Difference between revisions of "EmonTx V3"

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(Optical Pulse Counting)
(Optical Pulse Counting)
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In the case of an electricity meter a pulse output corresponds to a certain amount of energy passing through the meter (KWhr/Wh). For single-phase domestic electricity meters (eg. Elster A100c) each pulse usually corresponds to 1 Wh (1000 pulses per kwh).
 
In the case of an electricity meter a pulse output corresponds to a certain amount of energy passing through the meter (KWhr/Wh). For single-phase domestic electricity meters (eg. Elster A100c) each pulse usually corresponds to 1 Wh (1000 pulses per kwh).
 +
  
 
'''The emonTx V3 has got one interrupt input (IRQ 0, Dig2) which can be used for pulse counting. This is broken out on terminal block port 4'''
 
'''The emonTx V3 has got one interrupt input (IRQ 0, Dig2) which can be used for pulse counting. This is broken out on terminal block port 4'''
 
 
   
 
   
The emonTx V3 pulse counting example sketch calculated the power by the calculating the time elapsed between pulses.
+
The emonTx V3 [https://github.com/openenergymonitor/emonTxFirmware/tree/master/emonTxV3/RFM12B/Examples pulse counting example sketch calculates the power by the calculating the time elapsed between pulses].
  
Read more about pulse counting [http://openenergymonitor.org/emon/buildingblocks/introduction-to-pulse-counting on OpenEnergyMonitor Buillding Block pagers here]
+
Read more about pulse counting [http://openenergymonitor.org/emon/buildingblocks/introduction-to-pulse-counting on the OpenEnergyMonitor Buillding Block pagers here]
  
 
   
 
   
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Connect the pulse input into emonTx V3 terminal block port 4 (IRQ 0 / Digital 2)
 
Connect the pulse input into emonTx V3 terminal block port 4 (IRQ 0 / Digital 2)
 
If you're connecting a hard-wired pulse output you may need to add a pull-down resistor onto the emonTx V3 PCB (R31)
 
If you're connecting a hard-wired pulse output you may need to add a pull-down resistor onto the emonTx V3 PCB (R31)
 
 
If you're using an optical counter (e.g [http://shop.openenergymonitor.com/tsl257-optical-pulse-sensing-kit/ TSL257]) you should connecting the power pin to the 3.3V or 5V (if running off 5V USB)
 
If you're using an optical counter (e.g [http://shop.openenergymonitor.com/tsl257-optical-pulse-sensing-kit/ TSL257]) you should connecting the power pin to the 3.3V or 5V (if running off 5V USB)
 
   
 
   

Revision as of 22:06, 22 November 2013

emonTx V3

The emontx v3 is the latest generation of the open source hardware emontx low power wireless energy monitoring node designed for measuring AC electrical power on 4 different (household/building) circuits using non-invasive clip on CT current sensors and an AC-AC Voltage adaptor to provide a voltage signal for full real power and powerfactor calculation.

Emontxv3.jpg

Features

  • Emontx v3 can measure real power, apparent power, power factor, rms voltage and current on 4 different mains circuits, it also has inputs for temperature and humidity sensing.
  • Pre-assembled SMT design
  • A single AC-AC adapter can now be used to power the emonTxV3 and provide AC voltage measurement
  • 4x CT current sensing inputs
  • An on-board 3x AA battery option
  • Flexible choice of RF radio module and removable microcontroller

Port Map

Overview

Power Supply Options

Uploading Firmware

Start by downloading the firmware, libraries and setting up the Arduino programming environment by following this guide:

Setup the Arduino Programming environment

Once complete the emonTx firmware location should be navigable from within the Arduino IDE by going to:

File > Sketchbook > OpenEnergyMonitor > emonTxFirmware > emonTxV3

These are the examples available so far:

RFM12B

  • emonTxV3_RFM12B_DiscreteSampling
  • Examples:
    • emonTxV3_4chan_continuous
    • emonTxV3_CurrentOnly
    • emonTxV3_RealPower_Voltage

SRF

  • SRF___Low_Power___Current_only_Apparent_Power

The emontx firmware is available on github here: Github:emonTxFirmware

Standard Operation

CT Energy Monitoring

Single Phase

Three-Phase

Accuracy

Extended Operation

Temperature Monitoring

A DS218B20 digital temperature sensor can easily be connected by the emonTx V3 by connecting the sensor into to the emonTx V3's screw terminal block. The default firmware supports auto-detecting one DS28B20. Many DS18B20's can be connected but this will require change of Arduino firmware.

In order to save power when running off batteries the emonTx V3 supports switching off the DS18B20 in between readings and performing the temperature conversion while the ATmega328 is sleeping. To do this the DS18B20 power pin is supplied with 3.3V from Dig5, this digital pin is switched off between readings. The data connection from the DS18B20 is connected to Dig19, this I/O pin has got a 4K7 pull-up resistor on-board the emonTx V3 PCB as required by the DS18B20.

To connect an external DS18B20 to the emonTx V3 screw terminal block connections are as follows

DS18B20 emonTx V3 screw terminal connections
Screw terminal pin DS18B20 Connection
3 - GND GND (Black)
5 - Dig5 Power (Red)
6 - Dig19 Data (White)

Utility Meter Interface

Optical Pulse Counting

Many meters have pulse outputs, including electricity meters: single phase, 3-phase, import, export.. Gas meters, Water flow meters etc. The pulse output may be a flashing LED or a switching relay (usually solid state) or both. We recommend using optical interface as this decouples the monitoring equipment from any high voltages.

In the case of an electricity meter a pulse output corresponds to a certain amount of energy passing through the meter (KWhr/Wh). For single-phase domestic electricity meters (eg. Elster A100c) each pulse usually corresponds to 1 Wh (1000 pulses per kwh).


The emonTx V3 has got one interrupt input (IRQ 0, Dig2) which can be used for pulse counting. This is broken out on terminal block port 4

The emonTx V3 pulse counting example sketch calculates the power by the calculating the time elapsed between pulses.

Read more about pulse counting on the OpenEnergyMonitor Buillding Block pagers here


emonTx V3 Hardware Connections

Connect the pulse input into emonTx V3 terminal block port 4 (IRQ 0 / Digital 2) If you're connecting a hard-wired pulse output you may need to add a pull-down resistor onto the emonTx V3 PCB (R31) If you're using an optical counter (e.g TSL257) you should connecting the power pin to the 3.3V or 5V (if running off 5V USB)

emonTx V3 pulse-counting screw terminal connections
Screw terminal pin Connection
1 5V (if powered via 5V USB)
2 3.3V
3 GND
4 IRQ 0 / Dig2

We recommend powering the emonTx V3 from 5V USB when using for pulse counting operation. Due to the additional power requirements of the optical pulse sensor battery life will be reduced compared to CT operation if powering from 3 x AA batteries.

Direct Optical Interface

if you have an Elster meter (tested with Elster 100C) the emonTx V3 with an IR TSL261R sensor can be used to interface directly with the meter protocol to read off the exact accumulated watt hours that you have generated or used. This reading can be used on it's own or to cross-check and calibrate CT based measurement. See here for original blog post

RF Connectivity

RFM12B

SRF

Electrical Characteristics

power consumption, absolute max values

Open-Hardware Design Files

Proudly open source, the hardware designs are released under the Creative Commons Attribution-ShareAlike 3.0 Unported License:

Download Schematic PNG: emontx-v3.png

Download Schematic: emonTx V3.2.sch

Download Board files: emonTx V3.2.brd

License

Environmental & Life Cycle

Disclaimer