NEWS
ecoflow-connector-Script zur dynamischen Leistungsanpassung
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11:11:10.707 info javascript.0 (29925) script.js.Ecoflow2: Fehler beim Decodieren:Cannot convert undefined or null to object 11:11:10.707 info javascript.0 (29925) script.js.Ecoflow2: hexString: "0a330a08a801a302b001e21610351820200128014014480150085801800103880103ca0110485735315a4f483453463554353531300a360a0b78048801f4b12180028d3e103518202001280140144804500b5801800103880103ca0110485735315a4f48345346355435353130" 11:11:10.708 info javascript.0 (29925) script.js.Ecoflow2: buffer: 3 ����5 (@HPX���HW51ZOH4SF5T5510 6 x���!��>5 (@HPX���HW51ZOH4SF5T5510 11:11:10.708 info javascript.0 (29925) script.js.Ecoflow2: protoSource2: syntax = "proto3"; message Message { repeated Header header = 1; bytes payload = 2; } message Header { bytes pdata = 1 [proto3_optional = true]; int32 src = 2 [proto3_optional = true]; int32 dest = 3 [proto3_optional = true]; int32 d_src = 4 [proto3_optional = true]; int32 d_dest = 5 [proto3_optional = true]; int32 enc_type = 6 [proto3_optional = true]; int32 check_type = 7 [proto3_optional = true]; int32 cmd_func = 8 [proto3_optional = true]; int32 cmd_id = 9 [proto3_optional = true]; int32 data_len = 10 [proto3_optional = true]; int32 need_ack = 11 [proto3_optional = true]; int32 is_ack = 12 [proto3_optional = true]; int32 seq = 14 [proto3_optional = true]; int32 product_id = 15 [proto3_optional = true]; int32 version = 16 [proto3_optional = true]; int32 payload_ver = 17 [proto3_optional = true]; int32 time_snap = 18 [proto3_optional = true]; int32 is_rw_cmd = 19 [proto3_optional = true]; int32 is_queue = 20 [proto3_optional = true]; int32 ack_type = 21 [proto3_optional = true]; string code = 22 [proto3_optional = true]; string from = 23 [proto3_optional = true]; string module_sn = 24 [proto3_optional = true]; string device_sn = 25 [proto3_optional = true]; } message InverterHeartbeat { optional uint32 inv_err_code = 1; optional uint32 inv_warn_code = 3; optional uint32 pv1_err_code = 2; optional uint32 pv1_warn_code = 4; optional uint32 pv2_err_code = 5; optional uint32 pv2_warning_code = 6; optional uint32 bat_err_code = 7; optional uint32 bat_warning_code = 8; optional uint32 llc_err_code = 9; optional uint32 llc_warning_code = 10; optional uint32 pv1_statue = 11; optional uint32 pv2_statue = 12; optional uint32 bat_statue = 13; optional uint32 llc_statue = 14; optional uint32 inv_statue = 15; optional int32 pv1_input_volt = 16; optional int32 pv1_op_volt = 17; optional int32 pv1_input_cur = 18; optional int32 pv1_input_watts = 19; optional int32 pv1_temp = 20; optional int32 pv2_input_volt = 21; optional int32 pv2_op_volt = 22; optional int32 pv2_input_cur = 23; optional int32 pv2_input_watts = 24; optional int32 pv2_temp = 25; optional int32 bat_input_volt = 26; optional int32 bat_op_volt = 27; optional int32 bat_input_cur = 28; optional int32 bat_input_watts = 29; optional int32 bat_temp = 30; optional uint32 bat_soc = 31; optional int32 llc_input_volt = 32; optional int32 llc_op_volt = 33; optional int32 llc_temp = 34; optional int32 inv_input_volt = 35; optional int32 inv_op_volt = 36; optional int32 inv_output_cur = 37; optional int32 inv_output_watts = 38; optional int32 inv_temp = 39; optional int32 inv_freq = 40; optional int32 inv_dc_cur = 41; optional int32 bp_type = 42; optional int32 inv_relay_status = 43; optional int32 pv1_relay_status = 44; optional int32 pv2_relay_status = 45; optional uint32 install_country = 46; optional uint32 install_town = 47; optional uint32 permanent_watts = 48; optional uint32 dynamic_watts = 49; optional uint32 supply_priority = 50; optional uint32 lower_limit = 51; optional uint32 upper_limit = 52; optional uint32 inv_on_off = 53; optional uint32 wireless_err_code = 54; optional uint32 wireless_warn_code = 55; optional uint32 inv_brightness = 56; optional uint32 heartbeat_frequency = 57; optional uint32 rated_power = 58; } message InverterHeartbeat2 { optional uint32 X_Unknown_1 = 1; optional uint32 X_Unknown_2 = 2; optional uint32 X_Unknown_3 = 3; optional uint32 X_Unknown_4 = 4; optional uint32 X_Unknown_5 = 5; optional uint32 X_Unknown_6 = 6; optional uint32 X_Unknown_7 = 7; optional uint32 X_Unknown_8 = 8; optional uint32 X_Unknown_9 = 9; optional uint32 X_Unknown_10 = 10; optional uint32 X_Unknown_11 = 11; optional uint32 X_Unknown_12 = 12; optional uint32 X_Unknown_13 = 13; optional uint32 X_Unknown_14 = 14; optional uint32 X_Unknown_15 = 15; optional int32 X_Unknown_16 = 16; optional uint32 X_Unknown_17 = 17; optional uint32 X_Unknown_18 = 18; optional uint32 X_Unknown_19 = 19; optional uint32 X_Unknown_20 = 20; optional uint32 X_Unknown_21 = 21; optional uint32 X_Unknown_22 = 22; optional uint32 X_Unknown_23 = 23; optional uint32 X_Unknown_24 = 24; optional uint32 X_Unknown_25 = 25; optional uint32 X_Unknown_26 = 26; optional uint32 X_Unknown_27 = 27; optional uint32 X_Unknown_28 = 28; optional uint32 X_Unknown_29 = 29; optional uint32 X_Unknown_30 = 30; optional uint32 X_Unknown_31 = 31; optional int32 X_Unknown_32 = 32; optional uint32 X_Unknown_33 = 33; optional uint32 X_Unknown_34 = 34; optional uint32 X_Unknown_35 = 35; optional uint32 X_Unknown_36 = 36; optional uint32 X_Unknown_37 = 37; optional uint32 X_Unknown_38 = 38; optional uint32 X_Unknown_39 = 39; optional uint32 X_Unknown_40 = 40; optional uint32 X_Unknown_41 = 41; optional int32 X_Unknown_42 = 42; optional uint32 X_Unknown_43 = 43; optional uint32 X_Unknown_44 = 44; optional uint32 X_Unknown_45 = 45; optional uint32 X_Unknown_46 = 46; optional uint32 X_Unknown_47 = 47; optional int32 X_Unknown_48 = 48; optional uint32 X_Unknown_49 = 49; optional int32 X_Unknown_50 = 50; optional uint32 X_Unknown_51 = 51; optional uint32 X_Unknown_52 = 52; optional uint32 X_Unknown_53 = 53; optional uint32 X_Unknown_54 = 54; optional uint32 X_Unknown_55 = 55; optional uint32 X_Unknown_56 = 56; optional uint32 X_Unknown_57 = 57; optional uint32 X_Unknown_58 = 58; optional uint32 X_Unknown_59 = 59; optional uint32 X_Unknown_60 = 60; optional uint32 X_Unknown_61 = 61; optional uint32 X_Unknown_62 = 62; optional uint32 X_Unknown_63 = 63; optional uint32 X_Unknown_64 = 64; optional uint32 X_Unknown_65 = 65; optional uint32 X_Unknown_66 = 66; optional uint32 X_Unknown_67 = 67; optional uint32 X_Unknown_68 = 68; optional uint32 X_Unknown_69 = 69; optional uint32 X_Unknown_70 = 70; } message setMessage { setHeader header = 1; } message setHeader { setValue pdata = 1 [proto3_optional = true]; int32 src = 2 [proto3_optional = true]; int32 dest = 3 [proto3_optional = true]; int32 d_src = 4 [proto3_optional = true]; int32 d_dest = 5 [proto3_optional = true]; int32 enc_type = 6 [proto3_optional = true]; int32 check_type = 7 [proto3_optional = true]; int32 cmd_func = 8 [proto3_optional = true]; int32 cmd_id = 9 [proto3_optional = true]; int32 data_len = 10 [proto3_optional = true]; int32 need_ack = 11 [proto3_optional = true]; int32 is_ack = 12 [proto3_optional = true]; int32 seq = 14 [proto3_optional = true]; int32 product_id = 15 [proto3_optional = true]; int32 version = 16 [proto3_optional = true]; int32 payload_ver = 17 [proto3_optional = true]; int32 time_snap = 18 [proto3_optional = true]; int32 is_rw_cmd = 19 [proto3_optional = true]; int32 is_queue = 20 [proto3_optional = true]; int32 ack_type = 21 [proto3_optional = true]; string code = 22 [proto3_optional = true]; string from = 23 [proto3_optional = true]; string module_sn = 24 [proto3_optional = true]; string device_sn = 25 [proto3_optional = true]; } message setValue { optional int32 value = 1; } message permanent_watts_pack { optional int32 permanent_watts = 1; } message supply_priority_pack { optional int32 supply_priority = 1; } message bat_lower_pack { optional int32 lower_limit = 1; } message bat_upper_pack { optional int32 upper_limit = 1; } message PowerItem { optional uint32 timestamp = 1; optional sint32 timezone = 2; optional uint32 inv_to_grid_power = 3; optional uint32 inv_to_plug_power = 4; optional int32 battery_power = 5; optional uint32 pv1_output_power = 6; optional uint32 pv2_output_power = 7; } message PowerPack { optional uint32 sys_seq = 1; repeated PowerItem sys_power_stream = 2; } message PowerAckPack { optional uint32 sys_seq = 1; } message node_massage { optional string sn = 1; optional bytes mac = 2; } message mesh_child_node_info { optional uint32 topology_type = 1; optional uint32 mesh_protocol = 2; optional uint32 max_sub_device_num = 3; optional bytes parent_mac_id = 4; optional bytes mesh_id = 5; repeated node_massage sub_device_list = 6; } message EnergyItem { optional uint32 timestamp = 1; optional uint32 watth_type = 2; repeated uint32 watth = 3; } message EnergyTotalReport { optional uint32 watth_seq = 1; optional EnergyItem watth_item = 2; } message BatchEnergyTotalReport { optional uint32 watth_seq = 1; repeated EnergyItem watth_item = 2; } message EnergyTotalReportAck { optional uint32 result = 1; optional uint32 watth_seq = 2; optional uint32 watth_type = 3; } message EventRecordItem { optional uint32 timestamp = 1; optional uint32 sys_ms = 2; optional uint32 event_no = 3; repeated float event_detail = 4; } message EventRecordReport { optional uint32 event_ver = 1; optional uint32 event_seq = 2; repeated EventRecordItem event_item = 3; } message EventInfoReportAck { optional uint32 result = 1; optional uint32 event_seq = 2; optional uint32 event_item_num = 3; } message ProductNameSet { optional string name = 1; } message ProductNameSetAck { optional uint32 result = 1; } message ProductNameGet {} message ProductNameGetAck { optional string name = 3; } message RTCTimeGet {} message RTCTimeGetAck { optional uint32 timestamp = 1; optional int32 timezone = 2; } message RTCTimeSet { optional uint32 timestamp = 1; optional int32 timezone = 2 [(nanopb).default = 0]; } message RTCTimeSetAck { optional uint32 result = 1; } message country_town_message { optional uint32 country = 1; optional uint32 town = 2; } message time_task_config { optional uint32 task_index = 1; optional time_range_strategy time_range = 2; optional uint32 type = 3; } message time_task_delet { optional uint32 task_index = 1; } message time_task_config_post { optional time_task_config task1 = 1; optional time_task_config task2 = 2; optional time_task_config task3 = 3; optional time_task_config task4 = 4; optional time_task_config task5 = 5; optional time_task_config task6 = 6; optional time_task_config task7 = 7; optional time_task_config task8 = 8; optional time_task_config task9 = 9; optional time_task_config task10 = 10; optional time_task_config task11 = 11; } message time_task_config_ack { optional uint32 task_info = 1; } message rtc_data { optional int32 week = 1 [(nanopb).default = 0]; optional int32 sec = 2 [(nanopb).default = 0]; optional int32 min = 3 [(nanopb).default = 0]; optional int32 hour = 4 [(nanopb).default = 0]; optional int32 day = 5 [(nanopb).default = 0]; optional int32 month = 6 [(nanopb).default = 0]; optional int32 year = 7 [(nanopb).default = 0]; } message time_range_strategy { optional bool is_config = 1; optional bool is_enable = 2; optional int32 time_mode = 3; optional int32 time_data = 4; optional rtc_data start_time = 5; optional rtc_data stop_time = 6; } message plug_ack_message { optional uint32 ack = 1; } message plug_heartbeat_pack { optional uint32 err_code = 1 [(nanopb).default = 0]; optional uint32 warn_code = 2 [(nanopb).default = 0]; optional uint32 country = 3 [(nanopb).default = 0]; optional uint32 town = 4 [(nanopb).default = 0]; optional int32 max_cur = 5 [(nanopb).default = 0]; optional int32 temp = 6 [(nanopb).default = 0]; optional int32 freq = 7 [(nanopb).default = 0]; optional int32 current = 8 [(nanopb).default = 0]; optional int32 volt = 9 [(nanopb).default = 0]; optional int32 watts = 10 [(nanopb).default = 0]; optional bool switch = 11 [(nanopb).default = false]; optional int32 brightness = 12 [(nanopb).default = 0]; optional int32 max_watts = 13 [(nanopb).default = 0]; optional int32 heartbeat_frequency = 14 [(nanopb).default = 0]; optional int32 mesh_enable = 15 [(nanopb).default = 0]; } message plug_switch_message { optional uint32 plug_switch = 1; } message brightness_pack { optional int32 brightness = 1 [(nanopb).default = 0]; } message max_cur_pack { optional int32 max_cur = 1 [(nanopb).default = 0]; } message max_watts_pack { optional int32 max_watts = 1 [(nanopb).default = 0]; } message mesh_ctrl_pack { optional uint32 mesh_enable = 1 [(nanopb).default = 0]; } message ret_pack { optional bool ret_sta = 1 [(nanopb).default = false]; } enum CmdFunction { Unknown = 0; PermanentWattsPack = 129; SupplyPriorityPack = 130; }
js.controller: 4.0.24
javascript: v6.1.4EDIT:
Powerstream: V1.0.0.154 V1.1.3.31 (WLAN) -
11:11:55.134 info javascript.0 (1121881) script.js.common.ecoFlow_PowerStream: protoSource2: syntax = "proto3"; message Message { repeated Header header = 1; bytes payload = 2; } message Header { bytes pdata = 1 [proto3_optional = true]; int32 src = 2 [proto3_optional = true]; int32 dest = 3 [proto3_optional = true]; int32 d_src = 4 [proto3_optional = true]; int32 d_dest = 5 [proto3_optional = true]; int32 enc_type = 6 [proto3_optional = true]; int32 check_type = 7 [proto3_optional = true]; int32 cmd_func = 8 [proto3_optional = true]; int32 cmd_id = 9 [proto3_optional = true]; int32 data_len = 10 [proto3_optional = true]; int32 need_ack = 11 [proto3_optional = true]; int32 is_ack = 12 [proto3_optional = true]; int32 seq = 14 [proto3_optional = true]; int32 product_id = 15 [proto3_optional = true]; int32 version = 16 [proto3_optional = true]; int32 payload_ver = 17 [proto3_optional = true]; int32 time_snap = 18 [proto3_optional = true]; int32 is_rw_cmd = 19 [proto3_optional = true]; int32 is_queue = 20 [proto3_optional = true]; int32 ack_type = 21 [proto3_optional = true]; string code = 22 [proto3_optional = true]; string from = 23 [proto3_optional = true]; string module_sn = 24 [proto3_optional = true]; string device_sn = 25 [proto3_optional = true]; } message InverterHeartbeat { optional uint32 inv_err_code = 1; optional uint32 inv_warn_code = 3; optional uint32 pv1_err_code = 2; optional uint32 pv1_warn_code = 4; optional uint32 pv2_err_code = 5; optional uint32 pv2_warning_code = 6; optional uint32 bat_err_code = 7; optional uint32 bat_warning_code = 8; optional uint32 llc_err_code = 9; optional uint32 llc_warning_code = 10; optional uint32 pv1_statue = 11; optional uint32 pv2_statue = 12; optional uint32 bat_statue = 13; optional uint32 llc_statue = 14; optional uint32 inv_statue = 15; optional int32 pv1_input_volt = 16; optional int32 pv1_op_volt = 17; optional int32 pv1_input_cur = 18; optional int32 pv1_input_watts = 19; optional int32 pv1_temp = 20; optional int32 pv2_input_volt = 21; optional int32 pv2_op_volt = 22; optional int32 pv2_input_cur = 23; optional int32 pv2_input_watts = 24; optional int32 pv2_temp = 25; optional int32 bat_input_volt = 26; optional int32 bat_op_volt = 27; optional int32 bat_input_cur = 28; optional int32 bat_input_watts = 29; optional int32 bat_temp = 30; optional uint32 bat_soc = 31; optional int32 llc_input_volt = 32; optional int32 llc_op_volt = 33; optional int32 llc_temp = 34; optional int32 inv_input_volt = 35; optional int32 inv_op_volt = 36; optional int32 inv_output_cur = 37; optional int32 inv_output_watts = 38; optional int32 inv_temp = 39; optional int32 inv_freq = 40; optional int32 inv_dc_cur = 41; optional int32 bp_type = 42; optional int32 inv_relay_status = 43; optional int32 pv1_relay_status = 44; optional int32 pv2_relay_status = 45; optional uint32 install_country = 46; optional uint32 install_town = 47; optional uint32 permanent_watts = 48; optional uint32 dynamic_watts = 49; optional uint32 supply_priority = 50; optional uint32 lower_limit = 51; optional uint32 upper_limit = 52; optional uint32 inv_on_off = 53; optional uint32 wireless_err_code = 54; optional uint32 wireless_warn_code = 55; optional uint32 inv_brightness = 56; optional uint32 heartbeat_frequency = 57; optional uint32 rated_power = 58; } message InverterHeartbeat2 { optional uint32 X_Unknown_1 = 1; optional uint32 X_Unknown_2 = 2; optional uint32 X_Unknown_3 = 3; optional uint32 X_Unknown_4 = 4; optional uint32 X_Unknown_5 = 5; optional uint32 X_Unknown_6 = 6; optional uint32 X_Unknown_7 = 7; optional uint32 X_Unknown_8 = 8; optional uint32 X_Unknown_9 = 9; optional uint32 X_Unknown_10 = 10; optional uint32 X_Unknown_11 = 11; optional uint32 X_Unknown_12 = 12; optional uint32 X_Unknown_13 = 13; optional uint32 X_Unknown_14 = 14; optional uint32 X_Unknown_15 = 15; optional int32 X_Unknown_16 = 16; optional uint32 X_Unknown_17 = 17; optional uint32 X_Unknown_18 = 18; optional uint32 X_Unknown_19 = 19; optional uint32 X_Unknown_20 = 20; optional uint32 X_Unknown_21 = 21; optional uint32 X_Unknown_22 = 22; optional uint32 X_Unknown_23 = 23; optional uint32 X_Unknown_24 = 24; optional uint32 X_Unknown_25 = 25; optional uint32 X_Unknown_26 = 26; optional uint32 X_Unknown_27 = 27; optional uint32 X_Unknown_28 = 28; optional uint32 X_Unknown_29 = 