albemasci Inviato 4 Ottobre 2017 Condividi Inviato 4 Ottobre 2017 Ciao a tutti! Ho voluto avventurarmi nel cambio della scheda madre della mia stampante (una anet A8 a cui di originale resta ben poco) per passare a smoothieware e stepsticks 8825 (e in un secondo momento vorrei passare a TMC2100). Sono ancora nelle fasi iniziali, ho aggiornato il firmware del monitor (TFT32) e della scheda madre; tuttavia non riesco a far funzionare i motori! Quando mi collego dal PC via USB, i motori eseguono l'ordine di muoversi di 1mm come richiesto, ma emettono un forte fischio. Chiedendo più volte di muoversi, dopo 3/4 tentativi smettono di rispondere e il fischio permane. Disconnettere la stampante dal PC (anche solo via software) fa cessare il fischio. I motori non rispondono affatto ai comandi imposti dallo schermo della stampante. Cosa potrei aver sbagliato? Cosa può indicare il fischio? Grazie in anticipo =) Albe. Cita Link al commento Condividi su altri siti Altre opzioni di condivisione...
Alep Inviato 4 Ottobre 2017 Condividi Inviato 4 Ottobre 2017 Le istruzioni della Smoothieware per questo difetto danno questa spiegazione a questo link http://smoothieware.org/troubleshooting#my-stepper-motor-does-not-turn-at-all-and-makes-a-very-high-pitched-sound " My stepper motor does not turn at all and makes a very high-pitched sound This can happen with Z axis (or any leadscrew driven stepper motor) due to the high steps per millimeter number. You are probably trying to move it too fast. Try asking it to move at a much lower speed ( for example G1 Z100 F100 ). It's also possible you are trying to home, or to probe too fast. See the corresponding modules for how to modify the default speeds. If you are using external stepper motor drivers (driven by ENn, Stn and DIRn pins) check polarity, voltage and timings of signals to your driver. Also consider increasing microseconds_per_step_pulse slightly if the default 1us pulse width is too narrow for your driver or cable lengths. " Sembra che le regolazioni che sono predisposte nel firmware non vadano bene per i motori che utilizzi e che il firmware è regolato con un numero troppo alto di passi per mm, o che hai i cavi di collegamento troppo lunghi per la frequenza di controllo dei motori che utilizzi che sarebbe molto elevata. Non è molto ma ti può indicare in che direzione lavorare- Cita Link al commento Condividi su altri siti Altre opzioni di condivisione...
albemasci Inviato 4 Ottobre 2017 Autore Condividi Inviato 4 Ottobre 2017 Grazie mille Alep! =) Mi spiace, non avevo trovato quella pagina altrimenti non avrei disturbato! Vi aggiorno se riesco a risolvere! Albe. Cita Link al commento Condividi su altri siti Altre opzioni di condivisione...
Alep Inviato 4 Ottobre 2017 Condividi Inviato 4 Ottobre 2017 Cento occhi vedono più di due 1 Cita Link al commento Condividi su altri siti Altre opzioni di condivisione...
