing pumps since I tested and used every available type.
Basically you can connect every pump you want which is able to run at 5V. There are two type pumps in the low cost range: Membrane and propeller. For our use case, we need the membrane pumps. Then, they can have a PWM controller (Type A) or run without (Type B). The bcMeter is able to handle both types of pump and you can just connect them to the PCB. For PWM pumps, remove Q4.
image
image
If you want to use an airflow meter, connect the input of the pump to the output of the airflow sensor as shown on the left.
The input of the airflow sensor needs to be connected to the air sampling connector.
The pump output needs to be connected to the air output of the bcMeter as shown on the right.


6. Secure the raspberry with 3d printed brackts
‌Finalizing the built
Screw the top part of the case handtight


<gallery>
BcMeter-assembly0018.jpg
BcMeter-assembly0020.jpg
</gallery>


[[File:Image_008.jpg|thumb|none]]
[[File:Image_009.png|thumb|none]]
[[File:Image_010.png|thumb|none]]


7. Put the rubber band (cut down to two peaces or use one) to prevent air leaks onto lower case, also add screw threads if you want to.  
[[File:Image_011.png|thumb|none]]


<gallery>
‌Technical overview of the PCB:
BcMeter-assembly0012.jpg
BcMeter-assembly0013.jpg
BcMeter-assembly0022.jpg
</gallery>


[[File:Image_012.png|thumb|none]]


8. Put filter paper on top of the rubber, screw the intake part on top and continue with software configuration.
U1: MCP3428 4 Channel Analogue / Digital Converter D1 / D2: IR LED connector for sensor and reference
<gallery>
BcMeter-assembly0021.jpg
BcMeter-assembly0023.jpg
</gallery>


Q1 / Q2: IR Phototransistor for sensor and reference (ADC Channel 1 and 2) J1: Omron D6F Airflow Sensor (ADC Channel 4)


J2: SSD1306 Display (optional J7: Heater or Fan (optional) J12: SPI Header (optional)


== Component locations ==
J5: Air Pump


J4: PWM + J9 Power for Air Pump (Remove Q4 for PWM Pump!)


