#include "checksumm.h"
#include "Gcode.h"
#include "SlowTicker.h"
-#include "Pauser.h"
#include "ConfigValue.h"
#include "PID_Autotuner.h"
#include "SerialMessage.h"
// Temp sensor implementations:
#include "Thermistor.h"
#include "max31855.h"
+#include "AD8495.h"
#include "MRI_Hooks.h"
#define preset1_checksum CHECKSUM("preset1")
#define preset2_checksum CHECKSUM("preset2")
+#define runaway_range_checksum CHECKSUM("runaway_range")
+#define runaway_heating_timeout_checksum CHECKSUM("runaway_heating_timeout")
+
TemperatureControl::TemperatureControl(uint16_t name, int index)
{
name_checksum= name;
{
if (this->temp_violated) {
this->temp_violated = false;
- THEKERNEL->streams->printf("Error: MINTEMP or MAXTEMP triggered. Check your temperature sensors!\n");
+ THEKERNEL->streams->printf("Error: MINTEMP or MAXTEMP triggered on %s. Check your temperature sensors!\n", designator.c_str());
THEKERNEL->streams->printf("HALT asserted - reset or M999 required\n");
THEKERNEL->call_event(ON_HALT, nullptr);
}
this->designator = THEKERNEL->config->value(temperature_control_checksum, this->name_checksum, designator_checksum)->by_default(string("T"))->as_string();
+ // Runaway parameters
+ this->runaway_range = THEKERNEL->config->value(temperature_control_checksum, this->name_checksum, runaway_range_checksum)->by_default(0)->as_number();
+ this->runaway_heating_timeout = THEKERNEL->config->value(temperature_control_checksum, this->name_checksum, runaway_heating_timeout_checksum)->by_default(0)->as_number();
+
// Max and min temperatures we are not allowed to get over (Safety)
this->max_temp = THEKERNEL->config->value(temperature_control_checksum, this->name_checksum, max_temp_checksum)->by_default(300)->as_number();
this->min_temp = THEKERNEL->config->value(temperature_control_checksum, this->name_checksum, min_temp_checksum)->by_default(0)->as_number();
sensor = new Thermistor();
} else if(sensor_type.compare("max31855") == 0) {
sensor = new Max31855();
+ } else if(sensor_type.compare("ad8495") == 0) {
+ sensor = new AD8495();
} else {
sensor = new TempSensor(); // A dummy implementation
}
if(this->active) {
// required so temp change happens in order
- THEKERNEL->conveyor->wait_for_empty_queue();
+ THEKERNEL->conveyor->wait_for_idle();
float v = gcode->get_value('S');
// wait for temp to be reached, no more gcodes will be fetched until this is complete
if( gcode->m == this->set_and_wait_m_code) {
if(isinf(get_temperature()) && isinf(sensor->get_temperature())) {
- THEKERNEL->streams->printf("Temperature reading is unreliable HALT asserted - reset or M999 required\n");
+ THEKERNEL->streams->printf("Temperature reading is unreliable on %s HALT asserted - reset or M999 required\n", designator.c_str());
THEKERNEL->call_event(ON_HALT, nullptr);
return;
}
this->waiting = true; // on_second_tick will announce temps
while ( get_temperature() < target_temperature ) {
THEKERNEL->call_event(ON_IDLE, this);
+ // check if ON_HALT was called (usually by kill button)
+ if(THEKERNEL->is_halted() || this->target_temperature == UNDEFINED) {
+ THEKERNEL->streams->printf("Wait on temperature aborted by kill\n");
+ break;
+ }
}
this->waiting = false;
}
pdr->set_data_ptr(&return_data);
pdr->set_taken();
}
- return;
- }else if(!pdr->second_element_is(this->name_checksum)) return;
+ }else if(pdr->second_element_is(poll_controls_checksum)) {
+ // polling for all temperature controls
+ // add our data to the list which is passed in via the data_ptr
+
+ std::vector<struct pad_temperature> *v= static_cast<std::vector<pad_temperature>*>(pdr->get_data_ptr());
