hoymiles dtsu666 Three Phase Smart Meter User Manual
- August 15, 2024
- hoymiles
Table of Contents
hoymiles dtsu666 Three Phase Smart Meter
Product Usage Instructions
Safety Instructions
Before installing or using the Smart Meter, ensure you read and understand all safety instructions provided in the user manual. Failure to follow safety precautions may result in injury or damage.
Product Introduction
The Three-phase Smart Meter is designed for accurate energy measurement in three-phase electrical systems. It includes various functions such as display, programming, communication, and energy measurement.
Product Installation
Follow the installation guidelines provided in the user manual. Ensure proper wiring and secure mounting according to the recommended standards to ensure accurate functionality.
Troubleshooting
If you encounter any issues with the Smart Meter, refer to the troubleshooting section of the user manual. Follow the steps outlined to identify and resolve common problems.
FAQ
- Q: What should I do if I encounter errors during programming?
- A: If you face errors during programming, double-check the parameters entered and ensure proper communication setup. If issues persist, refer to the troubleshooting section or contact customer support.
- Q: Can the Smart Meter be used in single-phase systems?
- A: No, the Smart Meter is specifically designed for three-phase systems. Using it in a single-phase setup may result in inaccurate readings and improper functionality.
Safety Instruction
Safety Symbols
The following types of safety precautions and general information symbols used in this manual must be followed during the installation, operation, and maintenance.
Personnel Requirements
This document is only applicable to qualified personnel who have received professional training and possess the following skills:
-
Knowledge of and compliance with this document and all safety instructions.
-
Familiar with all safety specifications of the electrical system.
-
Understanding of the composition and working principles of the grid-tied PV power system and local regulations.
-
Proficiency in energy meter installation, operation, and maintenance.
Note: -
The qualified personnel must wear personal protective equipment (PPE) during all operations.
-
The qualified personnel should comply with local laws and regulations during installation and operation. The safety instructions in this document are only supplements to laws and regulations.
Product-related Requirements
- When transporting and unpacking the products, please confirm they are not severely impacted.
- The package of the meter should use materials that can meet environmental requirements.
- The instrument and accessories shall be stored in dry and ventilated places, to avoid humidity and corrosive gas erosion. The storage environment temperature is -40℃ to 70℃, and the relative humidity should be no more than 75%.
- Transport and store the product based on transportation, basic environmental conditions, and testing methods for instruments and meters of JB/T9329-1999.
Disclaimer
Hoymiles shall not be liable for the following situations:
- Any damage caused by incorrect installation and operation.
- Any damage caused by improper transportation and storage.
- Any damage caused by unauthorized modifications to the product.
- Any installation, operation, and maintenance performed by unqualified personnel.
- Failure to comply with all safety and operation instructions described in this document.
Maintenance and Replacement
- Disconnect the power supply before any maintenance and repair operation.
- All maintenance and replacement operations must be performed by qualified personnel.
- It is recommended to carry out regular inspection and maintenance for safety reasons.
- If users find any quality problem within 18 months from the date of dispatch, Hoymiles is responsible for repairing or replacing it for free, on the condition that users operate the product according to the manual’s provision, and the seal is intact.
Product Introduction
Product Overview
Type DTSU666 three-phase smart meter (Din-rail) (hereinafter referred to as
the “instrument”) adopts
a large-scale integrated circuit and applies digital sampling technology. It
is designed based on power monitoring and energy metering demands for electric
power systems, the communication industry, the construction industry, etc, as
a new generation of intelligent instruments combining measurement and
communication functions, mainly applied to the measurement and display of the
electric parameters in the electric circuit including three voltage, three
current, active power, reactive power, frequency, positive and negative
energy, four quadrant energy, etc. Adopting the standard DIN35 mm din rail
mounting and modular design, it is characterized by small volume, easy
installation, and networking, widely applied to the internal energy monitoring
and assessment for industrial and mining enterprises, hotels, schools, and
large public buildings.
This type of energy meter conforms to the following standards:
- IEC 61010-1:2010《Safety requirements for an electrical requirement for measurement, control, and laboratory use Part1: General requirements》;
- IEC 61326-1:2013《Electrical requirement for measurement, control, and laboratory use-EMC requirements Part1: General requirements》;
- MODUS-RTU protocol.
