Documentation, BOM and source code

Documentation, BOM and source code

Co-Authored-By: Robert Turinský <rturinsky@users.noreply.github.com>

DOCUMENTATION/.gitkeep

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+

DOCUMENTATION/PRINT SETTINGS/recommended print settings for Original Prusa MINI.md

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+### Recommended print settings :
+
+Printer : **Original Prusa MINI**
+
+Print settings : **0.20mm Quality**
+
+Material : **Prusament PETG**
+
+Nozzle : **0.4 mm**
+
+Layer : **0.2 mm**
+
+Support : **no supports**
+
+### **Edit :**
+
+Infill pattern : **grid**
+
+Infill density : **10 %**
+
+<br/>
+
+### **Parts :**
+
+
+- MINI-z-bottom-cover
+
+- MINI-z-bottom-cable-cover
+
+- MINI-fan-spacer
+
+- MINI-fan-spacer-clip
+
+- MINI-fsenzor-box
+
+- MINI-fsenzor-cover
+
+- MINI-fsenzor-lever
+
+- MINI-minda-holder
+
+- MINI-inspection-door
+
+- MINI-knob
+
+- MINI-heatbed-cable-cover-bottom
+
+- MINI-heatbed-cable-cover-top
+
+- MINI-rail-spoolholder
+
+- MINI-base-spoolholder
+
+
+
+
+
+
+-------------------------------------------------------------------------------------------------------------------
+
+### Recommended print settings :
+
+Printer : **Original Prusa MINI**
+
+Print settings : **0.20mm Quality**
+
+Material : **Prusament PETG**
+
+Nozzle : **0.4 mm**
+
+Layer : **0.2 mm**
+
+Support : **no supports**
+
+### **Edit :**
+
+Infill pattern : **grid**
+
+Infill density : **20 %**
+
+<br/>
+
+### **Parts :**
+
+
+- MINI-x-carriage
+
+- MINI-x-end
+
+- MINI-y-belt-holder
+
+- MINI-y-idler
+
+- MINI-y-plate-rear
+
+- MINI-y-plate-front
+
+- MINI-z-carriage-rear
+
+- MINI-z-carriage-front
+
+- MINI-z-bottom
+
+- MINI-z-top
+
+- MINI-extruder-rear
+
+- MINI-extruder-front
+
+- MINI-extruder-idler
+
+- MINI-display-box
+
+
+
+
+
+
+-----------------------------------------------------------------------------------------------
+
+Please keep in mind thermal expansion of used material especially in XY plane. Printed parts are tempered by heatbed - then cooled down to room temperature so parts shrink.
+
+```
+Apply this linear relation: delta D´ = D * gamma * delta T
+	delta D´	= final dimension difference
+	D		= original dimension
+	gamma		= coefficient of thermal expansion for used material
+	delta T		= printed part temperature difference between current temperature 
+			  while it's printed and ambient temperature in use
+
+Example:
+material	PETG: 	HB temp. = 90 [°C]
+			amb. temp. = 25 [°C] 
+delta T		90 - 25 = 65 [°C]
+gamma		0.000068 [m/m*°C] [1/°C] (doesn't matter if Celsius or Kelvin)
+D		100 [mm]
+Use basic unit!
+
+delta D´ = D * gamma * delta T
+delta D´ = 0.1 * 0.000068 * 65
+delta D´ = 0.000442 [m] = 0.442 [mm]
+```
+
+Linear thermal expansion works for each layer if there's any delta T but every layer has different delta T if the heatbed temperates printed part - the higher layer position the smaller delta T. It's due to cooling printed part by ambient air and air flow from print fan.

DOCUMENTATION/PRINT SETTINGS/recommended print settings for Original Prusa i3 MK3S.md

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+### Recommended print settings :
+
+Printer : **Original Prusa i3 MK3S**
+
+Print settings : **0.20mm Quality**
+
+Material : **Prusament PETG**
+
+Nozzle : **0.4 mm**
+
+Layer : **0.2 mm**
+
+Support : **no supports**
+
+### **Edit :**
+
+Infill pattern : **grid**
+
+Infill density : **10 %**
+
+<br/>
+
+### **Parts :**
+
+
+- MINI-z-bottom-cover
+
+- MINI-z-bottom-cable-cover
+
+- MINI-fan-spacer
+
+- MINI-fan-spacer-clip
+
+- MINI-fsenzor-box
+
+- MINI-fsenzor-cover
+
+- MINI-fsenzor-lever
+
+- MINI-minda-holder
+
+- MINI-inspection-door
+
+- MINI-knob
+
+- MINI-heatbed-cable-cover-bottom
+
+- MINI-heatbed-cable-cover-top
+
+- MINI-rail-spoolholder
+
+- MINI-base-spoolholder
+
+
+
+
+
+
+-------------------------------------------------------------------------------------------------------------------
+
+### Recommended print settings :
+
+Printer : **Original Prusa i3 MK3S**
+
+Print settings : **0.20mm Quality**
+
+Material : **Prusament PETG**
+
+Nozzle : **0.4 mm**
+
+Layer : **0.2 mm**
+
+Support : **no supports**
+
+### **Edit :**
+
+Infill pattern : **grid**
+
+Infill density : **20 %**
+
+<br/>
+
+### **Parts :**
+
+
+- MINI-x-carriage
+
+- MINI-x-end
+
+- MINI-y-belt-holder
+
+- MINI-y-idler
+
+- MINI-y-plate-rear
+
+- MINI-y-plate-front
+
+- MINI-z-carriage-rear
+
+- MINI-z-carriage-front
+
+- MINI-z-bottom
+
+- MINI-z-top
+
+- MINI-extruder-rear
+
+- MINI-extruder-front
+
+- MINI-extruder-idler
+
+- MINI-display-box
+
+
+
+
+
+
+-----------------------------------------------------------------------------------------------
+
+Please keep in mind thermal expansion of used material especially in XY plane. Printed parts are tempered by heatbed - then cooled down to room temperature so parts shrink.
+
+```
+Apply this linear relation: delta D´ = D * gamma * delta T
+	delta D´	= final dimension difference
+	D		= original dimension
+	gamma		= coefficient of thermal expansion for used material
+	delta T		= printed part temperature difference between current temperature 
+			  while it's printed and ambient temperature in use
+
+Example:
+material	PETG: 	HB temp. = 90 [°C]
+			amb. temp. = 25 [°C] 
+delta T		90 - 25 = 65 [°C]
+gamma		0.000068 [m/m*°C] [1/°C] (doesn't matter if Celsius or Kelvin)
+D		100 [mm]
+Use basic unit!
+
+delta D´ = D * gamma * delta T
+delta D´ = 0.1 * 0.000068 * 65
+delta D´ = 0.000442 [m] = 0.442 [mm]
+```
+
+Linear thermal expansion works for each layer if there's any delta T but every layer has different delta T if the heatbed temperates printed part - the higher layer position the smaller delta T. It's due to cooling printed part by ambient air and air flow from print fan.