Klemsan KLEA 320P-DC Energy Analyzer User Manual
- June 11, 2024
- Klemsan
Table of Contents
KLEA 320P-DC Energy Analyzer
Product Information
The KLEA Energy Analyzer is a multi-functional energy analyzer that is designed to measure and analyze energy consumption in various applications. It is equipped with KleaCom software and a front panel display that provides real-time data on voltage, current, power, and energy usage.
General Information
The product comes with a user manual that contains important information,
symbols, general warnings, and technical specifications. The symbols used in
the manual are caution and danger of electric shock. The product has a Klea
Order Number and base model statement that should be checked upon package
receipt.
Installation
The installation process is outlined in the user manual. Please follow the instructions carefully to ensure proper installation and operation of the product.
Menus
The KLEA Energy Analyzer has several menus that can be accessed through the
front panel display. These menus include settings, measure, meters, alarms,
and analysis. Each menu provides different information about the energy usage
and can be customized to meet specific needs.
Modbus Protocol
The KLEA Energy Analyzer is equipped with Modbus Protocol that allows it to
communicate with other devices. The protocol is outlined in the user manual
and includes message format, int (32 bit) data type, and implemented functions
for Modbus RTU Protocol.
Technical Specifications
The technical specifications of the KLEA Energy Analyzer are outlined in the user manual. These specifications include input voltage range, frequency range, accuracy, and dimensions.
Product Usage Instructions
To use the KLEA Energy Analyzer, follow the installation instructions provided
in the user manual. Once installed, access the menus through the front panel
display to view real-time data on energy consumption. Customize the menus to
meet specific needs and use the Modbus Protocol to communicate with other
devices. Refer to
the technical specifications for input voltage range, frequency range,
accuracy, and dimensions.
Energy Analyzer Net woKr kLEAAnalyzer USER MANUAL
Energy Analyzer
SECTION 1 GENERAL INFORMATION
9
SECTION 1 GENERAL INFORMATION
SECTION 1 GENERAL INFORMATION
1.1 Symbols
Caution: Wherever used, this symbol indicates that there is important
information that must be taken into consideration.
Danger of Electric Shock: This symbol indicates that there is dangerous
voltage or current.
1.2 General Warnings
· Do not work under live supply conditions. Before installation, turn off the
power of the panel or any other related equipment.
· Installation, operation and commissioning (putting into service) of KLEA
must be performed by qualified personnel.
· The device must be put into service only after all connections are made. ·
KLEA is connected to current transformer(s). Before disconnecting current
transformer
leads, be sure that they are short circuited elsewhere or connected to a
parallel load which has sufficiently low impedance. Otherwise dangerously high
voltages will be induced at the current transformer leads. Same phenomena also
apply for putting into service. · Keep and store away from moisture, dust,
vibration and wet environment. · For cleaning, remove the dust with a dry
cloth. Do not use abrasives, solvents or alcohol. · There are no user
serviceable parts inside. Maintenance and calibration can only be carried out
at manufacturer’s end. · It is recommend to connect circuit breakers or
automatic fuses between voltage inputs of Klea and the network.
10
SECTION 1 GENERAL INFORMATION
1.3 Receipt Control and Contents of Delivery
When you receive the package, please be sure that,
· packing is in good condition, · product has not been damaged during transportation, · product name and reference (order) number conforms to your order.
KLEA Order Number: 606100 606101 606102 606103 6061 6061
Statement: Klea base model
Klea Klea
(18…60VDC)
Please also check the contents of delivery as listed below:
· 1 pc. KLEA · 1 pc., CD-ROM (User manuel and KleaCom software) · 2 pcs.,
fixing brackets and screws · 1 pc., 4-pin female terminal block for alarm
outputs (NO, C/out2, C/out1, NO) · 1 pc., 6-pin female terminal block for
current inputs (I1 , k1 , I2 , k2 , I3 , k3) · 1 pc., 3-pin female terminal
block for supply input (Un) · 1 pc., 3-pin terminal block for digital inputs
(DI1, GND, DI2) · 1 pc., 4-pin female terminal block for voltage inputs (L1 ,
L2 , L3 , N) · 1 pc., 7-pin female terminal block for digital output and RS485
(B, GND1, A, DO1+,
DO1-, DO2+, DO2-) · 2 pcs., 10-pin female terminal block for digital IO
optional (KLEA – 606101) product
(DO3+, DO3- …), (DI3, GND3… ) · 1 pc., 4-pin female terminal block for two
analog output optional (KLEA – 606102)
product (AO1-GND, AO2-GND) · 1 pc., 8-pin female terminal block for four
analog output optional (KLEA – 606103)
product (AO1-GND, …, AO4-GND)
1.4 KLEA Energy Analyzer
KLEA is a multi functional energy analyzer. KLEA,
· measures/calculates » current, voltage and frequency » active, reactive and
apparent power » Current and voltage harmonics up to 51. harmonic » THDV, THDI
» Power factor, cosØ
for each phase.
11
SECTION 1 GENERAL INFORMATION
· KLEA has “1st tariff” and “2nd tariff” meters. These meters record “Imp.
Active”, “Exp. Active”, “Import Reactive” and “Export Reactive” energy values.
· There is an isolated RS485 port in KLEA. · KLEA’s 1st Tariff and 2nd Tariff
energy values can be assigned to digital outputs. · It has 2 pieces of relay
outputs. Besides, KLEA has numerous features such as; · Setting alarms for
various measurement parameters, · Monitoring official energy meters by means
of assigning initial values for Klea tariff
meters, · Compatibility for 3 phase/3 wire, 3 phase/4wire or aron connected
systems, · Avoiding unauthorized control by a 4-digit password. KLEA Energy
Analyzer has, · 2 programmable alarm relay outputs, 2 digital outputs (totally
7 pieces in optional
digital IO model), 2 digital input (totally 7 pieces in optional digital IO
model), 1 piece of RS-485 communication port, 2/4 analog outputs (optional),
battery supported realtime clock and memory. · There are 6 keys and 160×240
graphical LCD on the front panel. By means of them, device settings and
monitoring of measurement values can easily be accomplished.
1.5 KleaCom Software
Operator can remotely reach a Klea device via KleaCom software. KleaCom
software can communicate with only one Klea at the same time; operator can
reach other Klea devices on the same network by changing the slave ID. All
measured/calculated parameters can be monitored with KleaCom. All settings of
Klea can be changed/read via KleaCom software. History (archive) data of Klea
can be downloaded using KleaCom and this data can be listed in an MS Excel or
WordPad file (selectable). KleaCom software is included in the CD-ROM received
with Klea package. Latest version of KleaCom software can be downloaded from
www.klemsan.com.tr
12
SECTION 1 GENERAL INFORMATION
1.6 KLEA Front Panel
1
Settings Measure Meters Alarms Analysis
2
V1 2 2 0 . 0 V I1
5.0 A
3
V2 2 2 0 . 0 V I2
5.0 A
V3 2 2 0 . 0 V I3
5.0 A
1 23
4
V I
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17:22
12
5 6 7 8 9 10 11
13
14
15
16
17
18
Figure 1-1 KLEA Display
1 Menus 2 L-N voltages belonging to three phases 3 Currents of three phases 4
Presence/Absence of currents-voltages belonging to three phases, and phase
sequence 5 Selected connection type 6 Alarm state symbol (for any alarm) 7
Temperature alarm state symbol (displayed only with a temperature alarm) 8
Alarm relay symbol (If 1st and/or 2nd alarm relay is assigned to any alarm and
also if there is
an alarm in the system at the same time, this symbol shall appear on the
screen. “1” stands for 1st Alarm Relay and “2” stands for 2nd Alarm Relay) 9
KLEA digital output symbol ( “1” indicates, digital output 1; and “2”
indicates digital output 2. This symbol shall be displayed as long as width of
the output pulse.) 10 KLEA digital output symbol (if there is an output from
optional output3, output4, output5, output6 and output7, this symbol shall be
displayed.) 11 RS485 communication symbol 12 Klea system time 13 X Key (in
order to cancel any change or to return to the upper menu) 14 Left key 15 Up
key 16 Down key 17 Right key 18 OK key (pressed in order to save any change or
to access submenus)
13
1.7 Four-Quadrant Represantation
The angle(Ø) between voltage and current provides us information about the direction of energy flow. A positive sign for active/reactive power indicates that active/reactive power is consumed. And also a negative sign for active/reactive power indicates that active/ reactive power is generated.
Reactive Power
QUADRANT -2
P
=> negative
Q => positive & capacitive
CosØ => capacitive
PF => negative
Meters Exp. Active & Imp. Reactive
QUADRANT -1
P
=> positive
Q => positive & inductive
CosØ => inductive
PF => positive
Meters Imp. Active & Imp. Reactive
S Q
P
Active Power
QUADRANT -3
P
=> negative
Q => negative & inductive
CosØ => inductive
PF => negative
Meters Exp. Active & Exp. Reactive
QUADRANT -4
P
=> positive
Q => negative & capacitive
CosØ => capacitive
PF => positive
Meters Imp. Active & Exp. Reactive
Figure 1-2 Four-Quadrant Representation
NOTE: If the signs of active and reactive power are examined, it can be defined the quadrant that Klea measures.
e.g.
P= +10kWh,Q= +5kVAr => P= -10kWh, Q= +5kVAr => P= -10kWh, Q= -5kVAr => P=
+10kWh,Q= -5kVAr =>
Quadrant-1 Quadrant-2 Quadrant-3 Quadrant-4
14
Energy Analyzer
SECTION 2 INSTALLATION
15
SECTION 2 INSTALLATION
SECTION 2 INSTALLATION
This section provides the information about installation, mounting, cable
routing and connections of Klea.
2.1 Preparing for Installation
The purchased KLEA may not include all hardware options referred in this
document. This situation does not constitute an impediment to the electrical
installation.
Assembly and related connections of KLEA, must be implemented by authorized
persons in accordance with the instructions of user manual. The device must
not be put into service if the operator is not sure that all connections are
correctly accomplished.
2.2 MOUNTING
KLEA is placed vertically into the gap located in the panel.
Figure 2-1 Mounting KLEA into the Panel
After the KLEA is placed into the panel, fixing brackets should be installed
on Klea and Klea should be fixed to the panel wall with the screws.
16
SECTION 2 INSTALLATION
NetwoKrkLEAAnalyzer
Figure 2-2 Fixing KLEA to the panel
There are 2.5mm2 and 1.5mm2 screwed female terminal blocks connected to fixed
male terminal blocks on KLEA. Remove female terminal blocks and loosen their
screws.
Figure 2-3 Loosening of Terminal Block Screws
Before wiring up voltage and current ends to KLEA, you must be sure that the
power is cut. KLEA is connected to current transformer(s). Before
disconnecting current transformer leads, be sure that they are short circuited
elsewhere or connected to a parallel load which has sufficiently low
impedance. Otherwise dangerously high voltages will be induced at the current
transformer leads. Same phenomena also apply for putting into service.
17
SECTION 2 INSTALLATION
The cable is placed into the related opening.
