netvox RP02RH Series User manual
Wireless Miniature Circuit
Breaker with Power Meter
RP02RH Series
User Manual
Copyright©Netvox Technology Co., Ltd.
This document contains proprietary technical information which is the property of NETVOX Technology. It shall
be maintained in strict confidence and shall not be disclosed to other parties, in whole or in part, without written
permission of NETVOX Technology. The specifications are subject to change without prior notice.
Wireless Miniature Circuit Breaker with Power Meter
Model: RP02RH Series
2
Table of Content
1. Introduction ..............................................................................................................................................................3
2. Appearance ...............................................................................................................................................................4
3. Circuit Breaker Specifications .................................................................................................................................5
4. Main Features...........................................................................................................................................................7
5. Set up Instruction .....................................................................................................................................................7
6. Data Transmission....................................................................................................................................................9
6.1 Default Value of Protection Parameters..........................................................................................................10
6.2 Example of ReportDataCmd...........................................................................................................................11
6.2.1 1PN/1PNL Report Data ..........................................................................................................................11
6.2.2 3PN/3PNL Report Data ..........................................................................................................................13
6.3 Example of ConfigureCmd by Acquisition Mode..........................................................................................15
6.3.1 Report Configuration..............................................................................................................................15
6.3.2 Remote Control Circuit Breaker ............................................................................................................16
6.3.3 Mode Switching......................................................................................................................................17
6.4 Example of Configurecmd By Transparent Transmission Mode...................................................................17
7. Application .............................................................................................................................................................18
8. Installation..............................................................................................................................................................21
8.1 Circuit Breaker Installation.............................................................................................................................21
8.2 Wiring..............................................................................................................................................................25
8.3 Dial Switch......................................................................................................................................................26
8.4 Manual/ Automatic Self Inspection Function (For 1PNL, 3PNL) .................................................................26
8.5 Combination of Power Modules and Circuit Breakers ..................................................................................27
9. Important Maintenance Instruction........................................................................................................................29
3
1. Introduction
RP02RH1PN Wireless 1P+N Miniature Circuit Breaker with Power Meter
RP02RH1PNL Wireless 1P+N Miniature Circuit Breaker with Power Meter and Leak Detection
RP02RH3PN Wireless 3P+N Miniature Circuit Breaker with Power Meter
RP02RH3PNL Wireless 3P+N Miniature Circuit Breaker with Power Meter and Leak Detection
RP02RH series is a class C smart Miniature Circuit Breaker with Power Meter based on LoRaWAN open protocol.
It can monitor the status of all external circuit breakers in real time. (connect up to 9 poles).
When the power line is abnormal (such as undervoltage, overvoltage, overload, leakage, etc.), the system will automatically
give early warning, alarm and power off to prevent electrical fire to the greatest extent. At the same time, it can periodically
monitor the temperature, electric quantity, current, voltage, power, leakage current, circuit breaker status and other data
information of all external circuit breakers and report to the gateway platform.
With the system, it can be controlled remotely and regularly, can be switched regularly, and can automatically conduct
monthly leakage self-inspection, with limited power and electric quantity. It has the function of local self-inspection and
reports the detection information to the gateway platform to make the hidden danger disappear.
At the same time, it can be switched to serial port transparent transmission mode, and can reply 128 bytes of data at most
(depending on the current communication rate). Serial port transparent transmission only supports RS-485 protocol.
The number of poles corresponding to each circuit breaker type
Circuit Breaker Type
Number of Poles
1PN / 1PNL
2
3PN / 3PNL
4
For example, a LoRa / LoRaWAN Radio Module can connect to:
(a) 4 * 1PN/1PNL (8 poles in total)
(b) 2 * 3PN/3PNL (8 poles in total)
(c) 2 * 1PN/1PNL + 1 * 3PN/3PNL (8 poles in total)
LoRa Wireless Technology:
LoRa is a wireless communication technology famous for its long-distance transmission and low power consumption.
