/*
* EMS-ESP - https://github.com/emsesp/EMS-ESP
* Copyright 2020 Paul Derbyshire
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see .
*/
#include "solar.h"
namespace emsesp {
REGISTER_FACTORY(Solar, EMSdevice::DeviceType::SOLAR);
uuid::log::Logger Solar::logger_{F_(solar), uuid::log::Facility::CONSOLE};
Solar::Solar(uint8_t device_type, uint8_t device_id, uint8_t product_id, const std::string & version, const std::string & name, uint8_t flags, uint8_t brand)
: EMSdevice(device_type, device_id, product_id, version, name, flags, brand) {
LOG_DEBUG(F("Adding new Solar module with device ID 0x%02X"), device_id);
// telegram handlers
if (flags == EMSdevice::EMS_DEVICE_FLAG_SM10) {
register_telegram_type(0x97, F("SM10Monitor"), false, MAKE_PF_CB(process_SM10Monitor));
register_telegram_type(0x96, F("SM10Config"), true, MAKE_PF_CB(process_SM10Config));
EMSESP::send_read_request(0x97, device_id);
}
if (flags == EMSdevice::EMS_DEVICE_FLAG_SM100) {
if (device_id == 0x2A) {
register_telegram_type(0x07D6, F("SM100wwTemperature"), false, MAKE_PF_CB(process_SM100wwTemperature));
register_telegram_type(0x07AA, F("SM100wwStatus"), false, MAKE_PF_CB(process_SM100wwStatus));
register_telegram_type(0x07AB, F("SM100wwCommand"), false, MAKE_PF_CB(process_SM100wwCommand));
} else {
register_telegram_type(0xF9, F("ParamCfg"), false, MAKE_PF_CB(process_SM100ParamCfg));
register_telegram_type(0x0358, F("SM100SystemConfig"), true, MAKE_PF_CB(process_SM100SystemConfig));
register_telegram_type(0x035A, F("SM100SolarCircuitConfig"), true, MAKE_PF_CB(process_SM100SolarCircuitConfig));
register_telegram_type(0x0362, F("SM100Monitor"), true, MAKE_PF_CB(process_SM100Monitor));
register_telegram_type(0x0363, F("SM100Monitor2"), true, MAKE_PF_CB(process_SM100Monitor2));
register_telegram_type(0x0366, F("SM100Config"), true, MAKE_PF_CB(process_SM100Config));
register_telegram_type(0x0364, F("SM100Status"), false, MAKE_PF_CB(process_SM100Status));
register_telegram_type(0x036A, F("SM100Status2"), false, MAKE_PF_CB(process_SM100Status2));
register_telegram_type(0x0380, F("SM100CollectorConfig"), true, MAKE_PF_CB(process_SM100CollectorConfig));
register_telegram_type(0x038E, F("SM100Energy"), true, MAKE_PF_CB(process_SM100Energy));
register_telegram_type(0x0391, F("SM100Time"), true, MAKE_PF_CB(process_SM100Time));
}
}
if (flags == EMSdevice::EMS_DEVICE_FLAG_ISM) {
register_telegram_type(0x0103, F("ISM1StatusMessage"), true, MAKE_PF_CB(process_ISM1StatusMessage));
register_telegram_type(0x0101, F("ISM1Set"), true, MAKE_PF_CB(process_ISM1Set));
}
// device values...
