local const = require("scada-common.constants") local log = require("scada-common.log") local rsio = require("scada-common.rsio") local types = require("scada-common.types") local util = require("scada-common.util") local plc = require("supervisor.session.plc") local qtypes = require("supervisor.session.rtu.qtypes") local RPS_TRIP_CAUSE = types.RPS_TRIP_CAUSE local TRI_FAIL = types.TRI_FAIL local CONTAINER_MODE = types.CONTAINER_MODE local DUMPING_MODE = types.DUMPING_MODE local PRIO = types.ALARM_PRIORITY local ALARM_STATE = types.ALARM_STATE local TBV_RTU_S_DATA = qtypes.TBV_RTU_S_DATA local DTV_RTU_S_DATA = qtypes.DTV_RTU_S_DATA local IO = rsio.IO local PLC_S_CMDS = plc.PLC_S_CMDS local AISTATE_NAMES = { "INACTIVE", "TRIPPING", "TRIPPED", "ACKED", "RING_BACK", "RING_BACK_TRIPPING" } local FLOW_STABILITY_DELAY_MS = const.FLOW_STABILITY_DELAY_MS local ANNUNC_LIMS = const.ANNUNCIATOR_LIMITS local ALARM_LIMS = const.ALARM_LIMITS ---@class unit_logic_extension local logic = {} -- compute Mekanism's rotation rate for a turbine ---@param turbine turbinev_session_db local function turbine_rotation(turbine) local build = turbine.build local inner_vol = build.steam_cap / const.mek.TURBINE_GAS_PER_TANK local disp_rate = (build.dispersers * const.mek.TURBINE_DISPERSER_FLOW) * inner_vol local vent_rate = build.vents * const.mek.TURBINE_VENT_FLOW local max_rate = math.min(disp_rate, vent_rate) local flow = math.min(max_rate, turbine.tanks.steam.amount) return (flow * (turbine.tanks.steam.amount / build.steam_cap)) / max_rate end -- update the annunciator ---@param self _unit_self function logic.update_annunciator(self) local DT_KEYS = self.types.DT_KEYS local _get_dt = self._get_dt local num_boilers = self.num_boilers local num_turbines = self.num_turbines local annunc = self.db.annunciator annunc.RCSFault = false -- variables for boiler, or reactor if no boilers used local total_boil_rate = 0.0 --#region Reactor annunc.AutoControl = self.auto_engaged -- check PLC status annunc.PLCOnline = self.plc_i ~= nil local plc_ready = annunc.PLCOnline if plc_ready then local plc_db = self.plc_i.get_db() -- update ready state -- - can't be tripped -- - must have received status at least once -- - must have received struct at least once plc_ready = plc_db.formed and (not plc_db.no_reactor) and (not plc_db.rps_tripped) and (next(self.plc_i.get_status()) ~= nil) and (next(self.plc_i.get_struct()) ~= nil) -- update auto control limit if (plc_db.mek_struct.max_burn > 0) and ((self.db.control.lim_br100 / 100) > plc_db.mek_struct.max_burn) then self.db.control.lim_br100 = math.floor(plc_db.mek_struct.max_burn * 100) end -- some alarms wait until the burn rate has stabilized, so keep track of that if math.abs(_get_dt(DT_KEYS.ReactorBurnR)) > 0 then self.last_rate_change_ms = util.time_ms() self.turbine_flow_stable = false for t = 1, self.num_turbines do self.turbine_stability_data[t] = { time_state = 0, time_tanks = 0, rotation = 1 } end end -- record reactor stats self.plc_cache.active = plc_db.mek_status.status self.plc_cache.ok = not (plc_db.rps_status.fault or plc_db.rps_status.sys_fail or plc_db.rps_status.force_dis) self.plc_cache.rps_trip = plc_db.rps_tripped self.plc_cache.rps_status = plc_db.rps_status self.plc_cache.damage = plc_db.mek_status.damage self.plc_cache.temp = plc_db.mek_status.temp self.plc_cache.waste = plc_db.mek_status.waste_fill -- track damage if plc_db.mek_status.damage > 0 then if self.damage_start == 0 then self.damage_decreasing = false self.damage_start = util.time_s() self.damage_initial = plc_db.mek_status.damage end else self.damage_decreasing = false self.damage_start = 0 self.damage_initial = 0 self.damage_last = 0 self.damage_est_last = 0 end -- heartbeat blink about every second if self.last_heartbeat + 1000 < plc_db.last_status_update then annunc.PLCHeartbeat = not annunc.PLCHeartbeat self.last_heartbeat = plc_db.last_status_update end local flow_low = ANNUNC_LIMS.RCSFlowLow_H2O local high_temp = plc_db.max_op_temp_H2O if plc_db.mek_status.ccool_type == types.FLUID.SODIUM then flow_low = ANNUNC_LIMS.RCSFlowLow_NA high_temp = plc_db.max_op_temp_Na end self.plc_cache.high_temp_lim = math.min(high_temp + ANNUNC_LIMS.OpTempTolerance, 1200) -- update other annunciator fields annunc.ReactorSCRAM = plc_db.rps_tripped annunc.ManualReactorSCRAM = plc_db.rps_trip_cause == types.RPS_TRIP_CAUSE.MANUAL annunc.AutoReactorSCRAM = plc_db.rps_trip_cause == types.RPS_TRIP_CAUSE.AUTOMATIC annunc.RCPTrip = plc_db.rps_tripped and (plc_db.rps_status.ex_hcool or plc_db.rps_status.low_cool) annunc.RCSFlowLow = _get_dt(DT_KEYS.ReactorCCool) < flow_low annunc.CoolantLevelLow = plc_db.mek_status.ccool_fill < ANNUNC_LIMS.CoolantLevelLow annunc.ReactorTempHigh = plc_db.mek_status.temp >= self.plc_cache.high_temp_lim annunc.ReactorHighDeltaT = _get_dt(DT_KEYS.ReactorTemp) > ANNUNC_LIMS.ReactorHighDeltaT annunc.FuelInputRateLow = _get_dt(DT_KEYS.ReactorFuel) < -1.0 or plc_db.mek_status.fuel_fill <= ANNUNC_LIMS.FuelLevelLow annunc.WasteLineOcclusion = _get_dt(DT_KEYS.ReactorWaste) > 1.0 or plc_db.mek_status.waste_fill >= ANNUNC_LIMS.WasteLevelHigh local heating_rate_conv = util.trinary(plc_db.mek_status.ccool_type == types.FLUID.SODIUM, 200000, 20000) local high_rate = plc_db.mek_status.burn_rate >= (plc_db.mek_status.ccool_amnt * 0.27 / heating_rate_conv) -- this advisory applies when no coolant is buffered (which we can't easily determine)
-- it's a rough estimation, see GitHub cc-mek-scada/wiki/High-Rate-Calculation annunc.HighStartupRate = not plc_db.mek_status.status and high_rate -- if no boilers, use reactor heating rate to check for boil rate mismatch if num_boilers == 0 then total_boil_rate = plc_db.mek_status.heating_rate end else self.plc_cache.ok = false end --#endregion --#region Misc RTUs local max_rad, any_faulted = 0, false for i = 1, #self.envd do local envd = self.envd[i] ---@type unit_session local db = envd.get_db() ---@type envd_session_db any_faulted = any_faulted or envd.is_faulted() if db.radiation_raw > max_rad then max_rad = db.radiation_raw end end annunc.RadiationMonitor = util.trinary(#self.envd == 0, 1, util.trinary(any_faulted, 2, 3)) annunc.RadiationWarning = max_rad >= ANNUNC_LIMS.RadiationWarning annunc.EmergencyCoolant = 1 for i = 1, #self.redstone do local db = self.redstone[i].get_db() ---@type redstone_session_db local io = db.io[IO.U_EMER_COOL] ---@type rs_db_dig_io|nil if io ~= nil then annunc.EmergencyCoolant = util.trinary(io.read(), 3, 2) break end end --#endregion --#region Boilers local boilers_ready = num_boilers == #self.boilers -- clear boiler online flags for i = 1, num_boilers do annunc.BoilerOnline[i] = false end -- aggregated statistics local boiler_steam_dt_sum = 0.0 local boiler_water_dt_sum = 0.0 if num_boilers > 0 then -- go through boilers for stats and online for i = 1, #self.boilers do local session = self.boilers[i] ---@type unit_session local boiler = session.get_db() ---@type boilerv_session_db local idx = session.get_device_idx() annunc.RCSFault = annunc.RCSFault or (not boiler.formed) or session.is_faulted() -- update ready state -- - must be formed -- - must have received build, state, and tanks at least once boilers_ready = boilers_ready and boiler.formed and (boiler.build.last_update > 0) and (boiler.state.last_update > 0) and (boiler.tanks.last_update > 0) total_boil_rate = total_boil_rate + boiler.state.boil_rate boiler_steam_dt_sum = _get_dt(DT_KEYS.BoilerSteam .. idx) boiler_water_dt_sum = _get_dt(DT_KEYS.BoilerWater .. idx) annunc.BoilerOnline[idx] = true annunc.WaterLevelLow[idx] = boiler.tanks.water_fill < ANNUNC_LIMS.WaterLevelLow end -- check heating rate low if self.plc_i ~= nil and #self.boilers > 0 then local r_db = self.plc_i.get_db() -- check for inactive boilers while reactor is active for i = 1, #self.boilers do local boiler = self.boilers[i] ---@type unit_session local idx = boiler.get_device_idx() local db = boiler.get_db() ---@type boilerv_session_db if r_db.mek_status.status then annunc.HeatingRateLow[idx] = db.state.boil_rate == 0 else annunc.HeatingRateLow[idx] = false end end end else boiler_steam_dt_sum = _get_dt(DT_KEYS.ReactorHCool) boiler_water_dt_sum = _get_dt(DT_KEYS.ReactorCCool) end --#endregion --#region Coolant Feed Mismatch -- check coolant feed mismatch if using boilers, otherwise calculate with reactor local cfmismatch = false if num_boilers > 0 then for i = 1, #self.boilers do local boiler = self.boilers[i] ---@type unit_session local idx = boiler.get_device_idx() local db = boiler.get_db() ---@type boilerv_session_db local gaining_hc = _get_dt(DT_KEYS.BoilerHCool .. idx) > 10.0 or db.tanks.hcool_fill == 1 -- gaining heated coolant cfmismatch = cfmismatch or gaining_hc -- losing cooled coolant cfmismatch = cfmismatch or _get_dt(DT_KEYS.BoilerCCool .. idx) < -10.0 or (gaining_hc and db.tanks.ccool_fill == 0) end elseif self.plc_i ~= nil then local r_db = self.plc_i.get_db() local gaining_hc = _get_dt(DT_KEYS.ReactorHCool) > 10.0 or r_db.mek_status.hcool_fill == 1 -- gaining heated coolant (steam) cfmismatch = cfmismatch or gaining_hc -- losing cooled coolant (water) cfmismatch = cfmismatch or _get_dt(DT_KEYS.ReactorCCool) < -10.0 or (gaining_hc and r_db.mek_status.ccool_fill == 0) end annunc.CoolantFeedMismatch = cfmismatch --#endregion --#region Turbines local turbines_ready = num_turbines == #self.turbines -- clear turbine online flags for i = 1, num_turbines do annunc.TurbineOnline[i] = false end -- aggregated statistics local total_flow_rate = 0 local total_input_rate = 0 local max_water_return_rate = 0 local turbines_stable = true -- recompute blade count on the chance that it may have changed self.db.control.blade_count = 0 -- go through turbines for stats and online for i = 1, #self.turbines do local session = self.turbines[i] ---@type unit_session local turbine = session.get_db() ---@type turbinev_session_db local idx = session.get_device_idx() annunc.RCSFault = annunc.RCSFault or (not turbine.formed) or session.is_faulted() annunc.TurbineOnline[idx] = true -- update ready state -- - must be formed -- - must have received build, state, and tanks at least once turbines_ready = turbines_ready and turbine.formed and (turbine.build.last_update > 0) and (turbine.state.last_update > 0) and (turbine.tanks.last_update > 0) total_flow_rate = total_flow_rate + turbine.state.flow_rate total_input_rate = total_input_rate + turbine.state.steam_input_rate max_water_return_rate = max_water_return_rate + turbine.build.max_water_output self.db.control.blade_count = self.db.control.blade_count + turbine.build.blades local last = self.turbine_stability_data[i] if (not self.turbine_flow_stable) and (turbine.state.steam_input_rate > 0) then local rotation = turbine_rotation(turbine) local rotation_stable = false -- see if data updated, and if so, check rotation speed change -- minimal change indicates the turbine is converging on a flow rate if last.time_tanks < turbine.tanks.last_update then if last.time_tanks > 0 then rotation_stable = math.abs(rotation - last.rotation) < 0.00000003 end last.time_tanks = turbine.tanks.last_update last.rotation = rotation end -- flow is stable if the flow rate is at the input rate or at the max (±1 mB/t) local flow_stable = false if last.time_state < turbine.state.last_update then if (last.time_state > 0) and (turbine.state.flow_rate > 0) then flow_stable = math.abs(turbine.state.flow_rate - math.min(turbine.state.steam_input_rate, turbine.build.max_flow_rate)) < 2 end last.time_state = turbine.state.last_update end if rotation_stable then log.debug(util.c("UNIT ", self.r_id, ": turbine ", idx, " reached rotational stability (", rotation, ")")) end if flow_stable then log.debug(util.c("UNIT ", self.r_id, ": turbine ", idx, " reached flow stability (", turbine.state.flow_rate, " mB/t)")) end turbines_stable = turbines_stable and (rotation_stable or flow_stable) else last.time_state = 0 last.time_tanks = 0 last.rotation = 1 turbines_stable = false end end self.turbine_flow_stable = self.turbine_flow_stable or turbines_stable -- check for boil rate mismatch (> 4% error) either between reactor and turbine or boiler and turbine annunc.BoilRateMismatch = math.abs(total_boil_rate - total_input_rate) > (0.04 * total_boil_rate) -- check for steam feed mismatch and max return rate local steam_dt_max = util.trinary(num_boilers == 0, ANNUNC_LIMS.SFM_MaxSteamDT_H20, ANNUNC_LIMS.SFM_MaxSteamDT_NA) local water_dt_min = util.trinary(num_boilers == 0, ANNUNC_LIMS.SFM_MinWaterDT_H20, ANNUNC_LIMS.SFM_MinWaterDT_NA) local sfmismatch = math.abs(total_flow_rate - total_input_rate) > ANNUNC_LIMS.SteamFeedMismatch sfmismatch = sfmismatch or boiler_steam_dt_sum > steam_dt_max or boiler_water_dt_sum < water_dt_min annunc.SteamFeedMismatch = sfmismatch annunc.MaxWaterReturnFeed = max_water_return_rate == total_flow_rate and total_flow_rate ~= 0 -- turbine safety checks for i = 1, #self.turbines do local turbine = self.turbines[i] ---@type