Compared with other communication methods, LoRa spread spectrum modulation technique greatly extend the
communication distance. It can be widely used in any use case that requires long-distance and low-data wireless
communications. For example, automatic meter reading, building automation device, wireless security systems, industrial
monitoring. It has features like small size, low power consumption, long transmission distance, strong anti-interference ability
and so on.
4
LoRaWAN:
LoRaWAN uses LoRa technology to define end-to-end standard specifications to ensure interoperability between devices and
gateways from different manufacturers.
2. Appearance
LoRa/LoRaWAN Radio Module
RP02RH1PN
RS-485 Interface
Indicator
Function Key
Antenna
Power Module
LoRa/LoRaWAN
Radio Module
External Circuit Breaker
485 Signal Line
5
3. Circuit Breaker Specifications
Breaker UEZ3 (1PN)
●Rated Voltage: AC230V / 50Hz
●Rated Current: 63A
●Breaking Capacity: 6kA
●Mechanical Life: 10000 times
●Electrical Life: 6000 times
●Communication Protocol: RS485, Modbus-RTU
●Alarm Function: Overload, overvoltage, undervoltage, temperature, overpower
●Protective Function: Short circuit protection, overcurrent protection based on current setting, overvoltage protection,
undervoltage protection, over temperature protection, overpower protection
●Information Collection: Current, voltage, power, frequency, temperature, lifetime, electricity
●Error Message: 10 messages
Breaker UEZ3 (3PN)
●Rated Voltage: AC400V / 50Hz
●Rated Current: 63A
●Breaking Capacity: 6kA
●Mechanical Life: 10000 times
●Electrical Life: 6000 times
●Communication Protocol: RS485, Modbus-RTU
●Alarm Function: Overload, overvoltage, undervoltage, temperature, overpower
●Protective Function: Short circuit protection, overcurrent protection based on current setting, overvoltage protection,
undervoltage protection, over temperature protection, overpower protection
●Information Collection: Current, voltage, power, frequency, temperature, lifetime, electricity
●Error Message: 10 messages
6
Breaker UEZ3L (1PNL) with leakage detection
●Rated Voltage: AC230V / 50Hz
●Rated Current: 63A
●Breaking Capacity: 6kA
●Mechanical Life: 10000 times
●Electrical Life: 6000 times
●Communication Protocol: RS485, Modbus-RTU
●Residual Current Type: AC type
●Residual Current: 30mA
●Alarm Function: Leakage, overload, overvoltage, undervoltage, temperature, overpower
●Protective Function: Leakage protection, short circuit protection, overcurrent protection based on current setting, overvoltage
protection, undervoltage protection, over temperature protection, overpower protection
●Information Collection: Leakage, current, voltage, power, frequency, temperature, lifetime, electricity
●Error Message: 10 messages
Breaker UEZ3L (3PNL) with leakage detection
●Rated Voltage: AC400V / 50Hz
●Rated Current: 63A
●Breaking Capacity:6kA
●Mechanical Life: 10000 times
●Electrical Life: 6000 times
●Communication Protocol: RS485, Modbus-RTU
●Residual Current Type: AC type
●Residual Current :30mA
●Alarm Function: Leakage, overload, overvoltage, undervoltage, temperature, overpower
●Protective Function: Leakage protection, short circuit protection, overcurrent protection based on current setting, overvoltage
protection, undervoltage protection, over temperature protection, overpower protection
●Information Collection: Leakage, current, voltage, power, frequency, temperature, lifetime, electricity
●Error Message: 10 messages
7
4. Main Features
⚫Compatible with LoRaWANTM
⚫Support RS485 serial port transparent transmission.
⚫Circuit breaker attribute value collection.
⚫Multiple circuit breaker protection.
⚫Simple operation and setting.
5. Set up Instruction
On/Restore to factory setting
Power on
Power supply of power module
Turn on
Power supply of power module, the green light flashes once: success
Turn off (Restore to factory setting)
Press and hold the function key for 5 seconds till green indicator flashes for 20 times.