// special case for a device_id with 0x2A where it's not actual a solar module
if (device_id == 0x2A) {
register_device_value(TAG_NONE, &type_, DeviceValueType::TEXT, nullptr, FL_(type), DeviceValueUOM::NONE);
strlcpy(type_, "warm water circuit", sizeof(type_));
register_device_value(TAG_NONE, &wwTemp_1_, DeviceValueType::UINT, nullptr, FL_(wwTemp1), DeviceValueUOM::DEGREES);
register_device_value(TAG_NONE, &wwTemp_3_, DeviceValueType::UINT, nullptr, FL_(wwTemp3), DeviceValueUOM::DEGREES);
register_device_value(TAG_NONE, &wwTemp_4_, DeviceValueType::UINT, nullptr, FL_(wwTemp4), DeviceValueUOM::DEGREES);
register_device_value(TAG_NONE, &wwTemp_5_, DeviceValueType::UINT, nullptr, FL_(wwTemp5), DeviceValueUOM::DEGREES);
register_device_value(TAG_NONE, &wwTemp_7_, DeviceValueType::UINT, nullptr, FL_(wwTemp7), DeviceValueUOM::DEGREES);
register_device_value(TAG_NONE, &wwPump_, DeviceValueType::UINT, nullptr, FL_(wwPump), DeviceValueUOM::DEGREES);
return;
}
register_device_value(TAG_NONE, &id_, DeviceValueType::UINT, nullptr, FL_(ID), DeviceValueUOM::NONE);
id_ = product_id;
register_device_value(TAG_NONE, &collectorTemp_, DeviceValueType::SHORT, FL_(div10), FL_(collectorTemp), DeviceValueUOM::DEGREES);
register_device_value(TAG_NONE, &tankBottomTemp_, DeviceValueType::SHORT, FL_(div10), FL_(tankBottomTemp), DeviceValueUOM::DEGREES);
register_device_value(TAG_NONE, &solarPump_, DeviceValueType::BOOL, nullptr, FL_(solarPump), DeviceValueUOM::BOOLEAN);
register_device_value(TAG_NONE, &pumpWorkTime_, DeviceValueType::TIME, nullptr, FL_(pumpWorkTime), DeviceValueUOM::MINUTES);
register_device_value(TAG_NONE, &tankMaxTemp_, DeviceValueType::UINT, nullptr, FL_(tankMaxTemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_TankMaxTemp));
if (flags == EMSdevice::EMS_DEVICE_FLAG_SM10) {
register_device_value(TAG_NONE, &solarPumpModulation_, DeviceValueType::UINT, nullptr, FL_(solarPumpModulation), DeviceValueUOM::PERCENT);
register_device_value(TAG_NONE, &solarPumpMinMod_, DeviceValueType::UINT, nullptr, FL_(pumpMinMod), DeviceValueUOM::PERCENT, MAKE_CF_CB(set_PumpMinMod));
register_device_value(
TAG_NONE, &solarPumpTurnonDiff_, DeviceValueType::UINT, nullptr, FL_(solarPumpTurnonDiff), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_TurnonDiff));
register_device_value(
TAG_NONE, &solarPumpTurnoffDiff_, DeviceValueType::UINT, nullptr, FL_(solarPumpTurnoffDiff), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_TurnoffDiff));
register_device_value(
TAG_NONE, &collectorMaxTemp_, DeviceValueType::UINT, nullptr, FL_(collectorMaxTemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_CollectorMaxTemp));
register_device_value(
TAG_NONE, &collectorMinTemp_, DeviceValueType::UINT, nullptr, FL_(collectorMinTemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_CollectorMinTemp));
register_device_value(TAG_NONE, &collectorShutdown_, DeviceValueType::BOOL, nullptr, FL_(collectorShutdown), DeviceValueUOM::BOOLEAN);
register_device_value(TAG_NONE, &solarPower_, DeviceValueType::ULONG, nullptr, FL_(solarPower), DeviceValueUOM::W);
register_device_value(TAG_NONE, &energyLastHour_, DeviceValueType::ULONG, FL_(div10), FL_(energyLastHour), DeviceValueUOM::WH);
register_device_value(TAG_NONE, &maxFlow_, DeviceValueType::UINT, FL_(div10), FL_(maxFlow), DeviceValueUOM::LMIN, MAKE_CF_CB(set_SM10MaxFlow));
register_device_value(TAG_NONE, &wwMinTemp_, DeviceValueType::UINT, nullptr, FL_(wwMinTemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_wwMinTemp));
register_device_value(TAG_NONE, &solarIsEnabled_, DeviceValueType::BOOL, nullptr, FL_(activated), DeviceValueUOM::BOOLEAN, MAKE_CF_CB(set_solarEnabled));