albemasci Inviato 5 Ottobre 2017 Autore Condividi Inviato 5 Ottobre 2017 Ciao Alep, Non riesco proprio a far smettere il fischio.. Puoi aiutarmi? Mi sono basato su un file da un progetto che usava la mia scheda e il mio monitor, e ho modificato i parametri di altre cose per adeguarli alla mia stampante, o quantomeno è quello che ho provato a fare! Eppure il fischio continua, e inoltre il motore z si muove decisamente più di quanto indicato (ma quello penso dipenda dagli step/mm). Questo è il mio file config: # Smoothieboard configuration file, see http://smoothieware.org/configuring-smoothie # NOTE Lines must not exceed 132 characters, and '#' characters mean what follows is ignored ## Robot module configurations : general handling of movement G-codes and slicing into moves # Basic motion configuration arm_solution corexy # for corexy kinetics default_feed_rate 10000 # Default speed (mm/minute) for G1/G2/G3 moves default_seek_rate 10000 # Default speed (mm/minute) for G0 moves mm_per_arc_segment 0.5 # Fixed length for line segments that divide arcs, 0 to disable mm_per_line_segment 5 # Cut lines into segments this size #mm_max_arc_error 0.01 # The maximum error for line segments that divide arcs 0 to disable # note it is invalid for both the above be 0 # if both are used, will use largest segment length based on radius # Arm solution configuration : Cartesian robot. Translates mm positions into stepper positions # See http://smoothieware.org/stepper-motors alpha_steps_per_mm 200 # Steps per mm for alpha ( X ) stepper beta_steps_per_mm 200 # Steps per mm for beta ( Y ) stepper gamma_steps_per_mm 200 # Steps per mm for gamma ( Z ) stepper # Planner module configuration : Look-ahead and acceleration configuration # See http://smoothieware.org/motion-control planner_queue_size 32 # Don't change this value unless You know what You are doing acceleration 100 # Acceleration in mm/second/second. z_acceleration 50 # Acceleration for Z only moves in mm/s^2, 0 uses acceleration which is the default. DO NOT SET ON A DELTA acceleration_ticks_per_second 1200 # Number of times per second at which speed is updated junction_deviation 0.02 # See http://smoothieware.org/motion-control#junction-deviation #z_junction_deviation 0.0 # For Z only moves, -1 uses junction_deviation, zero disables junction_deviation on z moves DO NOT SET ON A DELTA # Cartesian axis speed limits x_axis_max_speed 1000 # Maximum speed in mm/min y_axis_max_speed 1000 # Maximum speed in mm/min z_axis_max_speed 200 # Maximum speed in mm/min # Stepper module configuration # Pins are defined as ports, and pin numbers, appending "!" to the number will invert a pin # See http://smoothieware.org/pin-configuration and http://smoothieware.org/pinout microseconds_per_step_pulse 1 # Duration of the stepped pulses to the stepwise controllers, in microseconds base_stepping_frequency 100000 # Base frequency for stepping, higher provides smoother movement alpha_step_pin 2.0 # Pin for alpha stepper step signal alpha_dir_pin 0.5 # Pin for alpha stepper direction, add '!' to reverse direction alpha_en_pin 0.4 # Pin for alpha enable pin alpha_current 0.8 # X stepper motor current alpha_max_rate 10000.0 # Maximum rate in mm/min beta_step_pin 2.1 # Pin for beta stepper step signal beta_dir_pin 0.11 # Pin for beta stepper direction, add '!' to reverse direction beta_en_pin 0.10 # Pin for beta enable beta_current 0.8 # Y stepper motor current beta_max_rate 10000.0 # Maxmimum rate in mm/min gamma_step_pin 2.2 # Pin for gamma stepper step signal gamma_dir_pin 0.20! # Pin for gamma stepper direction, add '!' to reverse direction gamma_en_pin 0.19 # Pin for gamma enable gamma_current 0.8 # Z stepper motor current gamma_max_rate 200.0 # Maximum rate in mm/min ## Extruder module configuration # See http://smoothieware.org/extruder extruder.hotend.enable true # Whether to activate the extruder module at all. All configuration is ignored if false extruder.hotend.steps_per_mm 418 # Steps per mm for extruder stepper extruder.hotend.default_feed_rate 600 # Default rate ( mm/minute ) for moves where only the extruder moves extruder.hotend.acceleration 500 # Acceleration for the stepper motor mm/sec² extruder.hotend.max_speed 50 # Maximum speed in mm/s extruder.hotend.step_pin 2.3 # Pin for extruder step signal extruder.hotend.dir_pin 0.22 # Pin for extruder dir signal ( add '!' to reverse direction ) extruder.hotend.en_pin 0.21 # Pin for extruder enable signal # Extruder offset #extruder.hotend.x_offset 0 # X offset from origin in mm #extruder.hotend.y_offset 0 # Y offset from origin in mm #extruder.hotend.z_offset 0 # Z offset from origin in mm # Firmware retract settings when using G10/G11, these are the defaults if not defined, must be defined for each extruder if not using the defaults #extruder.hotend.retract_length 4 # Retract length in mm #extruder.hotend.retract_feedrate 45 # Retract feedrate in mm/sec #extruder.hotend.retract_recover_length 0 # Additional length for recover #extruder.hotend.retract_recover_feedrate 8 # Recover feedrate in mm/sec (should be less than retract feedrate) #extruder.hotend.retract_zlift_length 0 # Z-lift on retract in mm, 0 disables #extruder.hotend.retract_zlift_feedrate 6000 # Z-lift feedrate in mm/min (Note mm/min NOT mm/sec) delta_current 1.5 # First extruder stepper motor current # Second extruder module configuration #extruder.hotend2.enable false # Whether to activate the extruder module at all. All configuration is ignored if false #extruder.hotend2.steps_per_mm 140 # Steps per mm for extruder stepper #extruder.hotend2.default_feed_rate 600 # Default rate ( mm/minute ) for moves where only the extruder moves #extruder.hotend2.acceleration 500 # Acceleration for the stepper motor, as of 0.6, arbitrary ratio #extruder.hotend2.max_speed 50 # mm/s #extruder.hotend2.step_pin 2.8 # Pin for extruder step signal #extruder.hotend2.dir_pin 2.13 # Pin for extruder dir signal ( add '!' to reverse direction ) #extruder.hotend2.en_pin 4.29 # Pin for extruder enable signal #extruder.hotend2.x_offset 0 # x offset from origin in mm #extruder.hotend2.y_offset 25.0 # y offset from origin in mm #extruder.hotend2.z_offset 0 # z offset from origin in mm #epsilon_current 1.5 # Second extruder stepper motor current ## Laser module configuration # See http://smoothieware.org/laser laser_module_enable false # Whether to activate the laser module at all laser_module_pwm_pin 2.5 # This pin will be PWMed to control the laser. # Only pins 2.0, 2.1, 2.2, 2.3, 2.4, 2.5, 1.18, 1.20, 1.21, 1.23, 1.24, 1.26, 3.25 and 3.26 # can be used since laser requires hardware PWM, see http://smoothieware.org/pinout #laser_module_ttl_pin 1.30 # This pin turns on when the laser turns on, and off when the laser turns off. #laser_module_maximum_power 1.0 # This is the maximum duty cycle that will be applied to the laser #laser_module_minimum_power 0.0 # This is a value just below the minimum duty cycle that keeps the laser # active without actually burning. #laser_module_default_power 0.8 # This is the default laser power that will be used for cuts if a power has not been specified. The value is a scale between # the maximum and minimum power levels specified above #laser_module_pwm_period 20 # This sets the pwm frequency as the period in microseconds ## Temperature control configuration # See http://smoothieware.org/temperaturecontrol # First hotend configuration temperature_control.hotend.enable true # Whether to activate this ( "hotend" ) module at all. temperature_control.hotend.thermistor_pin 0.23 # Pin for the thermistor to read temperature_control.hotend.heater_pin 2.7 # Pin that controls the heater, set to nc if a readonly thermistor is being defined temperature_control.hotend.thermistor EPCOS100K # See http://smoothieware.org/temperaturecontrol#toc5 #temperature_control.hotend.beta 4066 # Or set the beta value temperature_control.hotend.set_m_code 104 # M-code to set the temperature for this module temperature_control.hotend.set_and_wait_m_code 109 # M-code to set-and-wait for this module temperature_control.hotend.designator T # Designator letter for