Power off
Disconnect the DC12V power supply
Note:
1. Five seconds after power on, the device will be in engineering test mode.
2. The interval between two power outages and power on shall be about 10 seconds to
avoid the interference of energy storage elements such as capacities and inductors.
Network Joining
Never joined the network
Turn on the device to search the network.
The green indicator stays on for 5 seconds: success
The green indicator remains off: fail
Had joined the network
(Not restore to factory setting)
Turn on the device to search the previous network.
The green indicator stays on for 5 seconds: success
The green indicator remains off: fail
Fail to join the network
When the network cannot be added, it is recommended to check the device registration
information on the gateway or consult your platform server provider.
8
Function Key
Press and hold for 5 seconds
Function: Restore to factory setting
The green indicator flashes for 20 times: success
The green indicator remains off: fail
Press once
The device is in the network: green indicator flashes once and sends a format report
87 + ReceiveData (ReceiveData is the latest received data) format report
The device is not in the network: green indicator remains off
Baud Rate Configuration
Default Baud Rate
9600
Collocation Method
Issue command through LoRaWAN
Baud Rate Options
00 Baudrate = 115200
01 Baudrate = 57600
02 Baudrate = 38400
03 Baudrate = 28800
04 Baudrate = 19200
05 Baudrate = 9600
06 Baudrate = 4800
07 Baudrate = 2400
9
6. Data Transmission
When the device is powered on, it will immediately send a version package report.
The Configuration Mode
Acquisition mode (default)
Transparent transmission mode
Default setting:
1. Acquisition Mode
ReportMaxTime: 900s // Subject to factory settings
ReportMinTime: 10s // Netvox LoRa private default is 30s
1PN/1PNL report count: 4
3PN/3PNL report count: 8
*ReportMaxTime must be greater than
(Number of 1PN/1PNL * 1PN/1PNL report count + Number of 3PN/3PNL * 3PN/3PNL report count)* MinTime
2. Serial Port Transparent Transmission Mode
The device has no operation before any configuration.
The device sends instructions through LoRaWAN to configure the data to be sent through RS485, and reports the data
received by RS485 to the gateway at the same time.
The device sends instructions through LoRaWAN to configure the time of sending the data periodically.
When the RS485 interface of LoRa/LoRaWAN Radio Module receives the serial port data sent by the RS485 device connected
with it, it will actively report the received data to the gateway in the format of 87 + Receive Data.
Note:
The data transmission cycle of the device shall be subject to the burning configuration.
The interval between two reports must be the maximum time.
Refer to Netvox LoRaWAN application command documents and command for data analysis reported by the device.
http://cmddoc.netvoxcloud.com/cmddoc
10
6.1 Default Value of Protection Parameters
Protection Method:
0x00
None
0x01
Alarm
0x02
Trip
0x03
Alarm and trip
Function
Protection Method
(Can modify)
Condition
(Cannot modify)
Overload Protection
0x02-Trip
Action value
120%Ir (3PN,3PNL)