Figure 2-4 Inserting Cable into the Terminal Block
After the cable is placed, the screws are tightened and the cable is fixed.
Figure 2-5 Fixing the Cable to the Terminal Block
The Terminal Block is inserted into its seat located on KLEA. If KLEA is used
together with current transformers, please pay attention to the following
warning. Threshold values for proper operation of current transformers differ
according to the type and size of the transformers being used. Before applying
the points mentioned in the following warning, please check that the measured
current value is larger than the current threshold value of the current
transformer (Refer to manual or datasheet of the current transformer).
For both of the warnings below, there must be a current in the system which is
higher than the threshold value of the current transformer (if any).
If KLEA is placed in a panel which consumes power; The signs on
Measure/Instantaneous/Active Power screen, should be positive, as the phases
consume power. If there is a negative sign, turn off the device, cut off the
panel power and then cross connect K and L ends of the current inputs
belonging to the related phase(s). After that, check that all values are
positive on Measure => Instantaneous => Active Power screen.
18
SECTION 2 INSTALLATION
If KLEA is placed in a panel which generates power; The signs on
Measure/Instantaneous/Active Power screen, should be negative, as the phases
generate power. If there is a positive sign, turn off the device, cut off the
panel power and then cross connect K and L ends of the current inputs
belonging to the related phase(s). After that, check that all values are
negative on Measure => Instantaneous => Active Power screen.
2.3 Wiring Diagrams 2.3.1 Three Phase Connection With Neutral (3P4W)
L1 L2 L3 N
out1 out2
2A 2A 2A 2A
A. Out1 GND A. Out2 GND A. Out3 GND A. Out4 GND B GND1 A DI2 GND DI1 DI3 GND
DI7 GND
DO1DO1+ DO2DO2+ DO3DO3+ DO7DO7+
C
C
NO
NO
Alarm Relay Outputs
N L3 L2 L1
k1 I1 k2 I2 k3 I3
N L
Power Supply
Current Measurement Inputs
Voltage Measurement Inputs
Analog Outputs (Optional)
RS485
Digital Inputs (Optional) …
Digital Outputs (Optional)
Figure 2-6 KLEA Star (WYE) Connection Diagram
19
SECTION 2 INSTALLATION
2.3.2 Three Phase Connection No Neutral (3P3W)
L1 L2 L3
2A
2A
2A
L1
L2
L3
k1
l1 k2
l2 k3
l3
Current Measurement Voltage Measurement
Inputs
Inputs
Figure 2-7 KLEA 3 Phase Delta Connection Diagram
2.3.3 Three Phase No Neutral Aron Connection
L1 L2 L3
2A
2A
2A
L1
L2
L3
k1
l1 k2
l2 k3
l3
Current Measurement Voltage Measurement
Inputs
Inputs
Figure 2-8 KLEA Aron Connection Diagram
20
SECTION 2 INSTALLATION
2.3.4 Digital Output Connection Diagram
DO (+)
DO (-)
External DC Power Supply must be connected. (5-30VDC)
+ –
load
Figure 2-9 Digital Output Connection Diagram
2.4 Dimensions
Dimensions are in millimeters.
96.8
7.0 65.0
96.8 89.6
Figure 2-10Dimensions
21
Energy Analyzer
SECTION 3 MENUS
22
SECTION 3 MENUS
SECTION 3 MENUS
3.1 “First Power-on” Settings
After its receipt, when KLEA is switched on”for the first time”, the following page appears.
Startup Settings
Language Date Time CTR VTR Connection Start
English 07 January 2013 17:45:28 1 1.0 3phase 4wire
3.1.1 Dil / Language
Figure 3-1 First Power-on Settings
When OK key is pressed on this tab, “Türkçe”, “English” and “P” options appear on the screen as seen below. Operator can scroll inside the options by pressing up and down keys and then should press “OK” to select the desired option. If language is selected as English, other tabs within this page will also be in English.
Startup Settings
Language Date Time CTR VTR Connection Start
E10177n:g4Jla5isn:hTPE2u8ünargrkylçis2eh013 1.0 3phase 4wire
Startup Settings
Language Date Time CTR VTR Connection Start
English 07 January 2013 17:45:28 1 1.0 3phase 4wire
Figure 3-2 Dil / Language
23
SECTION 3 MENUS
3.1.2 Date
In order to change the date, operator should press OK key, when”Date”tab is highlighted. Press right and left to move between day, month and year entries. Press up and down keys to change the values. Press OK key to complete date setting.
Startup Settings
Language Date Time CTR VTR Connection Start
English 07 January 2013 17:45:28 1 1.0 3phase 4wire
Figure 3-3 Date
Example: In order to enter “7 January 2013”:
1
Date
06 December 2012
2
Date
07 December 2012
3
Date
07 December 2012
4
Date
07 January 2012
5
Date
07 January 2012
6
Date
07 January 2013
7
Date
07 January 2013
Figure 3-4 Example for Setting the Date
24
SECTION 3 MENUS
3.1.3 Time
Time setting for KLEA is accomplished as explained in 3.1.2 Date menu.
3.1.4 Current Transformer Ratio (CTR)
In this tab, current transformer ratio is entered. The current transformer
ratio can be adjusted between 1-5000. When this tab is highlighted; if the
operator presses OK key, KLEA Virtual Keyboard will appear on the screen.
Startup Settings
Language Date Time CTR VTR Connection Start
English1 07 January 2013
17:45:28 1 2 3 4
1 1.0
5678
3phase 4w9ire 0 . –
ok clr
Low limit 1
High limit 5000
Figure 3-5 Current Transformer Ratio
Use arrow keys (left, right, up and down) of Klea to navigate inside the
virtual keyboard. In order to enter any number in the virtual keyboard as a
value, when that number is highlighted, press OK key of Klea. When ok’ box of virtual keyboard is highlighted, pressOK’ key of Klea to complete current
transformer setting.
In case an incorrect digit is entered, scroll inside the virtual keyboard to select box. Then pres `OK’ key of Klea to erase erroneous entered digit(s).
In order for KLEA to perform accurate measurements, current transformer ratio should be entered correctly.
25
SECTION 3 MENUS
Example:
1
1 1234 5678 90 . ok clr
Low limit 1 High limit 5000
2
1
1234
5678
90 . –
ok clr Low limit 1 High limit 5000
3
2
1234
5678
90 . –
ok clr Low limit 1 High limit 5000
4
2
1234
5678
90 . –
ok clr Low limit 1 High limit 5000
5
20
1234
5678
90 . –
ok clr
Low limit 1 High limit 5000
6
20
1234
5678
90 . –
ok clr
Low limit 1 High limit 5000
1
2
Startup Settings
Language Date Time CTR VTR Connection Start
English 07 January 2013 17:45:28 20 1.0 3phase 4wire
Figure 3-6 Entering Values to the Virtual Keyboard
To enter a decimal value, enter the integer part of the decimal number first.
Then scroll inside virtual keyboard till box is highlighted. Press OK key of
Klea to insert the decimal point. Following the point, enter the decimal part
of the desired value.
To enter a negative value, enter the number, move inside the virtual keyboard
point to the negative sign box and press OK.
26
SECTION 3 MENUS
3.1.5 Voltage Transformer Ratio (VTR)
In this tab voltage transformer ratio is entered. (For Virtual Keyboard Refer
to 3.1.4 Example). The voltage transformer ratio can be adjusted between 1 –
5000.
To enter a decimal value, enter the integer part of the decimal number first.
Then scroll inside virtual keyboard till box is highlighted. Press OK key of
Klea to insert the decimal point. Following the point, enter the decimal part
of the desired value.
Startup Settings
Language Date Time CTR VTR Connection Start
English1 07 January 2013
17:45:28 1 2 3 4
1 1.0
5678
3phase 4w9ire 0 . –
ok clr
Low limit 1.0
High limit 5000.0
Figure 3-7 Voltage Transformer Ratio
In order for KLEA to perform accurate measurements, current transformer ratio should be entered correctly.
3.1.6 Connection
This menu contains information about how to connect KLEA to the
panel/electrical network. There are 3 connection types:
· 3 phase 4 wire connection · 3 phase 3 wire connection · Aron connection
Startup Settings
Language Date Time CTR VTR Connection Start
E1077n:g4Jla5isn:h33A2upp8raohhrnaayss2ee0431ww3 iirree 1 1.0 3phase 4wire
Initializing …………………….. Figure 3-8 Connection Types
27
SECTION 3 MENUS
3.1.7 Start
When Start tab is selected, press OK key to initialize Klea.
Startup Settings
Language Date Time CTR VTR Connection Start
English 07 January 2013 17:45:28 1 1.0 3phase 4wire
Initializing ……………………..
Figure 3-9 Start
KLEA “first power-on” settings page only appears when KLEA is powered up for
the first time after factory production. Following this first initialization,
all the required settings (including “first power-on” page settings) can be
accomplished via Settings menu of KLEA.
3.2 Startup Screen
After KLEA is turned on, following page appears.
Settings Measure Meters Alarms Analysis
V1 2 2 0 . 0 V I1
5.0 A
V2 2 2 0 . 0 V I2
5.0 A
V3 2 2 0 . 0 V I3
5.0 A
1 23 V
I
1212
E
17:22
Figure 3-10 Startup Screen
At the top of the screen, there are multiple selection menus. In the middle,
instantaneous voltage and current values pertaining to each phase are shown.
At the bottom left of the screen, current and voltage values of the three
phases and connection type are shown. At the bottom right corner, system clock
(KLEA time) is shown. Operator can navigate between the multiple selection
menus by pressing right and left arrow keys. Press OK key to enter into any
multiple selection menu.
When 3phase-4wire or ARON connection is selected, VL-N voltages are shown in
startup screen. When 3phase-3wire connection is selected, VL-L voltages are
shown in startup screen
28
SECTION 3 MENUS
3.2.1 Settings
KLEA settings are made in this menu. Select Settings menu and press OK key.
When OK key is pressed, submenus will appear as seen in the Figure 3-11. Under
the Settings menu, the following submenus exist.
· Setup · Date/Time · System info · Password · Restart · Default Settings
Settings Measure Meters Alarms
Setup
0 . 0 DVa1te / Time
System info
Password
0 . 0 RDVee2sfataurltt settings
V I1 V I2
Analysis
5.0 A 5.0 A
V3 2 2 0 . 0 V I3
5.0 A
1 23 V
I
1212
E
17:22
3.2.1.1 Setup Menu
Figure 3-11 Settings Menu
The following submenus are available inside Setup menu:
· Network · Device · Energy · Digital input · Digital output · Communication ·
Alarm · Clear
The user can scroll inside the menus by pressing up and down keys. Press OK
key in order to access contents of each submenus (the submenus under the setup
menu) .
In order for the new settings to be accepted by KLEA and stored in the memory,
operator should navigate back (by pressing X key) to Startup Screen from the
tab at which change has been made. When the operator returns to Startup page,
“Settings changed. Save?” message will appear on the screen. If OK is pressed,
changes will be accepted and stored in permanent memory. If X key is pressed,
the changes will not be accepted by KLEA and will not be stored in permanent
memory.