29; optional uint32 X_Unknown_30 = 30; optional uint32 X_Unknown_31 = 31; optional int32 X_Unknown_32 = 32; optional uint32 X_Unknown_33 = 33; optional uint32 X_Unknown_34 = 34; optional uint32 X_Unknown_35 = 35; optional uint32 X_Unknown_36 = 36; optional uint32 X_Unknown_37 = 37; optional uint32 X_Unknown_38 = 38; optional uint32 X_Unknown_39 = 39; optional uint32 X_Unknown_40 = 40; optional uint32 X_Unknown_41 = 41; optional int32 X_Unknown_42 = 42; optional uint32 X_Unknown_43 = 43; optional uint32 X_Unknown_44 = 44; optional uint32 X_Unknown_45 = 45; optional uint32 X_Unknown_46 = 46; optional uint32 X_Unknown_47 = 47; optional int32 X_Unknown_48 = 48; optional uint32 X_Unknown_49 = 49; optional int32 X_Unknown_50 = 50; optional uint32 X_Unknown_51 = 51; optional uint32 X_Unknown_52 = 52; optional uint32 X_Unknown_53 = 53; optional uint32 X_Unknown_54 = 54; optional uint32 X_Unknown_55 = 55; optional uint32 X_Unknown_56 = 56; optional uint32 X_Unknown_57 = 57; optional uint32 X_Unknown_58 = 58; optional uint32 X_Unknown_59 = 59; optional uint32 X_Unknown_60 = 60; optional uint32 X_Unknown_61 = 61; optional uint32 X_Unknown_62 = 62; optional uint32 X_Unknown_63 = 63; optional uint32 X_Unknown_64 = 64; optional uint32 X_Unknown_65 = 65; optional uint32 X_Unknown_66 = 66; optional uint32 X_Unknown_67 = 67; optional uint32 X_Unknown_68 = 68; optional uint32 X_Unknown_69 = 69; optional uint32 X_Unknown_70 = 70; } message setMessage { setHeader header = 1; } message setHeader { setValue pdata = 1 [proto3_optional = true]; int32 src = 2 [proto3_optional = true]; int32 dest = 3 [proto3_optional = true]; int32 d_src = 4 [proto3_optional = true]; int32 d_dest = 5 [proto3_optional = true]; int32 enc_type = 6 [proto3_optional = true]; int32 check_type = 7 [proto3_optional = true]; int32 cmd_func = 8 [proto3_optional = true]; int32 cmd_id = 9 [proto3_optional = true]; int32 data_len = 10 [proto3_optional = true]; int32 need_ack = 11 [proto3_optional = true]; int32 is_ack = 12 [proto3_optional = true]; int32 seq = 14 [proto3_optional = true]; int32 product_id = 15 [proto3_optional = true]; int32 version = 16 [proto3_optional = true]; int32 payload_ver = 17 [proto3_optional = true]; int32 time_snap = 18 [proto3_optional = true]; int32 is_rw_cmd = 19 [proto3_optional = true]; int32 is_queue = 20 [proto3_optional = true]; int32 ack_type = 21 [proto3_optional = true]; string code = 22 [proto3_optional = true]; string from = 23 [proto3_optional = true]; string module_sn = 24 [proto3_optional = true]; string device_sn = 25 [proto3_optional = true]; } message setValue { optional int32 value = 1; } message permanent_watts_pack { optional int32 permanent_watts = 1; } message supply_priority_pack { optional int32 supply_priority = 1; } message bat_lower_pack { optional int32 lower_limit = 1; } message bat_upper_pack { optional int32 upper_limit = 1; } message PowerItem { optional uint32 timestamp = 1; optional sint32 timezone = 2; optional uint32 inv_to_grid_power = 3; optional uint32 inv_to_plug_power = 4; optional int32 battery_power = 5; optional uint32 pv1_output_power = 6; optional uint32 pv2_output_power = 7; } message PowerPack { optional uint32 sys_seq = 1; repeated PowerItem sys_power_stream = 2; } message PowerAckPack { optional uint32 sys_seq = 1; } message node_massage { optional string sn = 1; optional bytes mac = 2; } message mesh_child_node_info { optional uint32 topology_type = 1; optional uint32 mesh_protocol = 2; optional uint32 max_sub_device_num = 3; optional bytes parent_mac_id = 4; optional bytes mesh_id = 5; repeated node_massage sub_device_list = 6; } message EnergyItem { optional uint32 timestamp = 1; optional uint32 watth_type = 2; repeated uint32 watth = 3; } message EnergyTotalReport { optional uint32 watth_seq = 1; optional EnergyItem watth_item = 2; } message BatchEnergyTotalReport { optional uint32 watth_seq = 1; repeated EnergyItem watth_item = 2; } message EnergyTotalReportAck { optional uint32 result = 1; optional uint32 watth_seq = 2; optional uint32 watth_type = 3; } message EventRecordItem { optional uint32 timestamp = 1; optional uint32 sys_ms = 2; optional uint32 event_no = 3; repeated float event_detail = 4; } message EventRecordReport { optional uint32 event_ver = 1; optional uint32 event_seq = 2; repeated EventRecordItem event_item = 3; } message EventInfoReportAck { optional uint32 result = 1; optional uint32 event_seq = 2; optional uint32 event_item_num = 3; } message ProductNameSet { optional string name = 1; } message ProductNameSetAck { optional uint32 result = 1; } message ProductNameGet {} message ProductNameGetAck { optional string name = 3; } message RTCTimeGet {} message RTCTimeGetAck { optional uint32 timestamp = 1; optional int32 timezone = 2; } message RTCTimeSet { optional uint32 timestamp = 1; optional int32 timezone = 2 [(nanopb).default = 0]; } message RTCTimeSetAck { optional uint32 result = 1; } message country_town_message { optional uint32 country = 1; optional uint32 town = 2; } message time_task_config { optional uint32 task_index = 1; optional time_range_strategy time_range = 2; optional uint32 type = 3; } message time_task_delet { optional uint32 task_index = 1; } message time_task_config_post { optional time_task_config task1 = 1; optional time_task_config task2 = 2; optional time_task_config task3 = 3; optional time_task_config task4 = 4; optional time_task_config task5 = 5; optional time_task_config task6 = 6; optional time_task_config task7 = 7; optional time_task_config task8 = 8; optional time_task_config task9 = 9; optional time_task_config task10 = 10; optional time_task_config task11 = 11; } message time_task_config_ack { optional uint32 task_info = 1; } message rtc_data { optional int32 week = 1 [(nanopb).default = 0]; optional int32 sec = 2 [(nanopb).default = 0]; optional int32 min = 3 [(nanopb).default = 0]; optional int32 hour = 4 [(nanopb).default = 0]; optional int32 day = 5 [(nanopb).default = 0]; optional int32 month = 6 [(nanopb).default = 0]; optional int32 year = 7 [(nanopb).default = 0]; } message time_range_strategy { optional bool is_config = 1; optional bool is_enable = 2; optional int32 time_mode = 3; optional int32 time_data = 4; optional rtc_data start_time = 5; optional rtc_data stop_time = 6; } message plug_ack_message { optional uint32 ack = 1; } message plug_heartbeat_pack { optional uint32 err_code = 1 [(nanopb).default = 0]; optional uint32 warn_code = 2 [(nanopb).default = 0]; optional uint32 country = 3 [(nanopb).default = 0]; optional uint32 town = 4 [(nanopb).default = 0]; optional int32 max_cur = 5 [(nanopb).default = 0]; optional int32 temp = 6 [(nanopb).default = 0]; optional int32 freq = 7 [(nanopb).default = 0]; optional int32 current = 8 [(nanopb).default = 0]; optional int32 volt = 9 [(nanopb).default = 0]; optional int32 watts = 10 [(nanopb).default = 0]; optional bool switch = 11 [(nanopb).default = false]; optional int32 brightness = 12 [(nanopb).default = 0]; optional int32 max_watts = 13 [(nanopb).default = 0]; optional int32 heartbeat_frequency = 14 [(nanopb).default = 0]; optional int32 mesh_enable = 15 [(nanopb).default = 0]; } message plug_switch_message { optional uint32 plug_switch = 1; } message brightness_pack { optional int32 brightness = 1 [(nanopb).default = 0]; } message max_cur_pack { optional int32 max_cur = 1 [(nanopb).default = 0]; } message max_watts_pack { optional int32 max_watts = 1 [(nanopb).default = 0]; } message mesh_ctrl_pack { optional uint32 mesh_enable = 1 [(nanopb).default = 0]; } message ret_pack { optional bool ret_sta = 1 [(nanopb).default = false]; } enum CmdFunction { Unknown = 0; PermanentWattsPack = 129; SupplyPriorityPack = 130; }
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@mattenausohz auch alles wie es soll ... ich versteh das nicht
bitte noch mal von der Console:
npm install protobufjs ausführen
protobufjs auch in den einstellungen der javascriptinstanz unter Module eintragen
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@waly_de Der Eintrag in der Javascriptinstanz war nicht da. Aber:
11:28:47.779 info javascript.0 (1721421) Start javascript script.js.common.ecoFlow_PowerStream 11:28:47.785 info javascript.0 (1721421) script.js.common.ecoFlow_PowerStream: registered 0 subscriptions, 0 schedules, 0 messages, 0 logs and 0 file subscriptions 11:28:47.990 info javascript.0 (1721421) script.js.common.ecoFlow_PowerStream: Verbunden mit dem Ecoflow MQTT-Broker 11:28:48.101 info javascript.0 (1721421) script.js.common.ecoFlow_PowerStream: Fehler beim Decodieren:Cannot convert undefined or null to object 11:28:48.102 info javascript.0 (1721421) script.js.common.ecoFlow_PowerStream: hexString: "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" 11:28:48.102 info javascript.0 (1721421) script.js.common.ecoFlow_PowerStream: buffer: � ���"����2"����$����7n��"����#���� C�d#����G�f5 (@�H P�X���HW51ZOH4SF4U0277 11:28:48.102 info javascript.0 (1721421) script.js.common.ecoFlow_PowerStream: protoSource2: syntax = "proto3"; message Message { repeated Header header = 1; bytes payload = 2; } message Header { bytes pdata = 1 [proto3_optional = true]; int32 src = 2 [proto3_optional = true]; int32 dest = 3 [proto3_optional = true]; int32 d_src = 4 [proto3_optional = true]; int32 d_dest = 5 [proto3_optional = true]; int32 enc_type = 6 [proto3_optional = true]; int32 check_type = 7 [proto3_optional = true]; int32 cmd_func = 8 [proto3_optional = true]; int32 cmd_id = 9 [proto3_optional = true]; int32 data_len = 10 [proto3_optional = true]; int32 need_ack = 11 [proto3_optional = true]; int32 is_ack = 12 [proto3_optional = true]; int32 seq = 14 [proto3_optional = true]; int32 product_id = 15 [proto3_optional = true]; int32 version = 16 [proto3_optional = true]; int32 payload_ver = 17 [proto3_optional = true]; int32 time_snap = 18 [proto3_optional = true]; int32 is_rw_cmd = 19 [proto3_optional = true]; int32 is_queue = 20 [proto3_optional = true]; int32 ack_type = 21 [proto3_optional = true]; string code = 22 [proto3_optional = true]; string from = 23 [proto3_optional = true]; string module_sn = 24 [proto3_optional = true]; string device_sn = 25 [proto3_optional = true]; } message InverterHeartbeat { optional uint32 inv_err_code = 1; optional uint32 inv_warn_code = 3; optional uint32 pv1_err_code = 2; optional uint32 pv1_warn_code = 4; optional uint32 pv2_err_code = 5; optional uint32 pv2_warning_code = 6; optional uint32 bat_err_code = 7; optional uint32 bat_warning_code = 8; optional uint32 llc_err_code = 9; optional uint32 llc_warning_code = 10; optional uint32 pv1_statue = 11; optional uint32 pv2_statue = 12; optional uint32 bat_statue = 13; optional uint32 llc_statue = 14; optional uint32 inv_statue = 15; optional int32 pv1_input_volt = 16; optional int32 pv1_op_volt = 17; optional int32 pv1_input_cur = 18; optional int32 pv1_input_watts = 19; optional int32 pv1_temp = 20; optional int32 pv2_input_volt = 21; optional int32 pv2_op_volt = 22; optional int32 pv2_input_cur = 23; optional int32 pv2_input_watts = 24; optional int32 pv2_temp = 25; optional int32 bat_input_volt = 26; optional int32 bat_op_volt = 27; optional int32 bat_input_cur = 28; optional int32 bat_input_watts = 29; optional int32 bat_temp = 30; optional uint32 bat_soc = 31; optional int32 llc_input_volt = 32; optional int32 llc_op_volt = 33; optional int32 llc_temp = 34; optional int32 inv_input_volt = 35; optional int32 inv_op_volt = 36; optional int32 inv_output_cur = 37; optional int32 inv_output_watts = 38; optional int32 inv_temp = 39; optional int32 inv_freq = 40; optional int32 inv_dc_cur = 41; optional int32 bp_type = 42; optional int32 inv_relay_status = 43; optional int32 pv1_relay_status = 44; optional int32 pv2_relay_status = 45; optional uint32 install_country = 46; optional uint32 install_town = 47; optional uint32 permanent_watts = 48; optional uint32 dynamic_watts = 49; optional uint32 supply_priority = 50; optional uint32 lower_limit = 51; optional uint32 upper_limit = 52; optional uint32 inv_on_off = 53; optional uint32 wireless_err_code = 54; optional uint32 wireless_warn_code = 55; optional uint32 inv_brightness = 56; optional uint32 heartbeat_frequency = 57; optional uint32 rated_power = 58; } message InverterHeartbeat2 { optional uint32 X_Unknown_1 = 1; optional uint32 X_Unknown_2 = 2; optional uint32 X_Unknown_3 = 3; optional uint32 X_Unknown_4 = 4; optional uint32 X_Unknown_5 = 5; optional uint32 X_Unknown_6 = 6; optional uint32 X_Unknown_7 = 7; optional uint32 X_Unknown_8 = 8; optional uint32 X_Unknown_9 = 9; optional uint32 X_Unknown_10 = 10; optional uint32 X_Unknown_11 = 11; optional uint32 X_Unknown_12 = 12; optional uint32 X_Unknown_13 = 13; optional uint32 X_Unknown_14 = 14; optional uint32 X_Unknown_15 = 15; optional int32 X_Unknown_16 = 16; optional uint32 X_Unknown_17 = 17; optional uint32 X_Unknown_18 = 18; optional uint32 X_Unknown_19 = 19; optional uint32 X_Unknown_20 = 20; optional uint32 X_Unknown_21 = 21; optional uint32 X_Unknown_22 = 22; optional uint32 X_Unknown_23 = 23; optional uint32 X_Unknown_24 = 24; optional uint32 X_Unknown_25 = 25; optional uint32 X_Unknown_26 = 26; optional uint32 X_Unknown_27 = 27; optional uint32 X_Unknown_28 = 28; optional uint32 X_Unknown_29 = 29; optional uint32 X_Unknown_30 = 30; optional uint32 X_Unknown_31 = 31; optional int32 X_Unknown_32 = 32; optional uint32 X_Unknown_33 = 33; optional uint32 X_Unknown_34 = 34; optional uint32 X_Unknown_35 = 35; optional uint32 X_Unknown_36 = 36; optional uint32 X_Unknown_37 = 37; optional uint32 X_Unknown_38 = 38; optional uint32 X_Unknown_39 = 39; optional uint32 X_Unknown_40 = 40; optional uint32 X_Unknown_41 = 41; optional int32 X_Unknown_42 = 42; optional uint32 X_Unknown_43 = 43; optional uint32 X_Unknown_44 = 44; optional uint32 X_Unknown_45 = 45; optional uint32 X_Unknown_46 = 46; optional uint32 X_Unknown_47 = 47; optional int32 X_Unknown_48 = 48; optional uint32 X_Unknown_49 = 49; optional int32 X_Unknown_50 = 50; optional uint32 X_Unknown_51 = 51; optional uint32 X_Unknown_52 = 52; optional uint32 X_Unknown_53 = 53; optional uint32 X_Unknown_54 = 54; optional uint32 X_Unknown_55 = 55; optional uint32 X_Unknown_56 = 56; optional uint32 X_Unknown_57 = 57; optional uint32 X_Unknown_58 = 58; optional uint32 X_Unknown_59 = 59; optional uint32 X_Unknown_60 = 60; optional uint32 X_Unknown_61 = 61; optional uint32 X_Unknown_62 = 62; optional uint32 X_Unknown_63 = 63; optional uint32 X_Unknown_64 = 64; optional uint32 X_Unknown_65 = 65; optional uint32 X_Unknown_66 = 66; optional uint32 X_Unknown_67 = 67; optional uint32 X_Unknown_68 = 68; optional uint32 X_Unknown_69 = 69; optional uint32 X_Unknown_70 = 70; } message setMessage { setHeader header = 1; } message setHeader { setValue pdata = 1 [proto3_optional = true]; int32 src = 2 [proto3_optional = true]; int32 dest = 3 [proto3_optional = true]; int32 d_src = 4 [proto3_optional = true]; int32 d_dest = 5 [proto3_optional = true]; int32 enc_type = 6 [proto3_optional = true]; int32 check_type = 7 [proto3_optional = true]; int32 cmd_func = 8 [proto3_optional = true]; int32 cmd_id = 9 [proto3_optional = true]; int32 data_len = 10 [proto3_optional = true]; int32 need_ack = 11 [proto3_optional = true]; int32 is_ack = 12 [proto3_optional = true]; int32 seq = 14 [proto3_optional = true]; int32 product_id = 15 [proto3_optional = true]; int32 version = 16 [proto3_optional = true]; int32 payload_ver = 17 [proto3_optional = true]; int32 time_snap = 18 [proto3_optional = true]; int32 is_rw_cmd = 19 [proto3_optional = true]; int32 is_queue = 20 [proto3_optional = true]; int32 ack_type = 21 [proto3_optional = true]; string code = 22 [proto3_optional = true]; string from = 23 [proto3_optional = true]; string module_sn = 24 [proto3_optional = true]; string device_sn = 25 [proto3_optional = true]; } message setValue { optional int32 value = 1; } message permanent_watts_pack { optional int32 permanent_watts = 1; } message supply_priority_pack { optional int32 supply_priority = 1; } message bat_lower_pack { optional int32 lower_limit = 1; } message bat_upper_pack { optional int32 upper_limit = 1; } message PowerItem { optional uint32 timestamp = 1; optional sint32 timezone = 2; optional uint32 inv_to_grid_power = 3; optional uint32 inv_to_plug_power = 4; optional int32 battery_power = 5; optional uint32 pv1_output_power = 6; optional uint32 pv2_output_power = 7; } message PowerPack { optional uint32 sys_seq = 1; repeated PowerItem sys_power_stream = 2; } message PowerAckPack { optional uint32 sys_seq = 1; } message node_massage { optional string sn = 1; optional bytes mac = 2; } message mesh_child_node_info { optional uint32 topology_type = 1; optional uint32 mesh_protocol = 2; optional uint32 max_sub_device_num = 3; optional bytes parent_mac_id = 4; optional bytes mesh_id = 5; repeated node_massage sub_device_list = 6; } message EnergyItem { optional uint32 timestamp = 1; optional uint32 watth_type = 2; repeated uint32 watth = 3; } message EnergyTotalReport { optional uint32 watth_seq = 1; optional EnergyItem watth_item = 2; } message BatchEnergyTotalReport { optional