125%Ir (1PN,1PNL)
Alarm value
113% Ir
Time coefficient
15s
Undervoltage Protection
0x02-Trip
Action value
160V
Alarm value
180V
Trip time
3s
Overvoltage Protection
0x02-Trip
Action value
270V
Alarm value
260V
Trip time
6s
Leakage Protection
(IΔn =30mA)
0x02-Trip
Alarm value
3PNL: 9mA
1PNL:50%*IΔn
Temperature Protection Leakage Protection
0x00-None
Action value
80℃
Alarm value
75℃
Trip time
30s
Phase Failure Protection
(3PN/3PNL support)
0x00-None
Action value
70%
Alarm value
80%
Trip time
10s
Overpower protection
(1PN, 1PNL support)
(P=rated voltage*setting current)
0x00-None
Action value
150%P
Alarm value
110%P
Trip time
30s
11
6.2 Example of ReportDataCmd
FPort:0x06
Bytes
1
1
1
Var(Fix=8 Bytes)
Version
DeviceType
ReportType
NetvoxPayLoadData
Version–1 byte –0x01——the Version of NetvoxLoRaWAN Application Command Version
DeviceType–1 byte –Device Type of Device
The DeviceType is listed in Netvox LoRaWAN Application DeviceType doc
ReportType – 1 byte –the presentation of the NetvoxPayLoadData,according the DeviceType
NetvoxPayLoadData– Fixed bytes (Fixed =8bytes)
6.2.1 1PN/1PNL Report Data
ReportType=0x01-0x04
Device
Device
Type
Repor
t
Type
NetvoxPayLoadData
RP02RH
1PN(L)
Series
0xC9
0x01
Breaker
RS485Addr
(1Byte)
BreakerType
(1Byte)
1:1P
2:1PN
3:1PNL
4:3P
5:3PN
6:3PNL
16:4P
BreakerProtect
StatusBits
(1Byte)
Bit0:Alarm,
Bit1:Pre-Trip
Bit2:Trip
Bit3-
Bit7:Reserved
AlarmStatusBits
(1Byte)
Bit0:OverLoad
Bit1:Reserved
Bit2:CreepAge
Bit3:UnderVol
Bit4:OverVol
Bit5:Temperature
Bit6:Other
Bit7:OverPower
Pre-TripStatusBits
(1Byte)
Bit0:OverLoad
Bit1: Other
Bit2:CreepAge
Bit3:UnderVol
Bit4:OverVol
Bit5:Temperature
Bit6:Other
Bit7:OverPower
TripStatusBits
(1Byte)
Bit0:OverLoad
Bit1: Other
Bit2:CreepAge
Bit3:UnderVol
Bit4:OverVol
Bit5: HighOverVo
Bit6: Temperature
Bit7: Other
HandOrAuto
ControlAnd
SelfTestStaus
(1Byte)
0x00_Auto
0x01_Hand
0x03_RemoteSelfTest
OnOffStatus
(1Byte)
0x00_Off
0x01_On
0x02
BreakerRS485Addr
(1Byte)
Current
(2Bytes,Unit:10mA)
Voltage
(2Bytes,Unit:1V)
Power
(2Bytes,Unit:1w)
Temperature
(1Byte)
Signed,Unit:1°C
0x03
BreakerRS485Addr
(1Byte)
Energy
(4Bytes, unit:1wh)
Frequency
(1Byte,Unit:1HZ)
PowerFactor
(1Byte,Range:0-100)
Reserved
(1Byte,fixed 0x00)
0x04
BreakerRS485Addr
(1Byte)
LeakageCurrent
(2Bytes,Unit:0.01mA)
*1PN Unsupported
OnOffTotalCount
(4Bytes)
Reserved
(1Byte,fixed 0x00)
Example of 1PN / 1PNL
#Packet 1: 01C9010203010800000100
1st byte (01): Version
2nd byte (C9): DeviceType - RP02RH1PN(L) Series
3rd byte (01): ReportType
4th byte (02): Breaker RS485Addr-2
12
5th byte (03): Breaker Type-3:1PNL
6th byte (01): BreakerProtectStatusBits-Alarm, 0x01=00000001 (bit 0=1)
7th byte (08): AlarmStatusBits-UnderVol (Low voltage alarm) , 0x08 = 00001000 (bit3=1)
8th byte (00): Pre-TripStatusBits-NULL
9th byte (00): TripStatusBits-NULL
10th byte (01): HandOrAutoControlAndSelfTestStaus-Hand
11th byte (00): OnOffStatus-Off
#Packet 2: 01C902020000009500001B
1st byte (01): Version
2nd byte (C9): DeviceType -RP02RH1PN(L) Series
3rd byte (02): ReportType
4th byte (02): Breaker RS485Addr-2
5th 6th byte (0000): Current-0mA
7th 8th byte (0095): Voltage-149V, 0x95=149
9th 10th byte (0000): Power-0 w