unit_session local db = turbine.get_db() ---@type turbinev_session_db local idx = turbine.get_device_idx() -- check if steam dumps are open if db.state.dumping_mode == DUMPING_MODE.IDLE then annunc.SteamDumpOpen[idx] = TRI_FAIL.OK elseif db.state.dumping_mode == DUMPING_MODE.DUMPING_EXCESS then annunc.SteamDumpOpen[idx] = TRI_FAIL.PARTIAL else annunc.SteamDumpOpen[idx] = TRI_FAIL.FULL end -- check if turbines are at max speed but not keeping up annunc.TurbineOverSpeed[idx] = (db.state.flow_rate == db.build.max_flow_rate) and (_get_dt(DT_KEYS.TurbineSteam .. idx) > 0.0) -- see notes at cc-mek-scada/wiki/Annunciator-Panels#Generator-Trip annunc.GeneratorTrip[idx] = (_get_dt(DT_KEYS.TurbinePower .. idx) > 0.0) and (db.tanks.energy_fill > 0.05) -- see notes at cc-mek-scada/wiki/Annunciator-Panels#Turbine-Trip local has_steam = db.state.steam_input_rate > 0 or db.tanks.steam_fill > 0.01 annunc.TurbineTrip[idx] = has_steam and db.state.flow_rate == 0 end --#endregion -- update auto control ready state for this unit self.db.control.ready = plc_ready and boilers_ready and turbines_ready end -- update an alarm state given conditions ---@param self _unit_self unit instance ---@param tripped boolean if the alarm condition is still active ---@param alarm alarm_def alarm table ---@return boolean new_trip if the alarm just changed to being tripped local function _update_alarm_state(self, tripped, alarm) local AISTATE = self.types.AISTATE local int_state = alarm.state local ext_state = self.db.alarm_states[alarm.id] -- alarm inactive if int_state == AISTATE.INACTIVE then if tripped then alarm.trip_time = util.time_ms() if alarm.hold_time > 0 then alarm.state = AISTATE.TRIPPING self.db.alarm_states[alarm.id] = ALARM_STATE.INACTIVE else alarm.state = AISTATE.TRIPPED self.db.alarm_states[alarm.id] = ALARM_STATE.TRIPPED log.info(util.c("UNIT ", self.r_id, " ALARM ", alarm.id, " (", types.ALARM_NAMES[alarm.id], "): TRIPPED [PRIORITY ", types.ALARM_PRIORITY_NAMES[alarm.tier],"]")) end else alarm.trip_time = util.time_ms() self.db.alarm_states[alarm.id] = ALARM_STATE.INACTIVE end -- alarm condition met, but not yet for required hold time elseif (int_state == AISTATE.TRIPPING) or (int_state == AISTATE.RING_BACK_TRIPPING) then if tripped then local elapsed = util.time_ms() - alarm.trip_time if elapsed > (alarm.hold_time * 1000) then alarm.state = AISTATE.TRIPPED self.db.alarm_states[alarm.id] = ALARM_STATE.TRIPPED log.info(util.c("UNIT ", self.r_id, " ALARM ", alarm.id, " (", types.ALARM_NAMES[alarm.id], "): TRIPPED [PRIORITY ", types.ALARM_PRIORITY_NAMES[alarm.tier],"]")) end elseif int_state == AISTATE.RING_BACK_TRIPPING then alarm.trip_time = 0 alarm.state = AISTATE.RING_BACK self.db.alarm_states[alarm.id] = ALARM_STATE.RING_BACK else alarm.trip_time = 0 alarm.state = AISTATE.INACTIVE self.db.alarm_states[alarm.id] = ALARM_STATE.INACTIVE end -- alarm tripped and alarming elseif int_state == AISTATE.TRIPPED then if tripped then if ext_state == ALARM_STATE.ACKED then -- was acked by coordinator alarm.state = AISTATE.ACKED end else alarm.state = AISTATE.RING_BACK self.db.alarm_states[alarm.id] = ALARM_STATE.RING_BACK end -- alarm acknowledged but still tripped elseif int_state == AISTATE.ACKED then if not tripped then alarm.state = AISTATE.RING_BACK self.db.alarm_states[alarm.id] = ALARM_STATE.RING_BACK end -- alarm no longer tripped, operator must reset to clear elseif int_state == AISTATE.RING_BACK then if tripped then alarm.trip_time = util.time_ms() if alarm.hold_time > 0 then alarm.state = AISTATE.RING_BACK_TRIPPING else alarm.state = AISTATE.TRIPPED self.db.alarm_states[alarm.id] = ALARM_STATE.TRIPPED end elseif ext_state == ALARM_STATE.INACTIVE then -- was reset by coordinator alarm.state = AISTATE.INACTIVE alarm.trip_time = 0 end else log.error(util.c("invalid alarm state for unit ", self.r_id, " alarm ", alarm.id), true) end -- check for state change if alarm.state ~= int_state then local change_str = util.c(AISTATE_NAMES[int_state], " -> ", AISTATE_NAMES[alarm.state]) log.debug(util.c("UNIT ", self.r_id, " ALARM ", alarm.id, " (", types.ALARM_NAMES[alarm.id], "): ", change_str)) return alarm.state == AISTATE.TRIPPED else return false end end -- evaluate alarm conditions ---@param self _unit_self unit instance function logic.update_alarms(self) local