- // ok this is targeted at us, so send back the requested data
- if(pdr->third_element_is(current_temperature_checksum)) {
- this->public_data_return.current_temperature = this->get_temperature();
- this->public_data_return.target_temperature = (target_temperature <= 0) ? 0 : this->target_temperature;
- this->public_data_return.pwm = this->o;
- this->public_data_return.designator= this->designator;
- pdr->set_data_ptr(&this->public_data_return);
+ struct pad_temperature t;
+ // setup data
+ t.current_temperature = this->get_temperature();
+ t.target_temperature = (target_temperature <= 0) ? 0 : this->target_temperature;
+ t.pwm = this->o;
+ t.designator= this->designator;
+ t.id= this->name_checksum;
+ v->push_back(t);
pdr->set_taken();
+
+ }else if(pdr->second_element_is(current_temperature_checksum)) {
+ // if targeted at us
+ if(pdr->third_element_is(this->name_checksum)) {
+ // ok this is targeted at us, so set the requ3sted data in the pointer passed into us
+ struct pad_temperature *t= static_cast<pad_temperature*>(pdr->get_data_ptr());
+ t->current_temperature = this->get_temperature();
+ t->target_temperature = (target_temperature <= 0) ? 0 : this->target_temperature;
+ t->pwm = this->o;
+ t->designator= this->designator;
+ t->id= this->name_checksum;
+ pdr->set_taken();
+ }
}
}
void TemperatureControl::on_second_tick(void *argument)
{
+
+ // If waiting for a temperature to be reach, display it to keep host programs up to date on the progress
if (waiting)
THEKERNEL->streams->printf("%s:%3.1f /%3.1f @%d\n", designator.c_str(), get_temperature(), ((target_temperature <= 0) ? 0.0 : target_temperature), o);
+
+ // Check whether or not there is a temperature runaway issue, if so stop everything and report it
+ if(THEKERNEL->is_halted()) return;
+
+ if( this->target_temperature <= 0 ){ // If we are not trying to heat, state is NOT_HEATING
+ this->runaway_state = NOT_HEATING;
+ }else{
+ switch( this->runaway_state ){
+ case NOT_HEATING: // If we were previously not trying to heat, but we are now, change to state WAITING_FOR_TEMP_TO_BE_REACHED
+ if( this->target_temperature > 0 ){
+ this->runaway_state = WAITING_FOR_TEMP_TO_BE_REACHED;
+ this->runaway_heating_timer = 0;
+ }
+ break;
+ case WAITING_FOR_TEMP_TO_BE_REACHED: // In we are in state 1 ( waiting for temperature to be reached ), and the temperature has been reached, change to state TARGET_TEMPERATURE_REACHED
+ if( this->get_temperature() >= this->target_temperature ){
+ this->runaway_state = TARGET_TEMPERATURE_REACHED;
+ }
+ this->runaway_heating_timer++;
+ if( this->runaway_heating_timer > this->runaway_heating_timeout && this->runaway_heating_timeout != 0 ){
+ this->runaway_heating_timer = 0;
+ THEKERNEL->streams->printf("Error : Temperature too long to be reached on %s, HALT asserted, TURN POWER OFF IMMEDIATELY - reset or M999 required\n", designator.c_str());
+ THEKERNEL->call_event(ON_HALT, nullptr);
+ }
+ break;
+ case TARGET_TEMPERATURE_REACHED: // If we are in state TARGET_TEMPERATURE_REACHED, check for thermal runaway
+ // If the temperature is outside the acceptable range
+ if( fabs( this->get_temperature() - this->target_temperature ) > this->runaway_range && this->runaway_range != 0 ){
+ THEKERNEL->streams->printf("Error : Temperature runaway on %s, HALT asserted, TURN POWER OFF IMMEDIATELY - reset or M999 required\n", designator.c_str());
+ THEKERNEL->call_event(ON_HALT, nullptr);
+ }
+ break;
+ }
+ }
}
void TemperatureControl::setPIDp(float p)