}
if (flags == EMSdevice::EMS_DEVICE_FLAG_ISM) {
register_device_value(TAG_NONE, &collectorShutdown_, DeviceValueType::BOOL, nullptr, FL_(collectorShutdown), DeviceValueUOM::BOOLEAN);
register_device_value(TAG_NONE, &tankHeated_, DeviceValueType::BOOL, nullptr, FL_(tankHeated), DeviceValueUOM::BOOLEAN);
register_device_value(TAG_NONE, &energyLastHour_, DeviceValueType::ULONG, FL_(div10), FL_(energyLastHour), DeviceValueUOM::WH);
}
if (flags == EMSdevice::EMS_DEVICE_FLAG_SM100) {
register_device_value(TAG_NONE, &solarPumpModulation_, DeviceValueType::UINT, nullptr, FL_(solarPumpModulation), DeviceValueUOM::PERCENT);
register_device_value(TAG_NONE, &solarPumpMinMod_, DeviceValueType::UINT, nullptr, FL_(pumpMinMod), DeviceValueUOM::PERCENT, MAKE_CF_CB(set_PumpMinMod));
register_device_value(
TAG_NONE, &solarPumpTurnonDiff_, DeviceValueType::UINT, nullptr, FL_(solarPumpTurnonDiff), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_TurnonDiff));
register_device_value(
TAG_NONE, &solarPumpTurnoffDiff_, DeviceValueType::UINT, nullptr, FL_(solarPumpTurnoffDiff), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_TurnoffDiff));
register_device_value(TAG_NONE, &tankBottomTemp2_, DeviceValueType::SHORT, FL_(div10), FL_(tank2BottomTemp), DeviceValueUOM::DEGREES);
register_device_value(TAG_NONE, &heatExchangerTemp_, DeviceValueType::SHORT, FL_(div10), FL_(heatExchangerTemp), DeviceValueUOM::DEGREES);
register_device_value(TAG_NONE, &cylinderPumpModulation_, DeviceValueType::UINT, nullptr, FL_(cylinderPumpModulation), DeviceValueUOM::PERCENT);
register_device_value(TAG_NONE, &valveStatus_, DeviceValueType::BOOL, nullptr, FL_(valveStatus), DeviceValueUOM::BOOLEAN);
register_device_value(TAG_NONE, &tankHeated_, DeviceValueType::BOOL, nullptr, FL_(tankHeated), DeviceValueUOM::BOOLEAN);
register_device_value(TAG_NONE, &collectorShutdown_, DeviceValueType::BOOL, nullptr, FL_(collectorShutdown), DeviceValueUOM::BOOLEAN);
register_device_value(
TAG_NONE, &collectorMaxTemp_, DeviceValueType::UINT, nullptr, FL_(collectorMaxTemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_CollectorMaxTemp));
register_device_value(
TAG_NONE, &collectorMinTemp_, DeviceValueType::UINT, nullptr, FL_(collectorMinTemp), DeviceValueUOM::DEGREES, MAKE_CF_CB(set_CollectorMinTemp));
register_device_value(TAG_NONE, &energyLastHour_, DeviceValueType::ULONG, FL_(div10), FL_(energyLastHour), DeviceValueUOM::WH);
register_device_value(TAG_NONE, &energyToday_, DeviceValueType::ULONG, nullptr, FL_(energyToday), DeviceValueUOM::WH);
register_device_value(TAG_NONE, &energyTotal_, DeviceValueType::ULONG, FL_(div10), FL_(energyTotal), DeviceValueUOM::KWH);
register_device_value(
TAG_NONE, &heatTransferSystem_, DeviceValueType::BOOL, nullptr, FL_(heatTransferSystem), DeviceValueUOM::BOOLEAN, MAKE_CF_CB(set_heatTransferSystem));
register_device_value(TAG_NONE, &externalTank_, DeviceValueType::BOOL, nullptr, FL_(externalTank), DeviceValueUOM::BOOLEAN, MAKE_CF_CB(set_externalTank));
register_device_value(
TAG_NONE, &thermalDisinfect_, DeviceValueType::BOOL, nullptr, FL_(thermalDisinfect), DeviceValueUOM::BOOLEAN, MAKE_CF_CB(set_thermalDisinfect));
register_device_value(TAG_NONE, &heatMetering_, DeviceValueType::BOOL, nullptr, FL_(heatMetering), DeviceValueUOM::BOOLEAN, MAKE_CF_CB(set_heatMetering));
register_device_value(TAG_NONE, &solarIsEnabled_, DeviceValueType::BOOL, nullptr, FL_(activated), DeviceValueUOM::BOOLEAN, MAKE_CF_CB(set_solarEnabled));
// telegram 0x035A
register_device_value(
TAG_NONE, &solarPumpMode_, DeviceValueType::ENUM, FL_(enum_solarmode), FL_(solarPumpMode), DeviceValueUOM::NONE, MAKE_CF_CB(set_solarMode));