29
SECTION 3 MENUS
When “Settings changed. Save?” message appears on KLEA screen; if OK is pressed, setting changes will be accepted and stored in permanent memory. If X key is pressed, the changes will not be accepted and will not be stored in permanent memory.
Settings changed. Save?
X
OK
3.2.1.1.1 Network Menu
Figure 3-12 KLEA Save Query
Electrical network related settings are accomplished in this menu.
Settings Measure Meters Alarms Analysis
Settings->Setup->Network
Setup
Network
CTR
10
0 . 0 DVa1te / Time
System info
DeviceV I1 Energy
5.0 A
VTR Connection
1.0 3phase 4wire
Password
Digital input
Demand period 15
min
0 . 0 RDVee2sfataurltt settings DCiogmitamlVuonuitcIp2auttion
5 . 0 A Power unit
Kilo
Alarm
V3 2 2 0 .C0lear V I3
5.0 A
1 23 V
I
1212
E
17:22
Figure 3-13 Network Menu
3.2.1.1.1.1 Current Transformer Ratio
In this submenu current transformer ratio is entered. Inside Network menu, press up and down keys to select CTR. Press OK key and KLEA virtual keyboard will appear on the screen. The current transformer ratio (CTR) can be adjusted between 1 – 5000. (For Virtual Keyboard Refer to 3.1.4 Example)
Settings->Setup->Network
CTR VTR Connection Demand period Power unit
1 1.0
10
3phase 4w1ire 2
15 Kilo
56
90
34 7 m8in
.-
ok clr
Low limit 1
High limit 5000
Figure 3-14 Setting Current Transformer Ratio
In order for KLEA to perform accurate measurements, current transformer ratio
should be entered correctly.
30
SECTION 3 MENUS
3.2.1.1.1.2 Voltage Transformer Ratio
In this submenu voltage transformer ratio is entered. Inside Network menu,
press up and down keys to select VTR. Press OK key and KLEA virtual keyboard
will appear on the screen. The voltage transformer ratio (VTR) can be adjusted
between 1 – 5000. (For Virtual Keyboard Refer to 3.1.4 Example). If a decimal
number is to be entered as a VTR,
with the help of Klea arrow keys point to the box on the Virtual Keyboard and
press OK key.
In order for KLEA to perform accurate measurements, the voltage transformer ratio should be entered correctly.
Settings->Setup->Network
CTR VTR Connection Demand period Power unit
1 1.0
1.0
3phase 4w1ire 2
15 Kilo
56
90
34 7 m8in
.-
ok clr
Low limit 1.0
High limit 5000.0
3.2.1.1.1.3 Connection
Figure 3-15 Setting Voltage Transformer Ratio
KLEA may perform measurements with three different connection types. · 3 phase
4 wire connection · 3 phase 3 wire connection · Aron connection
Inside Network menu, press up and down keys to select Connection. Press OK key
and the above connection types will appear on the screen. Select the
connection type and press OK to finish the setting.
Settings->Setup->Network
CTR VTR Connection Demand period Power unit
311p.00hase33Appr4ohhwnaaissreee
4wire 3wire
15
min
Kilo
Figure 3-16 Connection
31
SECTION 3 MENUS
3.2.1.1.1.4 Demand Period
Inside Network menu, press up and down keys to select (highlight) Demand period’ menu item. WhenDemand period’ is selected, press OK key and KLEA
virtual keyboard will appear on the screen. Demand period can be adjusted
between 1 – 60 minutes. (For Virtual Keyboard Refer to 3.1.4 Example)
Settings->Setup->Network
CTR VTR Connection Demand period Power unit
1 1.0
15
3phase 4w1ire 2
15 Kilo
56
90
34 7 m8in
.-
ok clr
Low limit 1
High limit 60
3.2.1.1.1.5 Power Unit
Figure 3-17 Demand Period
KLEA displays total power or total energy values in two different units: · Kilo · Mega
Inside Network menu, press up and down keys to select (highlight) Power unit’ menu item. WhenPower unit’ is selected, press OK key and the aforementioned
options will appear on the screen. Press up and down keys to select the
desired option and press OK key to complete the setting.
Settings->Setup->Network
CTR VTR Connection
311p.0haseMKi4elowgaire
Demand period 15
min
Power unit
Kilo
Figure 3-18 Power Unit Setup
32
SECTION 3 MENUS
3.2.1.1.2 Device Menu
· Language · Contrast · New Password · ·
Settings Measure Meters Alarms Analysis
Settings->Setup->Device
Setup
Network
0 . 0 DVa1te / Time
System info
DeviceV I 1 Energy
Password
Digital input
0 . 0 RDVee2sfataurltt settings DCiogmitamlVuonuitcIp2auttion
Alarm
V3 2 2 0 .C0lear V I3
Language
English
5 . 0 A Contrast
Level 0
Pass.protection Off
New password 1
5 . 0 A Display on
Time dependent sec
Display on time 600
5.0 A
1 23 V
I
1212
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17:22
3.2.1.1.2.1 Language
Settings->Setup->Device
Language Contrast Pass.protection New password
OE1Lenffvgelils0hTPEünrgklçiseh
Display on
Time dependent sec
Display on time 600
33
SECTION 3 MENUS
3.2.1.1.2.2 Contrast
Level -4.
Settings->Setup->Device
Language Contrast
EnglishLevel -4 Level 0Level -3
Pass.protection Off Level -2
New password 1 Level -1
Display on
Time deLpeevenld0ent min
Display on time 600 Level 1
Level 2
Level 3
Level 4
3.2.1.1.2.3 Password Protect~on and New Password
KLEA has a password protect on and default password protect on s Off .
Keyboard Refer to 3.1.4 Example).
Settings->Setup->Device
Language Contrast
Pass.protection
New password Display on Display on time
ELenvgelils0h1
Off
1234
1
567
Time dependent
m8in
600
90 . –
ok clr
Low limit 1
High limit 9999
34
SECTION 3 MENUS
3.2.1.1.2.4 Display on Selection
· ·
Settings->Setup->Device
Language Contrast Pass.protection
New password Display on Display on time
ELenvgelils0h600
Off
1234
1 Time
depe5nde6nt
7
m8in
600
90 . –
ok clr
Low limit 1
High limit 600
3.2.1.1.2.5 Display on T~me
to 3.1.4 Example).
3.2.1.1.3 Energy Menu
Settings->Setup->Energy
T1_1 start time
8
T1_2 start time
16
T1_3 start time
0
Start of day
0
Start of month
1
T1 kWh
0.0
T1 kWh E.
0.0
T1 kVArh I.
0.0
T1 kVArh E.
0.0
T1_1 kWh
0.0
T1_1 kWh E.
0.0
T1_1 kVArh I.
0.0
hr hr hr hr
kWh kWh kVArh kVArh kWh kWh kVArh
Energy Menu
35
Refer
SECTION 3 MENUS
3.2.1.1.3.1 T1_1 start time
Electric meters can have more than one tariff and also individual tariffs can
be sliced in time.
`T1_1′ abbreviation refers to the first time slice of tariff 1 meter. T1_1
start time can be adjusted between 0-23 (for Virtual Keyboard Refer to 3.1.4
Example).
“T1 rate1” meter (the first time slice of T1 meter – T1_1) counts between T1_1
start time and T1_2 start time.
Example:
Assume that T1_1 start time’ andT1_2 start time’ are adjusted as 8 and 16
respectively. “T1 rate1 meter (T1_1)” counts starting from 08:00 and ceases at
16:00.
Meters Alarms Analysis
T1 TV11 rate1 T1 rate2 T1 rate3 TDV2i2gital input
0.0 0.0
V I1 V I2
V3 2 2 0 . 0 V I3
5.0 A 5.0 A 5.0 A
1 23 V
I
1212
E
17:22
Settings->Setup->Energy
T1_1 start time
8
T1_2 start time
16
T1_3 start time
0
Start of day
0
Start of month
1
T1 kWh
0.0
T1 kWh E.
0.0
T1 kVArh I.
0.0
T1 kVArh E.
0.0
T1_1 kWh
0.0
T1_1 kWh E.
0.0
T1_1 kVArh I.
0.0
hr hr hr hr
kWh kWh kVArh kVArh kWh kWh kVArh
3.2.1.1.3.2 T1_2 start time
Figure 3-25 T1_1 start time
`T1_2′ abbreviation refers to the second time slice of tariff 1 meter.
T1_2 start time can be adjusted between 0-23 (for Virtual Keyboard Refer to
3.1.4 Example).
“T1 rate2” meter (the second time slice of T1 meter – T1_2) counts between
T1_2 start time and T1_2 start time.
Example:
Assume that T1_2 start time’ andT1_3 start time’ are adjusted as 16 and 0
respectively. “T1 rate 2 meter (T1_2)” counts starting from 16:00 and ceases
at 00:00.
36
SECTION 3 MENUS
Meters Alarms Analysis
T1 TV11 rate1 T1 rate2 T1 rate3 TDV2i2gital input
0.0 0.0
V I1 V I2
V3 2 2 0 . 0 V I3
5.0 A 5.0 A 5.0 A
1 23 V
I
1212
E
17:22
Settings->Setup->Energy
T1_1 start time
8
T1_2 start time
16
T1_3 start time
0
Start of day
0
Start of month
1
T1 kWh
0.0
T1 kWh E.
0.0
T1 kVArh I.
0.0
T1 kVArh E.
0.0
T1_1 kWh
0.0
T1_1 kWh E.
0.0
T1_1 kVArh I.
0.0
Figure 3-26 T1_2 start time
hr hr hr hr
kWh kWh kVArh kVArh kWh kWh kVArh
3.2.1.1.3.3 T1_3 start time
T1_3′ abbreviation refers to the third time slice of tariff 1 meter. T1_3 start time can be adjusted between 0-23 (for Virtual Keyboard Refer to 3.1.4 Example). “T1 rate3” meter (the second time slice of T1 meter – T1_3) counts between T1_3 start time and T1_1 start time. Example: Assume thatT1_3 start time’ and `T1_1 start time’ are adjusted as 0 and 8
respectively. “T1 rate 3 meter (T1_3)” counts starting from 16:00 and ceases
at 00:00.
Meters Alarms Analysis
T1 TV11 rate1 T1 rate2 T1 rate3 TDV2i2gital input
0.0 0.0
V I1 V I2
V3 2 2 0 . 0 V I3
5.0 A 5.0 A 5.0 A
1 23 V
I
1212
E
17:22
Settings->Setup->Energy
T1_1 start time
8
T1_2 start time
16
T1_3 start time
0
Start of day
0
Start of month
1
T1 kWh
0.0
T1 kWh E.
0.0
T1 kVArh I.
0.0
T1 kVArh E.
0.0
T1_1 kWh
0.0
T1_1 kWh E.
0.0
T1_1 kVArh I.
0.0
hr hr hr hr
kWh kWh kVArh kVArh kWh kWh kVArh
Figure 3-27 T1_3 start time
If T1_1 and T1_2 have the same value, T1_1 and T1_3 counters count; If T1_1 and T1_3 have the same value T1_1 and T1_2 counters count; if T1_2 and T1_3 have the same value; T1_1 and T1_2 counters count, If T1_1, T1_2 and T1_3 have the same value, only T1_1 counter will count.