uint32 watth_seq = 1; repeated EnergyItem watth_item = 2; } message EnergyTotalReportAck { optional uint32 result = 1; optional uint32 watth_seq = 2; optional uint32 watth_type = 3; } message EventRecordItem { optional uint32 timestamp = 1; optional uint32 sys_ms = 2; optional uint32 event_no = 3; repeated float event_detail = 4; } message EventRecordReport { optional uint32 event_ver = 1; optional uint32 event_seq = 2; repeated EventRecordItem event_item = 3; } message EventInfoReportAck { optional uint32 result = 1; optional uint32 event_seq = 2; optional uint32 event_item_num = 3; } message ProductNameSet { optional string name = 1; } message ProductNameSetAck { optional uint32 result = 1; } message ProductNameGet {} message ProductNameGetAck { optional string name = 3; } message RTCTimeGet {} message RTCTimeGetAck { optional uint32 timestamp = 1; optional int32 timezone = 2; } message RTCTimeSet { optional uint32 timestamp = 1; optional int32 timezone = 2 [(nanopb).default = 0]; } message RTCTimeSetAck { optional uint32 result = 1; } message country_town_message { optional uint32 country = 1; optional uint32 town = 2; } message time_task_config { optional uint32 task_index = 1; optional time_range_strategy time_range = 2; optional uint32 type = 3; } message time_task_delet { optional uint32 task_index = 1; } message time_task_config_post { optional time_task_config task1 = 1; optional time_task_config task2 = 2; optional time_task_config task3 = 3; optional time_task_config task4 = 4; optional time_task_config task5 = 5; optional time_task_config task6 = 6; optional time_task_config task7 = 7; optional time_task_config task8 = 8; optional time_task_config task9 = 9; optional time_task_config task10 = 10; optional time_task_config task11 = 11; } message time_task_config_ack { optional uint32 task_info = 1; } message rtc_data { optional int32 week = 1 [(nanopb).default = 0]; optional int32 sec = 2 [(nanopb).default = 0]; optional int32 min = 3 [(nanopb).default = 0]; optional int32 hour = 4 [(nanopb).default = 0]; optional int32 day = 5 [(nanopb).default = 0]; optional int32 month = 6 [(nanopb).default = 0]; optional int32 year = 7 [(nanopb).default = 0]; } message time_range_strategy { optional bool is_config = 1; optional bool is_enable = 2; optional int32 time_mode = 3; optional int32 time_data = 4; optional rtc_data start_time = 5; optional rtc_data stop_time = 6; } message plug_ack_message { optional uint32 ack = 1; } message plug_heartbeat_pack { optional uint32 err_code = 1 [(nanopb).default = 0]; optional uint32 warn_code = 2 [(nanopb).default = 0]; optional uint32 country = 3 [(nanopb).default = 0]; optional uint32 town = 4 [(nanopb).default = 0]; optional int32 max_cur = 5 [(nanopb).default = 0]; optional int32 temp = 6 [(nanopb).default = 0]; optional int32 freq = 7 [(nanopb).default = 0]; optional int32 current = 8 [(nanopb).default = 0]; optional int32 volt = 9 [(nanopb).default = 0]; optional int32 watts = 10 [(nanopb).default = 0]; optional bool switch = 11 [(nanopb).default = false]; optional int32 brightness = 12 [(nanopb).default = 0]; optional int32 max_watts = 13 [(nanopb).default = 0]; optional int32 heartbeat_frequency = 14 [(nanopb).default = 0]; optional int32 mesh_enable = 15 [(nanopb).default = 0]; } message plug_switch_message { optional uint32 plug_switch = 1; } message brightness_pack { optional int32 brightness = 1 [(nanopb).default = 0]; } message max_cur_pack { optional int32 max_cur = 1 [(nanopb).default = 0]; } message max_watts_pack { optional int32 max_watts = 1 [(nanopb).default = 0]; } message mesh_ctrl_pack { optional uint32 mesh_enable = 1 [(nanopb).default = 0]; } message ret_pack { optional bool ret_sta = 1 [(nanopb).default = false]; } enum CmdFunction { Unknown = 0; PermanentWattsPack = 129; SupplyPriorityPack = 130; } 11:28:48.102 info javascript.0 (1721421) script.js.common.ecoFlow_PowerStream: PowerMessage: Type .Message 11:28:48.106 info javascript.0 (1721421) script.js.common.ecoFlow_PowerStream: Fehler beim Decodieren:Cannot convert undefined or null to object 11:28:48.106 info javascript.0 (1721421) script.js.common.ecoFlow_PowerStream: hexString: "0a0a1020182070f9f0b6830b" 11:28:48.107 info javascript.0 (1721421) script.js.common.ecoFlow_PowerStream: buffer: p�� 11:28:48.107 info javascript.0 (1721421) script.js.common.ecoFlow_PowerStream: protoSource2: syntax = "proto3"; message Message { repeated Header header = 1; bytes payload = 2; } message Header { bytes pdata = 1 [proto3_optional = true]; int32 src = 2 [proto3_optional = true]; int32 dest = 3 [proto3_optional = true]; int32 d_src = 4 [proto3_optional = true]; int32 d_dest = 5 [proto3_optional = true]; int32 enc_type = 6 [proto3_optional = true]; int32 check_type = 7 [proto3_optional = true]; int32 cmd_func = 8 [proto3_optional = true]; int32 cmd_id = 9 [proto3_optional = true]; int32 data_len = 10 [proto3_optional = true]; int32 need_ack = 11 [proto3_optional = true]; int32 is_ack = 12 [proto3_optional = true]; int32 seq = 14 [proto3_optional = true]; int32 product_id = 15 [proto3_optional = true]; int32 version = 16 [proto3_optional = true]; int32 payload_ver = 17 [proto3_optional = true]; int32 time_snap = 18 [proto3_optional = true]; int32 is_rw_cmd = 19 [proto3_optional = true]; int32 is_queue = 20 [proto3_optional = true]; int32 ack_type = 21 [proto3_optional = true]; string code = 22 [proto3_optional = true]; string from = 23 [proto3_optional = true]; string module_sn = 24 [proto3_optional = true]; string device_sn = 25 [proto3_optional = true]; } message InverterHeartbeat { optional uint32 inv_err_code = 1; optional uint32 inv_warn_code = 3; optional uint32 pv1_err_code = 2; optional uint32 pv1_warn_code = 4; optional uint32 pv2_err_code = 5; optional uint32 pv2_warning_code = 6; optional uint32 bat_err_code = 7; optional uint32 bat_warning_code = 8; optional uint32 llc_err_code = 9; optional uint32 llc_warning_code = 10; optional uint32 pv1_statue = 11; optional uint32 pv2_statue = 12; optional uint32 bat_statue = 13; optional uint32 llc_statue = 14; optional uint32 inv_statue = 15; optional int32 pv1_input_volt = 16; optional int32 pv1_op_volt = 17; optional int32 pv1_input_cur = 18; optional int32 pv1_input_watts = 19; optional int32 pv1_temp = 20; optional int32 pv2_input_volt = 21; optional int32 pv2_op_volt = 22; optional int32 pv2_input_cur = 23; optional int32 pv2_input_watts = 24; optional int32 pv2_temp = 25; optional int32 bat_input_volt = 26; optional int32 bat_op_volt = 27; optional int32 bat_input_cur = 28; optional int32 bat_input_watts = 29; optional int32 bat_temp = 30; optional uint32 bat_soc = 31; optional int32 llc_input_volt = 32; optional int32 llc_op_volt = 33; optional int32 llc_temp = 34; optional int32 inv_input_volt = 35; optional int32 inv_op_volt = 36; optional int32 inv_output_cur = 37; optional int32 inv_output_watts = 38; optional int32 inv_temp = 39; optional int32 inv_freq = 40; optional int32 inv_dc_cur = 41; optional int32 bp_type = 42; optional int32 inv_relay_status = 43; optional int32 pv1_relay_status = 44; optional int32 pv2_relay_status = 45; optional uint32 install_country = 46; optional uint32 install_town = 47; optional uint32 permanent_watts = 48; optional uint32 dynamic_watts = 49; optional uint32 supply_priority = 50; optional uint32 lower_limit = 51; optional uint32 upper_limit = 52; optional uint32 inv_on_off = 53; optional uint32 wireless_err_code = 54; optional uint32 wireless_warn_code = 55; optional uint32 inv_brightness = 56; optional uint32 heartbeat_frequency = 57; optional uint32 rated_power = 58; } message InverterHeartbeat2 { optional uint32 X_Unknown_1 = 1; optional uint32 X_Unknown_2 = 2; optional uint32 X_Unknown_3 = 3; optional uint32 X_Unknown_4 = 4; optional uint32 X_Unknown_5 = 5; optional uint32 X_Unknown_6 = 6; optional uint32 X_Unknown_7 = 7; optional uint32 X_Unknown_8 = 8; optional uint32 X_Unknown_9 = 9; optional uint32 X_Unknown_10 = 10; optional uint32 X_Unknown_11 = 11; optional uint32 X_Unknown_12 = 12; optional uint32 X_Unknown_13 = 13; optional uint32 X_Unknown_14 = 14; optional uint32 X_Unknown_15 = 15; optional int32 X_Unknown_16 = 16; optional uint32 X_Unknown_17 = 17; optional uint32 X_Unknown_18 = 18; optional uint32 X_Unknown_19 = 19; optional uint32 X_Unknown_20 = 20; optional uint32 X_Unknown_21 = 21; optional uint32 X_Unknown_22 = 22; optional uint32 X_Unknown_23 = 23; optional uint32 X_Unknown_24 = 24; optional uint32 X_Unknown_25 = 25; optional uint32 X_Unknown_26 = 26; optional uint32 X_Unknown_27 = 27; optional uint32 X_Unknown_28 = 28; optional uint32 X_Unknown_29 = 29; optional uint32 X_Unknown_30 = 30; optional uint32 X_Unknown_31 = 31; optional int32 X_Unknown_32 = 32; optional uint32 X_Unknown_33 = 33; optional uint32 X_Unknown_34 = 34; optional uint32 X_Unknown_35 = 35; optional uint32 X_Unknown_36 = 36; optional uint32 X_Unknown_37 = 37; optional uint32 X_Unknown_38 = 38; optional uint32 X_Unknown_39 = 39; optional uint32 X_Unknown_40 = 40; optional uint32 X_Unknown_41 = 41; optional int32 X_Unknown_42 = 42; optional uint32 X_Unknown_43 = 43; optional uint32 X_Unknown_44 = 44; optional uint32 X_Unknown_45 = 45; optional uint32 X_Unknown_46 = 46; optional uint32 X_Unknown_47 = 47; optional int32 X_Unknown_48 = 48; optional uint32 X_Unknown_49 = 49; optional int32 X_Unknown_50 = 50; optional uint32 X_Unknown_51 = 51; optional uint32 X_Unknown_52 = 52; optional uint32 X_Unknown_53 = 53; optional uint32 X_Unknown_54 = 54; optional uint32 X_Unknown_55 = 55; optional uint32 X_Unknown_56 = 56; optional uint32 X_Unknown_57 = 57; optional uint32 X_Unknown_58 = 58; optional uint32 X_Unknown_59 = 59; optional uint32 X_Unknown_60 = 60; optional uint32 X_Unknown_61 = 61; optional uint32 X_Unknown_62 = 62; optional uint32 X_Unknown_63 = 63; optional uint32 X_Unknown_64 = 64; optional uint32 X_Unknown_65 = 65; optional uint32 X_Unknown_66 = 66; optional uint32 X_Unknown_67 = 67; optional uint32 X_Unknown_68 = 68; optional uint32 X_Unknown_69 = 69; optional uint32 X_Unknown_70 = 70; } message setMessage { setHeader header = 1; } message setHeader { setValue pdata = 1 [proto3_optional = true]; int32 src = 2 [proto3_optional = true]; int32 dest = 3 [proto3_optional = true]; int32 d_src = 4 [proto3_optional = true]; int32 d_dest = 5 [proto3_optional = true]; int32 enc_type = 6 [proto3_optional = true]; int32 check_type = 7 [proto3_optional = true]; int32 cmd_func = 8 [proto3_optional = true]; int32 cmd_id = 9 [proto3_optional = true]; int32 data_len = 10 [proto3_optional = true]; int32 need_ack = 11 [proto3_optional = true]; int32 is_ack = 12 [proto3_optional = true]; int32 seq = 14 [proto3_optional = true]; int32 product_id = 15 [proto3_optional = true]; int32 version = 16 [proto3_optional = true]; int32 payload_ver = 17 [proto3_optional = true]; int32 time_snap = 18 [proto3_optional = true]; int32 is_rw_cmd = 19 [proto3_optional = true]; int32 is_queue = 20 [proto3_optional = true]; int32 ack_type = 21 [proto3_optional = true]; string code = 22 [proto3_optional = true]; string from = 23 [proto3_optional = true]; string module_sn = 24 [proto3_optional = true]; string device_sn = 25 [proto3_optional = true]; } message setValue { optional int32 value = 1; } message permanent_watts_pack { optional int32 permanent_watts = 1; } message supply_priority_pack { optional int32 supply_priority = 1; } message bat_lower_pack { optional int32 lower_limit = 1; } message bat_upper_pack { optional int32 upper_limit = 1; } message PowerItem { optional uint32 timestamp = 1; optional sint32 timezone = 2; optional uint32 inv_to_grid_power = 3; optional uint32 inv_to_plug_power = 4; optional int32 battery_power = 5; optional uint32 pv1_output_power = 6; optional uint32 pv2_output_power = 7; } message PowerPack { optional uint32 sys_seq = 1; repeated PowerItem sys_power_stream = 2; } message PowerAckPack { optional uint32 sys_seq = 1; } message node_massage { optional string sn = 1; optional bytes mac = 2; } message mesh_child_node_info { optional uint32 topology_type = 1; optional uint32 mesh_protocol = 2; optional uint32 max_sub_device_num = 3; optional bytes parent_mac_id = 4; optional bytes mesh_id = 5; repeated node_massage sub_device_list = 6; } message EnergyItem { optional uint32 timestamp = 1; optional uint32 watth_type = 2; repeated uint32 watth = 3; } message EnergyTotalReport { optional uint32 watth_seq = 1; optional EnergyItem watth_item = 2; } message BatchEnergyTotalReport { optional uint32 watth_seq = 1; repeated EnergyItem watth_item = 2; } message EnergyTotalReportAck { optional uint32 result = 1; optional uint32 watth_seq = 2; optional uint32 watth_type = 3; } message EventRecordItem { optional uint32 timestamp = 1; optional uint32 sys_ms = 2; optional uint32 event_no = 3; repeated float event_detail = 4; } message EventRecordReport { optional uint32 event_ver = 1; optional uint32 event_seq = 2; repeated EventRecordItem event_item = 3; } message EventInfoReportAck { optional uint32 result = 1; optional uint32 event_seq = 2; optional uint32 event_item_num = 3; } message ProductNameSet { optional string name = 1; } message ProductNameSetAck { optional uint32 result = 1; } message ProductNameGet {} message ProductNameGetAck { optional string name = 3; } message RTCTimeGet {} message RTCTimeGetAck { optional uint32 timestamp = 1; optional int32 timezone = 2; } message RTCTimeSet { optional uint32 timestamp = 1; optional int32 timezone = 2 [(nanopb).default = 0]; } message RTCTimeSetAck { optional uint32 result = 1; } message country_town_message { optional uint32 country = 1; optional uint32 town = 2; } message time_task_config { optional uint32 task_index = 1; optional time_range_strategy time_range = 2; optional uint32 type = 3; } message time_task_delet { optional uint32 task_index = 1; } message time_task_config_post { optional time_task_config task1 = 1; optional time_task_config task2 = 2; optional time_task_config task3 = 3; optional time_task_config task4 = 4; optional time_task_config task5 = 5; optional time_task_config task6 = 6; optional time_task_config task7 = 7; optional time_task_config task8 = 8; optional time_task_config task9 = 9; optional time_task_config task10 = 10; optional time_task_config task11 = 11; } message time_task_config_ack { optional uint32 task_info = 1; } message rtc_data { optional int32 week = 1 [(nanopb).default = 0]; optional int32 sec = 2 [(nanopb).default = 0]; optional int32 min = 3 [(nanopb).default = 0]; optional int32 hour = 4 [(nanopb).default = 0]; optional int32 day = 5 [(nanopb).default = 0]; optional int32 month = 6 [(nanopb).default = 0]; optional int32 year = 7 [(nanopb).default = 0]; } message time_range_strategy { optional bool is_config = 1; optional bool is_enable = 2; optional int32 time_mode = 3; optional int32 time_data = 4; optional rtc_data start_time = 5; optional rtc_data stop_time = 6; } message plug_ack_message { optional uint32 ack = 1; } message plug_heartbeat_pack { optional uint32 err_code = 1 [(nanopb).default = 0]; optional uint32 warn_code = 2 [(nanopb).default = 0]; optional uint32 country = 3 [(nanopb).default = 0]; optional uint32 town = 4 [(nanopb).default = 0]; optional int32 max_cur = 5 [(nanopb).default = 0]; optional int32 temp = 6 [(nanopb).default = 0]; optional int32 freq = 7 [(nanopb).default = 0]; optional int32 current = 8 [(nanopb).default = 0]; optional int32 volt = 9 [(nanopb).default = 0]; optional int32 watts = 10 [(nanopb).default = 0]; optional bool switch = 11 [(nanopb).default = false]; optional int32 brightness = 12 [(nanopb).default = 0]; optional int32 max_watts = 13 [(nanopb).default = 0]; optional int32 heartbeat_frequency = 14 [(nanopb).default = 0]; optional int32 mesh_enable = 15 [(nanopb).default = 0]; } message plug_switch_message { optional uint32 plug_switch = 1; } message brightness_pack { optional int32 brightness = 1 [(nanopb).default = 0]; } message max_cur_pack { optional int32 max_cur = 1 [(nanopb).default = 0]; } message max_watts_pack { optional int32 max_watts = 1 [(nanopb).default = 0]; } message mesh_ctrl_pack { optional uint32 mesh_enable = 1 [(nanopb).default = 0]; } message ret_pack { optional bool ret_sta = 1 [(nanopb).default = false]; } enum CmdFunction { Unknown = 0; PermanentWattsPack = 129; SupplyPriorityPack = 130; } 11:28:48.107 info javascript.0 (1721421) script.js.common.ecoFlow_PowerStream: PowerMessage: Type .Message 11:28:48.133 info javascript.0 (1721421) script.js.common.ecoFlow_PowerStream: Fehler beim Decodieren:Cannot convert undefined or null to object 11:28:48.133 info javascript.0 (1721421) script.js.common.ecoFlow_PowerStream: hexString: "0a0a1020182070f9f0b6830b" 11:28:48.133 info javascript.0 (1721421) script.js.common.ecoFlow_PowerStream: buffer: p��
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@ponti92 sagte in ecoflow-connector-Script zur dynamischen Leistungsanpassung:
javascript: v6.1.4
vielleicht kannst du den noch updaten? ich hab 7.0.3
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@waly_de Hab ich grade aktualisiert, aber immer noch der selbe Fehler..