register_device_value(TAG_NONE,
&solarPumpKick_,
DeviceValueType::BOOL,
nullptr,
FL_(solarPumpKick),
DeviceValueUOM::BOOLEAN,
MAKE_CF_CB(set_solarPumpKick)); // pump kick for vacuum collector, 00=off
register_device_value(TAG_NONE,
&plainWaterMode_,
DeviceValueType::BOOL,
nullptr,
FL_(plainWaterMode),
DeviceValueUOM::BOOLEAN,
MAKE_CF_CB(set_plainWaterMode)); // system does not use antifreeze, 00=off
register_device_value(TAG_NONE,
&doubleMatchFlow_,
DeviceValueType::BOOL,
nullptr,
FL_(doubleMatchFlow),
DeviceValueUOM::BOOLEAN,
MAKE_CF_CB(set_doubleMatchFlow)); // double Match Flow, 00=off
// telegram 0x380
register_device_value(TAG_NONE, &climateZone_, DeviceValueType::UINT, nullptr, FL_(climateZone), DeviceValueUOM::NONE, MAKE_CF_CB(set_climateZone)); // climate zone identifier
register_device_value(TAG_NONE,
&collector1Area_,
DeviceValueType::USHORT,
FL_(div10),
FL_(collector1Area),
DeviceValueUOM::NONE,
MAKE_CF_CB(set_collector1Area)); // Area of collector field 1
register_device_value(TAG_NONE,
&collector1Type_,
DeviceValueType::ENUM,
FL_(enum_collectortype),
FL_(collector1Type),
DeviceValueUOM::NONE,
MAKE_CF_CB(set_collector1Type)); // Type of collector field 1, 01=flat, 02=vacuum
}
}
// publish HA config
bool Solar::publish_ha_config() {
StaticJsonDocument doc;
doc["uniq_id"] = F_(solar);
doc["ic"] = F_(icondevice);
char stat_t[Mqtt::MQTT_TOPIC_MAX_SIZE];
snprintf_P(stat_t, sizeof(stat_t), PSTR("%s/%s"), Mqtt::base().c_str(), Mqtt::tag_to_topic(device_type(), DeviceValueTAG::TAG_NONE).c_str());
doc["stat_t"] = stat_t;
char name_s[40];
snprintf_P(name_s, sizeof(name_s), PSTR("* %s Product ID"), device_type_name().c_str());
doc["name"] = name_s;
doc["val_tpl"] = FJSON("{{value_json.id}}");
JsonObject dev = doc.createNestedObject("dev");
dev["name"] = FJSON("EMS-ESP Solar");
dev["sw"] = EMSESP_APP_VERSION;
dev["mf"] = brand_to_string();
dev["mdl"] = name();
JsonArray ids = dev.createNestedArray("ids");
ids.add("ems-esp-solar");
char topic[Mqtt::MQTT_TOPIC_MAX_SIZE];
snprintf_P(topic, sizeof(topic), PSTR("sensor/%s/solar/config"), Mqtt::base().c_str());
Mqtt::publish_ha(topic, doc.as()); // publish the config payload with retain flag
return true;
}
// SM10Monitor - type 0x96
// Solar(0x30) -> All(0x00), (0x96), data: FF 18 19 0A 02 5A 27 0A 05 2D 1E 0F 64 28 0A
void Solar::process_SM10Config(std::shared_ptr telegram) {
has_update(telegram->read_value(solarIsEnabled_, 0)); // FF on
uint8_t colmax = collectorMaxTemp_ / 10;
has_update(telegram->read_value(colmax, 3));
collectorMaxTemp_ = colmax * 10;
uint8_t colmin = collectorMinTemp_ / 10;
has_update(telegram->read_value(colmin, 4));
collectorMinTemp_ = colmin * 10;
has_update(telegram->read_value(solarPumpMinMod_, 2));
has_update(telegram->read_value(solarPumpTurnonDiff_, 7));
has_update(telegram->read_value(solarPumpTurnoffDiff_, 8));
has_update(telegram->read_value(tankMaxTemp_, 5));
has_update(telegram->read_value(wwMinTemp_, 6));
}
// SM10Monitor - type 0x97
void Solar::process_SM10Monitor(std::shared_ptr telegram) {
uint8_t solarpumpmod = solarPumpModulation_;
has_update(telegram->read_bitvalue(collectorShutdown_, 0, 3));
// has_update(telegram->read_bitvalue(tankHeated_, 0, x)); // tank full, to be determined
has_update(telegram->read_value(collectorTemp_, 2)); // collector temp from SM10, is *10
has_update(telegram->read_value(tankBottomTemp_, 5)); // tank bottom temp from SM10, is *10
has_update(telegram->read_value(solarPumpModulation_, 4)); // modulation solar pump
has_update(telegram->read_bitvalue(solarPump_, 7, 1));
has_update(telegram->read_value(pumpWorkTime_, 8, 3));
// mask out pump-boosts