37
SECTION 3 MENUS
3.2.1.1.3.4 Start of day
Start of day can be adjusted between 0 – 23. (for Virtual Keyboard Refer to
3.1.4 Example)
3.2.1.1.3.5 Start of month
Start of month can be adjusted between 1 – 28. (for Virtual Keyboard Refer to
3.1.4 Example) The settings listed below (between 3.2.1.1.3.6 and
3.2.1.1.3.25) are used to synchronize the system electric meter and KLEA
meter. Each of the below items can be adjusted between 0.000 20000000000,0
(for Virtual Keyboard Refer to 3.1.4 Example).
Klea meters calculate energy by multiplying with CTR and VTR values.User
should take this fact into account when entering the below intial energy
values.
3.2.1.1.3.6 T1 kWh
“Initial” value for import active energy of T1 can be entered in this tab.
3.2.1.1.3.7 T1 kWh E.
“Initial” value for export active energy of T1 can be entered in this tab.
3.2.1.1.3.8 T1 kVArh I.
“Initial” value for import reactive energy of T1 can be entered in this tab.
3.2.1.1.3.9 T1 kVArh E.
“Initial” value for export reactive energy of T1 can be entered in this tab.
3.2.1.1.3.10 T1_1 kWh
“Initial” value for import active energy of T1_1 can be entered in this tab.
3.2.1.1.3.11 T1_1 kWh E.
“Initial” value for export active energy of T1_1 can be entered in this tab.
3.2.1.1.3.12 T1_1 kVArh I.
“Initial” value for import reactive energy of T1_1 can be entered in this tab.
3.2.1.1.3.13 T1_1 kVArh E.
“Initial” value for export reactive energy of T1_1 can be entered in this tab.
38
SECTION 3 MENUS
3.2.1.1.3.14 T1_2 kWh
“Initial” value for import active energy of T1_2 can be entered in this tab.
3.2.1.1.3.15 T1_2 kWh E.
“Initial” value for export active energy of T1_2 can be entered in this tab.
3.2.1.1.3.16 T1_2 kVArh I.
“Initial” value for import reactive energy of T1_2 can be entered in this tab.
3.2.1.1.3.17 T1_2 kVArh E.
“Initial” value for export reactive energy of T1_2 can be entered in this tab.
3.2.1.1.3.18 T1_3 kWh
“Initial” value for import active energy of T1_3 can be entered in this tab.
3.2.1.1.3.19 T1_3 kWh E.
“Initial” value for export active energy of T1_3 can be entered in this tab.
3.2.1.1.3.20 T1_3 kVArh I.
“Initial” value for import reactive energy of T1_3 can be entered in this tab.
3.2.1.1.3.21 T1_3 kVArh E.
“Initial” value for export reactive energy of T1_3 can be entered in this tab.
3.2.1.1.3.22 T2 kWh
“Initial” value for import active energy of T2 can be entered in this tab.
3.2.1.1.3.23 T2 kWh E.
“Initial” value for export active energy of T2 can be entered in this tab.
3.2.1.1.3.24 T2 kVArh I.
“Initial” value for import reactive energy of T2 can be entered in this tab.
39
SECTION 3 MENUS
3.2.1.1.3.25 T2 kVArh E.
“Initial” value for export reactive energy of T2 can be entered in this tab.
3.2.1.1.4 Digital Input Menu
Digital input menu consists of Input1 and Input2 menus. KLEA digital inputs
are used in order to activate Tariff 2 meter and/or to count a digital signal.
Settings Measure Meters Alarms Analysis
Setup
Network
Input1
0 . 0 DVa1te / Time
System info
DeviceV I1 Energy
5 Input2 . 0 A
Password
Digital input
0 . 0 RDVee2sfataurltt settings DCiogmitamlVuonuitcIp2auttion
5.0 A
Alarm
V3 2 2 0 .C0lear V I3
5.0 A
1 23 V
I
1212
E
17:22
Figure 3-28 Digital Input Menu
Settings Measure Meters Alarms Analysis
Setup
Network
Input1
0 . 0 DVa1te / Time
System info
DeviceV I1 Energy
5 . 0 Input2
A
Input3
Password
Digital input Input4
0 . 0 5 . 0 RDVee2sfataurltt settings
DCiogmitamlVuonuitcIp2auttion
Input5 Input6
A
Alarm
Input7
V3 2 2 0 .C0lear V I3
5.0 A
1 23 V
I
1212
E
17:22
Figure 3-29 Digital Input Menu (With IO option)
40
SECTION 3 MENUS
3.2.1.1.4.1 Input1 Menu
Input1 operates when DI1 and GND pins of KLEA are short circuited. Input1 menu
has two settings:
· Mode · Delay
3.2.1.1.4.1.1 Mode
Mode options are as seen below (Figure 3-30). Press up and down keys to scroll inside options. Press OK key to select the desired option.
Settings->Setup->Digital input->Input1
Mode Delay
Off 100
Off 2nd tariff
Counter
Figure 3-30 Mode Selection
· Assume that for digital input 1, 2nd tariff’ is selected as the mode setting. Under this condition, when digital input 1 is short circuited (activated), tariff 1 meter will stop and tariff 2 meter will start to count. · Assume that for digital input 1,Counter’ is selected as the mode setting.
Under this condition, each time DI1 and GND pins are short-circuited,
“Meters->Digital input-> Digital input1 counter” counts (Figure 3-31).
Meters Alarms Analysis
T1 TV11 rate1 T1 rate2 T1 rate3 TDV2i2gital input
0.0 0.0
V I1 V I2
V3 2 2 0 . 0 V I3
5.0 A
Meters->Digital input
Counter 1
0
Counter 2
0
5.0 A
5.0 A
1 23 V
I
1212
E
17:22
Figure 3-31 Digital Input1 Counter
41
SECTION 3 MENUS
3.2.1.1.4.1.2 Delay
Digital input delay can be adjusted between 10 2000 milliseconds. In order for
2nd tariff’ orCounter’ modes to be activated; DI1 and GND pins should be
short-circuited at least “delay” period of time. (for Virtual Keyboard Refer
to 3.1.4 Example)
Delay
100
msec
Example: Digital input Mode Delay
Figure 3-32 Delay
: Input1 : Counter, : 200 msec
When DI1 and GND pins are short-circuited for minimum 200 msec, `Input 1 Counter’ increments by 1.
Example: Digital input Mode Delay
: Input1 : Tariff 2 : 200 msec
In order for the Tariff 2 meter to be active, DI1 and GND pins should be short-circuited for minimum 200 msec. Tariff 2 meter will be active during the course of short circuit time.
DI1 and GND short circuit <200msec>
DI1 ve GND open circuit
DI1 and GND short circuit <100msec>
Time
tari~ 1 c ounts
tari~ 2 c ounts
Tari~ 1 c ounts
3.2.1.1.4.2 Input 2 Menu
Figure 3-33 Tariff 1 or Tariff 2 Activation
Input 2 applications and settings are the same as Input1. Digital input2
operates with DI2 and GND pins.
3.2.1.1.4.3 Input 3 Menu (optional)
Input 3 is applicable to optional digital IO Klea models. Input 3 applications and settings are the same as Input1. Digital input3 operates with DI3 and GND pins.
42
SECTION 3 MENUS
3.2.1.1.4.4 Input 4 Menu (optional)
Input 4 is applicable to optional digital IO Klea models. Input 4 applications
and settings are the same as Input1. Digital input4 operates with DI4 and GND
pins.
3.2.1.1.4.5 Input 5 Menu (optional)
Input 5 is applicable to optional digital IO Klea models. Input 5 applications
and settings are the same as Input1. Digital input5 operates with DI5 and GND
pins.
3.2.1.1.4.6 Input 6 Menu (optional)
Input 6 is applicable to optional digital IO Klea models. Input 6 applications
and settings are the same as Input1. Digital input6 operates with DI6 and GND
pins.
3.2.1.1.4.7 Input 7 Menu (optional)
Input 7 is applicable to optional digital IO Klea models. Input 7 applications
and settings are the same as Input1. Digital input7 operates with DI7 and GND
pins.
3.2.1.1.5 Digital Output Menu
It comprises of Output1 and Output2 menus.
Settings Measure Meters Alarms Analysis
Setup
Network
Output1
0 . 0 DVa1te / Time
System info
DeviceV I1 Energy
5 . 0 Output2
A
Password
Digital input
0 . 0 RDVee2sfataurltt settings CDoigmitamlVuonuitcIp2auttion
5.0 A
Alarm
V3 2 2 0 .C0lear V I3
5.0 A
1 23 V
I
1212
E
17:22
Figure 3-34 Digital Output Menu
Settings Measure Meters Alarms Analysis
Setup
Network
Output11
0 . 0 DVa1te / Time
System info
DeviceV I1 Energy
5 . 0 Output2
A
Output3
Password
Digital input Output4
0 . 0 5 . 0 RDVee2sfataurltt settings
CDoigmitamlVuonuitcIp2auttion
Output5 Output6
A
Alarm
Output7
V3 2 2 0 .C0lear V I3
5.0 A
1 23 V
I
1212
E
17:22
Figure 3-35 Digital Output Menu (optional digital I/O model
43
SECTION 3 MENUS
3.2.1.1.5.1 Output1 Menu
Output1 gives output from D01- and D01+ pins.
Mode: Press up and down keys to navigate between digital outputs. Press OK on
the desired output, and options seen in Figure 3-36 will appear. Any of them
can be assigned as output1 operating mode.
Mode setting has the following options.
· Off · T1 kWh · T1 kWh E. · T1 kVArh I. · T1 kVArh E. · T1_1 kWh · T1_1 kWh
E. · T1_1 kVArh I. · T1_1 kVArh E. · T1_2 kWh · T1_2 kWh E. · T1_2 kVArh I. ·
T1_2 kVArh E. · T1_3 kWh · T1_3 kWh E. · T1_3 kVArh I. · T1_3 kVArh E. · T2
kWh · T2 kWh E. · T2 kVArh I. · T2 kVArh E. · Digital Input
Settings->Setup->Digital output->Output1
Mode Energy Width Multiplier
Off 1
100
Off
T1 kWh T1 kWh E.
1
T1 kVArh I.
T1 kVArh E.
T1_1 kWh
T1_1 kWh E.
T1_1 kVArh I.
T1_1 kVArh E.
T1_2 kWh
T1_2 kWh E.
T1_2 kVArh I.
Figure 3-36 Output1 Menu
44
SECTION 3 MENUS
Energy: When selected meter option(mode option) counts for the selected
“energy” value, Output1 generates a pulse (for Virtual Keyboard Refer to 3.1.4
Example).
Width: It can be adjusted between 50 2500 msec (for Virtual Keyboard Refer
to 3.1.4 Example).
Multiplier: Multiplier is of use only when “Output1->mode” is adjusted as
“Digital input”.
When “digital input1 counter” (Refer to Digital input 3.2.3.6) reaches the `multiplier’; “digital output1” generates a pulse from DO1+ and DO1- pins.