Kann es evtl daran liegen, dass ich bei Node.js: v14.21.3 noch veraltet bin?
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@waly_de 7.0.3 hab ich auch. Außerdem neuste node.js installiert:
11:36:57.916 info javascript.0 (1723840) Start javascript script.js.common.ecoFlow_PowerStream 11:36:57.991 info javascript.0 (1723840) script.js.common.ecoFlow_PowerStream: registered 0 subscriptions, 0 schedules, 0 messages, 0 logs and 0 file subscriptions 11:36:58.365 info javascript.0 (1723840) script.js.common.ecoFlow_PowerStream: Verbunden mit dem Ecoflow MQTT-Broker 11:36:58.690 info javascript.0 (1723840) script.js.common.ecoFlow_PowerStream: Fehler beim Decodieren:Cannot convert undefined or null to object 11:36:58.691 info javascript.0 (1723840) script.js.common.ecoFlow_PowerStream: hexString: "0a0a10201820708fe8d4830b" 11:36:58.691 info javascript.0 (1723840) script.js.common.ecoFlow_PowerStream: buffer: p��ԃ 11:36:58.691 info javascript.0 (1723840) script.js.common.ecoFlow_PowerStream: protoSource2: syntax = "proto3"; message Message { repeated Header header = 1; bytes payload = 2; } message Header { bytes pdata = 1 [proto3_optional = true]; int32 src = 2 [proto3_optional = true]; int32 dest = 3 [proto3_optional = true]; int32 d_src = 4 [proto3_optional = true]; int32 d_dest = 5 [proto3_optional = true]; int32 enc_type = 6 [proto3_optional = true]; int32 check_type = 7 [proto3_optional = true]; int32 cmd_func = 8 [proto3_optional = true]; int32 cmd_id = 9 [proto3_optional = true]; int32 data_len = 10 [proto3_optional = true]; int32 need_ack = 11 [proto3_optional = true]; int32 is_ack = 12 [proto3_optional = true]; int32 seq = 14 [proto3_optional = true]; int32 product_id = 15 [proto3_optional = true]; int32 version = 16 [proto3_optional = true]; int32 payload_ver = 17 [proto3_optional = true]; int32 time_snap = 18 [proto3_optional = true]; int32 is_rw_cmd = 19 [proto3_optional = true]; int32 is_queue = 20 [proto3_optional = true]; int32 ack_type = 21 [proto3_optional = true]; string code = 22 [proto3_optional = true]; string from = 23 [proto3_optional = true]; string module_sn = 24 [proto3_optional = true]; string device_sn = 25 [proto3_optional = true]; } message InverterHeartbeat { optional uint32 inv_err_code = 1; optional uint32 inv_warn_code = 3; optional uint32 pv1_err_code = 2; optional uint32 pv1_warn_code = 4; optional uint32 pv2_err_code = 5; optional uint32 pv2_warning_code = 6; optional uint32 bat_err_code = 7; optional uint32 bat_warning_code = 8; optional uint32 llc_err_code = 9; optional uint32 llc_warning_code = 10; optional uint32 pv1_statue = 11; optional uint32 pv2_statue = 12; optional uint32 bat_statue = 13; optional uint32 llc_statue = 14; optional uint32 inv_statue = 15; optional int32 pv1_input_volt = 16; optional int32 pv1_op_volt = 17; optional int32 pv1_input_cur = 18; optional int32 pv1_input_watts = 19; optional int32 pv1_temp = 20; optional int32 pv2_input_volt = 21; optional int32 pv2_op_volt = 22; optional int32 pv2_input_cur = 23; optional int32 pv2_input_watts = 24; optional int32 pv2_temp = 25; optional int32 bat_input_volt = 26; optional int32 bat_op_volt = 27; optional int32 bat_input_cur = 28; optional int32 bat_input_watts = 29; optional int32 bat_temp = 30; optional uint32 bat_soc = 31; optional int32 llc_input_volt = 32; optional int32 llc_op_volt = 33; optional int32 llc_temp = 34; optional int32 inv_input_volt = 35; optional int32 inv_op_volt = 36; optional int32 inv_output_cur = 37; optional int32 inv_output_watts = 38; optional int32 inv_temp = 39; optional int32 inv_freq = 40; optional int32 inv_dc_cur = 41; optional int32 bp_type = 42; optional int32 inv_relay_status = 43; optional int32 pv1_relay_status = 44; optional int32 pv2_relay_status = 45; optional uint32 install_country = 46; optional uint32 install_town = 47; optional uint32 permanent_watts = 48; optional uint32 dynamic_watts = 49; optional uint32 supply_priority = 50; optional uint32 lower_limit = 51; optional uint32 upper_limit = 52; optional uint32 inv_on_off = 53; optional uint32 wireless_err_code = 54; optional uint32 wireless_warn_code = 55; optional uint32 inv_brightness = 56; optional uint32 heartbeat_frequency = 57; optional uint32 rated_power = 58; } message InverterHeartbeat2 { optional uint32 X_Unknown_1 = 1; optional uint32 X_Unknown_2 = 2; optional uint32 X_Unknown_3 = 3; optional uint32 X_Unknown_4 = 4; optional uint32 X_Unknown_5 = 5; optional uint32 X_Unknown_6 = 6; optional uint32 X_Unknown_7 = 7; optional uint32 X_Unknown_8 = 8; optional uint32 X_Unknown_9 = 9; optional uint32 X_Unknown_10 = 10; optional uint32 X_Unknown_11 = 11; optional uint32 X_Unknown_12 = 12; optional uint32 X_Unknown_13 = 13; optional uint32 X_Unknown_14 = 14; optional uint32 X_Unknown_15 = 15; optional int32 X_Unknown_16 = 16; optional uint32 X_Unknown_17 = 17; optional uint32 X_Unknown_18 = 18; optional uint32 X_Unknown_19 = 19; optional uint32 X_Unknown_20 = 20; optional uint32 X_Unknown_21 = 21; optional uint32 X_Unknown_22 = 22; optional uint32 X_Unknown_23 = 23; optional uint32 X_Unknown_24 = 24; optional uint32 X_Unknown_25 = 25; optional uint32 X_Unknown_26 = 26; optional uint32 X_Unknown_27 = 27; optional uint32 X_Unknown_28 = 28; optional uint32 X_Unknown_29 = 29; optional uint32 X_Unknown_30 = 30; optional uint32 X_Unknown_31 = 31; optional int32 X_Unknown_32 = 32; optional uint32 X_Unknown_33 = 33; optional uint32 X_Unknown_34 = 34; optional uint32 X_Unknown_35 = 35; optional uint32 X_Unknown_36 = 36; optional uint32 X_Unknown_37 = 37; optional uint32 X_Unknown_38 = 38; optional uint32 X_Unknown_39 = 39; optional uint32 X_Unknown_40 = 40; optional uint32 X_Unknown_41 = 41; optional int32 X_Unknown_42 = 42; optional uint32 X_Unknown_43 = 43; optional uint32 X_Unknown_44 = 44; optional uint32 X_Unknown_45 = 45; optional uint32 X_Unknown_46 = 46; optional uint32 X_Unknown_47 = 47; optional int32 X_Unknown_48 = 48; optional uint32 X_Unknown_49 = 49; optional int32 X_Unknown_50 = 50; optional uint32 X_Unknown_51 = 51; optional uint32 X_Unknown_52 = 52; optional uint32 X_Unknown_53 = 53; optional uint32 X_Unknown_54 = 54; optional uint32 X_Unknown_55 = 55; optional uint32 X_Unknown_56 = 56; optional uint32 X_Unknown_57 = 57; optional uint32 X_Unknown_58 = 58; optional uint32 X_Unknown_59 = 59; optional uint32 X_Unknown_60 = 60; optional uint32 X_Unknown_61 = 61; optional uint32 X_Unknown_62 = 62; optional uint32 X_Unknown_63 = 63; optional uint32 X_Unknown_64 = 64; optional uint32 X_Unknown_65 = 65; optional uint32 X_Unknown_66 = 66; optional uint32 X_Unknown_67 = 67; optional uint32 X_Unknown_68 = 68; optional uint32 X_Unknown_69 = 69; optional uint32 X_Unknown_70 = 70; } message setMessage { setHeader header = 1; } message setHeader { setValue pdata = 1 [proto3_optional = true]; int32 src = 2 [proto3_optional = true]; int32 dest = 3 [proto3_optional = true]; int32 d_src = 4 [proto3_optional = true]; int32 d_dest = 5 [proto3_optional = true]; int32 enc_type = 6 [proto3_optional = true]; int32 check_type = 7 [proto3_optional = true]; int32 cmd_func = 8 [proto3_optional = true]; int32 cmd_id = 9 [proto3_optional = true]; int32 data_len = 10 [proto3_optional = true]; int32 need_ack = 11 [proto3_optional = true]; int32 is_ack = 12 [proto3_optional = true]; int32 seq = 14 [proto3_optional = true]; int32 product_id = 15 [proto3_optional = true]; int32 version = 16 [proto3_optional = true]; int32 payload_ver = 17 [proto3_optional = true]; int32 time_snap = 18 [proto3_optional = true]; int32 is_rw_cmd = 19 [proto3_optional = true]; int32 is_queue = 20 [proto3_optional = true]; int32 ack_type = 21 [proto3_optional = true]; string code = 22 [proto3_optional = true]; string from = 23 [proto3_optional = true]; string module_sn = 24 [proto3_optional = true]; string device_sn = 25 [proto3_optional = true]; } message setValue { optional int32 value = 1; } message permanent_watts_pack { optional int32 permanent_watts = 1; } message supply_priority_pack { optional int32 supply_priority = 1; } message bat_lower_pack { optional int32 lower_limit = 1; } message bat_upper_pack { optional int32 upper_limit = 1; } message PowerItem { optional uint32 timestamp = 1; optional sint32 timezone = 2; optional uint32 inv_to_grid_power = 3; optional uint32 inv_to_plug_power = 4; optional int32 battery_power = 5; optional uint32 pv1_output_power = 6; optional uint32 pv2_output_power = 7; } message PowerPack { optional uint32 sys_seq = 1; repeated PowerItem sys_power_stream = 2; } message PowerAckPack { optional uint32 sys_seq = 1; } message node_massage { optional string sn = 1; optional bytes mac = 2; } message mesh_child_node_info { optional uint32 topology_type = 1; optional uint32 mesh_protocol = 2; optional uint32 max_sub_device_num = 3; optional bytes parent_mac_id = 4; optional bytes mesh_id = 5; repeated node_massage sub_device_list = 6; } message EnergyItem { optional uint32 timestamp = 1; optional uint32 watth_type = 2; repeated uint32 watth = 3; } message EnergyTotalReport { optional uint32 watth_seq = 1; optional EnergyItem watth_item = 2; } message BatchEnergyTotalReport { optional uint32 watth_seq = 1; repeated EnergyItem watth_item = 2; } message EnergyTotalReportAck { optional uint32 result = 1; optional uint32 watth_seq = 2; optional uint32 watth_type = 3; } message EventRecordItem { optional uint32 timestamp = 1; optional uint32 sys_ms = 2; optional uint32 event_no = 3; repeated float event_detail = 4; } message EventRecordReport { optional uint32 event_ver = 1; optional uint32 event_seq = 2; repeated EventRecordItem event_item = 3; } message EventInfoReportAck { optional uint32 result = 1; optional uint32 event_seq = 2; optional uint32 event_item_num = 3; } message ProductNameSet { optional string name = 1; } message ProductNameSetAck { optional uint32 result = 1; } message ProductNameGet {} message ProductNameGetAck { optional string name = 3; } message RTCTimeGet {} message RTCTimeGetAck { optional uint32 timestamp = 1; optional int32 timezone = 2; } message RTCTimeSet { optional uint32 timestamp = 1; optional int32 timezone = 2 [(nanopb).default = 0]; } message RTCTimeSetAck { optional uint32 result = 1; } message country_town_message { optional uint32 country = 1; optional uint32 town = 2; } message time_task_config { optional uint32 task_index = 1; optional time_range_strategy time_range = 2; optional uint32 type = 3; } message time_task_delet { optional uint32 task_index = 1; } message time_task_config_post { optional time_task_config task1 = 1; optional time_task_config task2 = 2; optional time_task_config task3 = 3; optional time_task_config task4 = 4; optional time_task_config task5 = 5; optional time_task_config task6 = 6; optional time_task_config task7 = 7; optional time_task_config task8 = 8; optional time_task_config task9 = 9; optional time_task_config task10 = 10; optional time_task_config task11 = 11; } message time_task_config_ack { optional uint32 task_info = 1; } message rtc_data { optional int32 week = 1 [(nanopb).default = 0]; optional int32 sec = 2 [(nanopb).default = 0]; optional int32 min = 3 [(nanopb).default = 0]; optional int32 hour = 4 [(nanopb).default = 0]; optional int32 day = 5 [(nanopb).default = 0]; optional int32 month = 6 [(nanopb).default = 0]; optional int32 year = 7 [(nanopb).default = 0]; } message time_range_strategy { optional bool is_config = 1; optional bool is_enable = 2; optional int32 time_mode = 3; optional int32 time_data = 4; optional rtc_data start_time = 5; optional rtc_data stop_time = 6; } message plug_ack_message { optional uint32 ack = 1; } message plug_heartbeat_pack { optional uint32 err_code = 1 [(nanopb).default = 0]; optional uint32 warn_code = 2 [(nanopb).default = 0]; optional uint32 country = 3 [(nanopb).default = 0]; optional uint32 town = 4 [(nanopb).default = 0]; optional int32 max_cur = 5 [(nanopb).default = 0]; optional int32 temp = 6 [(nanopb).default = 0]; optional int32 freq = 7 [(nanopb).default = 0]; optional int32 current = 8 [(nanopb).default = 0]; optional int32 volt = 9 [(nanopb).default = 0]; optional int32 watts = 10 [(nanopb).default = 0]; optional bool switch = 11 [(nanopb).default = false]; optional int32 brightness = 12 [(nanopb).default = 0]; optional int32 max_watts = 13 [(nanopb).default = 0]; optional int32 heartbeat_frequency = 14 [(nanopb).default = 0]; optional int32 mesh_enable = 15 [(nanopb).default = 0]; } message plug_switch_message { optional uint32 plug_switch = 1; } message brightness_pack { optional int32 brightness = 1 [(nanopb).default = 0]; } message max_cur_pack { optional int32 max_cur = 1 [(nanopb).default = 0]; } message max_watts_pack { optional int32 max_watts = 1 [(nanopb).default = 0]; } message mesh_ctrl_pack { optional uint32 mesh_enable = 1 [(nanopb).default = 0]; } message ret_pack { optional bool ret_sta = 1 [(nanopb).default = false]; } enum CmdFunction { Unknown = 0; PermanentWattsPack = 129; SupplyPriorityPack = 130; } 11:36:58.691 info javascript.0 (1723840) script.js.common.ecoFlow_PowerStream: PowerMessage: Type .Message 11:36:58.707 info javascript.0 (1723840) script.js.common.ecoFlow_PowerStream: Fehler beim Decodieren:Cannot convert undefined or null to object 11:36:58.707 info javascript.0 (1723840) script.js.common.ecoFlow_PowerStream: hexString: "0a0a10201820708fe8d4830b" 11:36:58.709 info javascript.0 (1723840) script.js.common.ecoFlow_PowerStream: buffer: p��ԃ
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ok hat erstmal keinen Sinn mehr .. muss auch los. aber ich kann jetzt den Fehler auf einem anderen host reproduzieren ...
kümmer mich später und melde mich....