11th byte (1B): Temperature-27°, 0x1B=27
#Packet 3: 01C9030200000038310000
1st byte (01): Version
2nd byte (C9): DeviceType - LoRa/LoRaWAN Radio Module
3rd byte (03): ReportType
4th byte (02): Breaker RS485Addr-2
5th -8th byte (00000038): Energy-56wh, 0x38=56
9th byte (31): Frequency-49 Hz, 0x31=49
10th byte (00): PowerFactor-0
11th byte (00): Reserved
#Packet 4: 01C9040200000000007100
1st byte (01): Version
2nd byte (C9): DeviceType - LoRa/LoRaWAN Radio Module
3rd byte (04): ReportType
4th byte (02): Breaker RS485Addr-2
5th 6th byte (0000): LeakageCurrent-0
7-10th byte (00000071): OnOffTotalCount-113, 0x71=113
11th byte (00): Reserved
13
6.2.2 3PN/3PNL Report Data
Report Type=0x11-0x18
Device
Device
Type
Report
Type
NetvoxPayLoadData
RP02RH
3PN(L)
Series
0xC9
0x11
BreakerRS485Addr
(1Byte)
BreakerType
(1Byte)
1:1P
2:1PN
3:1PNL
4:3P
5:3PN
6:3PNL
16:4P
BreakerProtectStatusBit
(2Bytes)
Bit0:Alarm
Bit1:Pre-Trip
Bit2:Trip
Bit3:OffLine
Bit4-Bit15:Reserved
AlarmStatusBit
(2Bytes)
Bit0:APhaseOverLoad
Bit1:BPhaseOverLoad
Bit2:CPhaseOverLoad
Bit3:NPhaseOverLoad
Bit4-5:Reserved
Bit6: CreepAge
Bit7:APhaseUnderVol
Bit8:BPhaseUnderVol
Bit9:CPhaseUnderVol
Bit10:APhaseOverVol
Bit11:BPhaseOverVol
Bit12:CPhaseOverVol
Bit13:Temperature
Bit14:Reserved
Bit15:LeakingPhase
Pre-TripStatusBits
(2Bytes)
Bit0:APhaseOverLoad
Bit1:BPhaseOverLoad
Bit2:CPhaseOverLoad
Bit3:NPhaseOverLoad
Bit4-5:Reserved
Bit6: CreepAge
Bit7:APhaseUnderVol
Bit8:BPhaseUnderVol
Bit9:CPhaseUnderVol
Bit10:APhaseOverVol
Bit11:BPhaseOverVol
Bit12:CPhaseOverVol
Bit13:Temperature
Bit14:Reserved
Bit15:LeakingPhase
0x12
BreakerRS485Addr
(1Byte)
TripStatusBits (2Bytes)
Bit0:A/NPhaseOverLoad
Bit1:BPhaseOverLoad
Bit2:CPhaseOverLoad
Bit3:APhaseInstantTrip
Bit4:BPhaseInstantTrip
Bit5:CPhaseInstantTrip
Bit6: CreepAge
Bit7:APhaseUnderVol
Bit8:BPhaseUnderVol
Bit9:CPhaseUnderVol
Bit10:APhaseOverVol
Bit11:BPhaseOverVol
Bit12:CPhaseOverVol
Bit13:Temperature
Bit14:RemoteSelfTest
Bit15:LeakingPhase
APhaseCurrent
(2Bytes,Unit:10mA)
BPhaseCurrent
(2Bytes,Unit:10mA)
Reserved
(1Byte,fixed 0x00)
0x13
BreakerRS485Addr
(1Byte)
CPhaseCurrent
(2Bytes,Unit:10mA)
APhaseVoltage
(2Bytes,Unit:1V)
BPhaseVoltage
(2Bytes,Unit:1V)
Temperature
(1Byte Signed,Unit:1°C)
0x14
BreakerRS485Addr
(1Byte)
CPhaseVoltage
(2Bytes,Unit:1V)
APhasePower
(2Bytes,Unit:1w)
BPhasePower
(2Bytes,Unit:1w)
Frequency
(1Byte,Unit:1HZ)
0x15
BreakerRS485Addr
(1Byte)
CPhasePower
(2Bytes,Unit:1w)
APhaseEnergy
(4Bytes, unit:1wh)
Reserved
(1Byte,fixed 0x00)
0x16
BreakerRS485Addr
(1Byte)
BPhaseEnergy
(4Bytes, unit:1wh)
APhasePowerFactor
(1Byte,Range:0-100)
BPhasePowerFactor
(1Byte,Range:0-100)
CPhasePowerFactor
(1Byte,Range:0-100)
0x17
BreakerRS485Addr
(1Byte)
CPhaseEnergy
(4Bytes, unit:1wh)
HandOrAuto
ControlStaus (1Byte)
0x00_Auto 0x01_Hand
OnOffStatus (1Byte)
0x00_Off 0x01_On
Reserved
(1Byte,fixed 0x00)
0x18
BreakerRS485Addr
(1Byte)
LeakageCurrent
(2Bytes,Unit:0.01mA)
*3PN Unsupported
OnOffTotalCount
(4Bytes)
Reserved
(1Byte,fixed 0x00)
14
Note:
Please refer to the above NetvoxPayLoadData description for the specific reported data. If no related alarm is set, all alarm related
information bits are set to 0.