It can be adjusted between 1 – 10000 (for Virtual Keyboard Refer to 3.1.4 Example).
Second example explains this implementation.
Example: Assume the settings are as below,
Digital output : Output1
Mode
: T1 kWh
Energy
: 2
Width
: 100msec
Assume that, Tariff 1 import active previous value is 1.1kWh. When T1 kWh reaches to 3.1kWh, 5.1kWh, 7.1kWh etc. a pulse of 100msec will be generated at the outputs of DO1- and DO1+.
Example:
Digital output : Output1
Mode
: Digital input
Energy
: When connection type is digital input, the Energy tab is not used.
Width
: 100msec
Multiplier : 100
Assume also that Digital input1 mode had been adjusted as “counter”. In this case, when Counter1 reaches 100 or multiples of 100, a pulse of 100 msec will be will be generated at the output pins DO1- and D01+.
Assume that the digital input 1 counter value was 35 before multiplier adjustment. Assume also that operator adjusts `Multiplier’ as 100. Under these conditions, Output 1 generates a pulse when digital input 1 counter reaches the values 135, 235, 335, 435 and so on.
45
SECTION 3 MENUS
3.2.1.1.5.2 Output2 Menu
Output 2 applications and settings are the same as Output1. Output2 generates
pulse from DO2+ and DO2- pins.
3.2.1.1.5.3 Output3 Menu (optional)
Output 3 applications and settings are the same as Output1. Output3 generates
pulse from DO3+ and DO3- pins.
3.2.1.1.5.4 Output4 Menu (optional)
Output 4 applications and settings are the same as Output1. Output4 generates
pulse from DO4+ and DO4- pins.
3.2.1.1.5.5 Output5 Menu (optional)
Output 5 applications and settings are the same as Output1. Output5 generates
pulse from DO5+ and DO5- pins.
3.2.1.1.5.6 Output6 Menu (optional)
Output 6 applications and settings are the same as Output1. Output6 generates
pulse from DO6+ and DO6- pins.
3.2.1.1.5.7 Output7 Menu (optional)
Output 7 applications and settings are the same as Output1. Output7 generates
pulse from DO7+ and DO7- pins.
3.2.1.1.6 Analog Output Menu (Optional)
Settings Measure Meters Alarms Analysis
Setup
Network
Output11
0 . 0 DVa1te / Time
System info
DeviceV I1 Energy
5 . 0 Output2
A
Output3
Password
Digital input Output4
0 . 0 RDVee2sfataurltt settings DAnigaitlaolgVoouutIpt2puutt
5.0 A
Communication
2 2 0 . 0 V3
ACllaeramr V I3
5.0 A
1 23 V
I
1212
E
17:22
Figure 3-37 Analog Output Menu
KLEA has two different optional analog output models; 2 analog output and 4 analog output models.
46
SECTION 3 MENUS
Operator can adjust KLEA to give output from analog output channels for the following parameters: voltage, current, active power, reactive power, apparent power, frequency, phase-phase voltages, neutral current, total current, total active power, total reactive power and total apparent power pertaining to L1, L2, L3 phases.
Analog output channels can be adjusted to generate signals as 0-5V, 0-10V, -5-5V, -1010V, 0-20mA, 4-20mA. Analog output menu comprises of the following submenus.
Output1 (available in 2 analog and 4 analog outputs models) Output2 (available
in 2 analog and 4 analog outputs models) Output3 (available only in 4 analog
outputs model) Output4 (available only in 4 analog outputs model)
3.2.1.1.6.1 Output1 Menu
Output1 menu comprises of the following submenus. · Input mode · Output conn. · Min. Value · Max. Value · Multiplier
Settings->Setup->Analog output->Output1
Input mode Output conn. Min. value Max. value Multiplier
V1 (L-N) 0-5V 0.0 0.0 1
Figure 3-38 Output1
47
SECTION 3 MENUS
3.2.1.1.6.1.1 Input mode
Analog output will generate a signal in accordance with the parameter selected
in Input mode tab. Analog output examples will clarify the application of
settings.
Input mode options are as follows:
V1(L-N) V2(L-N) V3(L-N) I1 I2 I3 P1 P2 P3 Q1 Q2 Q3 S1 S2 S3 F IN VLL12 VLL23
VLL31 I tot. P tot. Q tot. S tot.
Settings->Setup->Analog output->Output1
Input mode Output conn. Min. value Max. value Multiplier
0V00..-1005V(L-NVVVI)1123
(L-N) (L-N) (L-N)
1
I2
I3
P1
P2
P3
Q1
Q2
Q3
Figure 3-39 Input mode
48
SECTION 3 MENUS
3.2.1.1.6.1.2 Output connection
Inside Output1 menu, press up and down keys to select (highlight) Output connection’ menu item. WhenOutput connection’ is selected, press OK key and
the options in Figure 3-40 will appear on the screen. Press up and down keys
to select the desired option and press OK key to complete the setting.
Settings->Setup->Analog output->Output1
Input mode Output conn. Min. value Max. value Multiplier
V1 (L-N0)- 5V 0-5V -5 – 5V 0.0 0 – 10V 0.0 -10 – 10V 1 0 – 20mA
4 – 20mA
Figure 3-40 Output connection
Assume that for analog output 1, output connection was selected as 0-5V (refer
to Figure 3.40). Then, operator should adjust the”analog output 1″dip switch
as seen in Figure 3-41 (Vout1 -> ON ; Iout1 -> OFF). After the dip switch
adjustment, setting will be completed.
OFF ON
IOut4 VOut4 IOut3 VOut3 IOut2 VOut2 IOut1 VOut1
Figure 3-41 Vout1 -> ON ; Iout1 -> OFF
Assume that for analog output 1, output connection was selected as 4-20 mA
(refer to Figure 3.40). Then, operator should adjust the “analog output 1” dip
switch as seen in Figure 3-42 (Vout1 -> OFF; Iout1 -> ON). After the dip
switch adjustment, setting will be completed.
OFF ON
IOut4 VOut4 IOut3 VOut3 IOut2 VOut2 IOut1 VOut1
Figure 3-42 Vout1 -> OFF; Iout1 -> ON
49
SECTION 3 MENUS
In order to obtain voltage output, Vout1 should be set to ON, and Iout1 should
be set to OFF. If both switches are ON or OFF at the same time, analog output
will not operate correctly.
In order to obtain current output, Vout1 should be set to OFF, and Iout1
should be set to ON. If both switches are ON or OFF at the same time, analog
output will not operate correctly.
If the setting of output connection and setting of the dip switch are incompatible, related analog output will not operate correctly.
3.2.1.1.6.1.3 Min. value
The minimum value for the selected input mode. See also 3.2.1.1.6.1.5
Multiplier setting.
3.2.1.1.6.1.4 Max. value
The maximum value for the selected input mode. See also 3.2.1.1.6.1.5
Multiplier setting.
If “Min. value” and “Max. value” are adjusted to be the same, then analog
output will not operate.
3.2.1.1.6.1.5 Multiplier
When `Multiplier’ is selected, press OK key and the options in Figure 3-43
will appear on the screen. Press up and down keys to select the desired option
and press OK key to complete the setting. Multiplier coefficient options are
as follows: · 1 · Kilo (1000) · Mega (1000000)
For example, assume that 10000000W and 350000000W are required to be entered
for min. and max. values. In this case, if operator selected Mega in
multiplier tab, then it will be sufficient to enter 10 and 350 for min. and
max. values.
Settings->Setup->Analog output->Output1
Input mode Output conn. Min. value Max. value Multiplier
0V00..-1005V(L-N1KM) ieloga 1
Figure 3-43 Multiplier
50
SECTION 3 MENUS
Klea can output 0 5V, -5 5V, 0 10V, -10 10V, 0 20mA and 0 20mA range signals from AOX-GND pins.
When the value of Input mode’ parameter falls belowMin. value’ with an
amplitude less than 2.5%; or exceeds Max. value’ with an amplitude again less than 2.5%; output signal will linearly follow this change. ForOutput conn.’
types whose low limit is zero, output signal will not fall below zero; only
high limit will change linearly up to 2.5% of its value.
In summary, output signals from AOX-GND pins will operate as follows:
0 5 V -5 5 V 0 10 V -10 10 V 0 20 mA 4 20mA
0 5.125 V -5.125 5.125 V 0 10.25 V -10.25 10.25 V 0 20.5 mA 3.9 20.5 mA
(output signal low value will not fall below zero) (output signal low value will not fall below zero) (output signal low value will not fall below zero)
When the value of Input mode’ parameter falls belowMin. value’ with an
amplitude more than 2.5%; or exceeds`Max. value’with an amplitude again more
than 2.5%; output signal will change. In this case, output signals from AOX-
GND pins will operate as follows in order to indicate that there is a problem
in the electrical network:
for 0 5 V setting; AOX-GND signal amplitude will be for -5 5V setting; AOX-GND signal amplitude will be for 0 10 V setting; AOX-GND signal amplitude will be for -10 10 V setting; AOX-GND signal amplitude will be for 0 20 mA setting; AOX-GND signal amplitude will be for 4 20 mA setting; AOX-GND signal amplitude will be
10 V 10 V 10.8 V 10.8 V 21.6 mA 21.6 mA
The amplitude of analog output signal on AO1-GND pins will be as calculated by the following formula.
[ ] AO1-GND = AO1 con.highlimit-AO1 con.lowlimit x (Meas. value-(Min value x Multip.)) + AO1 con. low limit (Max value-Min value) x Multip.
Example1: Assume that the following values have been assigned;
Input connection : V1(L-N) (phase-neutral voltage of phase 1)
Output connection: 0-5V
Min. value
: 100V
Max. value
: 200V
Multiplier
: 1
Then, when measure is KLEA V1(L-N)=120V, the result will be as follows,
51
SECTION 3 MENUS
[ AO1-GND =
5-0
] x (120-(100×1)) + 0 = 1V
(200-100)x1
When measure is KLEA V1(L-N)=185V, the result will be as follows,
[ AO1-GND =
5-0
] x1 x (185-(100×1)) + 0 = 4.25V
(200-100)x1
Example2:
Assume that the following have been assigned;
Input connection : P tot.(total active power)
Output connection: 4-20mA
Min. value
: 600W
Max. value
: 1000W
Multiplier
: 1
Then, when measure is KLEA P tot. = 732W, the result will be as follows,
[ ] AO1-GND =
20-4 x (732-(600×1)) + 4 = 5.28mA
(1000-600)x1
When measure is KLEA V1(L-N)=992W, the result will be as follows,
[ ] AO1-GND =
20-4 x (992-(600×1)) + 4 = 19.68mA
(200-100)x1
Example3:
Assume that the following have been assigned;
Input connection : Q tot.(total reactive power)
Output connection: -10 – 10V
Min. value
:1400VAr
Max. value
:1800VAr,
Multiplier
: kilo
When measure is KLEA S tot.=1485000VAr, the result will be as follows,
[ AO1-GND =
10-(-10)
] x (1485000-(1400×1000)) + (-10) = -5.75V
(1800-1400)x1000
When measure is KLEA V1(L-N)=1695000VA , the result will be as follows,
[ AO1-GND =
10-(-10)
] x (1695000-(1400×1000)) + (-10) = 4,75V
(1800-1400)x1000
3.2.1.1.6.2 Output2 Menu
Analog output 2 settings are the same as Output1. Analog output2 gives output from AO2- GND pins.