annunc = self.db.annunciator local plc_cache = self.plc_cache -- Containment Breach -- lost plc with critical damage (rip plc, you will be missed) _update_alarm_state(self, (not plc_cache.ok) and (plc_cache.damage > 99), self.alarms.ContainmentBreach) -- Containment Radiation local rad_alarm = false for i = 1, #self.envd do self.last_radiation = self.envd[i].get_db().radiation_raw rad_alarm = self.last_radiation >= ALARM_LIMS.HIGH_RADIATION break end _update_alarm_state(self, rad_alarm, self.alarms.ContainmentRadiation) -- Reactor Lost _update_alarm_state(self, self.had_reactor and self.plc_i == nil, self.alarms.ReactorLost) -- Critical Damage _update_alarm_state(self, plc_cache.damage >= 100, self.alarms.CriticalDamage) -- Reactor Damage local rps_dmg_90 = plc_cache.rps_status.high_dmg and not self.last_rps_trips.high_dmg if _update_alarm_state(self, (plc_cache.damage > 0) or rps_dmg_90, self.alarms.ReactorDamage) then log.debug(util.c(">> Trip Detail Report for ", types.ALARM_NAMES[self.alarms.ReactorDamage.id]," <<")) log.debug(util.c("| plc_cache.damage[", plc_cache.damage, "] rps_dmg_90[", rps_dmg_90, "]")) end -- Over-Temperature local rps_high_temp = plc_cache.rps_status.high_temp and not self.last_rps_trips.high_temp if _update_alarm_state(self, (plc_cache.temp >= 1200) or rps_high_temp, self.alarms.ReactorOverTemp) then log.debug(util.c(">> Trip Detail Report for ", types.ALARM_NAMES[self.alarms.ReactorOverTemp.id]," <<")) log.debug(util.c("| plc_cache.temp[", plc_cache.temp, "] rps_high_temp[", rps_high_temp, "]")) end -- High Temperature local high_temp = math.min(math.max(self.plc_cache.high_temp_lim, 1100), 1199.995) _update_alarm_state(self, plc_cache.temp >= high_temp, self.alarms.ReactorHighTemp) -- Waste Leak _update_alarm_state(self, plc_cache.waste >= 1.0, self.alarms.ReactorWasteLeak) -- High Waste local rps_high_waste = plc_cache.rps_status.ex_waste and not self.last_rps_trips.ex_waste if _update_alarm_state(self, (plc_cache.waste > ALARM_LIMS.HIGH_WASTE) or rps_high_waste, self.alarms.ReactorHighWaste) then log.debug(util.c(">> Trip Detail Report for ", types.ALARM_NAMES[self.alarms.ReactorHighWaste.id]," <<")) log.debug(util.c("| plc_cache.waste[", plc_cache.waste, "] rps_high_waste[", rps_high_waste, "]")) end -- RPS Transient (excludes timeouts and manual trips) local rps_alarm = false if plc_cache.rps_status.manual ~= nil then if plc_cache.rps_trip then for key, val in pairs(plc_cache.rps_status) do if key ~= "manual" and key ~= "timeout" then rps_alarm = rps_alarm or val end end end end _update_alarm_state(self, rps_alarm, self.alarms.RPSTransient) -- RCS Transient local any_low = annunc.CoolantLevelLow local any_over = false local gen_trip = false for i = 1, #annunc.WaterLevelLow do any_low = any_low or annunc.WaterLevelLow[i] end for i = 1, #annunc.TurbineOverSpeed do any_over = any_over or annunc.TurbineOverSpeed[i] end for i = 1, #annunc.GeneratorTrip do gen_trip = gen_trip or annunc.GeneratorTrip[i] end local rcs_trans = any_low or any_over or gen_trip or annunc.RCPTrip or annunc.MaxWaterReturnFeed if plc_cache.active then -- these conditions may not indicate an issue when flow is changing after a burn rate change if self.num_boilers == 0 then if (util.time_ms() - self.last_rate_change_ms) > FLOW_STABILITY_DELAY_MS then rcs_trans = rcs_trans or annunc.BoilRateMismatch end if self.turbine_flow_stable then rcs_trans = rcs_trans or annunc.RCSFlowLow or annunc.CoolantFeedMismatch or annunc.SteamFeedMismatch end else if (util.time_ms() - self.last_rate_change_ms) > FLOW_STABILITY_DELAY_MS then rcs_trans = rcs_trans or annunc.RCSFlowLow or annunc.BoilRateMismatch or annunc.CoolantFeedMismatch end if self.turbine_flow_stable then rcs_trans = rcs_trans or annunc.SteamFeedMismatch end end end if _update_alarm_state(self, rcs_trans, self.alarms.RCSTransient) then log.debug(util.c(">> Trip Detail Report for ", types.ALARM_NAMES[self.alarms.RCSTransient.id]," <<")) log.debug(util.c("| any_low[", any_low, "] any_over[", any_over, "] gen_trip[", gen_trip, "]")) log.debug(util.c("| RCPTrip[", annunc.RCPTrip, "] MaxWaterReturnFeed[", annunc.MaxWaterReturnFeed, "]")) log.debug(util.c("| RCSFlowLow[", annunc.RCSFlowLow, "] BoilRateMismatch[", annunc.BoilRateMismatch, "] CoolantFeedMismatch[", annunc.CoolantFeedMismatch, "] SteamFeedMismatch[", annunc.SteamFeedMismatch, "]")) end -- Turbine Trip local any_trip = false for i = 1, #annunc.TurbineTrip do any_trip = any_trip or annunc.TurbineTrip[i] end _update_alarm_state(self, any_trip, self.alarms.TurbineTrip) -- update last trips table for key, val in pairs(plc_cache.rps_status) do self.last_rps_trips[key] = val end end -- update the internal automatic safety control performed while in auto control mode ---@param public reactor_unit reactor unit public functions ---@param self _unit_self unit instance function logic.update_auto_safety(public, self) local AISTATE = self.types.AISTATE if self.auto_engaged then local alarmed = false for _, alarm in pairs(self.alarms) do if alarm.tier <= PRIO.URGENT and (alarm.state == AISTATE.TRIPPED or alarm.state == AISTATE.ACKED) then if not self.auto_was_alarmed then log.info(util.c("UNIT ", self.r_id, " AUTO SCRAM due to ALARM ", alarm.id, " (", types.ALARM_NAMES[alarm.id], ") [PRIORITY ", types.ALARM_PRIORITY_NAMES[alarm.tier],"]")) end alarmed = true break end end if alarmed and not self.plc_cache.rps_status.automatic then public.auto_scram() end self.auto_was_alarmed = alarmed else self.auto_was_alarmed = false end end -- update the two unit status text messages ---@param self _unit_self unit instance function logic.update_status_text(self) local AISTATE = self.types.AISTATE local annunc = self.db.annunciator -- check if an alarm is active (tripped or ack'd) ---@nodiscard ---@param alarm table alarm entry ---@return boolean active local function is_active(alarm) return alarm.state == AISTATE.TRIPPED or alarm.state == AISTATE.ACKED end -- update status text (what the reactor doin?) if is_active(self.alarms.ContainmentBreach) then -- boom? or was boom disabled if self.plc_i ~= nil and self.plc_i.get_rps().force_dis then self.status_text = { "REACTOR FORCE DISABLED", "meltdown would have occurred" } else self.status_text = { "CORE MELTDOWN", "reactor destroyed" } end elseif is_active(self.alarms.CriticalDamage) then -- so much for it being a "routine turbin' trip"... self.status_text = { "MELTDOWN IMMINENT", "evacuate facility immediately" } elseif is_active(self.alarms.ReactorDamage) then -- attempt to determine when a chance of a meltdown will occur self.status_text[1] = "CONTAINMENT TAKING DAMAGE" if self.plc_cache.damage >= 100 then self.status_text[2] = "damage critical" elseif (self.plc_cache.damage < self.damage_last) or ((self.plc_cache.damage - self.damage_initial) < 0) then self.damage_decreasing = true self.status_text = { "CONTAINMENT TOOK DAMAGE", "damage level lowering..." } -- reset damage estimation data in case it goes back up again self.damage_initial = self.plc_cache.damage self.damage_start = util.time_s() self.damage_est_last = 0 elseif (not self.damage_decreasing) or (self.plc_cache.damage > self.damage_last) then self.damage_decreasing = false if (self.plc_cache.damage - self.damage_initial) > 0 then if self.plc_cache.damage > self.damage_last then local rate = (self.plc_cache.damage - self.damage_initial) / (util.time_s() - self.damage_start) self.damage_est_last = (100 - self.plc_cache.damage) / rate end self.status_text[2] = util.c("damage critical in ", util.sprintf("%.1f", self.damage_est_last), "s") else self.status_text[2] = "estimating time to critical..." end else self.status_text = { "CONTAINMENT TOOK DAMAGE", "damage level lowering..." } end self.damage_last = self.plc_cache.damage elseif is_active(self.alarms.ContainmentRadiation) then self.status_text[1] = "RADIATION DETECTED" if self.last_radiation >= const.EXTREME_RADIATION then self.status_text[2] = "extremely high radiation level" elseif self.last_radiation >= const.SEVERE_RADIATION then self.status_text[2] = "severely high radiation level" elseif self.last_radiation >= const.VERY_HIGH_RADIATION then self.status_text[2] = "very high level of radiation" elseif self.last_radiation >= const.HIGH_RADIATION then self.status_text[2] = "high level of radiation" elseif self.last_radiation >= const.HAZARD_RADIATION then self.status_text[2] = "hazardous level of radiation" else self.status_text[2] = "elevated level of radiation" end elseif is_active(self.alarms.ReactorOverTemp) then self.status_text = { "CORE OVER TEMP", "reactor core temp damaging" } elseif is_active(self.alarms.ReactorWasteLeak) then