this module #temperature_control.hotend.max_temp 300 # Set maximum temperature - Will prevent heating above 300 by default #temperature_control.hotend.min_temp 0 # Set minimum temperature - Will prevent heating below if set # Safety control is enabled by default and can be overidden here, the values show the defaults # See http://smoothieware.org/temperaturecontrol#runaway #temperature_control.hotend.runaway_heating_timeout 900 # How long it can take to heat up, max is 2040 seconds. #temperature_control.hotend.runaway_cooling_timeout 0 # How long it can take to cool down if temp is set lower, max is 2040 seconds #temperature_control.hotend.runaway_range 10 # How far from the set temperature it can wander, max setting is 63°C # PID configuration # See http://smoothieware.org/temperaturecontrol#pid #temperature_control.hotend.p_factor 13.7 # P ( proportional ) factor #temperature_control.hotend.i_factor 0.097 # I ( integral ) factor #temperature_control.hotend.d_factor 24 # D ( derivative ) factor #temperature_control.hotend.max_pwm 64 # Max pwm, 64 is a good value if driving a 12v resistor with 24v. # Second hotend configuration #temperature_control.hotend2.enable false # Whether to activate this ( "hotend" ) module at all. #temperature_control.hotend2.thermistor_pin 0.25 # Pin for the thermistor to read #temperature_control.hotend2.heater_pin 1.23 # Pin that controls the heater #temperature_control.hotend2.thermistor EPCOS100K # See http://smoothieware.org/temperaturecontrol#thermistor ##temperature_control.hotend2.beta 4066 # or set the beta value #temperature_control.hotend2.set_m_code 104 # M-code to set the temperature for this module #temperature_control.hotend2.set_and_wait_m_code 109 # M-code to set-and-wait for this module #temperature_control.hotend2.designator T1 # Designator letter for this module #temperature_control.hotend2.p_factor 13.7 # P ( proportional ) factor #temperature_control.hotend2.i_factor 0.097 # I ( integral ) factor #temperature_control.hotend2.d_factor 24 # D ( derivative ) factor #temperature_control.hotend2.max_pwm 64 # Max pwm, 64 is a good value if driving a 12v resistor with 24v. temperature_control.bed.enable true # Whether to activate this ( "hotend" ) module at all. temperature_control.bed.thermistor_pin 0.24 # Pin for the thermistor to read temperature_control.bed.heater_pin 2.5 # Pin that controls the heater temperature_control.bed.thermistor Honeywell100K # See http://smoothieware.org/temperaturecontrol#thermistor #temperature_control.bed.beta 3974 # Or set the beta value temperature_control.bed.set_m_code 140 # M-code to set the temperature for this module temperature_control.bed.set_and_wait_m_code 190 # M-code to set-and-wait for this module temperature_control.bed.designator B # Designator letter for this module # Bang-bang ( simplified ) control # See http://smoothieware.org/temperaturecontrol#bang-bang #temperature_control.bed.bang_bang false # Set to true to use bang bang control rather than PID #temperature_control.bed.hysteresis 2.0 # Set to the temperature in degrees C to use as hysteresis ## Switch modules # See http://smoothieware.org/switch # Switch module for fan control switch.fan.enable true # Enable this module switch.fan.input_on_command M106 # Command that will turn this switch on switch.fan.input_off_command M107 # Command that will turn this switch off switch.fan.output_pin 2.6 # Pin this module controls switch.fan.output_type pwm # PWM output settable with S parameter in the input_on_comand #switch.fan.max_pwm 255 # Set max pwm for the pin default is 255 #switch.misc.enable true # Enable this module #switch.misc.input_on_command M42 # Command that will turn this switch on #switch.misc.input_off_command M43 # Command that will turn this switch off #switch.misc.output_pin 2.4 # Pin this module controls #switch.misc.output_type digital # Digital means this is just an on or off pin ## Temperatureswitch # See http://smoothieware.org/temperatureswitch # Automatically toggle a switch at a specified temperature. Different ones of these