{| class="wikitable collapsible sortable"
+ several header (I2C, ADC, Power) for expandability
! Ref !! Value !! Part !! Footprint !! Description !! Vendor
|-
| C1 || 330nF || Device:CP || Capacitor_THT:CP_Radial_D5.0mm_P2.50mm || Polarized capacitor ||
|-
| C2 || 100nF || Device:C || Capacitor_THT:C_Disc_D5.0mm_W2.5mm_P2.50mm || Unpolarized capacitor ||
|-
| C3 || 330nF || Device:CP || Capacitor_THT:CP_Radial_D5.0mm_P2.50mm || Polarized capacitor ||
|-
| C4 || 100nF || Device:C || Capacitor_THT:C_Disc_D5.0mm_W2.5mm_P2.50mm || Unpolarized capacitor ||
|-
| C5 || 10nF || Device:C || Capacitor_THT:C_Disc_D5.0mm_W2.5mm_P2.50mm || Unpolarized capacitor ||
|-
| C6 || 1nF || Device:C || Capacitor_THT:C_Disc_D5.0mm_W2.5mm_P2.50mm || Unpolarized capacitor ||
|-
| C7 || 10uF || Device:CP || Capacitor_THT:C_Disc_D5.0mm_W2.5mm_P2.50mm || Polarized capacitor ||
|-
| C8 || 100nF || Device:C || Capacitor_THT:C_Disc_D5.0mm_W2.5mm_P2.50mm || Unpolarized capacitor ||
|-
| C9 || 10nF || Device:C || Capacitor_THT:C_Disc_D5.0mm_W2.5mm_P2.50mm || Unpolarized capacitor ||
|-
| C10 || 1nF || Device:C || Capacitor_THT:C_Disc_D5.0mm_W2.5mm_P2.50mm || Unpolarized capacitor ||
|-
| C11 || 10nF || Device:C || Capacitor_THT:C_Disc_D5.0mm_W2.5mm_P2.50mm || Unpolarized capacitor ||
|-
| C12 || 1nF || Device:C || Capacitor_THT:C_Disc_D5.0mm_W2.5mm_P2.50mm || Unpolarized capacitor ||
|-
| D1 || IRL81A || Device:LED || LED_THT:LED_SideEmitter_Rectangular_W4.5mm_H1.6mm || Light emitting diode ||
|-
| D2 || IRL81A || Device:LED || LED_THT:LED_SideEmitter_Rectangular_W4.5mm_H1.6mm || Light emitting diode ||
|-
| J1 || Jack-DC || Connector:Jack-DC || Connector_BarrelJack:BarrelJack_Wuerth_6941xx301002 || DC Barrel Jack ||
|-
| J2 || Raspberry_Pi_2_3 || Connector:Raspberry_Pi_2_3 || Connector_PinSocket_2.54mm:PinSocket_2x20_P2.54mm_Vertical || expansion header for Raspberry Pi 2 & 3 ||
|-
| J3 || Conn_02x13_Odd_Even || Connector_Generic:Conn_02x13_Odd_Even || Connector_PinHeader_2.54mm:PinHeader_2x13_P2.54mm_Vertical || Generic connector, double row, 02x13, odd/even pin numbering scheme (row 1 odd numbers, row 2 even numbers), script generated (kicad-library-utils/schlib/autogen/connector/) ||
|-
| J4 || RTC || Connector_Generic:Conn_01x05 || Connector_PinHeader_2.54mm:PinHeader_1x05_P2.54mm_Vertical || Generic connector, single row, 01x05, script generated (kicad-library-utils/schlib/autogen/connector/) ||
|-
| J5 || TMP || Connector_Generic:Conn_01x04 || Connector_PinHeader_2.54mm:PinHeader_1x04_P2.54mm_Vertical || Generic connector, single row, 01x04, script generated (kicad-library-utils/schlib/autogen/connector/) ||
|-
| M1 || 12V Pump || Motor:Fan_CPU_4pin || Connector_PinHeader_2.54mm:PinHeader_1x04_P2.54mm_Vertical || CPU Fan, tacho output, PWM input, 4-pin connector ||
|-
| M2 || AirflowMeter || Motor:Fan_Tacho_PWM || Connector_PinHeader_2.54mm:PinHeader_1x03_P2.54mm_Vertical || Fan, tacho output, PWM input, 4-pin connector ||
|-
| Q1 || LPT80A || Sensor_Optical:LPT80A || OptoDevice:Osram_LPT80A || NPN phototransistor ||
|-
| Q2 || MMBT3904 || Transistor_BJT:MMBT3904 || Package_TO_SOT_SMD:SOT-23 || 0.2A Ic, 40V Vce, Small Signal NPN Transistor, SOT-23 ||
|-
| Q3 || LPT80A || Sensor_Optical:LPT80A || OptoDevice:Osram_LPT80A || NPN phototransistor ||
|-
| R1 || 2k2 || Device:R || Resistor_THT:R_Axial_DIN0207_L6.3mm_D2.5mm_P7.62mm_Horizontal || Resistor ||
|-
| R2 || 100 || Device:R || Resistor_THT:R_Axial_DIN0207_L6.3mm_D2.5mm_P7.62mm_Horizontal || Resistor ||
|-
| R3 || 2k2 || Device:R || Resistor_THT:R_Axial_DIN0207_L6.3mm_D2.5mm_P7.62mm_Horizontal || Resistor ||
|-
| R4 || 10k || Device:R || Resistor_THT:R_Axial_DIN0207_L6.3mm_D2.5mm_P7.62mm_Horizontal || Resistor ||
|-
| RV1 || R_POT || Device:R_POT || Connector_PinHeader_2.54mm:PinHeader_1x03_P2.54mm_Vertical || Potentiometer ||
|-
| SW1 || Interrupt || Switch:SW_Push_Open || Connector_PinHeader_2.54mm:PinHeader_2x01_P2.54mm_Vertical || Push button switch, push-to-open, generic, two pins ||
|-
| U1 || L7809 || Regulator_Linear:L7809 || Connector_PinHeader_2.54mm:PinHeader_1x03_P2.54mm_Vertical || Positive 1.5A 35V Linear Regulator, Fixed Output 9V, TO-220/TO-263/TO-252 ||
|-
| U2 || L7805 || Regulator_Linear:L7805 || Connector_PinHeader_2.54mm:PinHeader_1x03_P2.54mm_Vertical || Positive 1.5A 35V Linear Regulator, Fixed Output 5V, TO-220/TO-263/TO-252 ||
|-
| U3 || MCP3426-xMS || Analog_ADC:MCP3426-xMS || Package_SO:MSOP-8_3x3mm_P0.65mm || 16-Bit, Multi-Channel ΔΣ Analog-to-Digital Converter with I2C Interface and On-Board Reference, MSOP-8 ||
|}