if (solarpumpmod == 0 && solarPumpModulation_ == 100) {
solarPumpModulation_ = solarPumpMinMod_; // set to minimum
}
if (!Helpers::hasValue(maxFlow_)) {
EMSESP::webSettingsService.read([&](WebSettings & settings) { maxFlow_ = settings.solar_maxflow; });
}
// solar publishes every minute, do not count reads by other devices
if (telegram->dest == 0) {
// water 4.184 J/gK, glycol ~2.6-2.8 J/gK, no aceotrope
// solarPower_ = (collectorTemp_ - tankBottomTemp_) * solarPumpModulation_ * maxFlow_ * 10 / 1434; // water
solarPower_ = (collectorTemp_ - tankBottomTemp_) * solarPumpModulation_ * maxFlow_ * 10 / 1665; //40% glycol@40°C
if (energy.size() >= 60) {
energy.pop_front();
}
energy.push_back(solarPower_);
uint32_t sum = 0;
for (auto e : energy) {
sum += e;
}
energyLastHour_ = sum / 6; // counts in 0.1 Wh
}
}
/*
* process_SM100SystemConfig - type 0x0358 EMS+ - for MS/SM100 and MS/SM200
* e.g. B0 0B FF 00 02 58 FF 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 FF 00 FF 01 00 00
*/
void Solar::process_SM100SystemConfig(std::shared_ptr telegram) {
has_update(telegram->read_value(heatTransferSystem_, 5, 1));
has_update(telegram->read_value(externalTank_, 9, 1));
has_update(telegram->read_value(thermalDisinfect_, 10, 1));
has_update(telegram->read_value(heatMetering_, 14, 1));
has_update(telegram->read_value(solarIsEnabled_, 19, 1));
}
/*
* process_SM100SolarCircuitConfig - type 0x035A EMS+ - for MS/SM100 and MS/SM200
* e.g. B0 0B FF 00 02 5A 64 05 00 58 14 01 01 32 64 00 00 00 5A 0C
*/
void Solar::process_SM100SolarCircuitConfig(std::shared_ptr telegram) {
has_update(telegram->read_value(collectorMaxTemp_, 0, 1));
has_update(telegram->read_value(tankMaxTemp_, 3, 1));
has_update(telegram->read_value(collectorMinTemp_, 4, 1));
has_update(telegram->read_value(solarPumpMode_, 5, 1));
has_update(telegram->read_value(solarPumpMinMod_, 6, 1));
has_update(telegram->read_value(solarPumpTurnoffDiff_, 7, 1));
has_update(telegram->read_value(solarPumpTurnonDiff_, 8, 1));
has_update(telegram->read_value(solarPumpKick_, 9, 1));
has_update(telegram->read_value(plainWaterMode_, 10, 1));
has_update(telegram->read_value(doubleMatchFlow_, 11, 1));
}
/* process_SM100ParamCfg - type 0xF9 EMS 1.0
* This telegram is used to inquire the min, default, max, and current values of a value that is usually read and written with another telegram ID
* The CS200 uses this method extensively to find out which values may be set in the SM100
* e.g. B0 10 F9 00 FF 02 5A 03 17 00 00 00 14 00 00 00 3C 00 00 00 5A 00 00 00 59 29 - requested with 90 B0 F9 00 11 FF 02 5A 03 AF
* byte 0 = 0xFF
* byte 1-2 = telegram ID used to write this value
* byte 3 = offset in telegram used to write this value
* byte 4 = unknown
* bytes 5..8 = minimum value
* bytes 9..12 = default value
* bytes 13..16 = maximum value
* bytes 17..20 = current value
*
* e.g. B0 0B F9 00 00 02 5A 00 00 6E
*/
void Solar::process_SM100ParamCfg(std::shared_ptr telegram) {
uint16_t t_id;
uint8_t of;
int32_t min, def, max, cur;
has_update(telegram->read_value(t_id, 1));
has_update(telegram->read_value(of, 3));
has_update(telegram->read_value(min, 5));
has_update(telegram->read_value(def, 9));
has_update(telegram->read_value(max, 13));
has_update(telegram->read_value(cur, 17));
// LOG_DEBUG(F("SM100ParamCfg param=0x%04X, offset=%d, min=%d, default=%d, max=%d, current=%d"), t_id, of, min, def, max, cur));
}
/*
* SM100Monitor - type 0x0362 EMS+ - for MS/SM100 and MS/SM200
* e.g. B0 0B FF 00 02 62 00 77 01 D4 80 00 80 00 80 00 80 00 80 00 80 00 80 00 80 00 00 F9 80 00 80 9E - for heat exchanger temp
* e.g, 30 00 FF 00 02 62 01 AC
* 30 00 FF 18 02 62 80 00