may be defined to monitor different temperatures and switch different swithxes # Useful to turn on a fan or water pump to cool the hotend #temperatureswitch.hotend.enable true # #temperatureswitch.hotend.designator T # first character of the temperature control designator to use as the temperature sensor to monitor #temperatureswitch.hotend.switch misc # select which switch to use, matches the name of the defined switch #temperatureswitch.hotend.threshold_temp 60.0 # temperature to turn on (if rising) or off the switch #temperatureswitch.hotend.heatup_poll 15 # poll heatup at 15 sec intervals #temperatureswitch.hotend.cooldown_poll 60 # poll cooldown at 60 sec intervals ## Endstops # See http://smoothieware.org/endstops endstops_enable true # The endstop module is enabled by default and can be disabled here #corexy_homing false # Set to true if homing on a hbot or corexy alpha_min_endstop 1.24^ # Pin to read min endstop, add a ! to invert if endstop is NO connected to ground #alpha_max_endstop 1.25^ # Pin to read max endstop, uncomment this and comment the above if using max endstops alpha_homing_direction home_to_min # Or set to home_to_max and set alpha_max and uncomment the alpha_max_endstop alpha_min 0 # This gets loaded as the current position after homing when home_to_min is set alpha_max 200 # This gets loaded as the current position after homing when home_to_max is set beta_min_endstop 1.26^ # Pin to read min endstop, add a ! to invert if endstop is NO connected to ground #beta_max_endstop 1.27^ # Pin to read max endstop, uncomment this and comment the above if using max endstops beta_homing_direction home_to_min # Or set to home_to_max and set alpha_max and uncomment the alpha_max_endstop beta_min 0 # This gets loaded as the current position after homing when home_to_min is set beta_max 200 # This gets loaded as the current position after homing when home_to_max is set gamma_min_endstop 1.28^ # Pin to read min endstop, add a ! to invert if endstop is NO connected to ground #gamma_max_endstop 1.29^ # Pin to read max endstop, uncomment this and comment the above if using max endstops gamma_homing_direction home_to_min # Or set to home_to_max and set alpha_max and uncomment the alpha_max_endstop gamma_min 0 # This gets loaded as the current position after homing when home_to_min is set gamma_max 200 # This gets loaded as the current position after homing when home_to_max is set alpha_max_travel 500 # Max travel in mm for alpha/X axis when homing beta_max_travel 500 # Max travel in mm for beta/Y axis when homing gamma_max_travel 500 # Max travel in mm for gamma/Z axis when homing # Optional enable limit switches, actions will stop if any enabled limit switch is triggered #alpha_limit_enable false # Set to true to enable X min and max limit switches #beta_limit_enable false # Set to true to enable Y min and max limit switches #gamma_limit_enable false # Set to true to enable Z min and max limit switches # Endstops home at their fast feedrate first, then once the endstop is found they home again at their slow feedrate for accuracy alpha_fast_homing_rate_mm_s 50 # Alpha/X fast homing feedrate in mm/second alpha_slow_homing_rate_mm_s 25 # Alpha/X slow homing feedrate in mm/second beta_fast_homing_rate_mm_s 50 # Beta/Y fast homing feedrate in mm/second beta_slow_homing_rate_mm_s 25 # Beta/Y slow homing feedrate in mm/second gamma_fast_homing_rate_mm_s 4 # Gamma/Z fast homing feedrate in mm/second gamma_slow_homing_rate_mm_s 2 # Gamma/Z slow homing feedrate in mm/second alpha_homing_retract_mm 5 # Distance to retract from the endstop after it is hit for alpha/X beta_homing_retract_mm 5 # Distance to retract from the endstop after it is hit for beta/Y gamma_homing_retract_mm 1 # Distance to retract from the endstop after it is hit for gamma/Z # Optional enable limit switches, actions will stop if any enabled limit switch is triggered (all are set for delta) #alpha_limit_enable false # Set to true to enable X min and max limit switches #beta_limit_enable false # Set to true to enable Y min