#Packet 1:01C9110105000103800000
BreakerRS485Addr=1
BreakerType=3PN
BreakerProtectStatusBits=Alarm
AlarmStatusBits= A/B/C Phase UnderVol (Low voltage alarm),0x380= 11 1000 0000(bit7~bit9=1)
Pre_TripStatusBits3PN=NULL
#Packet 2:01C9120100000000000000
BreakerRS485Addr=1
TripStatusBits3PN=NULL
APhaseCurrent=0.0mA
BPhaseCurrent=0.0mA
Reserved=0
#Packet 3:01C9130100000000000020
BreakerRS485Addr=1
CPhaseCurrent=0.0mA
APhaseVoltage=0V
BPhaseVoltage=0V
Temperature=32°C
#Packet 4:01C9140100950000000032
BreakerRS485Addr=1
CPhaseVoltage=149V
APhasePower=0W
BPhasePower=0W
Frequency=50HZ
#Packet 5:01C9150100000000000000
BreakerRS485Addr=1
CPhasePower=0W
APhaseEnergy=0wh
#Packet 6:01C9160100000000000000
BreakerRS485Addr=1
BPhaseEnergy=0wh
15
APhasePowerFactor=0
BPhasePowerFactor=0
CPhasePowerFactor=0
#Packet 7:01C917010000000C010000
BreakerRS485Addr=1
CPhaseEnergy=12wh
HandOrAutoControlStaus=Hand
onoff_status=off
#Packet 8:01C91801FFFF000003D900
BreakerRS485Addr=1
LeakageCurrent=NA
OnOffTotalCount-985, 0x3D9=985
6.3 Example of ConfigureCmd by Acquisition Mode
FPort:0x07
Bytes
1
1
Var (Fix =9 Bytes)
CmdID
DeviceType
NetvoxPayLoadData
CmdID–1 byte
DeviceType–1 byte –Device Type of Device
NetvoxPayLoadData– var bytes (Max=9bytes)
6.3.1 Report Configuration
Description
Device
Cmd
ID
Device
Type
NetvoxPayLoadData
Config
ReportReq
RP02RH
Series
0x01
0xC9
MinTime
(2bytes Unit:s)
MaxTime
(2bytes Unit:s)
Reserved
(5Bytes,Fixed 0x00)
Config
ReportRsp
0x81
Status
(0x00_success)
Reserved
(8Bytes,Fixed 0x00)
ReadConfig
ReportReq
0x02
Reserved
(9Bytes,Fixed 0x00)
ReadConfig
ReportRsp
0x82
MinTime
(2bytes Unit:s)
MaxTime
(2bytes Unit:s)
Reserved
(5Bytes,Fixed 0x00)
16
(1) Configure RP02RH Series parameters MinTime=10s, MaxTime=3600s
Downlink: 01C9000A0E100000000000
Device return: 81C9000000000000000000 (configuration successful)
81C9010000000000000000 (configuration failed)
(2) Read the RP02RH Series parameter
Downlink: 02C9000000000000000000
Device return: 82C9000A0E100000000000 (device current parameter)
Note:
Since the 1PN/1PNL report count of 1PN/1PNL breaker is 4 packets (0x01~0x04) and the 3PN/3PNL report count of 3PN/3PNL
breaker is 8 packets (0x11~0x18), the maximum configuration time needs to determine the configured ReportMaxTime
according to the type and number of external circuit breakers.
