19 KiB
Frequently asked questions
- How can I donate to the project?
- How do I calculate the step_distance parameter in the printer config file?
- Where's my serial port?
- When the micro-controller restarts the device changes to /dev/ttyUSB1
- The "make flash" command doesn't work
- How do I change the serial baud rate?
- Can I run Klipper on something other than a Raspberry Pi 3?
- Why can't I move the stepper before homing the printer?
- Why is the Z position_endstop set to 0.5 in the default configs?
- I converted my config from Marlin and the X/Y axes work fine, but I just get a screeching noise when homing the Z axis
- My TMC motor driver turns off in the middle of a print
- I keep getting random "Lost communication with MCU" errors
- My Raspberry Pi keeps rebooting during prints
- When I set "restart_method=command" my AVR device just hangs on a restart
- Will the heaters be left on if the Raspberry Pi crashes?
- How do I convert a Marlin pin number to a Klipper pin name?
- How do I cancel an M109/M190 "wait for temperature" request?
- How do I upgrade to the latest software?
How can I donate to the project?
Thanks. Kevin has a Patreon page at: https://www.patreon.com/koconnor
How do I calculate the step_distance parameter in the printer config file?
If you know the steps per millimeter for the axis then use a calculator to divide 1.0 by steps_per_mm. Then round this number to six decimal places and place it in the config (six decimal places is nano-meter precision).
The step_distance defines the distance that the axis will travel on each motor driver pulse. It can also be calculated from the axis pitch, motor step angle, and driver microstepping. If unsure, do a web search for "calculate steps per mm" to find an online calculator.
Where's my serial port?
The general way to find a USB serial port is to run ls -l /dev/serial/by-id/
from an ssh terminal on the host machine. It will
likely produce output similar to the following:
lrwxrwxrwx 1 root root 13 Jun 1 21:12 usb-1a86_USB2.0-Serial-if00-port0 -> ../../ttyUSB0
The name found in the above command is stable and it is possible to use it in the config file and while flashing the micro-controller code. For example, a flash command might look similar to:
sudo service klipper stop
make flash FLASH_DEVICE=/dev/serial/by-id/usb-1a86_USB2.0-Serial-if00-port0
sudo service klipper start
and the updated config might look like:
[mcu]
serial: /dev/serial/by-id/usb-1a86_USB2.0-Serial-if00-port0
Be sure to copy-and-paste the name from the "ls" command that you ran above as the name will be different for each printer.
If you are using multiple micro-controllers and they do not have
unique ids (common on boards with a CH340 USB chip) then follow the
directions above using the directory /dev/serial/by-path/
instead.
When the micro-controller restarts the device changes to /dev/ttyUSB1
Follow the directions in the "Where's my serial port?" section to prevent this from occurring.
The "make flash" command doesn't work
The code attempts to flash the device using the most common method for each platform. Unfortunately, there is a lot of variance in flashing methods, so the "make flash" command may not work on all boards.
If you're having an intermittent failure or you do have a standard setup, then double check that Klipper isn't running when flashing (sudo service klipper stop), make sure OctoPrint isn't trying to connect directly to the device (open the Connection tab in the web page and click Disconnect if the Serial Port is set to the device), and make sure FLASH_DEVICE is set correctly for your board (see the question above).
However, if "make flash" just doesn't work for your board, then you will need to manually flash. See if there is a config file in the config directory with specific instructions for flashing the device. Also, check the board manufacturer's documentation to see if it describes how to flash the device. Finally, on AVR devices, it may be possible to manually flash the device using avrdude with custom command-line parameters - see the avrdude documentation for further information.
How do I change the serial baud rate?
The recommended baud rate for Klipper is 250000. This baud rate works well on all micro-controller boards that Klipper supports. If you've found an online guide recommending a different baud rate, then ignore that part of the guide and continue with the default value of 250000.
If you want to change the baud rate anyway, then the new rate will need to be configured in the micro-controller (during make menuconfig) and that updated code will need to be compiled and flashed to the micro-controller. The Klipper printer.cfg file will also need to be updated to match that baud rate (see the example.cfg file for details). For example:
[mcu]
baud: 250000
The baud rate shown on the OctoPrint web page has no impact on the internal Klipper micro-controller baud rate. Always set the OctoPrint baud rate to 250000 when using Klipper.
The Klipper micro-controller baud rate is not related to the baud rate of the micro-controller's bootloader. See the bootloader document for additional information on bootloaders.
Can I run Klipper on something other than a Raspberry Pi 3?
The recommended hardware is a Raspberry Pi 2 or a Raspberry Pi 3.
Klipper will run on a Raspberry Pi 1 and on the Raspberry Pi Zero, but these boards don't have enough processing power to run OctoPrint well. It's not uncommon for print stalls to occur on these slower machines (the printer may move faster than OctoPrint can send movement commands) when printing directly from OctoPrint. If you wish to run on one one of these slower boards anyway, consider using the "virtual_sdcard" feature (see config/example-extras.cfg for details) when printing.