self.status_text = { "WASTE LEAK", "radioactive waste leak detected" } elseif is_active(self.alarms.ReactorHighTemp) then self.status_text = { "CORE TEMP HIGH", "reactor core temperature high" } elseif is_active(self.alarms.ReactorHighWaste) then self.status_text = { "WASTE LEVEL HIGH", "waste accumulating in reactor" } elseif is_active(self.alarms.TurbineTrip) then self.status_text = { "TURBINE TRIP", "turbine stall occurred" } elseif is_active(self.alarms.RCSTransient) then self.status_text = { "RCS TRANSIENT", "check coolant system" } -- elseif is_active(self.alarms.RPSTransient) then -- RPS status handled when checking reactor status elseif self.emcool_opened then self.status_text = { "EMERGENCY COOLANT OPENED", "reset RPS to close valve" } -- connection dependent states elseif self.plc_i ~= nil then local plc_db = self.plc_i.get_db() if plc_db.mek_status.status then self.status_text[1] = "ACTIVE" if annunc.ReactorHighDeltaT then self.status_text[2] = "core temperature rising" elseif annunc.ReactorTempHigh then self.status_text[2] = "core temp high, system nominal" elseif annunc.FuelInputRateLow then self.status_text[2] = "insufficient fuel input rate" elseif annunc.WasteLineOcclusion then self.status_text[2] = "insufficient waste output rate" elseif (util.time_ms() - self.last_rate_change_ms) <= FLOW_STABILITY_DELAY_MS then self.status_text[2] = "awaiting coolant flow stability" elseif not self.turbine_flow_stable then self.status_text[2] = "awaiting turbine flow stability" else self.status_text[2] = "system nominal" end elseif plc_db.rps_tripped then local cause = "unknown" if plc_db.rps_trip_cause == RPS_TRIP_CAUSE.OK then -- hmm... elseif plc_db.rps_trip_cause == RPS_TRIP_CAUSE.HIGH_DMG then cause = "core damage high" elseif plc_db.rps_trip_cause == RPS_TRIP_CAUSE.HIGH_TEMP then cause = "core temperature high" elseif plc_db.rps_trip_cause == RPS_TRIP_CAUSE.LOW_COOLANT then cause = "insufficient coolant" elseif plc_db.rps_trip_cause == RPS_TRIP_CAUSE.EX_WASTE then cause = "excess waste" elseif plc_db.rps_trip_cause == RPS_TRIP_CAUSE.EX_HCOOLANT then cause = "excess heated coolant" elseif plc_db.rps_trip_cause == RPS_TRIP_CAUSE.NO_FUEL then cause = "insufficient fuel" elseif plc_db.rps_trip_cause == RPS_TRIP_CAUSE.FAULT then cause = "hardware fault" elseif plc_db.rps_trip_cause == RPS_TRIP_CAUSE.TIMEOUT then cause = "connection timed out" elseif plc_db.rps_trip_cause == RPS_TRIP_CAUSE.MANUAL then cause = "manual operator SCRAM" elseif plc_db.rps_trip_cause == RPS_TRIP_CAUSE.AUTOMATIC then cause = "automated system SCRAM" elseif plc_db.rps_trip_cause == RPS_TRIP_CAUSE.SYS_FAIL then cause = "PLC system failure" elseif plc_db.rps_trip_cause == RPS_TRIP_CAUSE.FORCE_DISABLED then cause = "reactor force disabled" end self.status_text = { "RPS SCRAM", cause } elseif annunc.RadiationWarning then -- elevated, non-hazardous level of radiation is low priority, so display it now if everything else was fine self.status_text = { "RADIATION DETECTED", "elevated level of radiation" } else self.status_text[1] = "IDLE" local temp = plc_db.mek_status.temp if temp < 350 then self.status_text[2] = "core cold" elseif temp < 600 then self.status_text[2] = "core warm" else self.status_text[2] = "core hot" end end elseif annunc.RadiationWarning then -- in case PLC was disconnected but radiation is present self.status_text = { "RADIATION DETECTED", "elevated level of radiation" } else self.status_text = { "REACTOR OFF-LINE", "awaiting connection..." } end end -- handle unit redstone I/O ---@param self _unit_self unit instance function logic.handle_redstone(self) local AISTATE = self.types.AISTATE local annunc = self.db.annunciator local cache = self.plc_cache local rps = cache.rps_status -- check if an alarm is active (tripped or ack'd) ---@nodiscard ---@param alarm table alarm entry ---@return boolean active local function is_active(alarm) return alarm.state == AISTATE.TRIPPED or alarm.state == AISTATE.ACKED end -- reactor controls if self.plc_s ~= nil then if (not rps.manual) and self.io_ctl.digital_read(IO.R_SCRAM) then -- reactor SCRAM requested but not yet done; perform it self.plc_s.in_queue.push_command(PLC_S_CMDS.SCRAM) end if cache.rps_trip and self.io_ctl.digital_read(IO.R_RESET) then -- reactor RPS reset requested but not yet done; perform it