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@waly_de VIELEN DANK FÜR DEINEN EINSATZ!
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@waly_de Weiß nicht ob es etwas damit zu tun hat aber die PV1 + PV2 Summe wird nicht als Objekt erzeugt.
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@mattenausohz Danke Bin jetzt etwas weiter.
Das Script sollte laufen. Allerdings spucken die Powerstream jetzt Daten aus, für die es noch keine Definition gibt. Wenn einer von Euch im Netz eine .proto-Definition für die neuen Nachrichten findet, dann bite sofort an mich weiterleiten.
Bis dahin hab ich provisorisch eine Definition mit X_Unknown_X Feldern erstellt.
Der Inhalt macht für mich noch keinen Sinn. Das könnte aber auch daran liegendes die Datentypen nicht klar sind. Aber vielleicht entdeckt Ihr ja den Sinn dahinter.
Die alten Daten scheinen auch noch zu kommen. Aber sehr selten. Ob damit eine Steuerung möglich ist, weiss ich nicht.
Meinen ersten PS werde ich erst mal nicht Updaten. Ohne das Update läuft das Script ohne Probleme./** * ecoflow-connector.js * Version: 0.6.7 * Release date: 01.08.2023 * Autor: Waly_de * Forum: https://forum.iobroker.net/topic/66743/ecoflow-connector-script-zur-dynamischen-leistungsanpassung * * * This JavaScript file establishes a simple connection between IOBroker and EcoFlow. * It automatically creates known states under 0_userdata. * * Please note that adjustments in the ConfigData section are required. Here, you need to enter your access credentials * used for the EcoFlow app, as well as the serial numbers of your devices. * * If you have a state that displays the current power consumption (SmartmeterID), please provide it as well. * This value will be used to dynamically adjust the Powerstream's feed-in power. * * Not all parameters of the Powerstream data are known yet. All known parameters will be automatically created as states. * By modifying the "protoSource" constant, newly discovered data will also be automatically created. * * The raw data of the interface is logged as a HEX string. * * Please exercise caution as this is the initial version of the script. Use it at your own risk! * * Requirements: * - Install protobuf using the command "npm install protobufjs" from the terminal console. * - The "Paho MQTT Client" is also required. If not already installed, use the command "npm install mqtt". * You can also simply add this libs to your javascript instance configuration (Zusätzliche NPM-Module) * * Note: It is encouraged to discover and publish missing data definitions to improve the script. * Suggestions, optimizations, and extensions are welcome at any time. * * Special thanks to all contributors for their valuable input and support. * * Changelog: * ----------------------------------------------------------- * (0.4) 29.06.2023 * Da der MQTT von ecoflow regelmäßig aufhört zu senden, vor allem, wenn die App genutzt und komplett geschlossen wird, * habe ich eine Überwachung der letzten ankommenden Nachrichten eingebaut. Kommt 5 Minuten lang nichts neues vom PowerStream, * Wird die Verbindung zum MQTT kompett neu aufgebaut. * * Ein Fehler bei der Erstellung der States wurde beseitigt * ----------------------------------------------------------- * (0.5.2) 06.07.2023 * State sumPV hinzugefügt (Summe aus PV1 und PV2) = Solar-Leistung gesamt * Abweichung der PV Power von der App versucht zu kompensieren * Neuen State RealPower zur besseren Ermittlung der Einspeiseleistung angelegt. Zeigt den Verbrauch im Haus ohne Einspeisung * History für RealPower wird automatisch aktiviert * Die koordinaten werden aus den Systemeistellungen ermittelt ( Sonst einfach selbst angeben ) * Diverse kleine Anpassungen und Bugfixes * Es werden jetzt mehrere PowerStream berücksichtigt. In der Konfiguration muss das Flag "isPowerStream" gesetzt werden * Gesteuert wird aber bisher nur die erste PowerStream * die protoSource so angepasst, dass in "Item" enthaltene unbekannte Daten auch als State angelegt werden. Bitte helft mit zu identifizieren * was was ist. Dann können wir die Felder entsprechend benennen... * Parameter "subscribe" bei der Gerätekonfiguration hinzugefügt. Damit lässt sich der Empfang von MQTT Telegrammen für das Gerät abstellen * Mein Delta Max hatte derart viel gesendet, dass der Raspi nicht mehr in der Lage war alles zu verarbeiten. Für die Steuerung braucht man die Daten der Batterie nicht. * Nach Sonnenuntergang wird jetzt weniger oft reconnectet, wenn keine Daten mehr kommen. * Reaktionszeiten für die Anpassung der Einspeisung wurde erhöht (30 sekunden) * State "totalPV" für die derzeitige komplett PV Leistung hinzugefügt * Funtion hinzugefügt, die die Einspeisung bei voller Batterie auf Maximum stellt. Ein und Ausschaltprozent können mit battPozOn und battPozOff eingestellt werden. * ----------------------------------------------------------- * (0.6.1) 26.07.2023 * ACHTUNG: Die Felddefinitionen für den Powerstream sind jetzt vollständig und an die von der Community ermittelten Daten angepasst. * Das bedeutet aber leider auch, dass alle States mit neuen Namen neu angelegt werden. Die vom Script generierten States bleiben erhalten (SerAC, totalPV, sumPV). * * Für die Delta Max sind nun einige States auch zum Schreiben verfügbar. Die Delta muss dazu nicht unbedingt auf "subscribe: true" gestellt werden. * Damit die States angelegt werden, müssen sie bei laufendem Script einmal in der App verändert werden. Möglich sind bisher: * Beep, slowChgPower, ACPower, DCPower, USBPower, minDsgSoc, maxChgSoc, curr12VMax, standByModeMins, lcdTimeMins, ACstandByMins, openOilSoc, closeOilSoc. * * Ob diese States auch so bei anderen Deltas funktionieren, kann ich nicht sagen. Wenn nicht, solltet Ihr im Log einen Eintrag finden: "Unbekannter Set Befehl: ". * Wenn ich diesen Eintrag mit einer kurzen Beschreibung erhalte, was es ist, kann ich es auch einbauen. * * Die States werden hier angelegt: 0_userdata.0.ecoflow.app_XXXXXXXXXXXXXXXXXXX_XXXXXXXXXXXXXXX_thing_property_set.writeables * * (0.6.7) 01.08.2023 * * Writeables für Delta2 Angelegt * totalPV / 10 geändert, damit ein echter Wattwert angezeigt wird. * Anpassung für neues Datenformat nach diversen Updates von ecoflow * Diverse Optimierungen und Bugfixe * * */ // SystemKoordinaten werden versucht zu ermittelm und als Default den Variablen zugeteilt var latitude; var longitude; // ermitteln des Standortes aus den Settings getStandortKoordinaten() /*************************************** ********** YOUR DATA HERE ************ ****************************************/ var ConfigData = { email: "your@mail.com", //Die App-Zugangsdaten von ecoFlow passwort: "yourAppPasswort!", seriennummern: [ { seriennummer: "XXXXXXXXXXXXX", name: "PowerStream", isPowerStream: true, subscribe: true }, { seriennummer: "XXXXXXXXXXXXX", name: "DELTA Max", isPowerStream: false, subscribe: false } ], SmartmeterID: "sonoff.0.Stromzaehler1.MT175_P", //State, das den aktuellen Gesamtverbrauch in Watt enthält BasePowerOffset: 50, //wird vom aktuellen Verbrauch abgezogen um die Einspeiseleistung zu berechnen MaxPower: 600, //Der höchst mögliche wert in Watt für die Einspeiseleistung MinValueMin: 3, //Der Zeitraum in Minuten, aus dem der letzte Gesamtverbrauchs-Minimalwert geholt werden soll ReconnectMin: 30, //Zeit in Minuten, nach der die Anwendung neu gestartet wird, wenn keine neuen Daten eintreffen statesPrefix: "0_userdata.0.ecoflow", //Hier werden die ecoFlow States angelegt latitude: latitude, //Breitengrad des Standortes (wird automatisch eingesetzt) longitude: longitude, //Längengrad des Standortes (wird automatisch eingesetzt) battPozOn: 98, battPozOff:93, //Wenn die Batterie bei battPozOn ist, Einspeisung auf MaxPower. Bei BattPozOff Normalbetieb Debug: false, PlotCmdID: 9999, }; //***************************************/ //***************************************/ const messageIDTypes = { 1: 'InverterHeartbeat', 4: 'InverterHeartbeat2', 11: 'setValue', 136: 'PowerPack', 138: 'PowerPack', 129: 'setValue', // Weitere cmd_func-Werte und zugehörige Nachrichtentypen }; const protoSource2 = ` syntax = "proto3"; message Message { repeated Header header = 1; bytes payload = 2; } message Header { bytes pdata = 1 [proto3_optional = false]; int32 src = 2 [proto3_optional = true]; int32 dest = 3 [proto3_optional = true]; int32 d_src = 4 [proto3_optional = true]; int32 d_dest = 5 [proto3_optional = true]; int32 enc_type = 6 [proto3_optional = true]; int32 check_type = 7 [proto3_optional = true]; int32 cmd_func = 8 [proto3_optional = true]; int32 cmd_id = 9 [proto3_optional = true]; int32 data_len = 10 [proto3_optional = true]; int32 need_ack = 11 [proto3_optional = true]; int32 is_ack = 12 [proto3_optional = true]; int32 seq = 14 [proto3_optional = true]; int32 product_id = 15 [proto3_optional = true]; int32 version = 16 [proto3_optional = true]; int32 payload_ver = 17 [proto3_optional = true]; int32 time_snap = 18 [proto3_optional = true]; int32 is_rw_cmd = 19 [proto3_optional = true]; int32 is_queue = 20 [proto3_optional = true]; int32 ack_type = 21 [proto3_optional = true]; string code = 22 [proto3_optional = true]; string from = 23 [proto3_optional = true]; string module_sn = 24 [proto3_optional = true]; string device_sn = 25 [proto3_optional = true]; } message InverterHeartbeat { optional uint32 inv_err_code = 1; optional uint32 inv_warn_code = 3; optional uint32 pv1_err_code = 2; optional uint32 pv1_warn_code = 4; optional uint32 pv2_err_code = 5; optional uint32 pv2_warning_code = 6; optional uint32 bat_err_code = 7; optional uint32 bat_warning_code = 8; optional uint32 llc_err_code = 9; optional uint32 llc_warning_code = 10; optional uint32 pv1_statue = 11; optional uint32 pv2_statue = 12; optional uint32 bat_statue = 13; optional uint32 llc_statue = 14; optional uint32 inv_statue = 15; optional int32 pv1_input_volt = 16; optional int32 pv1_op_volt = 17; optional int32 pv1_input_cur = 18; optional int32 pv1_input_watts = 19; optional int32 pv1_temp = 20; optional int32 pv2_input_volt = 21; optional int32 pv2_op_volt = 22; optional int32 pv2_input_cur = 23; optional int32 pv2_input_watts = 24; optional int32 pv2_temp = 25; optional int32 bat_input_volt = 26; optional int32 bat_op_volt = 27; optional int32 bat_input_cur = 28; optional int32 bat_input_watts = 29; optional int32 bat_temp = 30; optional uint32 bat_soc = 31; optional int32 llc_input_volt = 32; optional int32 llc_op_volt = 33; optional int32 llc_temp = 34; optional int32 inv_input_volt = 35; optional int32 inv_op_volt = 36; optional int32 inv_output_cur = 37; optional int32 inv_output_watts = 38; optional int32 inv_temp = 39; optional int32 inv_freq = 40; optional int32 inv_dc_cur = 41; optional int32 bp_type = 42; optional int32 inv_relay_status = 43; optional int32 pv1_relay_status = 44; optional int32 pv2_relay_status = 45; optional uint32 install_country = 46; optional uint32 install_town = 47; optional uint32 permanent_watts = 48; optional uint32 dynamic_watts = 49; optional uint32 supply_priority = 50; optional uint32 lower_limit = 51; optional uint32 upper_limit = 52; optional uint32 inv_on_off = 53; optional uint32 wireless_err_code = 54; optional uint32 wireless_warn_code = 55; optional uint32 inv_brightness = 56; optional uint32 heartbeat_frequency = 57; optional uint32 rated_power = 58; } message InverterHeartbeat2 { optional int32 X_Unknown_1 = 1; optional int32 X_Unknown_2 = 2; optional int32 X_Unknown_3 = 3; optional int32 X_Unknown_4 = 4; optional int32 X_Unknown_5 = 5; optional int32 X_Unknown_6 = 6; optional int32 X_Unknown_7 = 7; optional int32 X_Unknown_8 = 8; optional int32 X_Unknown_9 = 9; optional int32 X_Unknown_10 = 10; optional int32 X_Unknown_11 = 11; optional int32 X_Unknown_12 = 12; optional int32 X_Unknown_13 = 13; optional int32 X_Unknown_14 = 14; optional int32 X_Unknown_15 = 15; optional int32 X_Unknown_16 = 16; optional int32 X_Unknown_17 = 17; optional int32 X_Unknown_18 = 18; optional int32 X_Unknown_19 = 19; optional int32 X_Unknown_20 = 20; optional int32 X_Unknown_21 = 21; optional int32 X_Unknown_22 = 22; optional int32 X_Unknown_23 = 23; optional int32 X_Unknown_24 = 24; optional int32 X_Unknown_25 = 25; optional int32 X_Unknown_26 = 26; optional int32 X_Unknown_27 = 27; optional int32 X_Unknown_28 = 28; optional int32 X_Unknown_29 = 29; optional int32 X_Unknown_30 = 30; optional int32 X_Unknown_31 = 31; optional int32 X_Unknown_32 = 32; optional int32 X_Unknown_33 = 33; optional int32 X_Unknown_34 = 34; optional int32 X_Unknown_35 = 35; optional int32 X_Unknown_36 = 36; optional int32 X_Unknown_37 = 37; optional int32 X_Unknown_38 = 38; optional int32 X_Unknown_39 = 39; optional int32 X_Unknown_40 = 40; optional int32 X_Unknown_41 = 41; optional int32 X_Unknown_42 = 42; optional int32 X_Unknown_43 = 43; optional int32 X_Unknown_44 = 44; optional int32 X_Unknown_45 = 45; optional int32 X_Unknown_46 = 46; optional int32 X_Unknown_47 = 47; optional int32 X_Unknown_48 = 48; optional int32 X_Unknown_49 = 49; optional int32 X_Unknown_50 = 50; optional int32 X_Unknown_51 = 51; optional int32 X_Unknown_52 = 52; optional int32 X_Unknown_53 = 53; optional int32 X_Unknown_54 = 54; optional int32 X_Unknown_55 = 55; optional int32 X_Unknown_56 = 56; optional int32 X_Unknown_57 = 57; optional int32 X_Unknown_58 = 58; optional int32 X_Unknown_59 = 59; optional int32 X_Unknown_60 = 60; optional int32 X_Unknown_61 = 61; optional int32 X_Unknown_62 = 62; optional int32 X_Unknown_63 = 63; optional int32 X_Unknown_64 = 64; optional int32 X_Unknown_65 = 65; optional int32 X_Unknown_66 = 66; optional int32 X_Unknown_67 = 67; optional int32 X_Unknown_68 = 68; optional int32 X_Unknown_69 = 69; optional int32 X_Unknown_70 = 70; } message setMessage { setHeader header = 1; } message setHeader { setValue pdata = 1 [proto3_optional = true]; int32 src = 2 [proto3_optional = true]; int32 dest = 3 [proto3_optional = true]; int32 d_src = 4 [proto3_optional = true]; int32 d_dest = 5 [proto3_optional = true]; int32 enc_type = 6 [proto3_optional = true]; int32 check_type = 7 [proto3_optional = true]; int32 cmd_func = 8 [proto3_optional = true]; int32 cmd_id = 9 [proto3_optional = true]; int32 data_len = 10 [proto3_optional = true]; int32 need_ack = 11 [proto3_optional = true]; int32 is_ack = 12 [proto3_optional = true]; int32 seq = 14 [proto3_optional = true]; int32 product_id = 15 [proto3_optional = true]; int32 version = 16 [proto3_optional = true]; int32 payload_ver = 17 [proto3_optional = true]; int32 time_snap = 18 [proto3_optional = true]; int32 is_rw_cmd = 19 [proto3_optional = true]; int32 is_queue = 20 [proto3_optional = true]; int32 ack_type = 21 [proto3_optional = true]; string code = 22 [proto3_optional = true]; string from = 23 [proto3_optional = true]; string module_sn = 24 [proto3_optional = true]; string device_sn = 25 [proto3_optional = true]; } message setValue { optional int32 value = 1; } message permanent_watts_pack { optional int32 permanent_watts = 1; } message supply_priority_pack { optional int32 supply_priority = 1; } message bat_lower_pack { optional int32 lower_limit = 1; } message bat_upper_pack { optional int32 upper_limit = 1; } message PowerItem { optional uint32 timestamp = 1; optional sint32 timezone = 2; optional uint32 inv_to_grid_power = 3; optional uint32 inv_to_plug_power = 4; optional int32 battery_power = 5; optional uint32 pv1_output_power = 6; optional uint32 pv2_output_power = 7; } message