Skip to content

Latest commit

 

History

History
289 lines (222 loc) · 7.3 KB

README.md

File metadata and controls

289 lines (222 loc) · 7.3 KB

Hardware

Printer

Chassis

Tenlog TL-3D Pro

Machine Dimensions Width Depth Height
Machine Size 590mm 520mm 760mm
Build Volume 300mm 300mm 350mm

No mechanical modification on the printer except fitting of the screw domes for the new motherboard.

Electronic

Motherboard

BIGTREETECH OCTOPUS Pro V1.0.1

CPU

STM32F429ZG

Stepper driver

The TMC2209 has only Step/Dir mode and UART, NO SPI.
Therefor the pins below the StepDriver are configured in UART mode:

oIoo
oIoo
oooo

The output voltage of the StepDriver should be the same as the supply voltage.
Since the TCM2209 is not supporting other output voltages, the jumper will use the 24V of the board:

o==

The TMC2209 supports StallGuard, which is connected to the diag pin.
The StallGuard is overwriting the endstops, therefor they will not be used:

oooooooo
oooooooo

Fans

The Fans are all 24V therefor the jumpers will bridge the last pins:

oo  5V
oo  12V
==  24V

PT100 DIP Switch

The Tenlog 3D-Pro is using PT100 temperature sensors.
Therefor all dip switches will be set to ON (which was default on my board).

Power supply

To avoid powering the board via USB,
the Power jumper in the center of the board needs to me removed.
For installation and debugging I will keep it connected for now,
But in production I need to remove the jumper!

BLTouch

The BLTouch will be connected the flowing way:

ooooo
||||'-- white  [OUT] \ Sensor     > PB7
|||'--- black  [GND] /            x N/C
||'---- yellow [IN]  \            > PB6
|'----- red    [+5V]  | Controll  > 5VDC
'------ blue   [GND] /            > GND

sub-D (DE-15)

E1/E2 Pinout

        Female               Male
   ,---------------.   ,---------------.
 5 \   o o o o o   / 1 \   * * * * *   / 5
10  \   o o o o o /  6  \   * * * * * / 10
15   \ o o o o o /  11   \ * * * * * /  15
      '---------'         '---------'
🟩 Pin Function 🟩 Pin Function
1 E 3 (C2) 3 E 1 (C1)
6 FZ - 8 LED +
2 E 4 (C2) 14 FC, FZ, H +
7 FC - 13 N/C
9 DJ 4 E 2 (C1)
🔀 10 H - 5 H -
11 RH 15 FC, FZ, H +
12 DJ, RH, LED -
Function Pins Explanation
FZ 6, 14, 15 Hot-End Cooling (red/black)
FC 7, 14, 15 Part Cooling (yellow/blue)
RH 11, 12 Temp Sensor
DJ 9, 12 Filament Run-Out Sensor
E 1, 2, 3, 4 Stepper
H 5, 10, 14, 15 Heater
LED 8, 12 Blue LED

Fans

Seems like all fans can be connected directly.

Housing Fans

Use the 2 extra fan plugs (Fan4 & Fan5) in Controller Fan Mode.
This disables the fans if there is no driver or MOSFETs in use.

Stepper

Plug Driver Axis
M0 Driver 0 X1
M1 Driver 1 Y
M2.1/M2.2 Driver 2 Z1
M3 Driver 3 Z2
M4 Driver 4 E0
M5 Driver 5 E1
M6 Driver 6 X2
M7 Driver 7 NC

Endstops/Filament

Port Plug Axis Mod
PG6 Stop 0 X1 Org:PSG > New:PGS
PG9 Stop 1 Y Org:PSG > New:PGS
PG10 Stop 2 Z1 Org:PSG > New:PGS
PG11 Stop 3 Z2 Org:PSG > New:PGS
PG12 Stop 4 E0 E1 sub-D 9
PG13 Stop 5 E1 E2 sub-D 9
PG14 Stop 6 X2 Org:PSG > New:PGS
PG15 Stop 7 NC

Fans

Port Plug Fan
PA8 FAN0 E0 Part Cooling Fan
PE5 FAN1 E1 Part Cooling Fan
PD12 FAN2 E0 Hot-End Cooling Fan
PD13 FAN3 E1 Hot-End Cooling Fan
PD14 FAN4 Housing Fan 1
PD15 FAN5 Housing Fan 2

Hot-Ends

Port Plug Device
PA1 Heated Bed Bed
PA2 HE0 E1
PA3 HE1 E2
PB10 HE2 N/C
PB11 HE3 Casing Light

Buffers

Increased all buffers to the max to reduce lags in WiFi data transfer.
Enabled XON/XOFF control characters.