52
SECTION 3 MENUS
3.2.1.1.6.3 Output3 Menu
Analog output 3 settings are the same as Output1. Analog output2 gives output
from AO3- GND pins.
3.2.1.1.6.4 Output4 Menu
Analog output 4 settings are the same as Output1. Analog output2 gives output
from AO4- GND pins.
3.2.1.1.7 Communication Menu
KLEA implements MODBUS over serial line with RTU mode. In this menu, settings
related with Modbus RTU are accomplished.
Settings Measure Meters Alarms
Setup
Network
0 . 0 DVa1te / Time
System info
DeviceV I1 Energy
Password
Digital input
0 . 0 RDVee2sfataurltt settings DCiogmitamlVuonuitcIp2auttion
Alarm
V3 2 2 0 .C0lear V I3
Analysis
5.0 A 5.0 A 5.0 A
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Figure 3-44 Communication Menu
3.2.1.1.7.1 Baud Rate Menu
Inside Communication menu, press up and down keys to select (highlight) `Baud
rate’ menu item. Press OK key and baud rate options will appear on the screen
as seen in Figure 3-45. Scroll inside options by pressing up and down keys;
press OK key to select the desired value. Avaliable baud rates are: 2400,
4800, 9600, 19200, 38400, 57600 and 115200 bit/sec.
Settings->Setup->Communication
Baud rate Slave Id
38400 2400 4800 9600 19200 38400 57600 115200
Figure 3-45 Setting Baud Rate
53
SECTION 3 MENUS
3.2.1.1.7.2 Slave Id
In this tab, operator can adjust the slave ID. (For Virtual Keyboard Refer to
3.1.4 Example).
Slave Id
1
Figure 3-46 Slave Id
KLEA can operate in an RS-485 network having a maximum quantity of 247 units.
As a result, Slave Id’ can be adjusted between 1 and 247. 3.2.1.1.8 Alarm Menu InsideSetup’ menu, when `Alarm’ is selected, press OK key and the options in
Figure 3-47 will appear on the screen. Press up and down keys to select the
desired option and press OK key to complete the setting.
Settings Measure Meters Alarms Analysis
Setup
Network
V(L-N)
0 . 0 DVa1te / Time
System info
DeviceV I1 Energy
5 . 0 V(L-L)
Current
A
Password
Digital input
P
0 . 0 5 . 0 RDVee2sfataurltt settings 220.0 5.0 V3
DCiogmitamlVuonuitcIp2auttion Alarm Clear
V I3
Q S CosØ PF IN F
A A
Harmonics V
Harmonics I
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3.2.1.1.8.1 V(L-N) Menu
Figure 3-47 Alarm Menu
Inside `Alarm’ menu, when V(L-N) is highlighted, press OK key and the following page will appear on the screen.
Settings->Setup->Alarm->V(L-N)
Alarm relay
Off
Low limit
0.0
V
High limit
0.0
V
Delay
0
sec
Hysteresis
0.0
%
Figure 3-48 V(L-N) Menu
54
SECTION 3 MENUS
Alarm relay:
This setting is merely used to energize or not to energize a relay, when an alarm occurs.
For alarm relay setting, following options are available:
Off
: In case of V(L-N) alarm, none of the alarm relays is energized
Relay1 : In case of V(L-N) alarm, relay 1 is energized
Relay2 : In case of V(L-N) alarm, relay 2 is energized
Press up and down keys to select the desired option and press OK key to complete the setting.
Alarm relay
Off
Figure 3-49 Alarm Relay Setup
In order to adjust Klea to issue V (L-N) alarms, operator should adjust low
limit and high limit values as described below.
When V(L-N) of “any” of the three phases exceeds “Low limit” or “High Limit”,
Klea gives an alarm.
Low Limit: Low limit value for the V(L-N) alarm. (For Virtual Keyboard Refer
to 3.1.4 Example). In order to set an alarm for V(L-N), operator should enter
a low limit value smaller than the high limit value. When low limit and high
limit values are entered to be the same, V(L-N) alarm will be deactivated (no
alarm will be set).
High Limit: High limit value for the V(L-N) alarm. (For Virtual Keyboard Refer
to 3.1.4 Example). In order to set an alarm for V(L-N), operator should enter
a high limit value larger than the low limit value. When low limit and high
limit values are entered to be the same, V(L-N) alarm will be deactivated (no
alarm will be set).
Delay: When the related alarm parameter exceeds the “Low limit” or “High
Limit” value; before declaring an alarm, Klea waits for “delay time”.
Similarly, when the related alarm parameter enters into the limit values, Klea
waits for “delay time”, before cancelling the alarm. “Delay” can be adjusted
between 0 600 sec. (For Virtual Keyboard Refer to 3.1.4 Example).
Delay
0
sec
Hysteresis:
Figure 3-50 Alarm Time Setting
It is the tolerance entered as percentage for high and low limits . Hysteresis can be
adjusted between 0 20. (For Virtual Keyboard Refer to 3.1.4 Example). Examine
following example and Figure 3-52.
55
SECTION 3 MENUS
Hysteresis
0.0
%
Figure 3-51 Hysteresis Setting
Example: For the following figure(`Delay’ is adjusted to be zero); At point A,
alarm occurs At point B, alarm disappears At point C, alarm occurs At point D,
alarm disappears
Amplitude
High limit
C
Hysteresis %
Hysteresis %
B
Low limit
A
D Waveform
Time
3.2.1.1.8.2 V(L-L) Menu
Figure 3-52 Alarm Example
Alarm for phase-to-phase voltages is adjusted in this submenu. V(L-L) settings are the same as V(L-N). Low and high limit values can be adjusted between 0 2600000.
3.2.1.1.8.3 Current Menu
Alarm for current is adjusted in this submenu. Current settings are the same
as V(L-N). Low and high limit values can be adjusted between 0 30000.
3.2.1.1.8.4 P Menu
Alarm for active power is adjusted in this submenu. P settings are the same as
V(L-N). Low and high limit values can be adjusted between -10000000000
10000000000.
3.2.1.1.8.5 Q Menu
Alarm for reactive power is adjusted in this submenu. Q settings are the same as V(L-N). Low and high limit values can be adjusted between -10000000000 10000000000.
56
SECTION 3 MENUS
3.2.1.1.8.6 S Menu
Alarm for apparent power is adjusted in this submenu. S settings are the same
as V(L-N). Low and high limit values can be adjusted between 0.0 10000000000.
3.2.1.1.8.7 CosØ Menu
Alarm for cosØ is adjusted in this submenu. cosØ settings are the same as
V(L-N). Low and high limit values can be adjusted between 0 1.
3.2.1.1.8.8 PF Menu
Alarm for power factor is adjusted in this submenu. Power factor settings are
the same as V(L-N). Low and high limit values can be adjusted between 0 1.
3.2.1.1.8.9 IN Menu
Alarm for neutral current is adjusted in this submenu. Neutral current
settings are the same as V(L-N). Low and high limit values can be adjusted
between 0 90000.
3.2.1.1.8.10 F Menu
Alarm for frequency is adjusted in this submenu. Frequency settings are the
same as V(L-N). Low and high limit values can be adjusted between 35 70.
3.2.1.1.8.11 Temp. Menu
Alarm for temperature is adjusted in this submenu. Temperature settings are
the same as V(L-N). Low and high limit values can be adjusted between -20 80.
When the low and high limit values are entered the same, KLEA will not issue an alarm.
Settings->Setup->Alarm->Current
Alarm relay
Relay1
Low limit
0.0
A
High limit
0.0
A
Delay
0.0
sec
Hysteresis
0.0
%
Figure 3-53 Setting for No Alarm
57
SECTION 3 MENUS
When operator enters a low limit value larger than the high limit, “Invalid limits. Please check.” message appears on the screen.
Settings->Setup->Alarm->Current
Alarm relay
Relay1
Low limit
0.0
A
High limit
0.0
A
Delay
0.0
sec
Hysteresis
0.0
%
Invalid limits! Please check.
X
OK
Figure 3-54 Invalid Limits message
3.2.1.1.8.12 Harmonics V Menu
Inside `Alarm’ menu, when Harmonics V is highlighted, press OK key and the following page will appear on the screen.
Settings->Setup->Alarm->Harmonics V
Alarm relay
Off
THDV hi limit
0.0
%
V3 hi limit
0.0
%
V5 hi limit
0.0
%
V7 hi limit
0.0
%
V9 hi limit
0.0
%
V11 hi limit
0.0
%
V13 hi limit
0.0
%
V15 hi limit
0.0
%
V17 hi limit
0.0
%
V19 hi limit
0.0
%
V21 hi limit
0.0
%
Delay
60
sec
Figure 3-55 Harmonics Menu
Alarm relay: Refer to 3.2.1.1.8.1 V(L-N) Menu – Alarm relay setting.
THDV High Limit: High limit value for total harmonic distortion – voltage
alarm (For Virtual Keyboard Refer to 3.1.4 Example). In order to set an alarm
for THDV, operator should enter a high limit value larger than zero. When high
limit is entered as zero, THDV alarm will be deactivated (no alarm will be
set). It can be adjusted between 0 100.
THDV hi limit
0.0
%
Figure 3-56 THDV High Limit Setting
58
SECTION 3 MENUS
V3 — V21 high limit: “3.”,”5.”…”21.”harmonic distortion high limit values are entered. In order to set an alarm for V3, V5 V21 operator should enter a high limit value larger than zero. When high limit is entered as zero (0.0), V3, V5 V21 alarm(s) will be deactivated (no alarm will be set). High limits can be adjusted between 0 100. (For Virtual Keyboard Refer to 3.1.4 Example)
V3 hi limit
0.0
%
V21 hi limit
0.0
%
Figure 3-57 V3 – V21 Harmonic High Limit
Delay: See 3.2.1.1.8.1 V(L-N) Menu – Delay setting.
3.2.1.1.8.13 Harmonics I Menu
“Harmonics I” settings are the same as the “Harmonics V” alarm settings.
3.2.1.1.9 Clear Menu
In this tab, operator can clear demand values, energy (tariff meter) values
and DI (Digital Input) counters. “All” option clears all, namely, demand,
energy and DI counter values. When “Clear” is highlighted, press OK key and
the following page will appear on the screen.
Settings Measure Meters Alarms Analysis
Setup
Network
Energy
0 . 0 DVa1te / Time
System info
DeviceV I1 Energy
5 . 0 Demand
A
DI meters
Password
Digital input
All
0 . 0 RDVee2sfataurltt settings DCiogmitamlVuonuitcIp2auttion
5.0 A
Alarm
V3 2 2 0 .C0lear V I3
5.0 A
Are you sure?