PowerPack { optional uint32 sys_seq = 1; repeated PowerItem sys_power_stream = 2; } message PowerAckPack { optional uint32 sys_seq = 1; } message node_massage { optional string sn = 1; optional bytes mac = 2; } message mesh_child_node_info { optional uint32 topology_type = 1; optional uint32 mesh_protocol = 2; optional uint32 max_sub_device_num = 3; optional bytes parent_mac_id = 4; optional bytes mesh_id = 5; repeated node_massage sub_device_list = 6; } message EnergyItem { optional uint32 timestamp = 1; optional uint32 watth_type = 2; repeated uint32 watth = 3; } message EnergyTotalReport { optional uint32 watth_seq = 1; optional EnergyItem watth_item = 2; } message BatchEnergyTotalReport { optional uint32 watth_seq = 1; repeated EnergyItem watth_item = 2; } message EnergyTotalReportAck { optional uint32 result = 1; optional uint32 watth_seq = 2; optional uint32 watth_type = 3; } message EventRecordItem { optional uint32 timestamp = 1; optional uint32 sys_ms = 2; optional uint32 event_no = 3; repeated float event_detail = 4; } message EventRecordReport { optional uint32 event_ver = 1; optional uint32 event_seq = 2; repeated EventRecordItem event_item = 3; } message EventInfoReportAck { optional uint32 result = 1; optional uint32 event_seq = 2; optional uint32 event_item_num = 3; } message ProductNameSet { optional string name = 1; } message ProductNameSetAck { optional uint32 result = 1; } message ProductNameGet {} message ProductNameGetAck { optional string name = 3; } message RTCTimeGet {} message RTCTimeGetAck { optional uint32 timestamp = 1; optional int32 timezone = 2; } message RTCTimeSet { optional uint32 timestamp = 1; optional int32 timezone = 2 [(nanopb).default = 0]; } message RTCTimeSetAck { optional uint32 result = 1; } message country_town_message { optional uint32 country = 1; optional uint32 town = 2; } message time_task_config { optional uint32 task_index = 1; optional time_range_strategy time_range = 2; optional uint32 type = 3; } message time_task_delet { optional uint32 task_index = 1; } message time_task_config_post { optional time_task_config task1 = 1; optional time_task_config task2 = 2; optional time_task_config task3 = 3; optional time_task_config task4 = 4; optional time_task_config task5 = 5; optional time_task_config task6 = 6; optional time_task_config task7 = 7; optional time_task_config task8 = 8; optional time_task_config task9 = 9; optional time_task_config task10 = 10; optional time_task_config task11 = 11; } message time_task_config_ack { optional uint32 task_info = 1; } message rtc_data { optional int32 week = 1 [(nanopb).default = 0]; optional int32 sec = 2 [(nanopb).default = 0]; optional int32 min = 3 [(nanopb).default = 0]; optional int32 hour = 4 [(nanopb).default = 0]; optional int32 day = 5 [(nanopb).default = 0]; optional int32 month = 6 [(nanopb).default = 0]; optional int32 year = 7 [(nanopb).default = 0]; } message time_range_strategy { optional bool is_config = 1; optional bool is_enable = 2; optional int32 time_mode = 3; optional int32 time_data = 4; optional rtc_data start_time = 5; optional rtc_data stop_time = 6; } message plug_ack_message { optional uint32 ack = 1; } message plug_heartbeat_pack { optional uint32 err_code = 1 [(nanopb).default = 0]; optional uint32 warn_code = 2 [(nanopb).default = 0]; optional uint32 country = 3 [(nanopb).default = 0]; optional uint32 town = 4 [(nanopb).default = 0]; optional int32 max_cur = 5 [(nanopb).default = 0]; optional int32 temp = 6 [(nanopb).default = 0]; optional int32 freq = 7 [(nanopb).default = 0]; optional int32 current = 8 [(nanopb).default = 0]; optional int32 volt = 9 [(nanopb).default = 0]; optional int32 watts = 10 [(nanopb).default = 0]; optional bool switch = 11 [(nanopb).default = false]; optional int32 brightness = 12 [(nanopb).default = 0]; optional int32 max_watts = 13 [(nanopb).default = 0]; optional int32 heartbeat_frequency = 14 [(nanopb).default = 0]; optional int32 mesh_enable = 15 [(nanopb).default = 0]; } message plug_switch_message { optional uint32 plug_switch = 1; } message brightness_pack { optional int32 brightness = 1 [(nanopb).default = 0]; } message max_cur_pack { optional int32 max_cur = 1 [(nanopb).default = 0]; } message max_watts_pack { optional int32 max_watts = 1 [(nanopb).default = 0]; } message mesh_ctrl_pack { optional uint32 mesh_enable = 1 [(nanopb).default = 0]; } message ret_pack { optional bool ret_sta = 1 [(nanopb).default = false]; } enum CmdFunction { Unknown = 0; PermanentWattsPack = 129; SupplyPriorityPack = 130; } `; const protoSource = ` syntax = "proto3"; message PowerItem { optional Meta meta = 1; optional uint32 src = 2; optional uint32 dest = 3; optional uint32 unknown1 = 4; optional uint32 unknown2 = 5; optional uint32 unknown3 = 6; optional uint32 unknown4 = 7; optional uint32 cmdFunc = 8; optional CmdFunction cmdId = 9; optional uint32 ValByte = 10; optional uint32 needAck = 11; uint64 timestamp = 14; optional uint32 unknown6 = 16; //3 Byte? optional uint32 unknown7 = 17; //3 Byte? optional string OS = 23; optional string serialNumber = 25; } message Message { PowerItem item = 1; } message Meta { optional int32 value = 1; optional int32 X_Unknown_3 = 3; optional int32 X_Unknown_4 = 4; optional int32 X_Unknown_5 = 5; optional int32 X_Unknown_6 = 6; optional int32 X_Unknown_7 = 7; optional int32 X_Unknown_8 = 8; optional int32 X_Unknown_9 = 9; optional int32 plugPower = 10; optional int32 X_Unknown_11 = 11; optional int32 X_Unknown_12 = 12; optional int32 X_Unknown_13 = 13; optional int32 M_Unknown7 = 14; // bei Prio-änderung gesehen optional int32 M_Unknown8 = 15; //bei Prio-änderung gesehen optional int32 M_Unknown10 = 16; optional int32 X_Unknown_17 = 17; optional int32 X_Unknown_18 = 18; optional int32 PV1_Power = 19; optional int32 X_Unknown_20 = 20; optional int32 M_Unknown1 = 21; optional int32 X_Unknown_22 = 22; optional int32 X_Unknown_23 = 23; optional int32 PV2_Power = 24; optional int32 X_Unknown_25 = 25; optional int32 X_Unknown_26 = 26; optional int32 X_Unknown_27 = 27; optional int32 X_Unknown_28 = 28; optional int32 From_Bat_Power = 29; optional int32 X_Unknown_30 = 30; optional int32 Batt_Poz = 31; optional int32 X_Unknown_32 = 32; optional int32 M_Unknown2 = 33; optional int32 X_Unknown_34 = 34; optional int32 M_Unknown3 = 35; optional int32 X_Unknown_36 = 36; optional int32 M_Unknown6 = 37; optional int32 ToHome_Power = 38; optional int32 X_Unknown_39 = 39; optional int32 X_Unknown_40 = 40; optional int32 X_Unknown_41 = 41; optional int32 X_Unknown_42 = 42; optional int32 M_Unknown9 = 43; //bei prio setzen gesehen optional int32 X_Unknown_44 = 44; optional int32 X_Unknown_45 = 45; optional int32 X_Unknown_46 = 46; optional int32 X_Unknown_47 = 47; optional int32 Needed_Power = 48; optional int32 X_Unknown_49 = 49; optional int32 X_Unknown_50 = 50; optional int32 X_Unknown_51 = 51; optional int32 X_Unknown_52 = 52; optional int32 X_Unknown_53 = 53; optional int32 X_Unknown_54 = 54; optional int32 X_Unknown_55 = 55; optional int32 X_Unknown_56 = 56; optional int32 X_Unknown_57 = 57; optional int32 X_Unknown_58 = 58; optional int32 M_Unknown4 = 59; optional int32 Bat_Minutes = 60; } enum CmdFunction { Unknown = 0; PermanentWattsPack = 129; SupplyPriorityPack = 130; } `; const writeables = [ { id: 38, name: 'Beep', ValueName: 'enabled', Typ: 'DM' }, { id: 69, name: 'slowChgPower', ValueName: 'slowChgPower', Typ: 'DM' }, { id: 66, name: 'ACPower', ValueName: 'enabled', Typ: 'DM' }, { id: 81, name: 'DCPower', ValueName: 'enabled', Typ: 'DM' }, { id: 34, name: 'USBPower', ValueName: 'enabled', Typ: 'DM' }, { id: 51, name: 'minDsgSoc', ValueName: 'minDsgSoc', Typ: 'DM' }, { id: 49, name: 'maxChgSoc', ValueName: 'maxChgSoc', Typ: 'DM' }, { id: 71, name: 'curr12VMax', ValueName: 'currMa', Typ: 'DM' }, { id: 33, name: 'standByModeMins', ValueName: 'standByMode', Typ: 'DM' }, { id: 49, name: 'lcdTimeMins', ValueName: 'lcdTime', Typ: 'DM' }, { id: 153, name: 'ACstandByMins', ValueName: 'standByMins', Typ: 'DM' }, { id: 52, name: 'openOilSoc', ValueName: 'openOilSoc', Typ: 'DM' }, { id: 53, name: 'closeOilSoc', ValueName: 'closeOilSoc', Typ: 'DM' }, { id: 0, name: 'acChgCfg_D2', ValueName: 'chgWatts', Typ: 'D2', MT: 5, AddParam: '{"chgWatts":600,"chgPauseFlag":255}' }, { id: 0, name: 'dcOutCfg_D2', ValueName: 'enabled', Typ: 'D2', MT: 1 }, { id: 0, name: 'quietMode_D2', ValueName: 'enabled', Typ: 'D2', MT: 5 }, { id: 0, name: 'dcChgCfg_D2', ValueName: 'dcChgCfg', Typ: 'D2', MT: 5 } ]; const musterGetPS = { "header": { "src": 32, "dest": 32, "seq": 1651831507, "OS": "ios" } } const musterSetAC = { header: { pdata: { value: 1300, }, src: 32, dest: 53, dSrc: 1, dDest: 1, checkType: 3, cmdFunc: 20, cmdId: 129, dataLen: 3, needAck: 1, seq: 1651831507, version: 19, payloadVer: 1, from: 'ios', deviceSn: 'ABCxxxxxxx123' } }; const musterSetAC2 = { header: { pdata: { value: 17477, }, src: 32, dest: 53, dSrc: 1, dDest: 1, checkType: 3, cmdFunc: 32, cmdId: 11, dataLen: 4, needAck: 1, seq: 1651831507, version: 19, payloadVer: 1, from: 'ios', deviceSn: 'ABCxxxxxxx123' } }; const musterslowChgPower = { "from": "iOS", "operateType": "TCP", "id": "816376009", "lang": "de-de", "params": { "id": 69, }, "version": "1.0" }; const musterDelta2 = { "from": "Android", "id": "458115693", "moduleType": 5, "operateType": "acChgCfg", "params": { } , "version": "1.0" } // @ts-ignore const mqtt = require('mqtt'); const https = require('https'); // @ts-ignore const protobuf = require("protobufjs"); const mqttDaten = { UserID: '', User: '', Passwort: '', URL: '', Port: '', protocol: '', clientID: '' } //Die erste PowerStream ermitteln let firstPsSn = ""; for (var i = 0; i < ConfigData.seriennummern.length; i++) { if (ConfigData.seriennummern[i].isPowerStream) { firstPsSn = ConfigData.seriennummern[i].seriennummer; break; } } /*======================================================= ========= Timer ============ =======================================================*/ //jede x Sekunden var intervalID = setInterval(function () { if (true || istTag()) { CheckforReconnect(function () { SetBasePower(firstPsSn); }); } else { ////SetBasePower(firstPsSn); } }, 10 * 1000); /* var intervalID2 = setInterval(function () { getLowestValue(ConfigData.statesPrefix + ".RealPower", 2) .then(lowestValue => { log( "lowestValue:" + lowestValue) }) .catch((error) => { console.warn('Fehler beim Abrufen des niedrigsten Werts:', error); }); }, 2 * 1000); //*/ // @ts-ignore await getEcoFlowMqttData(ConfigData.email, ConfigData.passwort) async function getEcoFlowMqttData(email, password) { const options = { hostname: 'api.ecoflow.com', path: '/auth/login', method: 'POST', headers: { 'Host': 'api.ecoflow.com', 'lang': 'de-de', 'platform': 'android', 'sysversion': '11', 'version': '4.1.2.02', 'phonemodel': 'SM-X200', 'content-type': 'application/json', 'user-agent': 'okhttp/3.14.9' } }; const data = { appVersion: "4.1.2.02", email: email, os: "android", osVersion: "30", password: Buffer.from(password).toString('base64'), scene: "IOT_APP", userType: "ECOFLOW" }; function httpsRequest(options, data) { return new Promise((resolve, reject) => { const req = https.request(options, res => { let data = ''; res.on('data', chunk => { data += chunk; }); res.on('end', () => { resolve(data); }); }); req.on('error', error => { reject(error); }); if (data) { req.write(JSON.stringify(data)); } req.end(); }); } function uuidv4() { return 'xxxxxxxx-xxxx-4xxx-yxxx-xxxxxxxxxxxx'.replace(/[xy]/g, function (c) { var r = Math.random() * 16 | 0, v = c === 'x' ? r : (r & 0x3 | 0x8); return v.toString(16); }); } let response = await httpsRequest(options, data); try { let token = JSON.parse(response).data.token; let userid = JSON.parse(response).data.user.userId; } catch (error) { log(response) throw new Error("Ein Fehler bei der Ermittlung der Zugangsdaten ist aufgetreten. Bitte prüfe die Zugangsdaten."); } let token = JSON.parse(response).data.token; let userid = JSON.parse(response).data.user.userId; options.path = `/iot-auth/app/certification?userId=${userid}`; options.method = 'GET'; options.headers.authorization = `Bearer ${token}`; response = await httpsRequest(options); try { mqttDaten.Passwort = JSON.parse(response).data.certificatePassword mqttDaten.Port = JSON.parse(response).data.port mqttDaten.UserID = userid mqttDaten.User = JSON.parse(response).data.certificateAccount mqttDaten.URL = JSON.parse(response).data.url mqttDaten.protocol = JSON.parse(response).data.protocol mqttDaten.clientID = "ANDROID_" + uuidv4() + "_" + userid } catch (error) { log(response) throw new Error("Ein Fehler bei der Ermittlung der Zugangsdaten ist aufgetreten. Bitte prüfe die Zugangsdaten."); } /* console.log("UserID: " + userid); console.log("User: " + JSON.parse(response).data.certificateAccount); console.log("Passwort: " + JSON.parse(response).data.certificatePassword); console.log("URL: " + JSON.parse(response).data.url); console.log("Port: " + JSON.parse(response).data.port); console.log("protocol: " + JSON.parse(response).data.protocol); console.log("clientID: ANDROID_" + uuidv4() + "_" + userid); */ } // @ts-ignore await createMyState("LastTopic") //################ MQTT Verbindung ################## function setupMQTTConnection() { //log("Neue MQTT Verbindung startet") // Verbindung herstellen const options = { port: mqttDaten.Port, clientId: mqttDaten.clientID, username: mqttDaten.User, password: mqttDaten.Passwort, protocol: mqttDaten.protocol }; const client = mqtt.connect("mqtt://" + mqttDaten.URL, options); // Event-Handler für Verbindungsaufbau client.on('connect', function () { console.log('Verbunden mit dem Ecoflow MQTT-Broker'); SubscribeEco(); for (var i = 0; i < ConfigData.seriennummern.length; i++) { if (ConfigData.seriennummern[i].isPowerStream) { setmusterGetPS(ConfigData.seriennummern[i].seriennummer); } } }); function SubscribeEco() { ConfigData.seriennummern.forEach(item => { client.subscribe('/app/' + mqttDaten.UserID + '/' + item.seriennummer + '/thing/property/set'); client.subscribe('/app/' + mqttDaten.UserID + '/' + item.seriennummer + '/thing/property/get'); if (item.subscribe) { client.subscribe('/app/device/property/' + item.seriennummer); } }); } // Auf Nachricht empfangen Ereignis reagieren client.on('message', async function (topic, message) { //log("Incomming Massage: " + topic) //log("Incomming Massage: " + message.length) if (message.length == 0) return //return var jsonMessage = "" const mqState = topic.replace(/^\//, '').replace(/\//g, '_') await createMyState(mqState + ".RAW") setState(ConfigData.statesPrefix + ".LastTopic", topic) try { jsonMessage = JSON.parse(message); if (!pruefeID(jsonMessage, mqState)) { return } if (false || ConfigData.Debug) log('JSON-Nachricht empfangen:' + topic + ':' + JSON.stringify(jsonMessage)); setState(ConfigData.statesPrefix + '.' + mqState + ".RAW", JSON.stringify(jsonMessage)) generateAndSyncSub("data", jsonMessage, false, ConfigData.statesPrefix + '.' + mqState) } catch (error) { //if (topic.indexOf("/set") !