Fix notifications during GCode export - only CRTICAL are now shown

Relax support detector parameters and warnings
This commit is contained in:
PavelMikus 2023-01-31 11:12:36 +01:00
parent 3e37067cc9
commit 716e0254f4
4 changed files with 28 additions and 23 deletions

View File

@ -1200,7 +1200,7 @@ void Print::alert_when_supports_needed()
} }
} }
message += "\n" + L("Consider enabling supports") + (recommend_brim ? (" " + L("and brim")) : "") + "."; message += "\n" + L("Consider enabling supports") + (recommend_brim ? (" " + L("and/or brim")) : "") + ".";
if (objects_isssues.size() > 0) { if (objects_isssues.size() > 0) {
this->active_step_add_warning(PrintStateBase::WarningLevel::NON_CRITICAL, message); this->active_step_add_warning(PrintStateBase::WarningLevel::NON_CRITICAL, message);

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@ -217,7 +217,7 @@ float estimate_curled_up_height(
float dist_factor = std::max(point.distance - params.malformation_distance_factors.first * flow_width, 0.01f) / float dist_factor = std::max(point.distance - params.malformation_distance_factors.first * flow_width, 0.01f) /
((params.malformation_distance_factors.second - params.malformation_distance_factors.first) * flow_width); ((params.malformation_distance_factors.second - params.malformation_distance_factors.first) * flow_width);
curled_up_height = layer_height * 2.0f * sqrt(sqrt(dist_factor)) * std::clamp(6.0f * point.curvature, 1.0f, 6.0f); curled_up_height = layer_height * sqrt(sqrt(dist_factor)) * std::clamp(3.0f * point.curvature, 1.0f, 3.0f);
curled_up_height = std::min(curled_up_height, params.max_curled_height_factor * layer_height); curled_up_height = std::min(curled_up_height, params.max_curled_height_factor * layer_height);
} }
@ -1183,23 +1183,22 @@ std::vector<std::pair<SupportPointCause, bool>> gather_issues(const SupportPoint
[](const PartialObject &left, const PartialObject &right) { return left.volume > right.volume; }); [](const PartialObject &left, const PartialObject &right) { return left.volume > right.volume; });
float max_volume_part = partial_objects.front().volume; float max_volume_part = partial_objects.front().volume;
bool unstable_floating_part_added = false;
for (const PartialObject &p : partial_objects) { for (const PartialObject &p : partial_objects) {
if (p.volume > max_volume_part / 500.0f && !p.connected_to_bed) { if (p.volume > max_volume_part / 200.0f && !p.connected_to_bed) {
result.emplace_back(SupportPointCause::UnstableFloatingPart, true); result.emplace_back(SupportPointCause::UnstableFloatingPart, true);
unstable_floating_part_added = true;
break; break;
} }
} }
if (!unstable_floating_part_added) { // should be detected in previous step
for (const SupportPoint &sp : support_points) { // if (!unstable_floating_part_added) {
if (sp.cause == SupportPointCause::UnstableFloatingPart) { // for (const SupportPoint &sp : support_points) {
result.emplace_back(SupportPointCause::UnstableFloatingPart, true); // if (sp.cause == SupportPointCause::UnstableFloatingPart) {
break; // result.emplace_back(SupportPointCause::UnstableFloatingPart, true);
} // break;
} // }
} // }
// }
std::vector<SupportPoint> ext_supp_points{}; std::vector<SupportPoint> ext_supp_points{};
ext_supp_points.reserve(support_points.size()); ext_supp_points.reserve(support_points.size());
@ -1245,7 +1244,7 @@ std::vector<std::pair<SupportPointCause, bool>> gather_issues(const SupportPoint
} }
} }
if (ext_supp_points.size() > 5) { if (ext_supp_points.size() > max_volume_part / 200.0f) {
result.emplace_back(SupportPointCause::FloatingExtrusion, false); result.emplace_back(SupportPointCause::FloatingExtrusion, false);
} }