* 30 00 FF 00 02 62 01 A1 - for tank bottom temps
* bytes 0+1 = TS1 Temperature sensor for collector
* bytes 2+3 = TS2 Temperature sensor 1 cylinder, bottom
* bytes 16+17 = TS5 Temperature sensor 2 cylinder, bottom, or swimming pool
* bytes 20+21 = TS6 Temperature sensor external heat exchanger
*/
void Solar::process_SM100Monitor(std::shared_ptr telegram) {
has_update(telegram->read_value(collectorTemp_, 0)); // is *10 - TS1: Temperature sensor for collector array 1
has_update(telegram->read_value(tankBottomTemp_, 2)); // is *10 - TS2: Temperature sensor 1 cylinder, bottom
has_update(telegram->read_value(tankBottomTemp2_, 16)); // is *10 - TS5: Temperature sensor 2 cylinder, bottom, or swimming pool
has_update(telegram->read_value(heatExchangerTemp_, 20)); // is *10 - TS6: Heat exchanger temperature sensor
}
// SM100wwTemperatur - 0x07D6
// Solar Module(0x2A) -> (0x00), (0x7D6), data: 01 C1 00 00 02 5B 01 AF 01 AD 80 00 01 90
void Solar::process_SM100wwTemperature(std::shared_ptr telegram) {
has_update(telegram->read_value(wwTemp_1_, 0));
has_update(telegram->read_value(wwTemp_3_, 4));
has_update(telegram->read_value(wwTemp_4_, 6));
has_update(telegram->read_value(wwTemp_5_, 8));
has_update(telegram->read_value(wwTemp_7_, 12));
}
// SM100wwStatus - 0x07AA
// Solar Module(0x2A) -> (0x00), (0x7AA), data: 64 00 04 00 03 00 28 01 0F
void Solar::process_SM100wwStatus(std::shared_ptr telegram) {
has_update(telegram->read_value(wwPump_, 0));
}
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wunused-parameter"
// SM100Monitor2 - 0x0363
// e.g. B0 00 FF 00 02 63 80 00 80 00 00 00 80 00 80 00 80 00 00 80 00 5A
void Solar::process_SM100Monitor2(std::shared_ptr telegram) {
// not implemented yet
}
// SM100wwCommand - 0x07AB
// Thermostat(0x10) -> Solar Module(0x2A), (0x7AB), data: 01 00 01
void Solar::process_SM100wwCommand(std::shared_ptr telegram) {
// not implemented yet
}
#pragma GCC diagnostic pop
// SM100Config - 0x0366
// e.g. B0 00 FF 00 02 66 01 62 00 13 40 14
void Solar::process_SM100Config(std::shared_ptr telegram) {
has_update(telegram->read_value(availabilityFlag_, 0));
has_update(telegram->read_value(configFlag_, 1));
has_update(telegram->read_value(userFlag_, 2));
}
/*
* SM100Status - type 0x0364 EMS+ for pump modulations - for MS/SM100 and MS/SM200
- PS1: Solar circuit pump for collector array 1
- PS5: Cylinder primary pump when using an external heat exchanger
* e.g. 30 00 FF 09 02 64 64 = 100%
*/
void Solar::process_SM100Status(std::shared_ptr telegram) {
uint8_t solarpumpmod = solarPumpModulation_;
uint8_t cylinderpumpmod = cylinderPumpModulation_;
has_update(telegram->read_value(cylinderPumpModulation_, 8));
has_update(telegram->read_value(solarPumpModulation_, 9));
if (solarpumpmod == 0 && solarPumpModulation_ == 100) { // mask out boosts
solarPumpModulation_ = solarPumpMinMod_; // set to minimum
}
if (cylinderpumpmod == 0 && cylinderPumpModulation_ == 100) { // mask out boosts
cylinderPumpModulation_ = solarPumpMinMod_; // set to minimum
}
has_update(telegram->read_bitvalue(tankHeated_, 3, 1)); // issue #422
has_update(telegram->read_bitvalue(collectorShutdown_, 3, 0)); // collector shutdown
}
/*
* SM100Status2 - type 0x036A EMS+ for pump on/off at offset 0x0A - for SM100 and SM200
* e.g. B0 00 FF 00 02 6A 03 03 03 03 01 03 03 03 03 03 01 03
* byte 4 = VS2 3-way valve for cylinder 2 : test=01, on=04 and off=03
* byte 10 = PS1 Solar circuit pump for collector array 1: test=b0001(1), on=b0100(4) and off=b0011(3)
*/
void Solar::process_SM100Status2(std::shared_ptr telegram) {
has_update(telegram->read_bitvalue(valveStatus_, 4, 2)); // on if bit 2 set