For running on the Beaglebone, see the Beaglebone specific installation instructions.
Klipper has been run on other machines. The Klipper host software only requires Python running on a Linux (or similar) computer. However, if you wish to run it on a different machine you will need Linux admin knowledge to install the system prerequisites for that particular machine. See the install-octopi.sh script for further information on the necessary Linux admin steps.
Why can't I move the stepper before homing the printer?
The code does this to reduce the chance of accidentally commanding the head into the bed or a wall. Once the printer is homed the software attempts to verify each move is within the position_min/max defined in the config file. If the motors are disabled (via an M84 or M18 command) then the motors will need to be homed again prior to movement.
If you want to move the head after canceling a print via OctoPrint, consider changing the OctoPrint cancel sequence to do that for you. It's configured in OctoPrint via a web browser under: Settings->GCODE Scripts
If you want to move the head after a print finishes, consider adding the desired movement to the "custom g-code" section of your slicer.
If the printer requires some additional movement as part of the homing process itself (or fundamentally does not have a homing process) then consider using a homing_override section in the config file. If you need to move a stepper for diagnostic or debugging purposes then consider adding a force_move section to the config file. See example-extras.cfg for further details on these options.
Why is the Z position_endstop set to 0.5 in the default configs?
For cartesian style printers the Z position_endstop specifies how far the nozzle is from the bed when the endstop triggers. If possible, it is recommended to use a Z-max endstop and home away from the bed (as this reduces the potential for bed collisions). However, if one must home towards the bed then it is recommended to position the endstop so it triggers when the nozzle is still a small distance away from the bed. This way, when homing the axis, it will stop before the nozzle touches the bed.
Almost all mechanical switches can still move a small distance (eg, 0.5mm) after they are triggered. So, for example, if the position_endstop is set to 0.5mm then one may still command the printer to move to Z0.2. The position_min config setting (which defaults to 0) is used to specify the minimum Z position one may command the printer to move to.
Note, the Z position_endstop specifies the distance from the nozzle to the bed when the nozzle and bed (if applicable) are hot. It is typical for thermal expansion to cause nozzle expansion of around .1mm, which is also the typical thickness of a sheet of printer paper. Thus, it is common to use the "paper test" to confirm calibration of the Z height - check that the bed and nozzle are at room temperature, check that there is no plastic on the head or bed, home the printer, place a piece of paper between the nozzle and bed, and repeatedly command the head to move closer to the bed checking each time if you feel a small amount of friction when sliding the paper between bed and nozzle - if all is calibrated well a small amount of friction would be felt when the height is at Z0.
I converted my config from Marlin and the X/Y axes work fine, but I just get a screeching noise when homing the Z axis
Short answer: Try reducing the max_z_velocity setting in the printer config. Also, if the Z stepper is moving in the wrong direction, try inverting the dir_pin setting in the config (eg, "dir_pin: !xyz" instead of "dir_pin: xyz").
Long answer: In practice Marlin can typically only step at a rate of around 10000 steps per second. If it is requested to move at a speed that would require a higher step rate then Marlin will generally just step as fast as it can. Klipper is able to achieve much higher step rates, but the stepper motor may not have sufficient torque to move at a higher speed. So, for a Z axis with a very precise step_distance the actual obtainable max_z_velocity may be smaller than what is configured in Marlin.
My TMC motor driver turns off in the middle of a print
There have been reports of some TMC drivers being disabled in the middle of a print. (In particular, with the TMC2208 driver.) When this issue occurs, the stepper associated with the driver moves freely, while the print continues.
It is believed this may be due to "over current" detection within the TMC driver. Trinamic has indicated that this could occur if the driver is in "stealthChop mode" and an abrupt velocity change occurs. If you experience this problem during homing, consider using a slower homing speed. If you experience this problem in the middle of a print, consider using a lower square_corner_velocity setting.
I keep getting random "Lost communication with MCU" errors
This is commonly caused by hardware errors on the USB connection between the host machine and the micro-controller. Things to look for:
- Use a good quality USB cable between the host machine and micro-controller. Make sure the plugs are secure.
- If using a Raspberry Pi, use a good quality power supply for the Raspberry Pi and use a good quality USB cable to connect that power supply to the Pi.
- Make sure the printer's power supply is not being overloaded. (Power fluctuations to the micro-controller's USB chip may result in resets of that chip.)
- There have been reports of high USB noise when both the printer's power supply and the host's 5V power supply are mixed. (If you find that the micro-controller powers on when either the printer's power supply is on or the USB cable is plugged in, then it indicates the 5V power supplies are being mixed.) It may help to configure the micro-controller to use power from only one source. (Alternatively, if the micro-controller board can not configure its power source, one may modify a USB cable so that it does not carry 5V power between the host and micro-controller.)