Product Naming Rule
Table 2-1 Model Specification
Model| Accuracy Grade| Referenced Voltage| Current
Specification
| Constant| Type
---|---|---|---|---|---
DTSU666 (CT-3 × 100 A)| Active Power 1| 3 × 230 V/400 V| 100 A/40 mA| 400
imp/kWh| Transformer Access
Working Principle
Working Principle Diagram
The instrument is composed of a highly accurate metering integrated circuit
(ASIC), management MCU, memory chip, RS485 communication module, etc. The
working principle block diagram of the instrument is shown in Figure 2-2:
Metering Part Principle
- The special metering integrated circuit (ASIC) integrated six loads in two orders ∑-△ a type of A/D conversion, please take the digital signal processing measured by the voltage circuit as well as all the power, energy, effective values,
- power factor, and frequency. This metering chip can measure the active power, reactive power, apparent power, active energy, reactive power, and apparent energy of each phase and combined phase, and at the same time, measure
- current, voltage effective values, power factor, phase angle, frequency, and other parameters, entirely satisfying the needs of the power meter. The chip provides an SPI interface, convenient for metering parameters as well as parameter
- calibration between the management MCU.
Data Processing Part Principle
- Management MCU will timely read the electrical parameters such as current, voltage, power, etc. in the metering chips, judging the current quadrant based on the read data, and judging the current operated rate based on time and
- time rate, then adding the energy read from the metering chip to the corresponding quadrant energy and total energy based on the rate and quadrant, at the same time, calculating the corresponding combined energy based on the
- energy combination mode, and then store and back up the energy.
Main Function
Display function
From the displayed interface, the electrical parameter and energy data are all
primary side data (that is, the multiplied by current and voltage ratios). The
energy measuring value will be displayed in seven bits, with the display range
from 0.00 kWh to 999999.9 kWh.
Table 2-2 Display Interface
Note
- Combined active energy=Positive active energy + Reserve active energy
- The communication address of Modbus protocol is 1 terminal data (1-247), and the factory default baud rate is 9600 bps, N.8.1; E1 means even check 1 stop bit, O1 means odd check 1 stop bit, and N1 means one stop bit without checking.
- The above interface is used to show the meaning of the display content. Due to the different functions of the instrument, the display symbols will increase or decrease.
Programming Function
Programming Parameter
Table 2-3 Programming Parameter
Programming Operation
Button description: The “SET” button represents “confirmation” or “cursor
shift” (when input digits); the The “ESC” button represents “exit”; the button
represents “add”. The input code is (default 701).
When input digits, “ ” can be used as a cursor shift button; “ ” is an “add”
button, “ ” means exiting the programming operation interface or switching to
the character interface from the digit modification interface; adding from the
beginning after setting the digit to the maximum value.
Note:
The communication address can also be set through the S-Miles App. Open the
S-Miles App, tap “Toolkit
Meter Location”, and enter the serial number of the smart meter, the
communication address will be automatically set to 002. If two meters are
required for an AC-coupled system, the address of the grid side meter should
be set to 002, and the address of the PV side meter should be set to 001.
Communication Function
It has an RS485 communication interface, and the baud rate can be changed
between 1200 bps, 2400 bps, 4800 bps, and 9600 bps.
The factory default communication parameter is Modbus-RTU protocol; the baud
rate is 9600 bps, with the calibration bit and stop bit to be n.1, and the
instrument address is 1.
Energy Measurement Function
The horizontal axis of the measurement plane represents the current vector I
(fixed on the horizontal axis), and the instantaneous voltage vector is used
to represent the current power transmission. Compared with the current vector
I, it has phase angleφ. The counter-clockwise direction φangle is positive.
Note:
- The measurement method for the combined active energy depends on the contents of character words of the active combined mode.