has_update(telegram->read_bitvalue(solarPump_, 10, 2)); // on if bit 2 set
}
/*
* SM100CollectorConfig - type 0x0380 EMS+ - for SM100 and SM200
* e.g. B0 0B FF 00 02 80 50 64 00 00 29 01 00 00 01
*/
void Solar::process_SM100CollectorConfig(std::shared_ptr telegram) {
has_update(telegram->read_value(climateZone_, 0, 1));
has_update(telegram->read_value(collector1Area_, 3, 2));
has_update(telegram->read_value(collector1Type_, 5, 1));
}
/*
* SM100Energy - type 0x038E EMS+ for energy readings
* e.g. 30 00 FF 00 02 8E 00 00 00 00 00 00 06 C5 00 00 76 35
*/
void Solar::process_SM100Energy(std::shared_ptr telegram) {
has_update(telegram->read_value(energyLastHour_, 0)); // last hour / 10 in Wh
has_update(telegram->read_value(energyToday_, 4)); // todays in Wh
has_update(telegram->read_value(energyTotal_, 8)); // total / 10 in kWh
}
/*
* SM100Time - type 0x0391 EMS+ for pump working time
*/
void Solar::process_SM100Time(std::shared_ptr telegram) {
has_update(telegram->read_value(pumpWorkTime_, 1, 3));
}
/*
* Junkers ISM1 Solar Module - type 0x0103 EMS+ for energy readings
* e.g. B0 00 FF 00 00 03 32 00 00 00 00 13 00 D6 00 00 00 FB D0 F0
*/
void Solar::process_ISM1StatusMessage(std::shared_ptr telegram) {
has_update(telegram->read_value(collectorTemp_, 4)); // Collector Temperature
has_update(telegram->read_value(tankBottomTemp_, 6)); // Temperature Bottom of Solar Boiler tank
uint16_t Wh = energyLastHour_ / 10;
has_update(telegram->read_value(Wh, 2)); // Solar Energy produced in last hour only ushort, is not * 10
energyLastHour_ = Wh * 10; // set to *10
has_update(telegram->read_bitvalue(solarPump_, 8, 0)); // PS1 Solar pump on (1) or off (0)
has_update(telegram->read_value(pumpWorkTime_, 10, 3)); // force to 3 bytes
has_update(telegram->read_bitvalue(collectorShutdown_, 9, 0)); // collector shutdown on/off
has_update(telegram->read_bitvalue(tankHeated_, 9, 2)); // tank full
}
/*
* Junkers ISM1 Solar Module - type 0x0101 EMS+ for setting values
*/
void Solar::process_ISM1Set(std::shared_ptr telegram) {
has_update(telegram->read_value(tankMaxTemp_, 6));
}
/*
* Settings
*/
// collector shutdown temperature
bool Solar::set_CollectorMaxTemp(const char * value, const int8_t id) {
int temperature;
if (!Helpers::value2number(value, temperature)) {
return false;
}
if (flags() == EMSdevice::EMS_DEVICE_FLAG_SM10) {
write_command(0x96, 3, (uint8_t)temperature / 10, 0x96);
} else {
write_command(0x35A, 0, (uint8_t)temperature, 0x35A);
}
return true;
}
// collector shutdown temperature
bool Solar::set_CollectorMinTemp(const char * value, const int8_t id) {
int temperature;
if (!Helpers::value2number(value, temperature)) {
return false;
}
if (flags() == EMSdevice::EMS_DEVICE_FLAG_SM10) {
write_command(0x96, 4, (uint8_t)temperature / 10, 0x96);
} else {
write_command(0x35A, 4, (uint8_t)temperature, 0x35A);
}
return true;
}
bool Solar::set_TankMaxTemp(const char * value, const int8_t id) {
int temperature;
if (!Helpers::value2number(value, temperature)) {
return false;
}
if (flags() == EMSdevice::EMS_DEVICE_FLAG_SM10) {
write_command(0x96, 5, (uint8_t)temperature, 0x96);
} else if (flags() == EMSdevice::EMS_DEVICE_FLAG_ISM) {
write_command(0x101, 6, (uint8_t)temperature, 0x101);
} else {
write_command(0x35A, 3, (uint8_t)temperature, 0x35A);
}
return true;
}
bool Solar::set_PumpMinMod(const char * value, const int8_t id) {
int modulation;
if (!Helpers::value2number(value, modulation)) {
return false;
}
write_command(0x96, 2, (uint8_t)modulation, 0x96);
return true;
}
bool Solar::set_wwMinTemp(const char * value, const int8_t id) {
int temperature;
if (!Helpers::value2number(value, temperature)) {
return false;
}
