klipper/klippy/extras/temperature_fan.py

158 lines
6.9 KiB
Python

# Support fans that are enabled when temperature exceeds a set threshold
#
# Copyright (C) 2016-2018 Kevin O'Connor <kevin@koconnor.net>
#
# This file may be distributed under the terms of the GNU GPLv3 license.
import fan
KELVIN_TO_CELSIUS = -273.15
MAX_FAN_TIME = 5.0
AMBIENT_TEMP = 25.
PID_PARAM_BASE = 255.
class TemperatureFan:
def __init__(self, config):
self.name = config.get_name().split()[1]
self.printer = config.get_printer()
self.fan = fan.PrinterFan(config, default_shutdown_speed=1.)
self.min_temp = config.getfloat('min_temp', minval=KELVIN_TO_CELSIUS)
self.max_temp = config.getfloat('max_temp', above=self.min_temp)
pheaters = self.printer.load_object(config, 'heaters')
self.sensor = pheaters.setup_sensor(config)
self.sensor.setup_minmax(self.min_temp, self.max_temp)
self.sensor.setup_callback(self.temperature_callback)
pheaters.register_sensor(config, self)
self.speed_delay = self.sensor.get_report_time_delta()
self.max_speed = config.getfloat('max_speed', 1., above=0., maxval=1.)
self.min_speed = config.getfloat('min_speed', 0.3, minval=0., maxval=1.)
self.last_temp = 0.
self.last_temp_time = 0.
self.target_temp_conf = config.getfloat(
'target_temp', 40. if self.max_temp > 40. else self.max_temp,
minval=self.min_temp, maxval=self.max_temp)
self.target_temp = self.target_temp_conf
algos = {'watermark': ControlBangBang, 'pid': ControlPID}
algo = config.getchoice('control', algos)
self.control = algo(self, config)
self.next_speed_time = 0.
self.last_speed_value = 0.
gcode = self.printer.lookup_object('gcode')
gcode.register_mux_command(
"SET_TEMPERATURE_FAN_TARGET", "TEMPERATURE_FAN", self.name,
self.cmd_SET_TEMPERATURE_FAN_TARGET_TEMP,
desc=self.cmd_SET_TEMPERATURE_FAN_TARGET_TEMP_help)
def set_speed(self, read_time, value):
if value <= 0.:
value = 0.
elif value < self.min_speed:
value = self.min_speed
if self.target_temp <= 0.:
value = 0.
if ((read_time < self.next_speed_time or not self.last_speed_value)
and abs(value - self.last_speed_value) < 0.05):
# No significant change in value - can suppress update
return
speed_time = read_time + self.speed_delay
self.next_speed_time = speed_time + 0.75 * MAX_FAN_TIME
self.last_speed_value = value
self.fan.set_speed(speed_time, value)
def temperature_callback(self, read_time, temp):
self.last_temp = temp
self.control.temperature_callback(read_time, temp)
def get_temp(self, eventtime):
return self.last_temp, self.target_temp
def get_min_speed(self):
return self.min_speed
def get_max_speed(self):
return self.max_speed
def get_status(self, eventtime):
status = self.fan.get_status(eventtime)
status["temperature"] = self.last_temp
status["target"] = self.target_temp
return status
cmd_SET_TEMPERATURE_FAN_TARGET_TEMP_help = "Sets a temperature fan target"
def cmd_SET_TEMPERATURE_FAN_TARGET_TEMP(self, gcmd):
temp = gcmd.get_float('TARGET', self.target_temp_conf)
self.set_temp(temp)
def set_temp(self, degrees):
if degrees and (degrees < self.min_temp or degrees > self.max_temp):
raise self.printer.command_error(
"Requested temperature (%.1f) out of range (%.1f:%.1f)"
% (degrees, self.min_temp, self.max_temp))
self.target_temp = degrees
######################################################################
# Bang-bang control algo
######################################################################
class ControlBangBang:
def __init__(self, temperature_fan, config):
self.temperature_fan = temperature_fan
self.max_delta = config.getfloat('max_delta', 2.0, above=0.)
self.heating = False
def temperature_callback(self, read_time, temp):
current_temp, target_temp = self.temperature_fan.get_temp(read_time)
if (self.heating
and temp >= target_temp+self.max_delta):
self.heating = False
elif (not self.heating
and temp <= target_temp-self.max_delta):
self.heating = True
if self.heating:
self.temperature_fan.set_speed(read_time, 0.)
else:
self.temperature_fan.set_speed(read_time,
self.temperature_fan.get_max_speed())
######################################################################
# Proportional Integral Derivative (PID) control algo
######################################################################
PID_SETTLE_DELTA = 1.
PID_SETTLE_SLOPE = .1
class ControlPID:
def __init__(self, temperature_fan, config):
self.temperature_fan = temperature_fan
self.Kp = config.getfloat('pid_Kp') / PID_PARAM_BASE
self.Ki = config.getfloat('pid_Ki') / PID_PARAM_BASE
self.Kd = config.getfloat('pid_Kd') / PID_PARAM_BASE
self.min_deriv_time = config.getfloat('pid_deriv_time', 2., above=0.)
imax = config.getfloat('pid_integral_max',
self.temperature_fan.get_max_speed(), minval=0.)
self.temp_integ_max = imax / self.Ki
self.prev_temp = AMBIENT_TEMP
self.prev_temp_time = 0.
self.prev_temp_deriv = 0.
self.prev_temp_integ = 0.
def temperature_callback(self, read_time, temp):
current_temp, target_temp = self.temperature_fan.get_temp(read_time)
time_diff = read_time - self.prev_temp_time
# Calculate change of temperature
temp_diff = temp - self.prev_temp
if time_diff >= self.min_deriv_time:
temp_deriv = temp_diff / time_diff
else:
temp_deriv = (self.prev_temp_deriv * (self.min_deriv_time-time_diff)
+ temp_diff) / self.min_deriv_time
# Calculate accumulated temperature "error"
temp_err = target_temp - temp
temp_integ = self.prev_temp_integ + temp_err * time_diff
temp_integ = max(0., min(self.temp_integ_max, temp_integ))
# Calculate output
co = self.Kp*temp_err + self.Ki*temp_integ - self.Kd*temp_deriv
bounded_co = max(0., min(self.temperature_fan.get_max_speed(), co))
self.temperature_fan.set_speed(
read_time, max(self.temperature_fan.get_min_speed(),
self.temperature_fan.get_max_speed() - bounded_co))
# Store state for next measurement
self.prev_temp = temp
self.prev_temp_time = read_time
self.prev_temp_deriv = temp_deriv
if co == bounded_co:
self.prev_temp_integ = temp_integ
def load_config_prefix(config):
return TemperatureFan(config)