For example, if the RP02RH series is externally connected with two 1PN and one 3PN,
the configured ReportMaxTime must be greater than (2 * 1PN reportcount + 1 * 3PN reportcount) * MinTime
6.3.2 Remote Control Circuit Breaker
Description
Device
CmdID
Device
Type
NetvoxPayLoadData
Off
RP02RH
Series
0x90
0xC9
BreakerRS485Addr
(1Byte)
Reserved
(8Bytes,Fixed 0x00)
On
0x91
BreakerRS485Addr
(1Byte)
Reserved
(8Bytes,Fixed 0x00)
ClearEnergy
0x93
BreakerRS485Addr
(1Byte)
Reserved
(8Bytes,Fixed 0x00)
LeakageCurrent
SeftTest
0x95
BreakerRS485Addr
(1Byte)
Reserved
(8Bytes,Fixed 0x00)
(1)Control address 1 circuit breaker off
Downlink: 90C9010000000000000000
(2)Control address 1 circuit braker on
Downlink: 91C9010000000000000000
(3)Clear the circuit breaker of address 1 and clear the electric energy
Downlink: 93C9010000000000000000
(4)Control address 1 circuit breaker leakage self-test
Downlink: 95C9010000000000000000
17
6.3.3 Mode Switching
Description
Device
Cmd
ID
Device
Type
NetvoxPayLoadData
SetPass
ThroughModeReq
RP02RH
Series
0x03
0xC9
PassThroughModeOn(1Byte)
0x00_Off
0x01_On
Reserved
(8Bytes,Fixed 0x00)
SetPassThrough
ModeRsp
0x83
Status
(0x00_success)
Reserved
(8Bytes,Fixed 0x00)
GetPassThrough
ModeReq
0x04
Reserved
(9Bytes,Fixed 0x00)
GetPassThrough
ModeRsp
0x84
PassThroughModeOn(1Byte)
0x00_Off
0x01_On
Reserved
(8Bytes,Fixed 0x00)
(1)The configuration mode is acquisition mode
Downlink: 03C900000000000000000
Device return: 83C9000000000000000000 (configuration successful)
83C9010000000000000000 (configuration failed)
(2)Get current device mode
Downlink: 04C900000000000000000
Device return:84C9000000000000000000 (acquisition mode)
84C9010000000000000000 (transparent transmission mode)
6.4 Example of Configurecmd By Transparent Transmission Mode
FPort:0x0A
Description
Device
CmdID
NetvoxPayLoadData
SetPollSensor
RawCmdReq
RP02RH
Series
0x05
SensorRawCmd
SetPollSensor
RawCmdRsp
0x85
Status
(0x00_success)
SensorRawCmd
Indication
0x87
SensorRawCmd
(Var bytes,according sensor datasheet)
18
It is assumed that the protocol format of the external RS485 device is
Transmission frame: 010400100002700E
Return frame: 01040440C5D2F2235C
Configure device SensorRawCmd
Downlink: 0501040010000270E
Device return: 8500 (configuration successful)
8501 (configuration failed)
Report after 5s: 8701040440C5D2F2235C
7. Application
Smart Home
Current situation of power consumption
⚫Unclear reason for the rise in electricity charges
⚫Unclear cause of electrical failure
⚫The waste of electric energy cannot be treated
⚫Electrical hazards cannot be eliminated in time
Coping strategies
⚫Effective energy saving: Master the power consumption information at home, reduce unconscious waste and standby power
consumption
⚫Remote control: Close the loop remotely, realize the one key disconnection function, and limit the time and power
⚫Ensure safety: Realize multiple protection and self-inspection of protection function
⚫Strengthen prevention: Push line fault and remind users in time to ensure personal safety
School
Current situation of power consumption
⚫Students use high-power electrical appliances in violation of regulations, which has great hidden dangers to cause fire
⚫Accidental contact of students and fire caused by electric leakage accident
⚫Complex power environment, high personnel destiny and poor strain capacity
⚫Serious waste of electric energy
Coping strategies
⚫Safety protection: Set rated power, over limit alarm, limit malignant load and ensure power safely
⚫Remote control: Timing control, energy saving and consumption reduction, realizing people walking lights off and device
power off
⚫Fault energy warning: Power off and maintain the lines with electrical hazards in advance to prevent accidents
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⚫Cost reduction: Students’ dormitories realize remote meter reading charges and reduce management costs