write_command(0x96, 6, (uint8_t)temperature, 0x96);
return true;
}
bool Solar::set_TurnoffDiff(const char * value, const int8_t id) {
int temperature;
if (!Helpers::value2number(value, temperature)) {
return false;
}
if (flags() == EMSdevice::EMS_DEVICE_FLAG_SM10) {
write_command(0x96, 8, (uint8_t)temperature, 0x96);
} else {
write_command(0x35A, 7, (uint8_t)temperature, 0x35A);
}
return true;
}
bool Solar::set_TurnonDiff(const char * value, const int8_t id) {
int temperature;
if (!Helpers::value2number(value, temperature)) {
return false;
}
if (flags() == EMSdevice::EMS_DEVICE_FLAG_SM10) {
write_command(0x96, 7, (uint8_t)temperature, 0x96);
} else {
write_command(0x35A, 8, (uint8_t)temperature, 0x35A);
}
return true;
}
// external value to calculate energy
bool Solar::set_SM10MaxFlow(const char * value, const int8_t id) {
float flow;
if (!Helpers::value2float(value, flow)) {
return false;
}
maxFlow_ = (flow * 10);
EMSESP::webSettingsService.update(
[&](WebSettings & settings) {
settings.solar_maxflow = maxFlow_;
return StateUpdateResult::CHANGED;
},
"local");
return true;
}
bool Solar::set_heatTransferSystem(const char * value, const int8_t id) {
bool v = false;
if (!Helpers::value2bool(value, v)) {
return false;
}
write_command(0x358, 5, v ? 0x01 : 0x00, 0x358);
return true;
}
bool Solar::set_externalTank(const char * value, const int8_t id) {
bool v = false;
if (!Helpers::value2bool(value, v)) {
return false;
}
write_command(0x358, 9, v ? 0x01 : 0x00, 0x358);
return true;
}
bool Solar::set_thermalDisinfect(const char * value, const int8_t id) {
bool v = false;
if (!Helpers::value2bool(value, v)) {
return false;
}
write_command(0x358, 10, v ? 0x01 : 0x00, 0x358);
return true;
}
bool Solar::set_heatMetering(const char * value, const int8_t id) {
bool v = false;
if (!Helpers::value2bool(value, v)) {
return false;
}
write_command(0x358, 14, v ? 0x01 : 0x00, 0x358);
return true;
}
bool Solar::set_solarEnabled(const char * value, const int8_t id) {
bool v = false;
if (!Helpers::value2bool(value, v)) {
return false;
}
if (flags() == EMSdevice::EMS_DEVICE_FLAG_SM10) {
write_command(0x96, 0, v ? 0xFF : 0x00, 0x96);
} else {
write_command(0x358, 19, v ? 0x01 : 0x00, 0x358);
}
return true;
}
bool Solar::set_solarMode(const char * value, const int8_t id) {
uint8_t num;
if (!Helpers::value2enum(value, num, FL_(enum_solarmode))) {
return false;
}
write_command(0x35A, 5, num, 0x35A);
return true;
}
bool Solar::set_solarPumpKick(const char * value, const int8_t id) {
bool v = false;
if (!Helpers::value2bool(value, v)) {
return false;
}
write_command(0x35A, 9, v ? 0x01 : 0x00, 0x35A);
return true;
}
bool Solar::set_plainWaterMode(const char * value, const int8_t id) {
bool v = false;
if (!Helpers::value2bool(value, v)) {
return false;
}
write_command(0x35A, 10, v ? 0x01 : 0x00, 0x35A);
return true;
}
bool Solar::set_doubleMatchFlow(const char * value, const int8_t id) {
bool v = false;
if (!Helpers::value2bool(value, v)) {
return false;
}
write_command(0x35A, 11, v ? 0x01 : 0x00, 0x35A);
return true;
}
bool Solar::set_climateZone(const char * value, const int8_t id) {
int v = 0;
if (!Helpers::value2number(value, v)) {
return false;
}
write_command(0x380, 0, v, 0x380);
return true;
}
bool Solar::set_collector1Area(const char * value, const int8_t id) {
float v = 0;
if (!Helpers::value2float(value, v)) {
return false;
}
write_command(0x380, 3, (uint16_t)(v * 10), 0x380);
return true;
}
bool Solar::set_collector1Type(const char * value, const int8_t id) {
uint8_t num;
if (!Helpers::value2enum(value, num, FL_(enum_collectortype))) {
return false;
}
write_command(0x380, 5, num, 0x380);
return true;
}
} // namespace emsesp