Latest revision as of 20:33, 13 October 2024


Overview of parts / Assembly

Requirements:

  1. Screwdriver
  2. Solder Iron
  3. Solder
  4. Flux
  5. 3D Printer / 3d printing service


LED and sensor brackets

Image 001.png

The orientation of both the 3D printed infrared LED and sensor assemblies have been simplified to reduce orientation mismatches. The infrared LEDs come in a clear looking part while the infrared sensors are dark parts. Each part needs to be correctly oriented; they have an spherical shaped part (lenses) which needs to point to the shorter end of the 3D printed brackets in a way that they both point to the filter paper.

Insert LED and sensor bracket assembly to the case

Image 002.png

Prepare both the counterparts for the LED and sensor bracket assemblies with superglue or hot glue before insertion to create airtight channels. Make sure to also completely cover the middle part between sample and sensor area with glue. This is absolutely crucial to avoid air leakage. Before inserting the brackets into the case, use superglue to fix the LEDs and sensors in place (avoid tilting and

Image 003.png

check orientation). Mount the brackets to the case and check that the lenses of are centered in the holes by looking straight from above; same goes for the dark infrared sensors in their bracket to be inserted in the bottom case. You have a little while to adjust with superglue; using hot glue, reheat the area as needed: Clean possible residue of glue with acetone as it affects the clarity of the LEDs. Reference & Sample parts

Image 004.png

In this area on the circuit board, the LEDs have to be connected in series, so the negative pin of the first LED is the positive pin of the second LED. Using a standard 4 pin 2.54mm JST connector and cable, solder the connections in the order red- black-yellow-white.

Image 005.png

Here, the infrared sensors for measuring the attenuation are connected parallel. Thus, they have to be connected in a different order than the LEDS: black-red-white-yellow. Now, you have completed the most crucial part of the bcMeter assembly. The orientation of the LEDs to the sensors and the air leakage have a huge influence on the later accuracy of the device. Smaller isalignments can't be avoided and compensated by the "Calibration" function from the interface. Sealing

Image 006.jpg

Now we can continue assembling the case itself by adding the rubber seal onto the bottom part. Make sure that the diameter is very well known as this is a crucial parameter for accuracy. Check for air leakage and if needed, add a second seal on the top part as well. Make sure that the holes a overlapping. To verify the diameter, you can just let the paper run black and then check the form and size of the sample spot. Also add the M3 screw threads to the poles and use superglue to make a solid connection.

‌Pump control circuit

Image 007.jpg


The bcMeter is very forgiving in choosing pumps since I tested and used every available type. Basically you can connect every pump you want which is able to run at 5V. There are two type pumps in the low cost range: Membrane and propeller. For our use case, we need the membrane pumps. Then, they can have a PWM controller (Type A) or run without (Type B). The bcMeter is able to handle both types of pump and you can just connect them to the PCB. For PWM pumps, remove Q4. image image If you want to use an airflow meter, connect the input of the pump to the output of the airflow sensor as shown on the left. The input of the airflow sensor needs to be connected to the air sampling connector. The pump output needs to be connected to the air output of the bcMeter as shown on the right.

‌Finalizing the built Screw the top part of the case handtight


Image 008.jpg
Image 009.png
Image 010.png
Image 011.png

‌Technical overview of the PCB:

Image 012.png

U1: MCP3428 4 Channel Analogue / Digital Converter D1 / D2: IR LED connector for sensor and reference

Q1 / Q2: IR Phototransistor for sensor and reference (ADC Channel 1 and 2) J1: Omron D6F Airflow Sensor (ADC Channel 4)

J2: SSD1306 Display (optional J7: Heater or Fan (optional) J12: SPI Header (optional)

J5: Air Pump

J4: PWM + J9 Power for Air Pump (Remove Q4 for PWM Pump!)

+ several header (I2C, ADC, Power) for expandability