Intelligent Building
Current situation of power consumption
⚫Complex power environment, high personnel density and poor strain capacity
⚫Serious waste of electric energy
⚫Personnel use high-power electrical appliances in violation of regulations, which has great hidden dangers to cause fire
⚫Accidental electric shock and electric leakage accident cause fire
Coping strategies
⚫Safety protection: Set rated power, over limit alarm, limit malignant load and ensure power safety
⚫Remote control: Timing control, energy saving and consumption reduction, realizing people walking lights off and device
power off
⚫Fault early warning: Power off and maintain the lines with electrical hazards in advance to prevent accidents
⚫Cost reduction: The meter can realize remote meter reading and charging, and reduce the management cost
Public Places
Current situation of power consumption
⚫Lack of effective power safely solutions
⚫Few professional managers and difficult management of many electric devices
⚫Poor safety awareness and failure to trouble shooting
⚫Electrical fire occurs frequently
Coping strategies
⚫Fault analysis: Accurately analyze fault types and give solutions in time
⚫Intelligent supervision: Real-time online monitoring of fire hazards, like a 24-hour close doctor using electricity
⚫Remote control: Timely power-off protection shall be provided for the fault line to master the power safely
⚫Fire prevention: Comply with the national fire safety management for dense places
Fire protection and security
Current situation of firefighting
⚫Traditional firefighting emphasizing fire elimination and neglecting prevention’’
⚫Electrical hazards cannot be eliminated in advance, causing major personal injury in case of fire
⚫Insufficient supervision investment and poor basic control ability
⚫Poor realization of fire protection design and no self-inspection function
Coping strategies
⚫Eliminate potential fire hazards: Overload, short circuit, real time monitoring of electric leakage, over temperature and
ignition to eliminate the fire at the source
⚫Reduce fire: The system is based on real-time acquisition, regular self-inspection and data processing, realize intelligent
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electrical fire early reduce the occurrence of electrical fire hazards
Information communication
Current situation of power consumption
⚫High requirements of power supply continuity
⚫Difficult regional maintenance and high fault maintenance cost
⚫Unclear cause of electrical fault
⚫Failure to supply power in time
Coping strategies
⚫Automatic reclosing: Use the automatic reclosing function to restore the power supply to the unattended base station in
time
⚫Fault warning: Power off and maintain the lines with electrical hazards in advance to prevent them from happening
⚫Fault analysis: Statistics and analysis of fault categories, and targeted maintenance and repair.
⚫Cost reduction: Reduce the operation cost and device maintenance labor caused by power failure
Charging Pile
Current situation of power consumption
⚫The traditional leakage circuit breaker + guide rail meter + contactor scheme has large volume and high space occupancy
⚫High frequency of electric shock and fire accidents
⚫Low safety, frequent failures and low durability
Coping strategies
⚫Small volume and low cost: Intelligent miniature circuit breaker= traditional leakage circuit breaker + guide rail meter +
contractor
⚫Intelligent control: Restore power supply in time in case of accidental power failure
⚫Fault alarm: Electrical fault alarm and leakage self-inspection to ensure the safe use of the device
⚫Fault analysis: Statistics and analysis of fault categories, and targeted maintenance and repair.
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