View File

@ -33,7 +33,7 @@ struct Params
} }
// the algorithm should use the following units for all computations: distance [mm], mass [g], time [s], force [g*mm/s^2] // the algorithm should use the following units for all computations: distance [mm], mass [g], time [s], force [g*mm/s^2]
const float bridge_distance = 12.0f; // mm const float bridge_distance = 16.0f; // mm
const float max_acceleration; // mm/s^2 ; max acceleration of object in XY -- should be applicable only to printers with bed slinger, const float max_acceleration; // mm/s^2 ; max acceleration of object in XY -- should be applicable only to printers with bed slinger,
// however we do not have such info yet. The force is usually small anyway, so not such a big deal to include it everytime // however we do not have such info yet. The force is usually small anyway, so not such a big deal to include it everytime
const int raft_layers_count; const int raft_layers_count;
@ -42,7 +42,7 @@ struct Params
BrimType brim_type; BrimType brim_type;
const float brim_width; const float brim_width;
const std::pair<float,float> malformation_distance_factors = std::pair<float, float> { 0.4, 1.2 }; const std::pair<float,float> malformation_distance_factors = std::pair<float, float> { 0.5, 1.1 };
const float max_curled_height_factor = 10.0f; const float max_curled_height_factor = 10.0f;
const float min_distance_between_support_points = 3.0f; //mm const float min_distance_between_support_points = 3.0f; //mm
@ -52,8 +52,8 @@ struct Params
const float gravity_constant = 9806.65f; // mm/s^2; gravity acceleration on Earth's surface, algorithm assumes that printer is in upwards position. const float gravity_constant = 9806.65f; // mm/s^2; gravity acceleration on Earth's surface, algorithm assumes that printer is in upwards position.
const double filament_density = 1.25e-3f; // g/mm^3 ; Common filaments are very lightweight, so precise number is not that important const double filament_density = 1.25e-3f; // g/mm^3 ; Common filaments are very lightweight, so precise number is not that important
const double material_yield_strength = 33.0f * 1e6f; // (g*mm/s^2)/mm^2; 33 MPa is yield strength of ABS, which has the lowest yield strength from common materials. const double material_yield_strength = 33.0f * 1e6f; // (g*mm/s^2)/mm^2; 33 MPa is yield strength of ABS, which has the lowest yield strength from common materials.
const float standard_extruder_conflict_force = 5.0f * gravity_constant; // force that can occasionally push the model due to various factors (filament leaks, small curling, ... ); const float standard_extruder_conflict_force = 10.0f * gravity_constant; // force that can occasionally push the model due to various factors (filament leaks, small curling, ... );
const float malformations_additive_conflict_extruder_force = 100.0f * gravity_constant; // for areas with possible high layered curled filaments const float malformations_additive_conflict_extruder_force = 65.0f * gravity_constant; // for areas with possible high layered curled filaments
// MPa * 1e^6 = (g*mm/s^2)/mm^2 = g/(mm*s^2); yield strength of the bed surface // MPa * 1e^6 = (g*mm/s^2)/mm^2 = g/(mm*s^2); yield strength of the bed surface
double get_bed_adhesion_yield_strength() const { double get_bed_adhesion_yield_strength() const {
@ -72,9 +72,8 @@ struct Params
} }
} }
//just return PLA adhesion value as value for supports
double get_support_spots_adhesion_strength() const { double get_support_spots_adhesion_strength() const {
return 0.02f * 1e6; return 0.016f * 1e6;
} }
}; };

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@ -4367,10 +4367,17 @@ void Plater::priv::clear_warnings()
} }
bool Plater::priv::warnings_dialog() bool Plater::priv::warnings_dialog()
{ {
if (current_warnings.empty()) std::vector<std::pair<Slic3r::PrintStateBase::Warning, size_t>> current_critical_warnings{};
for (const auto& w : current_warnings) {
if (w.first.level == PrintStateBase::WarningLevel::CRITICAL) {
current_critical_warnings.push_back(w);
}
}
if (current_critical_warnings.empty())
return true; return true;
std::string text = _u8L("There are active warnings concerning sliced models:") + "\n"; std::string text = _u8L("There are active warnings concerning sliced models:") + "\n";
for (auto const& it : current_warnings) { for (auto const& it : current_critical_warnings) {
size_t next_n = it.first.message.find_first_of('\n', 0); size_t next_n = it.first.message.find_first_of('\n', 0);
text += "\n"; text += "\n";
if (next_n != std::string::npos) if (next_n != std::string::npos)