My Raspberry Pi keeps rebooting during prints
This is most likely do to voltage fluctuations. Follow the same troubleshooting steps for a "Lost communication with MCU" error.
When I set "restart_method=command" my AVR device just hangs on a restart
Some old versions of the AVR bootloader have a known bug in watchdog event handling. This typically manifests when the printer.cfg file has restart_method set to "command". When the bug occurs, the AVR device will be unresponsive until power is removed and reapplied to the device (the power or status LEDs may also blink repeatedly until the power is removed).
The workaround is to use a restart_method other than "command" or to flash an updated bootloader to the AVR device. Flashing a new bootloader is a one time step that typically requires an external programmer - search the web to find the instructions for your particular device.
Will the heaters be left on if the Raspberry Pi crashes?
The software has been designed to prevent that. Once the host enables a heater, the host software needs to confirm that enablement every 5 seconds. If the micro-controller does not receive a confirmation every 5 seconds it goes into a "shutdown" state which is designed to turn off all heaters and stepper motors.
See the "config_digital_out" command in the MCU commands document for further details.
In addition, the micro-controller software is configured with a minimum and maximum temperature range for each heater at startup (see the min_temp and max_temp parameters in the example.cfg file for details). If the micro-controller detects that the temperature is outside of that range then it will also enter a "shutdown" state.
Separately, the host software also implements code to check that heaters and temperature sensors are functioning correctly. See the "verify_heater" section of the example-extras.cfg for further details.
How do I convert a Marlin pin number to a Klipper pin name?
Short answer: In some cases one can use Klipper's pin_map: arduino
feature. Otherwise, for "digital" pins, one method is to search for
the requested pin in Marlin's fastio header files. The Atmega2560 and
Atmega1280 chips use
fastio_1280.h,
while the Atmega644p and Atmega1284p chips use
fastio_644.h.
For example, if you are looking to translate Marlin's digital pin
number 23 on an atmega2560 then one could find the following line in
Marlin's fastio_1280.h file:
#define DIO23_PIN PINA1
The DIO23
indicates the line is for Marlin's pin 23 and the PINA1
indicates the pin uses the hardware name of PA1
. Klipper uses the
hardware names (eg, PA1
).
Long answer: Klipper uses the standard pin names defined by the
micro-controller. On the Atmega chips these hardware pins have names
like PA4
, PC7
, or PD2
.
Long ago, the Arduino project decided to avoid using the standard
hardware names in favor of their own pin names based on incrementing
numbers - these Arduino names generally look like D23
or A14
. This
was an unfortunate choice that has lead to a great deal of confusion.
In particular the Arduino pin numbers frequently don't translate to
the same hardware names. For example, D21
is PD0
on one common
Arduino board, but is PC7
on another common Arduino board.
In order to support 3d printers based on real Arduino boards, Klipper
supports the Arduino pin aliases. This feature is enabled by adding
pin_map: arduino
to the [mcu] section of the config file. When these
aliases are enabled, Klipper understands pin names that start with the
prefix "ar" (eg, Arduino pin D23
is Klipper alias ar23
) and the
prefix "analog" (eg, Arduino pin A14
is Klipper alias analog14
).
Klipper does not use the Arduino names directly because we feel a name
like D7 is too easily confused with the hardware name PD7.
Marlin primarily follows the Arduino pin numbering scheme. However, Marlin supports a few chips that Arduino does not support and in some cases it supports pins that Arduino boards do not expose. In these cases, Marlin chose their own pin numbering scheme. Klipper does not support these custom pin numbers - check Marlin's fastio headers (see above) to translate these pin numbers to their standard hardware names.
How do I cancel an M109/M190 "wait for temperature" request?
Navigate to the OctoPrint terminal tab and issue an M112 command in the terminal box. The M112 command will cause Klipper to enter into a "shutdown" state, and it will cause OctoPrint to disconnect from Klipper. Navigate to the OctoPrint connection area and click on "Connect" to cause OctoPrint to reconnect. Navigate back to the terminal tab and issue a FIRMWARE_RESTART command to clear the Klipper error state. After completing this sequence, the previous heating request will be canceled and a new print may be started.
How do I upgrade to the latest software?
The general way to upgrade is to ssh into the Raspberry Pi and run:
cd ~/klipper
git pull
~/klipper/scripts/install-octopi.sh
Then one can recompile and flash the micro-controller code. For example:
make menuconfig
make clean
make
sudo service klipper stop
make flash FLASH_DEVICE=/dev/ttyACM0
sudo service klipper start
However, it's often the case that only the host software changes. In this case, one can update and restart just the host software with:
cd ~/klipper
git pull
sudo service klipper restart
If after using this shortcut the software warns about needing to reflash the micro-controller or some other unusual error occurs, then follow the full upgrade steps outlined above. Note that the RESTART and FIRMWARE_RESTART g-code commands do not load new software - the above "sudo service klipper restart" and "make flash" commands are needed for a software change to take effect.