#define BLOCK_BUFFER_SIZE 32
#define MAX_CMD_SIZE 96
#define BUFSIZE 32
#define TX_BUFFER_SIZE 256
#define RX_BUFFER_SIZE 2048
#define SERIAL_XON_XOFF

Calibration

PID Auto Tune

Bed

I run a PID Auto Tune with 9 cycles on the bed:

M303 C9 S60 D1 U1 E-1

With the new values the configuration is:

#define DEFAULT_bedKp 136.38
#define DEFAULT_bedKi 25.83
#define DEFAULT_bedKd 480.06

Hotends

I run a PID Auto Tune with 9 cycles on both hotends:

M303 C9 S210 D1 U1 E0
M303 C9 S210 D1 U1 E1

With the new values the configuration is:

#define DEFAULT_Kp_LIST { 26.65, 24.61 }
#define DEFAULT_Ki_LIST {  3.00,  2.65 }
#define DEFAULT_Kd_LIST { 59.16, 57.10 }

Step Driver Current

TMC2209

$I_{RMS}=\frac{325\textup{mV}}{R_{sense}+20\textup{m}\Omega}\cdot\frac{1}{\sqrt{2}}\cdot\frac{V_{ref}}{2.5\textup{V}}$

Model Length Current Resistance Inductance H.Torque D.Torque
17HS2408 28 mm 0.6 A 8 Ω 10 mH 12 N·cm 1.6 N·cm
17HS3401 34 mm 1.3 A 2.4 Ω 2.8 mH 28 N·cm 1.6 N·cm
17HS3410 34 mm 1.7 A 1.2 Ω 1.8 mH 28 N·cm 1.6 N·cm
17HS3403 34 mm 0.4 A 30 Ω 35 mH 28 N·cm 1.6 N·cm
17HS4401 40 mm 1.7 A 1.5 Ω 2.8 mH 40 N·cm 2.2 N·cm
17HS4402 40 mm 1.3 A 2.5 Ω 5 mH 40 N·cm 2.2 N·cm
17HS8401 48 mm 1.7 A 1.8 Ω 3.2 mH 52 N·cm 2.6 N·cm
17HS8402 48 mm 1.3 A 3.2 Ω 5.5 mH 52 N·cm 2.6 N·cm
17HS8403 48 mm 2.3 A 1.2 Ω 1.6 mH 46 N·cm 2.6 N·cm
  • X- & Z-Axis
    • 42-40 Motor (~3.2 Ω)
    • 1.3 A (- 10%) => 1170
  • Y- & E-Axis
    • 42-48 Motor (~3.2 Ω)
    • 1.3 A (- 10%) => 1170

UBL

  1. Level bed manually on all 4 corners
  2. Run
    G0 Z10
    G30 X154 Y154
    
  3. Read out result and calculate
    $Z_{M851}=Z_{M851}-Z_{Probe}$
  4. Write probe offset with
    M851 Z#.##
    
  5. Run UBL
    M420 S0   ; disable bed leveling
    G28       ; home all axes
    M155 S30  ; reduce temperature reporting rate to reduce output pollution
    M190 S60  ; wait for the bed to get up to temperature
    G4 S60    ; wait another 1 min for the bed to reach temperature
    G29 P0    ; clear mesh
    G29 P1    ; automatically populate mesh with all reachable points
    G29 P3    ; infer the rest of the mesh values
    G29 P3    ; infer the rest of the mesh values again
    M420 S1 V ; enabled leveling and report the new mesh
    M500      ; save the new mesh to EEPROM
    M155 S3   ; reset temperature reporting
    M140 S0   ; cooling down the bed
    
  6. Correct whole mesh with
    G29 P6 C#.##