Table 2-4 Character words of active combined mode
| Bit 7 | Bit 6 | Bit 5 | Bit 4 | Bit 3 | Bit 2 | Bit 1 | Bit 0 |
|---|
Reserved
|
Reserved
|
Reserved
|
Reserved
| Reverse active (0
no less, 1 less)
| Reverse active (0 not added, 1 added)| Positive active (0
no less, 1 less)
| Positive active (0 not added, 1 added)
Example:
when the content of the active combination mode is 05, combined active
energy=positive active energy +reverse active energy factory default value:
combined active energy=positive energy
- The combined reactive energy of four quadrants can be respectively measured and the reactive energy can be set as the sum of arbitrarily four-quadrant energy, with its measurement mode depending on the contents of character words 1 and 2 of the reactive combination mode.
Table 2-5 Character words of the combined reactive combination mode
| Bit 7 | Bit 6 | Bit 5 | Bit 4 | Bit 3 | Bit 2 | Bit 1 | Bit 0 |
|---|
IV
quadrant (0 no less,
1 less)
| IV
quadrant (0 not
added, 1 added)
|
III
quadrant (0 no less,
1 less)
| III
quadrant (0 not
added, 1 added)
|
II
quadrant (0 no less,
1 less)
| II
quadrant (0 not
added, 1 added)
|
I
quadrant (0 no less,
1 less)
| I
quadrant (0 not
added, 1 added)
0 bit: I quadrant reactive; 0-Not counted into combined reactive; 1-Counted
into combined reactive; First bit: I quadrant reactive; 0-Not counted into
combined reactive; 1-Minus the quadrant reactive; Second bit: II quadrant
reactive; 0-Not counted into combined reactive; 1-Counted into combined
reactive Third bit: II quadrant reactive; 0-Not counted into combined
reactive; 1-Minus the quadrant reactive; Fourth bit: III quadrant reactive;
0-Not counted into combined reactive; 1-Counted into combined reactive Fifth
bit: III quadrant reactive; 0-Not counted into combined reactive; 1-Minus the
quadrant reactive; Sixth bit: IV quadrant reactive; 0-Not counted into
combined reactive; 1-Counted into combined reactive Seventh bit: IV quadrant
reactive; 0-Not counted into combined reactive; 1-Minus the quadrant reactive;
For example: when the content of the reactive combination mode is A5;
Combined reactive energy = I quadrant reactive + II quadrant reactive – III
quadrant reactive – IV quadrant reactive
Factory default value: combined reactive 1 energy=I + IV, combined reactive 2
energy=II + III.
Product Dimensions
Table 2-6 Product Structure
| Model | Modulus | Outline Size (W × H × D) | Installation Size (Din-rail) |
|---|---|---|---|
| DTSU666 (CT-3 × 100 A) | 4 | 72 × 100 × 65 mm | DIN35 standard din-rail |
Note:
- The undeclared tolerance is ±1 mm.
- The above information only indicates the product size and the shape of different specifications is slightly different.
Product Installation
| ****
• Before connecting the cables, ensure that the smart meter is not damaged in any
way. Otherwise, electric shocks or fires may occur.
---|---
| • Before installation, please check whether the model and specifications of the
products on the box are in line with the material, if not, please contact the supplier.
• Check whether the packing case of the product is damaged, if damaged, please contact the supplier.
• When unpacking the carton, if the shell has obvious signs caused by severe impact or falling, please contact the supplier as soon as possible.
• After the instrument is removed from the packing box, it should be placed in a flat and safe place, facing up, not overlaying for more than five layers; if the inner package or shell has been damaged, please do not install the product.
Procedure (Hybrid System)
Steps
| • Clamp the meter to the guide rail directly, and install the meter and the rail in or near the distribution box, right after the utility meter.
• Connect grid L1/L2/L3/N to meter’s terminals 3/6/9/10.
• Clamp three CTs to L1/L2/L3 and respectively connect wirings to terminals 13/14, 16/17, and 19/21. The arrow on the surface of CT should point to the grid.
• Connect the communication cable between the inverter and the smart meter.
Note:
- When installing, clip the end of the card slot into the guide rail.
- When disassembling, use a screwdriver to press the card to remove the instrument.
Typical Wiring
| • High voltage may cause an electric shock, which will result in
serious injury, death, or serious property damage. Please strictly comply with
the safety instructions in this document and other relevant documents.