== -1) log('Binäre Nachricht empfangen:' + topic + ':' + message.toString('hex')); if (ConfigData.Debug) log('Binäre Nachricht empfangen:' + topic + ':' + message.toString('hex')); await createMyState(mqState + ".RAW_HEX") setState(ConfigData.statesPrefix + '.' + mqState + ".RAW_HEX", message.toString('hex')) const messagedecoded = decodeAndPrint(message.toString('hex')) //log(messagedecoded) if (ConfigData.Debug) log('Decodierte Nachricht:' + messagedecoded) setState(ConfigData.statesPrefix + '.' + mqState + ".RAW", messagedecoded) generateAndSyncSub("", JSON.parse(messagedecoded), false, ConfigData.statesPrefix + '.' + mqState) } }); // Callback für Fehler client.on('error', function (error) { log('Fehler bei der Ecoflow MQTT-Verbindung:' + error, 'warn'); }); client.on('reconnect', function () { console.log('Reconnecting to Ecoflow MQTT broker...'); }); // Weitere Event-Handler hier... return client; } function findWriteableByID(id) { const foundItem = writeables.find((item) => item.id === id); return foundItem || null; } function findWriteableByValueName(id) { //log("suche nach writeable: " + id) const foundItem = writeables.find((item) => item.name === id); return foundItem || null; } function pruefeID(json, mqState) { //log(mqState + " : " + JSON.stringify(json)) if (mqState.includes("thing_property_set")) { if ('params' in json && 'id' in json.params) { // ('params' in json && 'id' in json.params) (Delta Max) const Ignores = [40, 72, 68]; const writeables = [69]; if (Ignores.includes(json.params.id)) { //log("Ignore: "+ JSON.stringify(json)) return false; } else if (mqState.includes("thing_property_set")) { const suchwriteable = findWriteableByID(json.params.id) if (suchwriteable) { //log("Schreibbar: " + JSON.stringify(json)) //log("Schreibbardaten: " + JSON.stringify(suchwriteable)) //log("wert: " + JSON.stringify(json.params[suchwriteable.ValueName])) createMyState(mqState + ".writeables." + suchwriteable.name + "", json.params[suchwriteable.ValueName].toString()) setState(ConfigData.statesPrefix + "." + mqState + ".writeables." + suchwriteable.name, json.params[suchwriteable.ValueName].toString(), true) } else { log("Unbekannter Set Befehl: " + JSON.stringify(json)) log("Adresse: " + mqState) } return true; } } else if ('params' in json && 'moduleType' in json && 'operateType' in json) { // Delta2 let suchwriteable suchwriteable = findWriteableByValueName(json.operateType + "_D2") /* for (const paramName in json.params) { suchwriteable = findWriteableByValueName(paramName) if(suchwriteable) break } */ if (suchwriteable) { //log("Schreibbar: " + JSON.stringify(json)) //log("Schreibbardaten: " + JSON.stringify(suchwriteable)) //log("wert: " + JSON.stringify(json.params[suchwriteable.ValueName])) createMyState(mqState + ".writeables." + suchwriteable.name, JSON.stringify(json.params[suchwriteable.ValueName].toString())) setState(ConfigData.statesPrefix + "." + mqState + ".writeables." + suchwriteable.name, JSON.stringify(json.params[suchwriteable.ValueName].toString()), true) } else { log("Unbekannter Delta2 Set Befehl: " + JSON.stringify(json)) log("Adresse: " + mqState) } return true; } else { // ('params' in json && 'id' in json.params) (Delta Max) log("nix gefunden") return true; } } //"thing_property_set" return true; } // Verbindung herstellen let client = setupMQTTConnection(); // Funktion zum Trennen und Neuaufbau der Verbindung function reconnect() { client.end(); // Verbindung trennen setTimeout(function () { client = setupMQTTConnection(); // Neue Verbindung herstellen //log("Ecoflow neuverbindung"); }, 2000); // Wartezeit } // close connection if script stopped onStop(function (callback) { if (client) { // close connection client.end(); log("Ecoflow MQTT-Client beendet") clearInterval(intervalID); } callback(); }, 2000); function CheckforReconnect(callback) { //log("CheckforReconnect") //return let wartezeit = 15 //bis eine Stunde nach Sonneuntergang kurze Reconnects dann 15 min. if (istTag(60)) wartezeit = 1 if (getState(ConfigData.statesPrefix + ".LastTopic")?.ts < Date.now() - ConfigData.ReconnectMin * 60 * 1000) { console.log("Der letzte Eintrag ist älter als " + ConfigData.ReconnectMin + " Minuten. Versuche Neustart."); setState(ConfigData.statesPrefix + ".LastTopic", "Last Action Restart:" + new Date().toLocaleString()) runScript(); return; // Wenn letzte Powerstream-Meldung älter als <wartezeit> min ist, reconnecte } else if (getState(ConfigData.statesPrefix + '.app_device_property_' + firstPsSn + '.RAW_HEX')?.ts < Date.now() - (wartezeit * 60 * 1000)) { log("Reconnect zu Ecoflow MQTT für PowerStream - Daten") //.ts Updaten const oldvalue = getState(ConfigData.statesPrefix + '.app_device_property_' + firstPsSn + '.RAW_HEX').val setState(ConfigData.statesPrefix + '.app_device_property_' + firstPsSn + '.RAW_HEX', oldvalue) reconnect(); return; //runScript(); } else { callback(); } } async function createMyState(name, value = undefined) { const stateName = ConfigData.statesPrefix + '.' + name; if (!(await existsObjectAsync(stateName))) { const state = { name: name.split('.').pop(), role: 'state', //type: 'string', // 'number', 'boolean', usw. read: true, write: true, }; // @ts-ignore await createStateAsync(stateName, value, false, state); // Wenn der optionale Parameter value übergeben wurde, schreibe den Wert in den State } } async function createMyStatealt(name) { if (!(await existsObjectAsync(ConfigData.statesPrefix + '.' + name))) { await createStateAsync(ConfigData.statesPrefix + '.' + name, { name: name.split('.').pop(), role: 'state', type: 'string', read: true, write: true }); } } //const hextest = "0a0a1020182070f9f0b6830b" function decodeAndPrint(hexString) { if (typeof hexString !== 'string' || !hexString) { log('Ungültiger hexString: "' + hexString + '"'); return "{}"; } const root = protobuf.parse(protoSource2).root; const PowerMessage = root.lookupType("Message"); //const message = PowerMessage.decode(Buffer.from(hexString, "hex")); let message = {} try{ message = PowerMessage.decode(Buffer.from(hexString, "hex")); }catch (error) { log('Fehler beim Decodieren:' + error.message); //log('hexString: "' + hexString +'"'); //log('buffer: ' + Buffer.from(hexString, "hex")) //log('PowerMessage: ' + PowerMessage) return "{}"; } //log("Ganze Nachricht :" + JSON.stringify(message)); let Rueckgabe = {} if (Array.isArray(message.header)) { //log("Nachricht Anzahl :" + message.header.length); for (let i = 0; i < message.header.length; i++) { const header = message.header[i]; if (!header.cmdId) header.cmdId = 0 //log("Nachricht :" + JSON.stringify(header)); //log("cmdId:" + header.cmdId) //log("Hex:" + hexString) //log(JSON.stringify(message)) const MessageType = messageIDTypes[header.cmdId] || "nichtDefiniert" //log("MessageType: " + MessageType) //log("cmdId: " + header.cmdId) if (header.cmdId == ConfigData.PlotCmdId) { log("--------------------------------------------") log("cmdId: " + header.cmdId) log("RAW: " + hexString) log("Nachricht: " + JSON.stringify(message)) log("Header: " + i + " von(" + message.header.length + ") " + JSON.stringify(header)) log("--------------------------------------------") } if (header.cmdId == 32 || header.cmdId == 99999) { //log(hexString) //log(JSON.stringify(message)) continue; } if (MessageType == "nichtDefiniert") { if (header.cmdId != 0 && header.cmdId) { console.warn('Ungültiger cmd_func-Wert:' + header.cmdId); log(hexString) } continue; } else { const PdataMessage = root.lookupType(MessageType); const pdata = PdataMessage.decode(header.pdata); const pdataObject = PdataMessage.toObject(pdata, { longs: Number, // Konvertiere Long-Werte in Zahlen (optional) enums: String, // Konvertiere Enum-Werte in Strings (optional) bytes: Buffer, // Konvertiere Bytes in Buffer (optional) }); const outputObject = { [MessageType]: pdataObject }; if (header.cmdId == ConfigData.PlotCmdId) { log("outputObject: " + JSON.stringify(outputObject)) log("--------------------------------------------") } Rueckgabe.data = outputObject; continue; } }; } else { // Das Ergebnis ist eine einzelne Message // log("Es wurde eine einzelne Message dekodiert:" + JSON.stringify(message)); return JSON.stringify(Rueckgabe); } //log("DURCHLAUF:" + JSON.stringify(Rueckgabe)) return JSON.stringify(Rueckgabe) } function SendProto(protomsg, topic) { //return const root = protobuf.parse(protoSource2).root; const PowerMessage = root.lookupType("setMessage"); const message = PowerMessage.create(JSON.parse(protomsg)); const messageBuffer = PowerMessage.encode(message).finish(); //log("Modifizierter Hex-String:" + Buffer.from(messageBuffer).toString("hex")); //log("topic:" + topic); client.publish(topic, messageBuffer, { qos: 1 }, function (error) { if (error) { console.error('Fehler beim Veröffentlichen der MQTT-Nachricht:', error); } else { if (ConfigData.Debug) log('Die MQTT-Nachricht wurde erfolgreich veröffentlicht.'); } }); } function SendJSON(protomsg, topic) { client.publish(topic, protomsg, { qos: 1 }, function (error) { if (error) { console.error('Fehler beim Veröffentlichen der MQTT-Nachricht:', error); } else { if (ConfigData.Debug) log('Die MQTT-Nachricht wurde erfolgreich veröffentlicht.'); } }); } function getStandortKoordinaten() { var obj = getObject('system.config'); if (obj) { latitude = obj.common.latitude; longitude = obj.common.longitude; } else { console.error('Fehler beim Abrufen der Einstellungen'); } } //Anmeldenachrichten der APP function setmusterGetPS(asn) { let updatedMusterSetAC = (musterGetPS); updatedMusterSetAC.header.seq = Date.now() //log(JSON.stringify(updatedMusterSetAC)); SendProto(JSON.stringify(updatedMusterSetAC), '/app/' + mqttDaten.UserID + '/' + asn + '/thing/property/get'); SendProto(JSON.stringify(updatedMusterSetAC), '/app/' + mqttDaten.UserID + '/' + asn + '/thing/property/get'); SendProto(JSON.stringify(updatedMusterSetAC), '/app/' + mqttDaten.UserID + '/' + asn + '/thing/property/get'); // @ts-ignore updatedMusterSetAC = (musterSetAC2); updatedMusterSetAC.header.seq = Date.now() updatedMusterSetAC.header.deviceSn = asn //log(JSON.stringify(updatedMusterSetAC)); SendProto(JSON.stringify(updatedMusterSetAC), '/app/' + mqttDaten.UserID + '/' + asn + '/thing/property/set'); } function generateAndSyncSub(id, JElements, sub = false, preset = "0_userdata.0") { if (!JElements || typeof JElements !== 'object') { log('Ungültige JElements übergeben!'); return; } for (var JElement in JElements) { var AktVal; if (typeof JElements[JElement] === "object") { if (id === "") { generateAndSyncSub(JElement, JElements[JElement], true, preset); } else { generateAndSyncSub(id + "." + JElement, JElements[JElement], true, preset); } //generateAndSyncSub(id + "." + JElement, JElements[JElement], true, preset); } else { try { if (isState2(preset + "." + id + "." + JElement)) AktVal = getState(preset + "." + id + "." + JElement).val; else AktVal = null } catch (e) { log("Fehler: " + e); } if (AktVal == null) { createState(preset + "." + id + "." + JElement, JElements[JElement], false); AktVal = JElements[JElement]; } if (AktVal != JElements[JElement]) { if (isState2(preset + "." + id + "." + JElement)) { setState(preset + "." + id + "." + JElement, JElements[JElement]); } } } } } /* Checks if a a given state or part of state is existing. * This is a workaround, as getObject() or getState() throw warnings in the log. * Set strict to true if the state shall match exactly. If it is false, it will add a wildcard * to the end. * See: https://forum.iobroker.net/topic/11354/ * @param {string} strStatePath Input string of state, like 'javascript.0.switches.Osram.Bedroom' * @param {boolean} [strict=false] Optional: if true, it will work strict, if false, it will add a wildcard * to the end of the string * @return {boolean} true if state exists, false if not */ function isState2(strStatePath, strict = true) { let mSelector; if (strict) { mSelector = $(strStatePath); } else { mSelector = $(strStatePath + "*"); } if (mSelector.length > 0) { return true; } else { return false; } } //--------- Prüft übergebne zeiträume und Tage und gibt True zurück wenn innerhalb //log("return: " + CheckTime2("22:00","11:00",[0,1,2,3,4,5,6],getDateObject("06 Nov 2018 08:30:00 GMT+0100"))); function CheckTime2(Startzeit, Endzeit, Wochentage, d = new Date()) { var locStartDate = getDateObject(formatDate(d, "MM DD YYYY " + Startzeit)); var locEndDate = getDateObject(formatDate(d, "MM DD YYYY " + Endzeit)); var LocOriginal = getDateObject(formatDate(d, "MM DD YYYY hh:mm:ss")); Wochentage = Wochentage.map(function (x) { return parseInt(x, 10); }); if (locStartDate.getTime() > locEndDate.getTime()) { if (LocOriginal.getTime() >= locStartDate.getTime() && LocOriginal.getTime() <= getDateObject(formatDate(d, "MM DD YYYY 23:59:59")).getTime()) { d.setDate(d.getDate() + 1); locEndDate = getDateObject(formatDate(d, "MM DD YYYY " + Endzeit)); } else { d.setDate(d.getDate() - 1); locStartDate = getDateObject(formatDate(d, "MM DD YYYY " + Startzeit)); } } var n = getDateObject(locStartDate).getDay(); if (Wochentage.includes(n) && LocOriginal.getTime() >= getDateObject(locStartDate).getTime() && LocOriginal.getTime() <= getDateObject(locEndDate).getTime()) { return true } else { return false } } function SunTimes(time = 0) { // @ts-ignore const SunCalc = require('suncalc'); const date = new Date(); // Berechnung von Sonnenaufgang und Sonnenuntergang const sunTimes = SunCalc.getTimes(date, ConfigData.latitude, ConfigData.longitude); const sunrise = sunTimes.sunrise.getHours() + ':' + sunTimes.sunrise.getMinutes(); const sunset = sunTimes.sunset.getHours() + ':' + sunTimes.sunset.getMinutes(); if (time == 0) { return sunrise } else { return sunset } } function istTag(offsetMin = 0) { //log("Ist Tag?: " + CheckTime2(SunTimes(0).toString(), addMinutesToTime(SunTimes(1).toString(),offsetMin), [0, 1, 2, 3, 4, 5, 6], new Date())); return CheckTime2(SunTimes(0).toString(), addMinutesToTime(SunTimes(1).toString(), offsetMin), [0, 1, 2, 3, 4, 5, 6]) } function addMinutesToTime(time, minutesToAdd) { var parts = time.split(":"); var hours = parseInt(parts[0]); var minutes = parseInt(parts[1]); var totalMinutes = hours * 60 + minutes + minutesToAdd; var newHours = Math.floor(totalMinutes / 60) % 24; var newMinutes = totalMinutes % 60; var newTime = newHours.toString().padStart(2, "0") + ":" + newMinutes.toString().padStart(2, "0"); return newTime; } //############ Funktionen zum Setzen von Werten for (var i = 0; i < ConfigData.seriennummern.length; i++) { if (ConfigData.seriennummern[i].isPowerStream) { const asn = ConfigData.seriennummern[i].seriennummer //log(asn) // @ts-ignore await createMyState('app_' + mqttDaten.UserID + '_' + asn + '_thing_property_set.setAC') on({ id: ConfigData.statesPrefix + '.app_' + mqttDaten.UserID + '_' + asn + '_thing_property_set.setAC', change: "any", ack: false }, function (obj) { setAC(asn, Number(obj.state.val)) setState(obj.id, obj.state.val, true); }); //Powersumme bilden und schreiben data.InverterHeartbeat.pv1InputWatts on({ id: new RegExp(ConfigData.statesPrefix + '.app_device_property_' + asn + '.data.InverterHeartbeat.pv.InputWatts'), change: "any" }, function (obj) { let state1 = ConfigData.statesPrefix + '.app_device_property_' + asn + '.data.InverterHeartbeat.pv1InputWatts'; let state2 = ConfigData.statesPrefix + '.app_device_property_' + asn + '.data.InverterHeartbeat.pv2InputWatts'; //let korstate = ConfigData.statesPrefix + '.app_device_property_' + asn + '.data.InverterHeartbeat.X_Unknown_5'; let sumState = ConfigData.statesPrefix + '.app_device_property_' + asn + '.data.InverterHeartbeat.sumPV'; if (existsState(state1) || existsState(state2)) { let pv1InputWatts = 0, pv2InputWatts = 0 if (existsState(state1)) pv1InputWatts = GetValAkt(state1, 30).val if (existsState(state2)) pv2InputWatts = GetValAkt(state2, 30).val //let sum = GetValAkt(state1, 30).val + GetValAkt(state2, 30).val - (getState(korstate).val * 20); let sum = (pv1InputWatts + pv2InputWatts) * (0.93); if (!existsState(sumState)) { createState(sumState, sum); } else { setState(sumState, sum); //log("Summe gesetzt für "+asn+": "+ sum) } } }); } } const idRegex = new RegExp(ConfigData.statesPrefix + '\.app_[A-Za-z0-9_]+_thing_property_set\\.writeables\\..