and max limit switches #gamma_limit_enable false # Set to true to enable Z min and max limit switches # Optional order in which axis will home, default is they all home at the same time, # If this is set it will force each axis to home one at a time in the specified order #homing_order XYZ # X axis followed by Y then Z last #move_to_origin_after_home false # Move XY to 0,0 after homing #endstop_debounce_count 100 # Uncomment if you get noise on your endstops, default is 100 #endstop_debounce_ms 1 # Uncomment if you get noise on your endstops, default is 1 millisecond debounce #home_z_first true # Uncomment and set to true to home the Z first, otherwise Z homes after XY # End of endstop config # Delete the above endstop section and uncomment next line and copy and edit Snippets/abc-endstop.config file to enable endstops for ABC axis #include abc-endstop.config ## Z-probe # See http://smoothieware.org/zprobe zprobe.enable true # Set to true to enable a zprobe zprobe.probe_pin 1.28!^ # Pin probe is attached to, if NC remove the ! zprobe.slow_feedrate 5 # Mm/sec probe feed rate #zprobe.debounce_count 100 # Set if noisy zprobe.fast_feedrate 100 # Move feedrate mm/sec zprobe.probe_height 5 # How much above bed to start probe #gamma_min_endstop nc # Normally 1.28. Change to nc to prevent conflict, # Levelling strategy # Example for 3-point levelling strategy, see wiki documentation for other strategies leveling-strategy.three-point-leveling.enable true # a leveling strategy that probes three points to define a plane and keeps the Z parallel to that plane leveling-strategy.three-point-leveling.point1 100.0,0.0 # the first probe point (x,y) optional may be defined with M557 leveling-strategy.three-point-leveling.point2 200.0,200.0 # the second probe point (x,y) leveling-strategy.three-point-leveling.point3 0.0,200.0 # the third probe point (x,y) leveling-strategy.three-point-leveling.home_first true # home the XY axis before probing leveling-strategy.three-point-leveling.tolerance 0.03 # the probe tolerance in mm, anything less that this will be ignored, default is 0.03mm leveling-strategy.three-point-leveling.probe_offsets 0,0,0 # the probe offsets from nozzle, must be x,y,z, default is no offset leveling-strategy.three-point-leveling.save_plane false # set to true to allow the bed plane to be saved with M500 default is false ## Panel # See http://smoothieware.org/panel # Please find your panel on the wiki and copy/paste the right configuration here panel.enable false # Set to true to enable the panel code # Example for reprap discount GLCD # on glcd EXP1 is to left and EXP2 is to right, pin 1 is bottom left, pin 2 is top left etc. # +5v is EXP1 pin 10, Gnd is EXP1 pin 9 #panel.lcd reprap_discount_glcd # #panel.spi_channel 0 # SPI channel to use ; GLCD EXP1 Pins 3,5 (MOSI, SCLK) #panel.spi_cs_pin 0.16 # SPI chip select ; GLCD EXP1 Pin 4 #panel.encoder_a_pin 3.25!^ # Encoder pin ; GLCD EXP2 Pin 3 #panel.encoder_b_pin 3.26!^ # Encoder pin ; GLCD EXP2 Pin 5 #panel.click_button_pin 1.30!^ # Click button ; GLCD EXP1 Pin 2 #panel.buzz_pin 1.31 # Pin for buzzer ; GLCD EXP1 Pin 1 #panel.back_button_pin 2.11!^ # Back button ; GLCD EXP2 Pin 8 panel.menu_offset 0 # Some panels will need 1 here panel.alpha_jog_feedrate 6000 # X jogging feedrate in mm/min panel.beta_jog_feedrate 6000 # Y jogging feedrate in mm/min panel.gamma_jog_feedrate 200 # Z jogging feedrate in mm/min panel.hotend_temperature 185 # Temp to set hotend when preheat is selected panel.bed_temperature 60 # Temp to set bed when preheat is selected ## Custom menus : Example of a custom menu entry, which will show up in the Custom entry. # NOTE _ gets converted to space in the menu and commands, | is used to separate multiple commands custom_menu.power_on.enable true # custom_menu.power_on.name Power_on # custom_menu.power_on.command M80 # custom_menu.power_off.enable true # custom_menu.power_off.name Power_off # custom_menu.power_off.command M81 # ## Network settings # See http://smoothieware.org/network network.enable false # Enable the ethernet