nothinman 5a8b3a84ae Merge pull request #1155 from thinkyhead/lcd_wait_better | преди 10 години | |
---|---|---|
ArduinoAddons | преди 11 години | |
Marlin | преди 10 години | |
.gitignore | преди 11 години | |
.travis.yml | преди 10 години | |
README.md | преди 10 години |
==========================
Marlin has a GPL license because I believe in open development. Please do not use this code in products (3D printers, CNC etc) that are closed source or are crippled by a patent.
This RepRap firmware is a mashup between Sprinter, grbl and many original parts.
Derived from Sprinter and Grbl by Erik van der Zalm. Sprinters lead developers are Kliment and caru. Grbls lead developer is Simen Svale Skogsrud. Sonney Jeon (Chamnit) improved some parts of grbl A fork by bkubicek for the Ultimaker was merged, and further development was aided by him. Some features have been added by: Lampmaker, Bradley Feldman, and others…
The default baudrate is 250000. This baudrate has less jitter and hence errors than the usual 115200 baud, but is less supported by drivers and host-environments.
Marlin has look-ahead. While sprinter has to break and re-accelerate at each corner, lookahead will only decelerate and accelerate to a velocity, so that the change in vectorial velocity magnitude is less than the xy_jerk_velocity. This is only possible, if some future moves are already processed, hence the name. It leads to less over-deposition at corners, especially at flat angles.
Slic3r can find curves that, although broken into segments, were ment to describe an arc. Marlin is able to print those arcs. The advantage is the firmware can choose the resolution, and can perform the arc with nearly constant velocity, resulting in a nice finish. Also, less serial communication is needed.
To reduce noise and make the PID-differential term more useful, 16 ADC conversion results are averaged.
If your gcode contains a wide spread of extruder velocities, or you realtime change the building speed, the temperature should be changed accordingly. Usually, higher speed requires higher temperature. This can now be performed by the AutoTemp function By calling M109 S B F you enter the autotemp mode.
You can leave it by calling M109 without any F. If active, the maximal extruder stepper rate of all buffered moves will be calculated, and named “maxerate” [steps/sec]. The wanted temperature then will be set to t=tempmin+factor*maxerate, while being limited between tempmin and tempmax. If the target temperature is set manually or by gcode to a value less then tempmin, it will be kept without change. Ideally, your gcode can be completely free of temperature controls, apart from a M109 S T F in the start.gcode, and a M109 S0 in the end.gcode.
If you know your PID values, the acceleration and max-velocities of your unique machine, you can set them, and finally store them in the EEPROM. After each reboot, it will magically load them from EEPROM, independent what your Configuration.h says.
If your hardware supports it, you can build yourself a LCD-CardReader+Click+encoder combination. It will enable you to realtime tune temperatures, accelerations, velocities, flow rates, select and print files from the SD card, preheat, disable the steppers, and do other fancy stuff. One working hardware is documented here: http://www.thingiverse.com/thing:12663 Also, with just a 20x4 or 16x2 display, useful data is shown.
If you have an SD card reader attached to your controller, also folders work now. Listing the files in pronterface will show “/path/subpath/file.g”. You can write to file in a subfolder by specifying a similar text using small letters in the path. Also, backup copies of various operating systems are hidden, as well as files not ending with “.g”.
If you place a file auto[0-9].g into the root of the sd card, it will be automatically executed if you boot the printer. The same file will be executed by selecting “Autostart” from the menu. First *0 will be performed, than *1 and so on. That way, you can heat up or even print automatically without user interaction.
If an endstop is hit while moving towards the endstop, the location at which the firmware thinks that the endstop was triggered is outputed on the serial port. This is useful, because the user gets a warning message. However, also tools like QTMarlin can use this for finding acceptable combinations of velocity+acceleration.
Not relevant from a user side, but Marlin was split into thematic junks, and has tried to partially enforced private variables. This is intended to make it clearer, what interacts which what, and leads to a higher level of modularization. We think that this is a useful prestep for porting this firmware to e.g. an ARM platform in the future. A lot of RAM (with enabled LCD ~2200 bytes) was saved by storing char []=“some message” in Program memory. In the serial communication, a #define based level of abstraction was enforced, so that it is clear that some transfer is information (usually beginning with “echo:”), an error “error:”, or just normal protocol, necessary for backwards compatibility.
An interrupt is used to manage ADC conversions, and enforce checking for critical temperatures. This leads to less blocking in the heater management routine.