X
OK
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Figure 3-58 Clear Menu
Scroll inside options by pressing up and down keys; press OK key to clear the
desired option. When OK key is pressed, “Are you sure?” message will appear on
the screen. Press again OK key to clear the parameter; press X key to exit
with no change in the selected parameter.
Assume that, “Meters->Tariff1->Imp. Active”(Import active power) submenu is as shown below
59
SECTION 3 MENUS
Meters->T1->Imp. active
Index Curr. hour Prev. hour Curr. day Prev. day Curr. month Prev. month
267500.1 0.5 0.6 21.3 22.6 598.4 439.5
kWh kWh kWh kWh kWh kWh kWh
Figure 3-59 Before Clear
When the clear process is completed, the submenu “Meters->T1->Imp. Active”
will be as shown in the Figure 3-60.
Meters->T1->Imp. active
Index
0.0
Curr. hour
0.0
Prev. hour
0.0
Curr. day
0.0
Prev. day
0.0
Curr. month
0.0
Prev. month
0.0
kWh kWh kWh kWh kWh kWh kWh
Figure 3-60 After Clear
After the clear process, for index parameters, a value different than zero may
be observed. This value, is the initial value entered by the operator.
Assume that, initial value of “Setup->Energy->T1 kWh” was entered as 2000 kWh. In this case, after the clear process is completed, “Meters->Tariff 1->Imp. Active” value will be 2000kWh. (See Figure 3.61).
Meters->T1->Imp. active
Index Curr. hour Prev. hour Curr. day Prev. day Curr. month Prev. month
2000.0 0.0 0.0 0.0 0.0 0.0 0.0
kWh kWh kWh kWh kWh kWh kWh
Figure 3-61 Initial Value, After Clear Process
60
SECTION 3 MENUS
3.2.1.2 Date / Time Menu
In the following menu Date / Time setting is made (For date/time setting Refer
to 3.1.2 Example).
Settings Measure Meters Alarms
Setup
0 . 0 DVa1te / Time
System info
Password
0 . 0 RDVee2sfataurltt settings
V I1 V I2
Analysis
5.0 A 5.0 A
V3 2 2 0 . 0 V I3
5.0 A
Settings->Date / Time
Time Date
17 : 22 : 17 07 January 2013
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3.2.1.3 System Info Menu
Figure 3-62 Date / Time Menu
This menu is for information no setting is accomplished.
Settings Measure Meters Alarms
Setup
0 . 0 DVa1te / Time
System info
Password
0 . 0 RDVee2sfataurltt settings
V I1 V I2
Analysis
5.0 A 5.0 A
V3 2 2 0 . 0 V I3
5.0 A
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KLEMSAN
KLEA – Network Analyzer
Model
606100
Serial number
2555953
Language
English
Firmware version
1.00
PCB version
1.1.e0
Build date
29 October 2012
Temperature
26.5 °C
Battery voltage
3.30 V
Figure 3-63 System Info
Temperature and battery voltage values can be reached via RS485.
61
SECTION 3 MENUS
3.2.1.4 Password Menu
If operator have not entered password; only Date/Time, System Info and
Password tabs are active inside settings menu. In order for the remaining tabs
to be activated, operator should login via `Password’ tab.
If the entered password is correct, “Login success” message appears on the
screen. Otherwise, “Password mismatch” message will be displayed on the
screen. (For Virtual Keyboard Refer to 3.1.4 Example).
Settings Measure Meters Alarms
Setup
0 . 0 DVa1te / Time
System info
Password
0 . 0 RDVee2sfataurltt settings
V I1 V I2
Analysis
5.0 A 5.0 A
V3 2 2 0 . 0 V I3
5.0 A
Login required! X
Login success. Password mismatch.
OK
X
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3.2.1.5 Restart Menu
Figure 3-64 Password
If OK key is pressed on the restart tab, “Are you sure?” message appears on the screen. Press again OK key to restart Klea.
Settings Measure Meters Alarms
Setup
0 . 0 DVa1te / Time
System info
Password
0 . 0 RDVee2sfataurltt settings
V I1 V I2
Analysis
5.0 A 5.0 A
V3 2 2 0 . 0 V I3
5.0 A
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Are you sure?
X
OK
Figure 3-65 Restart
62
SECTION 3 MENUS
3.2.1.6 Default Settings
This menu is used to return to factory default settings. All settings except
date and time return to the factory defaults.
Note: Tariff meter indexes are not assumed to be a setting. As a result, index
values will not be cleared via this menu.
Settings Measure Meters Alarms
Setup
0 . 0 DVa1te / Time
System info
Password
0 . 0 RDVee2sfataurltt settings
V I1 V I2
Analysis
5.0 A 5.0 A
V3 2 2 0 . 0 V I3
5.0 A
Default settings will be assigned. Are you sure?
X
OK
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3.2.2 Measure Menu
Figure 3-66 Default Settings Command
The following submenus are included under the measure menu. Operator can
navigate inside measure menu by up and down keys. When the desired menu item
is highlighted, press OK key to select. Following menu items are available:
· Instantaneous · Demand · Phasor diagram · Signals · Harmonics
Measure Meters Alarms Analysis
Instantaneous
0 . 0 DVe1mand
Phasor diagram
Signals
2 HVa2rmonics 2 0 . 0
V I1 V I2
5.0 A 5.0 A
V3 2 2 0 . 0 V I3
5.0 A
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Figure 3-67 Measure Menu
63
SECTION 3 MENUS
3.2.2.1 Instantaneous Menu
This menu includes instantaneous values. If OK is pressed on this tab, the
following page appears on the screen. Operator can scroll inside Instantaneous
values by pressing right and left keys.
Measure->Instantaneous->V L-N
V1 220.0
V
V2 220.0
V
V3 220.0
V
Vo 220.0
V
Powers V L-N V L-L
Figure 3-68 Instantaneous Menu
· Line-to-neutral V (L-N) voltage for each phase and their average · Line-to-
line V(L-L) voltage for each phase and their average · Phase currents (I) and
their sum · Neutral current (IN) · CosØ for each phase and CosØ of system ·
Power factor (PF) for each phase and power factor (PF) of system · Active
power (P) for each phase and their sum · Reactive power (Q) for each phase and
their sum · Apparent power (S) for each phase and their sum · Frequency (F)
for each phase · THDV values for each phase and their sum · THDI values for
each phase and their sum · Total powers
If “3phase 3 wire” is selected as connection type, “VL-N” title in
instantaneous menu will be replaced with “V”.
In Measure-Instantaneous-P(active power) page; if active power value(of any
phase) is positive (a “+” sign after the number), that phase consumes power,
if active power value(of any phase) is negative (a “-” sign after the number),
that phase generates power. The above phenomenon also applies for total P
(active power) value.
When Klea is mounted on a panel which consumes power, the values in
MeasureInstantaneous-P page should be positive(+). When Klea is mounted on a
panel which generates power, the values in Measure-Instantaneous-P page should
be negative(-). Otherwise, K-L leads of the current should be cross connected.
64
SECTION 3 MENUS
Measure->Instantaneous->P
P1 1100.0
W +
P2 1100.0
W +
P3 1100.0
W +
Pt 3300.0
W +
PF
P
Q
Meters->T1->Imp. active
Index Curr. hour Prev. hour Curr. day Prev. day Curr. month Prev. month
267500.1 0.5 0.6 21.3 22.6 598.4 439.5
kWh kWh kWh kWh kWh kWh kWh
Figure 3-69 Connecting the K-L ends of Current Correctly
3.2.2.2 Demand Menu
During demand period, Klea, calculates averages for current, active, reactive
and apparent powers for three phases. Maximum of these averages are stored as
the demand value with a corresponding time stamp.
Measure Meters Alarms Analysis
Instantaneous
0 . 0 DVe1mand
Phasor diagram
Signals
2 HVa2rmonics 2 0 . 0
V I1 V I2
5.0 A 5.0 A
V3 2 2 0 . 0 V I3
5.0 A
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Figure 3-70 Demand Menu
Example: The following graph shows the averages of current signals that are
calculated/measured during the 15 minutes (demand period=15) and demand value.
Amplitude
Waveform
15 minutes average value=3 amps
15 minutes average value=5 amps
15 minutes average value=4 amps
demand=3A
demand=5A
*demand period=15 minutes
demand=5A
Figure 3-71 Demand Example
65
Time (min)
SECTION 3 MENUS
3.2.2.2.1 Current Month Menu
This menu displays demand values of current, active, reactive and apparent
power of three phases and their totals for the current (present) month.
Measure Meters Alarms Analysis
Instantaneous Curr. month
0 . 0 DVe1mand
1 monVth aIg1o
Phasor diagram 2 months ago
Signals
3 months ago
2 2 0 . 0 HVa2rmonics
V I2
5.0 A 5.0 A
Measure Meters Alarms Analysis
Instantaneous Curr. month
0 . 0 DVe1mand
1 monVth aIg1o
Phasor diagram 2 months ago
Signals
3 months ago
2 2 0 . 0 HVa2rmonics
V I2
Current
5 . 0 Act. power A
Rea. power App. power
5.0 A
V3 2 2 0 . 0 V I3
5.0 A V3 220.0 V I3
5.0 A
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Figure 3-72 Current Month Menu
“Start of day” and “start of month” settings are adjusted in
“Settings->Setup->Energy” menu. “Start of day” and “start of month” are
important for “Curr. Month”, “1 month ago”, “2 months ago” and “3 months ago”
submenus.
Example: Assume that start of day is “8”, and start of month is “26”; When
time is 08.00 on 26th day of the month;
“Current month” values will be assigned as “1 month ago” values,
“1 month ago” values will be assigned as
“2 months ago” values,
“2 months ago” values will be assigned as
“3 months ago” values.
And new values will be saved in “current month” menu.
Settings->Setup ->Energy
T1_1 start time
8
T1_2 start time
16
T1_3 start time
0
Start of day
8
Start of month
26
T1 kWh
0.0
T1 kWh E
0.0
T1 kVArh I.
0.0
T1 kVArh E.
0.0
T1_1 kWh
0.0
T1_1 kWh E
0.0
T1_1 kVArh I.
0.0
hr hr hr hr
kWh kWh kVArh kVArh kWh kWh kVArh
Figure 3-73 Example of Current Month Menu
66
SECTION 3 MENUS
3.2.2.2.1.1 Current Menu
This menu shows demand values of currents of each phase and the demand value for the sum of phase currents. Date and time information for demand values can be seen on the screen.
Measure Meters Alarms Analysis
Instantaneous Curr. month
0 . 0 DVe1mand
1 monVth aIg1o
Phasor diagram 2 months ago
Signals
3 months ago
2 2 0 . 0 HVa2rmonics
V I2
Current
5 . 0 Act. power A
Rea. power App. power
5.0 A
V3 2 2 0 . 0 V I3
5.0 A
Measure->Demand->Curr. month->Current
Phase 1 Phase 2 Phase 3 Total
5.0
A
02:44:59 – 10/10/12
5.1
A
13:29:59 – 11/10/12
4.9
A
14:29:59 – 09/10/12
15.6
A
09:14:59 – 12/10/12
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Figure 3-74 Current Menu
Example: Assume that demand period is entered as 15 minutes. Also assume that
the current (present) month’s `current demand’ and date are: Phase1 5.0 A
02:44:59 – 10/10/12. This means:
On October 10, 2012, demand value of phase1 current in the time interval 02:29:59 02:44:59, is 5.0 A.