self.plc_s.in_queue.push_command(PLC_S_CMDS.RPS_RESET) end if (not self.auto_engaged) and (not cache.active) and (not cache.rps_trip) and self.io_ctl.digital_read(IO.R_ENABLE) then -- reactor enable requested and allowable, but not yet done; perform it self.plc_s.in_queue.push_command(PLC_S_CMDS.ENABLE) end end -- check for request to ack all alarms if self.io_ctl.digital_read(IO.U_ACK) then for i = 1, #self.db.alarm_states do if self.db.alarm_states[i] == ALARM_STATE.TRIPPED then self.db.alarm_states[i] = ALARM_STATE.ACKED end end end -- write reactor status outputs self.io_ctl.digital_write(IO.R_ACTIVE, cache.active) self.io_ctl.digital_write(IO.R_AUTO_CTRL, self.auto_engaged) self.io_ctl.digital_write(IO.R_SCRAMMED, cache.rps_trip) self.io_ctl.digital_write(IO.R_AUTO_SCRAM, rps.automatic) self.io_ctl.digital_write(IO.R_HIGH_DMG, rps.high_dmg) self.io_ctl.digital_write(IO.R_HIGH_TEMP, rps.high_temp) self.io_ctl.digital_write(IO.R_LOW_COOLANT, rps.low_cool) self.io_ctl.digital_write(IO.R_EXCESS_HC, rps.ex_hcool) self.io_ctl.digital_write(IO.R_EXCESS_WS, rps.ex_waste) self.io_ctl.digital_write(IO.R_INSUFF_FUEL, rps.no_fuel) self.io_ctl.digital_write(IO.R_PLC_FAULT, rps.fault) self.io_ctl.digital_write(IO.R_PLC_TIMEOUT, rps.timeout) -- write unit outputs local has_alarm = false for i = 1, #self.db.alarm_states do if self.db.alarm_states[i] == ALARM_STATE.TRIPPED or self.db.alarm_states[i] == ALARM_STATE.ACKED then has_alarm = true break end end self.io_ctl.digital_write(IO.U_ALARM, has_alarm) ----------------------- -- Emergency Coolant -- ----------------------- local boiler_water_low = false for i = 1, #annunc.WaterLevelLow do boiler_water_low = boiler_water_low or annunc.WaterLevelLow[i] end local enable_emer_cool = rps.low_cool or (self.auto_engaged and (annunc.CoolantLevelLow or (boiler_water_low and rps.ex_hcool)) and is_active(self.alarms.ReactorOverTemp)) if enable_emer_cool and not self.emcool_opened then log.debug(util.c(">> Emergency Coolant Enable Detail Report (Unit ", self.r_id, ") <<")) log.debug(util.c("| CoolantLevelLow[", annunc.CoolantLevelLow, "] CoolantLevelLowLow[", rps.low_cool, "] ExcessHeatedCoolant[", rps.ex_hcool, "]")) log.debug(util.c("| ReactorOverTemp[", AISTATE_NAMES[self.alarms.ReactorOverTemp.state], "]")) for i = 1, #annunc.WaterLevelLow do log.debug(util.c("| WaterLevelLow(", i, ")[", annunc.WaterLevelLow[i], "]")) end end -- don't turn off emergency coolant on sufficient coolant level since it might drop again -- turn off once system is OK again -- if auto control is engaged, alarm check will SCRAM on reactor over temp so that's covered if not cache.rps_trip then -- set turbines to not dump steam for i = 1, #self.turbines do local session = self.turbines[i] ---@type unit_session local turbine = session.get_db() ---@type turbinev_session_db if turbine.state.dumping_mode ~= DUMPING_MODE.IDLE then session.get_cmd_queue().push_data(TBV_RTU_S_DATA.SET_DUMP_MODE, DUMPING_MODE.IDLE) end end if annunc.EmergencyCoolant > 1 and self.emcool_opened then log.info(util.c("UNIT ", self.r_id, " emergency coolant valve closed")) log.info(util.c("UNIT ", self.r_id, " turbines set to not dump steam")) end self.emcool_opened = false elseif enable_emer_cool or self.emcool_opened then -- set turbines to dump excess steam for i = 1, #self.turbines do local session = self.turbines[i] ---@type unit_session local turbine = session.get_db() ---@type turbinev_session_db if turbine.state.dumping_mode ~= DUMPING_MODE.DUMPING_EXCESS then session.get_cmd_queue().push_data(TBV_RTU_S_DATA.SET_DUMP_MODE, DUMPING_MODE.DUMPING_EXCESS) end end -- make sure dynamic tanks are allowing outflow for i = 1, #self.tanks do local session = self.tanks[i] ---@type unit_session local tank = session.get_db() ---@type dynamicv_session_db if tank.state.container_mode == CONTAINER_MODE.FILL then session.get_cmd_queue().push_data(DTV_RTU_S_DATA.SET_CONT_MODE, CONTAINER_MODE.BOTH) end end if annunc.EmergencyCoolant > 1 and not self.emcool_opened then log.info(util.c("UNIT ", self.r_id, " emergency coolant valve opened")) log.info(util.c("UNIT ", self.r_id, " turbines set to dump excess steam")) end self.emcool_opened = true end -- set valve state always if self.emcool_opened then self.valves.emer_cool.open() else self.valves.emer_cool.close() end end return logic