M Codes
Install the arduino software IDE/toolset v23 (Some configurations also work with 1.x.x) http://www.arduino.cc/en/Main/Software
Download the Marlin firmware https://github.com/ErikZalm/Marlin/tree/Marlin_v1 Use the “Download Zip” button on the right.
For gen6/gen7 and sanguinololu the Sanguino directory in the Marlin dir needs to be copied to the arduino environment. copy ArduinoAddons\Arduino_x.x.x\sanguino \hardware\Sanguino
Start the arduino IDE. Select Tools -> Board -> Arduino Mega 2560 or your microcontroller Select the correct serial port in Tools ->Serial Port Open Marlin.pde
Click the Verify/Compile button
Click the Upload button If all goes well the firmware is uploading
That’s ok. Enjoy Silky Smooth Printing.
===============================================
There are two options for this feature. You may choose to use a servo mounted on the X carriage or you may use a sled that mounts on the X axis and can be docked when not in use. See the section for each option below for specifics about installation and configuration. Also included are instructions that apply to both options.
By default, RAMPS have no power on servo bus (if you happen to have a multimeter, check the voltage on servo power pins). In order to get the servo working, you need to supply 5V to 5V pin.. You can do it using your power supply (if it has a 5V output) or jumping the “Vcc” from Arduino to the 5V RAMPS rail. These 2 pins are located just between the Reset Button and the yellow fuses… There are marks in the board showing 5V and VCC.. just connect them.. If jumping the arduino Vcc do RAMPS 5V rail, take care to not use a power hungry servo, otherwise you will cause a blackout in the arduino board ;-)
Uncomment the “ENABLE_AUTO_BED_LEVELING” define (commented by default)
The following options define the probing positions. These are good starting values. I recommend to keep a better clearance from borders in the first run and then make the probes as close as possible to borders:
A few more options:
X and Y axis travel speed between probes, in mm/min. Bear in mind that really fast moves may render step skipping. 6000 mm/min (100mm/s) is a good value.
The Z axis is lifted when traveling to the first probe point by Z_RAISE_BEFORE_PROBING value and then lifted when traveling from first to second and second to third point by Z_RAISE_BETWEEN_PROBINGS. All values are in mm as usual.
You will probably need a swivel Z-MIN endstop in the extruder. A rc servo do a great job. Check the system working here: http://www.youtube.com/watch?v=3IKMeOYz-1Q (Enable English subtitles) Teasing ;-) video: http://www.youtube.com/watch?v=x8eqSQNAyro
In order to get the servo working, you need to enable:
#define NUM_SERVOS 1 // Servo index starts with 0 for M280 command
#define SERVO_ENDSTOPS {-1, -1, 0} // Servo index for X, Y, Z. Disable with -1
#define SERVO_ENDSTOP_ANGLES {0,0, 0,0, 165,60} // X,Y,Z Axis Extend and Retract angles
The first define tells firmware how many servos you have. The second tells what axis this servo will be attached to. In the example above, we have a servo in Z axis. The third one tells the angle in 2 situations: Probing (165º) and resting (60º). Check this with command M280 P0 S{angle} (example: M280 P0 S60 moves the servo to 60º)
Next you need to define the Z endstop (probe) offset from hotend. My preferred method:
h) Fill the defines bellow multiplying the values by “-1” (just change the signal)
#define X_PROBE_OFFSET_FROM_EXTRUDER -24.3
#define Y_PROBE_OFFSET_FROM_EXTRUDER 31.4
#define Z_PROBE_OFFSET_FROM_EXTRUDER -5.1
The sled option uses an electromagnet to attach and detach to/from the X carriage. See http://www.thingiverse.com/thing:396692 for more details on how to print and install this feature. It uses the same connections as the servo option.
To use the sled option, you must define two additional things in Configuration.h:
Uncomment the Z_PROBE_SLED to define to enable the sled (commented out by default).
Uncomment the SLED_DOCKING_OFFSET to set the extra distance the X axis must travel to dock the sled. This value can be found by moving the X axis to its maximum position then measure the distance to the right X end and subtract the width of the sled (23mm if you printed the sled from Thingiverse).
Next you need to define the Z endstop (probe) offset from hotend. My preferred method:
For example, suppose you measured the endstop position and it was 20mm to the right of the line running front-to-back, 10mm toward the front of the line running left-to-right, and the value from (k) was 2.85. The values for the defines would be:
That’s it.. enjoy never having to calibrate your Z endstop neither leveling your bed by hand anymore ;-)