*'); on({ id: idRegex, change: "any", ack: false }, function (obj) { const idParts = obj.id.split('.'); const lastPart = idParts[idParts.length - 1]; const matchedEntry = writeables.find((entry) => entry.name === lastPart); if (matchedEntry) { //log("Write Event: " + obj.id + " val: " + obj.state.val + " | Matched Entry: " + JSON.stringify(matchedEntry)); let updatedMuster if (matchedEntry.Typ == "DM") { updatedMuster = JSON.parse(JSON.stringify(musterslowChgPower));; updatedMuster.id = Date.now().toString() updatedMuster.params.id = matchedEntry.id updatedMuster.params[matchedEntry.ValueName] = Number(obj.state.val) } else if (matchedEntry.Typ == "D2") { updatedMuster = JSON.parse(JSON.stringify(musterDelta2));; updatedMuster.id = Date.now().toString() updatedMuster.moduleType = Number(matchedEntry.MT) updatedMuster.operateType = matchedEntry.name.replace("_D2", "") if (matchedEntry.AddParam) updatedMuster.params = JSON.parse(matchedEntry.AddParam); //updatedMuster.params.chgPauseFlag = 255 updatedMuster.params[matchedEntry.ValueName] = Number(obj.state.val) } const asn = obj.id.match(/.*?\.app_.*?_(.*?)_thing_property_set.*/)[1]; //log("Gefunden und gesendet:Topic: " + '/app/' + mqttDaten.UserID + '/' + asn + '/thing/property/set' + " Daten:" + JSON.stringify(updatedMuster)) SendJSON(JSON.stringify(updatedMuster), '/app/' + mqttDaten.UserID + '/' + asn + '/thing/property/set'); //delete updatedMuster.params[matchedEntry.ValueName] } else { log("Write Event: " + obj.id + " val: " + obj.state.val + " | No matching entry found."); } setState(obj.id, obj.state.val, true); }); //State für die gesamte PV-Leistung 'totalPV' erstellen und beschreiben on({ id: new RegExp(ConfigData.statesPrefix + '\.app_device_property_[A-Za-z0-9]{13,17}\.data\.InverterHeartbeat\.sumPV'), change: "any" }, function (obj) { //log("sumpv Evemnt:" + obj.id + " val: " + obj.state.val) let totalPV = 0 for (var i = 0; i < ConfigData.seriennummern.length; i++) { if (ConfigData.seriennummern[i].isPowerStream) { const asn = ConfigData.seriennummern[i].seriennummer if (isState2(ConfigData.statesPrefix + '.app_device_property_' + asn + '.data.InverterHeartbeat.sumPV')) { totalPV = totalPV + GetValAkt(ConfigData.statesPrefix + '.app_device_property_' + asn + '.data.InverterHeartbeat.sumPV', 20).val } } } totalPV = totalPV / 10 let totalPVState = ConfigData.statesPrefix + '.totalPV'; if (!existsState(totalPVState)) { createState(totalPVState, Number(totalPV.toFixed(0))); } else { setState(totalPVState, Number(totalPV.toFixed(0))); //log("Summe gesetzt für "+asn+": "+ sum) } }) // Einstellen der Einspeiseleistung function setAC(asn, Value) { let updatedMusterSetAC = musterSetAC; if (Value <= -1) { delete updatedMusterSetAC.item.meta; delete updatedMusterSetAC.item.ValByte; } else { updatedMusterSetAC.header.pdata.value = Value updatedMusterSetAC.header.dataLen = getVarintByteSize(Value) } updatedMusterSetAC.header.seq = Date.now() updatedMusterSetAC.header.deviceSn = asn //log(JSON.stringify(updatedMusterSetAC)) setState(ConfigData.statesPrefix + '.app_' + mqttDaten.UserID + '_' + asn + '_thing_property_set.setAC', Value.toString(), true) SendProto(JSON.stringify(updatedMusterSetAC), '/app/' + mqttDaten.UserID + '/' + asn + '/thing/property/set'); } // ########### Grundbedarf/Einspeiseleistung steuern // Den niedrigeste Wert vom Gesamtverbrauch der letzten x Minuten ermitteln function getLowestValue(id, minuten = 120) { //log("getLowestValue-Aufruf für:" + id) const now = Date.now(); const range = minuten * 60 * 1000; return new Promise((resolve, reject) => { sendTo('history.0', 'getHistory', { id: id, options: { start: now - range, end: now, aggregate: 'none', ignoreNull: true } }, (result) => { if (result.error) { log("getLowestValue-fehler: " + result.error) reject(result.error); } else if (result.result && result.result.length > 0) { let lowestValue = result.result[0].val; for (let i = 1; i < result.result.length; i++) { if (result.result[i].val < lowestValue) { lowestValue = result.result[i].val; } //log(result.result[i].val ) } let Dauer = ((Date.now() - now) / 1000) if (Dauer > 1) log("getLowestValue-Dauer: " + ((Date.now() - now) / 1000) + "s") resolve(Math.floor(Number(lowestValue))); } else { //log("getLowestValue-fehler NoData: " + error.message) // reject({ message: "Keine Daten verfügbar" }); reject(new Error('No data')); } }); }); } //Einspeiseleistung berechnen und bei Änderung setzen var OldNewValue = 0 var FullPower = false function SetBasePower(asn) { //log("SetBasePower") //return if (isState2(ConfigData.SmartmeterID)) { const batstate = ConfigData.statesPrefix + ".app_device_property_" + asn + ".data.InverterHeartbeat.batSoc" if (Number(GetValAkt(batstate, 60).val) >= ConfigData.battPozOn && !FullPower) { FullPower = true setAC(asn, (Math.floor(ConfigData.MaxPower) * 10)) if (true || ConfigData.Debug) log("Batterie ist bei " + ConfigData.battPozOn + "%: Einspeisung auf Maximum.") return } else if ((Number(GetValAkt(batstate, 60).val) > ConfigData.battPozOff || (Number(GetValAkt(batstate, 60).val) == 0)) && FullPower) { return } else if (FullPower) { FullPower = false if (true || ConfigData.Debug) log("Batterie runter auf " + ConfigData.battPozOff + "%: Normalbetieb.") } const batInputWatts = ConfigData.statesPrefix + ".app_device_property_" + asn + ".data.InverterHeartbeat.batInputWatts" if (Number(GetValAkt(batInputWatts, 60).val - 10) <= ConfigData.MaxPower * -10) { log("Maximalleistung geht in die Batterie. Stelle zusäzlich Einpeisung auf 200 W") setAC(asn, (200 * 10)); return } getLowestValue(ConfigData.statesPrefix + ".RealPower", ConfigData.MinValueMin) .then(lowestValue => { //log("SetBasePower lowestValue " + lowestValue) if (lowestValue != 0) { var AndereVerbraucher = 0 const ToHomeId = ConfigData.statesPrefix + ".app_device_property_" + asn + ".data.InverterHeartbeat.invOutputWatts" if (isState2(ToHomeId)) { AndereVerbraucher = Number(GetValAkt(ToHomeId).val) / 10 var NewValue = (lowestValue - ConfigData.BasePowerOffset) //Einspeisung der andernen Powerstream feststellen und abziehen: let otherPS = 0 for (var i = 0; i < ConfigData.seriennummern.length; i++) { if (ConfigData.seriennummern[i].isPowerStream && ConfigData.seriennummern[i].seriennummer != asn) { const asn = ConfigData.seriennummern[i].seriennummer otherPS = otherPS + Number(GetValAkt(ConfigData.statesPrefix + '.app_device_property_' + asn + '.data.InverterHeartbeat.invOutputWatts').val) //log("otherPS: " + otherPS / 10) } } NewValue = Number((NewValue - (otherPS / 10)).toFixed(0)) if (NewValue > ConfigData.MaxPower) NewValue = ConfigData.MaxPower //log("Newval:"+ NewValue) if (NewValue < 0) NewValue = 0 //log("LowVal in " + ConfigData.MinValueMin + " Minuten: " + lowestValue + " W, Andere: " + (otherPS / 10) + " W, Offset " + ConfigData.BasePowerOffset + "W, neu: " + NewValue + " W"); if (false || ConfigData.Debug) { log("Tiefster Wert der letzten " + ConfigData.MinValueMin + " Minuten: " + lowestValue + " W"); log("Summe der Anderen PS: " + (otherPS / 10) + " W"); log("Rest ist: " + Math.floor((lowestValue) - (otherPS / 10)) + " W"); log("Offset von: " + ConfigData.BasePowerOffset + " W abziehen = " + (Math.floor((lowestValue) - (otherPS / 10)) - ConfigData.BasePowerOffset) + " W Neuer Einspeisewert") log("Neuer Wert unter Berücksichtigung der Limits: " + NewValue + " W") log("Einspeisung aktuell: " + AndereVerbraucher + " W") log("===================================================") } //setAC(asn,10) if (OldNewValue != NewValue) { setAC(asn, (Math.floor(NewValue) * 10)) if (false || ConfigData.Debug) log("Änderung für Einspeisung gesendet" + Math.floor(NewValue) * 10) } OldNewValue = NewValue } } }) .catch(error => { log("Fehler beim Abrufen des niedrigsten Werts: " + error); }); } } function GetValAkt(id, minuten = 15, reset = true) { if (isState2(id)) { const state = getState(id) if (state.ts > Date.now() - minuten * 60 * 1000) { return state } else { if (typeof state.val === 'number') { if (reset || state.val != 0) setState(id, 0, true) } else { if (reset || state.val != "0") setState(id, "0", true) } state.val = 0 return state } } else { //log("Kein State: " + id + "lege an.") createState(id, "0", false) //return getState(id) const leerstate = {} leerstate.val = "0" leerstate.ts = Date.now() return leerstate } } // State RealPower anlegen wenn noch nicht vorhanden und History aktivieren if (isState2(ConfigData.SmartmeterID)) { if (!isState2(ConfigData.statesPrefix + ".RealPower")) { const stateObject = { name: "RealPower", role: "state", type: "number", read: true, write: true, custom: { "history.0": { enabled: true, aliasId: "", debounceTime: 0, blockTime: 0, changesOnly: true, changesRelogInterval: 0, changesMinDelta: 0, ignoreBelowNumber: "", disableSkippedValueLogging: true, retention: 86400, customRetentionDuration: 365, maxLength: 960, enableDebugLogs: false, debounce: 1000 } } }; createState(ConfigData.statesPrefix + ".RealPower", stateObject, function () { //* const stateId = ConfigData.statesPrefix + ".RealPower"; // Hier den ID des States angeben // Aktiviere die History-Funktion für den State const historyOptions = { id: stateId, options: { enabled: true // Setze den Wert auf true, um die History zu aktivieren } }; sendTo("history.0", "enableHistory", historyOptions, (result) => { if (result.error) { log("Fehler beim Aktivieren der History für " + stateId + ": " + result.error); } else { log("History für " + stateId + " erfolgreich aktiviert"); } }); // }); } //Wert für den realen Verbrauch. Wird alle 5 Sekunden gesetzt, wenn sich die Werte vom Smartmeter ändern let WorkInProz = false on({ id: ConfigData.SmartmeterID, change: "any" }, function (obj) { //log("SmartmeterID ereignis!") if (!WorkInProz) { WorkInProz = true setTimeout(function () { const Hausstrom = Number(getState(ConfigData.SmartmeterID).val); let Einspeisung = 0 for (var i = 0; i < ConfigData.seriennummern.length; i++) { if (ConfigData.seriennummern[i].isPowerStream) { const asn = ConfigData.seriennummern[i].seriennummer const LastACset = getState(ConfigData.statesPrefix + '.app_' + mqttDaten.UserID + '_' + asn + '_thing_property_set.setAC').ts const invOutputWattsState = GetValAkt(ConfigData.statesPrefix + ".app_device_property_" + asn + ".data.InverterHeartbeat.invOutputWatts", 50, true) const invOutputWatts = (Number(invOutputWattsState.val) / 10) //const invOutputWatts = Number(GetValAkt(ConfigData.statesPrefix + ".app_device_property_" + asn + ".data.InverterHeartbeat.invOutputWatts", 50, true).val.toFixed(0)) / 10 //Nur Werte berücksichtigen, die nicht älter als 60 Minuten sind const lastOutset = invOutputWattsState.ts if (lastOutset > Date.now() - 60 * 60 * 1000) { //Nach Änderung der AC-Leistung müssen die States (invOutputWatts) neuer sein als die Änderung if ((Number(lastOutset) < Number(LastACset)) && invOutputWatts != 0) { //log("RealPower Set Warte auf aktuelle Daten... " + new Date(lastOutset).toLocaleTimeString('de-DE') + " / " + new Date(LastACset).toLocaleTimeString('de-DE')) //WorkInProz = false; //return } Einspeisung = Einspeisung + invOutputWatts; //log("Einspeisung: " + Einspeisung) } } } setState(ConfigData.statesPrefix + ".RealPower", Number((Hausstrom + Einspeisung).toFixed(0))); //log("Neu gesetzte Realpower: " + Number((Hausstrom + Einspeisung).toFixed(0))); WorkInProz = false; }, 5000); } }); } function getVarintByteSize(number) { let byteSize = 0; while (number >= 128) { byteSize++; number >>= 7; // Rechtsschiebeoperation um 7 Bits } byteSize++; byteSize++; return byteSize; }
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@waly_de Danke! Ich hab erstmal den Objekt-Baum gelöscht und gucke was da so kommt. Ist ja auch irgendwie spannend...
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@waly_de Es läuft irgendwie. Aber ich bekomme diese Meldung:
6:08:31.903 info javascript.0 (1725654) script.js.common.ecoFlow_PowerStream: Fehler beim Abrufen des niedrigsten Werts: Error: No data
Der History Adapter läuft aber.
EDIT: Hatte mal das Debug gestartet und jetzt plötzlich geht es.
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@waly_de 0_userdata.0.ecoflow.app_device_property_HWXXX.data.InverterHeartbeat2.X_Unknown_45
Das ist der Watt-Wert, der aus dem Inverter in das Netz geht.
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@waly_de
Ich habe jetzt auch die neueste Version 0.6.7 des Scripts im Test. Es läuft auf jeden Fall erstmal wieder. Wenn mir was auffällt, gebe ich Bescheid.
Danke für das Engagement! -
@dreffi Der Batterie-Ladestand ist noch nicht verfügbar bei mir.
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@mattenausohz
Bei mir ist er aktuell vorhanden. Als ich das Script heute morgen gestartet habe, wurde er aber auch lange Zeit nicht aktualisiert/angezeigt. Das Script läuft jetzt seit knapp 3 Stunden und er ist da.
Ich werde für ein paar wichtige Werte wieder die Historie aktivieren zur Fehlersuche.Nachtrag: einige Werte werden im Moment nur sehr sehr selten aktualisiert. Meine Batterieladung ist jetzt in 10 Minuten um mehr als 3% angestiegen, aber beim Powerstream wird der Wert nicht aktualisiert.
Nachtrag 2: jetzt wurde der SOC im Powerstream mal aktualisiert. Der Sprung war damit von 18 auf 40%. Ich beobachte weiter in welchen Zeitabständen hier eine Aktualisierung erfolgt.
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Huhu,
Ich würde gerne "nur" die Leistung die der Powerstream von den Panelen bekommt in den History-Adapter bekommen.
Kann ich das Script dafür nutzen ohne dass irgendwelche Änderungen an meinem Powerstream vorgenommen werden? Leider steige ich beim javascript noch nicht so durch um es aus dem Script herauslesen zu können. -
@xfirf said in ecoflow-connector-Script zur dynamischen Leistungsanpassung:
Huhu,
Ich würde gerne "nur" die Leistung die der Powerstream von den Panelen bekommt in den History-Adapter bekommen.
Kann ich das Script dafür nutzen ohne dass irgendwelche Änderungen an meinem Powerstream vorgenommen werden? Leider steige ich beim javascript noch nicht so durch um es aus dem Script herauslesen zu können.Ich hatte gerade einen vergleichbaren Gedanken, ich würde mich gerne erst langsam rantasten und vorerst den Powerstream nicht beeinflussen wollen (Wetter ist hier eh so bescheiden, dass nichts für den Akku da ist
Bevor ich anfange zu suchen, gibt es (ggf. bereits) eine einfache Möglichkeit es sozusagen im Demo Modus laufen zu lassen.
Also alles soll ablaufen (Daten von Ecoflow mqtt broker holen, verarbeiten in ioBroker, ... aber nicht den Powerstream steuern), alles was als Einstellung/set zum ecoflow mqtt broker gehen würde, würde auf einen lokalen mqtt broker umgeleitet oder anderweitig in iobroker protokolliert (dann könnte ich gewisse "Trockenübungen" machen)? -
Ich habe das Script nun zum Laufen bekommen und habe auch viele Werte unter "0_userdata/0/ecoflow" reinbekommen. Aber wenn ich dann nach z.B. data.item.meta.PV1_Power suche finde ich nichts. Bezieht sich die Variable auf den Speicher? Den habe ich noch nicht.