---|---
Voltage signal
- 3——UA (Phase A voltage input terminal)
- 6——UB (Phase B voltage input terminal)
- 9——UC (Phase C voltage input terminal)
- 10——UN (Phase N voltage input terminal)
Current signal
- 13——IA* (Phase A current input terminal)
- 14——IA (Phase A current output terminal)
- 16——IB* (Phase B current input terminal)
- 17——IB (Phase B current output terminal)
- 19——IC* (Phase C current input terminal)
- 21——IC (Phase C current output terminal)
RS485 communication
- 24——A (RS485 terminal A)
- 25——B (RS485 Terminal B)
Troubleshooting
| Fault Phenomenon | Factor Analysis | Elimination Method |
|---|
No display after the instrument is powered on
| ****
• Incorrect wiring mode.
• Abnormal voltage supplied for the instrument.
| • If the wiring mode is incorrect, please reconnect based on the correct wiring mode (see the wiring diagram).
• If the supplied voltage is abnormal, please supply the voltage on the instrument specification.
• If the fault still exists, please contact the local supplier.
Abnormal RS485 communication
| ****
• The RS485 communication cable is disconnected, short-circuited, or reversely connected.
• The address, baud rate, data bit and parity bit of the instrument are not in accordance with the host computer.
• The end of the RS485 communication cable has not been matched with resistance. (when the distance is over 100 meters.)
• Not matched with the communication protocol order of the host computer.
| ****
• If there is any problem with the communication cable, please reconnect or change the cable.
• Set the address, baud rate, data bit, and parity bit to be the same as the host computer through buttons; for button settings, please see “parameter setting”.
• If the communication distance is over 100 meters, and the communication parameter settings are the same as the host computer, but cannot communicate, please lower the baud rate or add a resistance of 120Ω at the start terminal and ending terminal.
Inaccurate energy metering
| • Incorrect wiring, please check whether the phase sequence corresponding to the voltage and current is correct.
• Check whether the high-end and low-end of the current transformer inlet are reversely connected.
• The power of Pa, Pb, and Pc will be abnormal if there is any negative value.
| ****
• If the wiring mode is incorrect, please reconnect based on the correct wiring mode (see the wiring diagram).
• If the fault still exists, please contact the local supplier.
Technical Specification
Limit of error caused by the current augment
Table 4-1 The limit value of the active percentage error of meters on a balanced load
Type
|
Current Value
|
Power Factor
| Percent Error Limits for Various Classes of Meter
---|---|---|---
Class C| Class B| Class A
Connection through current transformers
| 0.01 In≤I<0.05 In| 1| ±1.0| ±1.5| ±2.0
0.05 In≤I≤Imax| 1| ±0.5| ±1.0| ±1.2
0.02 In≤I<0.1 In| 0.5L, 0.8C| ±1.0| ±1.5| ±2.0
0.1 In≤I≤Imax| 0.5L, 0.8C| ±1.0| ±1.0| ±1.2
Direct connection
| 0.05 Ib≤I<0.1 Ib| 1| –| ±1.5| ±2.0
0.1 Ib≤I≤Imax| 1| –| ±1.0| ±1.2
0.01 Ib≤I<0.2 Ib| 0.5L, 0.8C| –| ±1.5| ±2.0
0.2 Ib≤I≤Imax| 0.5L, 0.8C| –| ±1.0| ±1.2
Note:
In: secondary rated current of the current transformer; Ib: calibrated current
of the meter L: inductive; C: capacitive
Table 4-2 The limit value of the reactive percentage error of meters on a balanced load
Current Value
|
sinφ
(inductive or capacitive)
| Percentage Error Limits for Various Classes of Meter
---|---|---
Direction connection
| Connection through current transformers|