network services network.webserver.enable true # Enable the webserver network.telnet.enable true # Enable the telnet server network.ip_address auto # Use dhcp to get ip address # Uncomment the 3 below to manually setup ip address #network.ip_address 192.168.3.222 # The IP address #network.ip_mask 255.255.255.0 # The ip mask #network.ip_gateway 192.168.3.1 # The gateway address #network.mac_override xx.xx.xx.xx.xx.xx # Override the mac address, only do this if you have a conflict ## System configuration # Serial communications configuration ( baud rate defaults to 9600 if undefined ) # For communication over the UART port, *not* the USB/Serial port uart0.baud_rate 115200 # Baud rate for the default hardware ( UART ) serial port second_usb_serial_enable false # This enables a second USB serial port #leds_disable true # Disable using leds after config loaded #play_led_disable true # Disable the play led # Kill button maybe assigned to a different pin, set to the onboard pin by default # See http://smoothieware.org/killbutton kill_button_enable true # Set to true to enable a kill button kill_button_pin 2.12 # Kill button pin. default is same as pause button 2.12 (2.11 is another good choice) #msd_disable false # Disable the MSD (USB SDCARD), see http://smoothieware.org/troubleshooting#disable-msd #dfu_enable false # For linux developers, set to true to enable DFU # Only needed on a smoothieboard # See http://smoothieware.org/currentcontrol currentcontrol_module_enable true # Control stepper motor current via the configuration file Stavo testando le cose una per volta, quindi magari devo fare delle modifiche a cosa che non ho ancora controllato, iniziavo appunto dal movimento dei motori. Vedi qualche possibile errore? Cita Link al commento Condividi su altri siti Altre opzioni di condivisione...
Alep Inviato 5 Ottobre 2017 Condividi Inviato 5 Ottobre 2017 Non essendo pratico di questa elettronica mi è difficile 'vedere errori' oltre che mi sembra strano che si preoccupino di segnalare una condizione di errore con un fischio senza dare un minimo di informazione a display del motivo del fischio, se non ho capito male il fischio inizia quando muovi i motori, fanno un passetto e subito inizia il fischio che non smette più e i motori si fermano. Hai possibilità col soft che usi a provare i motori uno alla volta? Sulle regolazioni io proverei a diminuire questo valore base_stepping_frequency 100000 ti dico subito che non sto seguendo qualche post di qualche forum o una intuizione geniale, sto solo cercando di interpretare il testo che ti ho postato prima, che sinceramente non è molto chiaro, diciamo che sto andando ad intuito, ma una prova costa poco, io arriverai anche a dimezzarlo. Cita Link al commento Condividi su altri siti Altre opzioni di condivisione...
albemasci Inviato 23 Novembre 2017 Autore Condividi Inviato 23 Novembre 2017 Ciao a tutti, vado a riesumare questo post perché avevo temporaneamente abbandonato questo progetto per riprenderlo solo ora. Ho provato a modificare quel parametro diminuendolo ed aumentandolo, e nel primo caso i motori non si muovevano, nel secondo non ho notato differenze (il solito fischio). Ho pensato dunque di ricominciare da capo creando un nuovo file da zero, sperando in un vostro aiuto! Vorrei sottoporvi il mio primo dubbio, forse banale: Smoothieware ha diverse configurazioni per selezionare la struttura della stampante: Corexy, Cartesian, Delta, Morgan. La mia stampante è però una reprap con il piano di stampa mobile. Che configurazione dovrei utilizzare fra cartesian e corexy? Cita Link al commento Condividi su altri siti Altre opzioni di condivisione...
Alep Inviato 23 Novembre 2017 Condividi Inviato 23 Novembre 2017 Nella Cartesiana il piatto si nuove lungo un asse in genere l'x e l'estrusore su un altro asse in genere y. Nella corexy il piatto sta fermo e l'estrusore si muove nei due assi. Sicuramente la tua è cartesiana. Cita Link al commento Condividi su altri siti Altre opzioni di condivisione...
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