klipper-dgus/klippy/extruder.py

146 lines
6.3 KiB
Python

# Code for handling printer nozzle extruders
#
# Copyright (C) 2016 Kevin O'Connor <kevin@koconnor.net>
#
# This file may be distributed under the terms of the GNU GPLv3 license.
import logging
import stepper, heater, homing
class PrinterExtruder:
def __init__(self, printer, config):
self.heater = heater.PrinterHeater(printer, config)
self.stepper = stepper.PrinterStepper(printer, config)
self.pressure_advance = config.getfloat('pressure_advance', 0.)
self.stepper_pos = 0
self.extrude_pos = 0.
def build_config(self):
self.heater.build_config()
self.stepper.set_max_jerk(9999999.9)
self.stepper.build_config()
def motor_off(self, move_time):
self.stepper.motor_enable(move_time, 0)
def check_move(self, move):
if not self.heater.can_extrude:
raise homing.EndstopError(move.end_pos, "Extrude below minimum temp")
if (not move.do_calc_junction
and not move.axes_d[0] and not move.axes_d[1]
and not move.axes_d[2]):
# Extrude only move - limit accel and velocity
move.limit_speed(self.stepper.max_velocity, self.stepper.max_accel)
def move(self, move_time, move):
axis_d = move.axes_d[3]
extrude_r = axis_d / move.move_d
inv_accel = 1. / (move.accel * extrude_r)
start_v = move.start_v * extrude_r
cruise_v = move.cruise_v * extrude_r
end_v = move.end_v * extrude_r
accel_t, cruise_t, decel_t = move.accel_t, move.cruise_t, move.decel_t
accel_d = move.accel_r * axis_d
cruise_d = move.cruise_r * axis_d
decel_d = move.decel_r * axis_d
retract_t = retract_d = retract_v = 0.
decel_v = cruise_v
# Update for pressure advance
start_pos = self.extrude_pos
if (axis_d >= 0. and (move.axes_d[0] or move.axes_d[1])
and self.pressure_advance):
# Increase accel_d and start_v when accelerating
move_extrude_r = move.extrude_r
prev_pressure_d = start_pos - move.start_pos[3]
if accel_t:
npd = move.cruise_v * move_extrude_r * self.pressure_advance
extra_accel_d = npd - prev_pressure_d
if extra_accel_d > 0.:
accel_d += extra_accel_d
start_v += extra_accel_d / accel_t
prev_pressure_d += extra_accel_d
# Update decel and retract parameters when decelerating
if decel_t:
if move.corner_min:
npd = move.corner_max*move_extrude_r * self.pressure_advance
extra_decel_d = prev_pressure_d - npd
if move.end_v > move.corner_min:
extra_decel_d *= ((move.cruise_v - move.end_v)
/ (move.cruise_v - move.corner_min))
else:
npd = move.end_v * move_extrude_r * self.pressure_advance
extra_decel_d = prev_pressure_d - npd
if extra_decel_d > 0.:
extra_decel_v = extra_decel_d / decel_t
decel_v -= extra_decel_v
end_v -= extra_decel_v
if decel_v <= 0.:
# The entire decel phase is replaced with retraction
retract_t = decel_t
retract_d = -(end_v + decel_v) * 0.5 * decel_t
retract_v = -decel_v
decel_t = decel_d = 0.
elif end_v < 0.:
# Split decel phase into decel and retraction
retract_t = -end_v * inv_accel
retract_d = -end_v * 0.5 * retract_t
decel_t -= retract_t
decel_d = decel_v * 0.5 * decel_t
else:
# There is still only a decel phase (no retraction)
decel_d -= extra_decel_d
# Prepare for steps
stepper_pos = self.stepper_pos
inv_step_dist = self.stepper.inv_step_dist
step_dist = self.stepper.step_dist
mcu_time, so = self.stepper.prep_move(move_time)
step_offset = stepper_pos - start_pos * inv_step_dist
# Acceleration steps
accel_multiplier = 2.0 * step_dist * inv_accel
if accel_d:
#t = sqrt(2*pos/accel + (start_v/accel)**2) - start_v/accel
accel_time_offset = start_v * inv_accel
accel_sqrt_offset = accel_time_offset**2
accel_steps = accel_d * inv_step_dist
count = so.step_sqrt(
mcu_time - accel_time_offset, accel_steps, step_offset
, accel_sqrt_offset, accel_multiplier)
stepper_pos += count
step_offset += count - accel_steps
mcu_time += accel_t
# Cruising steps
if cruise_d:
#t = pos/cruise_v
cruise_multiplier = step_dist / cruise_v
cruise_steps = cruise_d * inv_step_dist
count = so.step_factor(
mcu_time, cruise_steps, step_offset, cruise_multiplier)
stepper_pos += count
step_offset += count - cruise_steps
mcu_time += cruise_t
# Deceleration steps
if decel_d:
#t = cruise_v/accel - sqrt((cruise_v/accel)**2 - 2*pos/accel)
decel_time_offset = decel_v * inv_accel
decel_sqrt_offset = decel_time_offset**2
decel_steps = decel_d * inv_step_dist
count = so.step_sqrt(
mcu_time + decel_time_offset, decel_steps, step_offset
, decel_sqrt_offset, -accel_multiplier)
stepper_pos += count
step_offset += count - decel_steps
mcu_time += decel_t
# Retraction steps
if retract_d:
#t = sqrt(2*pos/accel + (start_v/accel)**2) - start_v/accel
accel_time_offset = retract_v * inv_accel
accel_sqrt_offset = accel_time_offset**2
accel_steps = -retract_d * inv_step_dist
count = so.step_sqrt(
mcu_time - accel_time_offset, accel_steps, step_offset
, accel_sqrt_offset, accel_multiplier)
stepper_pos += count
self.stepper_pos = stepper_pos
self.extrude_pos = start_pos + accel_d + cruise_d + decel_d - retract_d