Class A
0.05 Ib≤I<0.1 Ib| 0.02 In≤I<0.05 In| 1| ±2.5
0.1 Ib≤I≤Imax| 0.05 In≤I≤Imax| 1| ±2.0
0.1 Ib≤I<0.2 Ib| 0.05 In≤I<0.1 In| 0.5| ±2.5
0.2 Ib≤I≤Imax| 0.1 In≤I≤Imax| 0.5| ±2.0
0.2 Ib≤I≤Imax| 0.1 In≤I≤Imax| 0.25| ±2.5
Table 4-3 The limit value of the reactive percentage error of meters on a balanced load
Current Value
|
Power Factor
| Percentage Error Limits for Various Classes of Meter
---|---|---
Direction connection
| Connection through current transformers|
Class C
|
Class B
|
Class A
0.1 Ib≤I≤Imax| 0.05 In≤I≤Imax| 1| ±0.6| ±2.0| ±3.0
0.2 Ib≤I≤Imax| 0.1 In≤I≤Imax| 0.5L| ±1.0| ±2.0| ±3.0
Table 4-4 The limit value of the reactive percentage error of meters on an imbalanced load
Current Value
|
Power Factor
| Percentage Error Limits for Various Classes of Meter
---|---|---
Direction connection
| Connection through current transformers|
Class A
0.1 Ib≤I≤Imax| 0.05 In≤I≤Imax| 1| ±3.0
0.2 Ib≤I≤Imax| 0.1 In≤I≤Imax| 0.5| ±3.0
Start
Under the power factor of 1.0 and started current, the instrument can be
started and continuously measured (for the multiple-phase instrument, it will
bring a balanced load). If the instrument is designed based on measurement for
dual directional energy, it is applicable for each direction of energy.
Table 4-5 Start Current
Type
| Class of Meter|
Power Factor
|
---|---|---|---
Class C| Class B| Class A|
Direct connection| –| 0.004 Ib| 0.005 Ib| 1|
Connection through current transformers| 0.001 Ib| 0.002 Ib| 0.003 Ib|
1|
Deflection
When the voltage is applied with no current flowing in the current circuit,
the test output of the meter shall not produce more than one pulse. When
testing, the current circuit shall be disconnected, and the applied voltage of
the voltage circuit shall be 115% of the referenced voltage.
Environmental Parameter
| Limited working temperature range | -25℃-70℃ |
|---|---|
| Relative humidity (annual average) | ≤75% |
| Altitude | ≤4000 m |
| Atmospheric pressure | 63 kPa-106 kPa |
Electrical Parameter
| Specified operating voltage range | 0.9 Un-1.1 Un |
|---|---|
| Extended operating voltage range | 0.8 Un-1.15 Un |
| Limiting operating voltage range | 0 Un-1.15 Un |
| Voltage line power consumption | ≤1.5 W/6 VA |
Current line power consumption
| Ib<10 A| ≤0.2 VA
Ib≥10 A| ≤0.4 VA
Data storage time after power interruption| ≥10 years
Technical Parameter
| Model | DTSU666 (CT-3 × 100 A) |
|---|---|
| Power Supply | |
| Grid type | 3P4W |
| Input voltage (phase voltage) | 154 Vac – 253 Vac |
| Power consumption | £1.5 W |
| Measuring Range | |
| Phase voltage | 154 Vac – 253 Vac |
| Current | 0 – 100 A |
| Measuring Accuracy | |
| 0.01 In £ I < 0.05 In(1) | ±1.5 % |
| 0.05 In £ I £ In(1) | ±1.0 % |
| Communication | |
| Interface | RS485 |
| Communication protocol | Modbus-RTU |
| Mechanical Data | |
| Wiring type | Via-CT |
| Ambient temperature range | -25℃ – 70℃ |
| Dimensions (W × H × D) | 72 × 100 × 65 mm |
| Mounting type | DIN35 Rail |
| CT Data | |
| Thread | Single turn |
| Install | Buckle |
| Ambient temperature range | -25℃ – 70℃ |
| Dimensions (W × H × D) | 44 × 77 × 33 mm |
| Cable length | 6 m |
(1) Secondary rated current of the current transformer.
CONTACT
- Floor 6-10, Building 5, 99 Housheng Road, Gongshu District,
- Hangzhou 310015
- P. R. China
- +86 571 2805 6101
- General inquiry: info@hoymiles.com
- Technical support: service@hoymiles.com
- Visit https://www.hoymiles.com/ for more information
References
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