In order for KLEA to keep demand values for “1 month ago”, “2 months ago” and
“3 months ago”; demand period should be set as 1, 2, 3, 4, 5, 6, 10, 12, 15,
20, 30 or 60 min (common divisors of 60). Otherwise, “1 month ago”, “2 months
ago” and “3 months ago” demand values will not be stored.
Example: When the system clock is 15:07:00, assume that demand period is
adjusted as 15 minutes. Sequentially, demand periods will be as follows:
05:07:00 – 15:14:59 = The 1st demand period 15:14:59 – 15:29:59 = The 2nd
demand period 15:29:59 – 15:44:59 = The 3rd demand period 15:44:59 – 15:59:59
= The 4th demand period 15:59:59 – 16:14:59 = The 5th demand period
67
SECTION 3 MENUS
3.2.2.2.1.2 Active power menu
The demand values for active power are as explained in the “Demand->Current
Month>Current” submenu.
3.2.2.2.1.3 Reactive power menu
The demand values on the reactive power are as explained in the
“Demand->Current Month->Current” submenu.
3.2.2.2.1.4 Apparent power menu
The demand values on the apparent power are as explained in the
“Demand->Current Month->Current” submenu.
3.2.2.2.2 1 month Ago Menu
The demand values on the 1 month ago menu are as explained in the
“Demand->Current Month” submenu.
3.2.2.2.3 2 Months Ago Menu
The demand values on the 2 months ago menu are as explained in the
“Demand>Current Month” submenu.
3.2.2.2.4 3 Months Ago Menu
The demand values on the 3 months ago menu are as explained in the
“Demand>Current Month” submenu.
68
SECTION 3 MENUS
3.2.2.3 Phasor Diagram Menu
In phasor diagram menu page, at the right of the phasor diagram, following
information is listed: · phase voltages (V1, V2, V3) · phase currents (I1, I2,
I3) · V1-V2, V2-V3 and V3-V1 phase difference angles · V1-I1, V2-I2 and V3-I3
phase difference angles
Within the phasor diagram, currents are drawn with gray lines, and voltages
are drawn with black lines. Within the phasor diagram, same size circles have
been added to the ends of lines belonging to the same phase. Thus, it will be
easy to follow currents and voltages of a phase.
Measure Meters Alarms Analysis
Instantaneous
1 5 0 . 0 DVe1mand
Phasor diagram
Signals
1 HVa2rmonics 5 0 . 0
V I1 V I2
3.0 A 3.0 A
V3 1 5 0 . 0 V I3
3.0 A
1 23 V
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Measure->Phasor diagram
V1
150.1 V
V2
150.2 V
V3
150.0 V
I1
3.0
A
I2
3.0
A
I3
3.0
A
V1-V2 120.9
V2-V3 119.6
V3-V1 119.5
V1-I1 29.4
V2-I2 29.3
V3-I3 29.7
3.2.2.4 Signals Menu
Figure 3-75 Phasor Diagram Menu
In this menu, current and voltage waveforms are shown. At the right hand side
of the waveforms, following information is listed:
· Voltage and current values of phases · Instantaneous frequency value · Phase
difference between current and voltage
Current signal is in gray, and voltage is in black color. Operator can scroll
inside signals menu by pressing left and right keys.
Measure Meters Alarms Analysis
Instantaneous
1 5 0 . 0 DVe1mand
Phasor diagram
Signals
1 HVa2rmonics 5 0 . 0
V I1 V I2
3.0 A 3.0 A
Measure->Signals->V2-I2
V3 1 5 0 . 0 V I3
3.0 A
1 23 V
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V1-I1 V2-I2
V3-I3
150.0V 3.0A
50.0Hz 30.0°
Figure 3-76 Signals Menu
69
SECTION 3 MENUS
3.2.2.5 Harmonics Menu
KLEA measures/calculates current and voltage harmonics up to 51st harmonic. Current and voltage harmonics can be monitored in table and in graph format.
Measure Meters Alarms Analysis
Instantaneous
2 2 0 . 0 DVe1mand
Phasor diagram
Signals
2 HVa2rmonics 2 0 . 0
V I1 V I2
5.0 A 5.0 A
V3 2 2 0 . 0 V I3
5.0 A
1 23 V
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3.2.2.5.1 Table Menu
Figure 3-77 Harmonics Menu
Current and voltage harmonics of each phase are displayed in a table format (See Figure 3-78). Operator can scroll inside table menu by pressing right and left keys. There are 6 table pages: V1, V2, V3, I1, I2, I3.
Measure->Harmonics->V1 %
1
2
3
4
5
1-5
99.01 0.00 1.02 0.00 0.05
6-10
0.00 2.10 0.00 3.30 0.00
11-15 5.70 0.00 0.75 0.00 0.00
16-20 0.00 0.00 0.00 0.00 0.00
21-25 0.00 0.00 0.00 0.00 0.00
26-30 0.00 0.00 0.00 0.00 0.00
31-35 0.00 0.00 0.00 0.00 0.00
36-40 0.00 0.00 0.00 0.00 0.00
41-45 0.00 0.00 0.00 0.00 0.00
46-50 0.00 0.00 0.00 0.00 0.00
I3 %
V1 % V2 %
Figure 3-78 Harmonics in Table Format
70
SECTION 3 MENUS
3.2.2.5.2 Graph Menu
pages: V1, V2, V3, I1, I2, I3.
Measure->Harmonics->V1 %
20 % 15 % 10 %
5 %
1
11
21
31
41
51
I3 %
V1 % V2 %
3.2.3 Meters Menu
· · · ·
from “0.0”.
3.2.3.1
energy values.
Meters Alarms Analysis
T1
TV11 rate1 T1 rate2
0.0
T1 rate3
0 . 0 TDV2i2gital input
Others
V3 220.0
V I1 V I2 V I3
5.0 A 5.0 A 5.0 A
Meters Alarms Analysis
T1
Imp. active
TV11 rate1 T1 rate2
0 . 0Exp. aVctivIe1 Imp. reactive
T1 rate3
Exp. reactive
0 . 0 TDV2i2gital input
V I2
Others
V3 2 2 0 . 0 V I3
5.0 A 5.0 A 5.0 A
1 23 V
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1 23 V
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71
SECTION 3 MENUS
3.2.3.1.1 Imp. Active Menu (Import Active Energy Menu)
Import active energy values are displayed as seen in the following figure:
Meters->T1->Imp. active
Index Curr. hour Prev. hour Curr. day Prev. day Curr. month Prev. month
267500.1 0.5 0.6 21.3 22.6 598.4 439.5
kWh kWh kWh kWh kWh kWh kWh
Figure 3-81 Imp. Active Energy Page
Index, active energy consumed up to present time. Current hour, active energy
value consumed from the beginning of current hour up to present time. Previous
hour, is the active energy value consumed during the previous hour.
Previous hour
Current hour
Current time (the moment when operator reads the measurement)
13:00 Starting time of previous hour
14:00 Starting time of
current hour
14:26
Figure 3-82 Example for Start of Hour
Current day is the active energy value consumed from `start of day’ up to present time. Previous day, is the active energy value consumed during the previous day.
Previous day
Current day
Current time (the moment when operator reads the measurement)
June 18 08:00 *Start of day:8
June 19 08:00
June 19 16:47
Figure 3-83 Example for Start of Day
72
SECTION 3 MENUS
Current month is the active energy value consumed from `start of month’ up to present time. Previous month is the active energy value consumed during the previous month.
Previous month
Current month
Current time (the moment when operator reads the measurement)
April 3 07:00 Start of day:7 Start of month: 3
May 3 07:00
May 17 17:47
Figure 3-84 Example for Start of Month
‘Start of day’ and start of month’ parameters can be adjusted in “Settings->Setup>Energy” menu. Example: Assume thatstart of day’ is adjusted as “0”. In this case, when the
system clock is 00:00, value in the “Current day” will be assigned to
“previous day”. “Current day” resets and starts to count from zero.
Example: Assume that start of month’ is adjusted as “1” andstart of day’ is
adjusted as “0”. In this case, when system time is 00:00 and day of month is
1, “Current month” will be assigned to “previous month”. “Current month”
resets and starts to count from zero.
3.2.3.1.2 Exp. Active Menu (The Consumed Active Energy Menu)
“Exp. active” menu consists of the same items as “Imp. active” menu. Please
refer to 3.2.3.1.1 (Meters->Tariff 1->Imp. active) energy menu for details.
3.2.3.1.3 Imp. reactive Menu (Import Reactive Energy Menu)
“Imp. reactive” menu consists of the same items as “Imp. active” menu. Please
refer to 3.2.3.1.1 (Meters->Tariff 1->Imp. active) energy menu for details.
3.2.3.1.4 Exp. reactive Menu (Export Reactive Energy Menu)
“Exp. reactive” menu consists of the same items as “Imp. active” menu. Please refer to 3.2.3.1.1 (Meters->Tariff 1->Imp. active) energy menu for details.
73
SECTION 3 MENUS
3.2.3.2 T1 Rate1 Menu
Refer to 3.2.1.1.3.1 and 3.2.1.1.3.2
Meters Alarms Analysis
T1 TV11 rate1 T1 rate2
Imp. active
0 . 0Exp. aVctivIe1 Imp. reactive
T1 rate3
Exp. reactive
0 . 0 TDV2i2gital input
V I2
Others
V3 2 2 0 . 0 V I3
5.0 A 5.0 A 5.0 A
1 23 V
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3.2.3.3 T1 Rate2 Menu
T1 Rate1 Menu
Refer to 3.2.1.1.3.2 and 3.2.1.1.3.3
Meters Alarms Analysis
T1 TV11 rate1 T1 rate2 T1 rate3 TDV2i2gital input Others
Imp. active
0 . 0Exp. aVctivIe1 Imp. reactive Exp. reactive
0.0 V I2
V3 2 2 0 . 0 V I3
5.0 A 5.0 A 5.0 A
1 23 V
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T1 Rate2 Menu
74
SECTION 3 MENUS
3.2.3.4 T1 Rate3 Menu
Refer to 3.2.1.1.3.3 and 3.2.1.1.3.1
3.2.3.5
Meters Alarms Analysis
T1 TV11 rate1 T1 rate2
Imp. active
0 . 0Exp. aVctivIe1 Imp. reactive
T1 rate3
Exp. reactive
0 . 0 TDV2i2gital input
V I2
Others
V3 2 2 0 . 0 V I3
5.0 A 5.0 A 5.0 A
1 23 V
I
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T1 Rate3 Menu
energy values. Refer to “3.2.1.1.4.1 Mode Sett~ng
Meters Alarms Analysis
T1 TV11 rate1 T1 rate2 T1 rate3 TDV2i2gital input Others
Imp. active
0 . 0Exp. aVctivIe1 Imp. reactive Exp. reactive
0.0 V I2
V3 2 2 0 . 0 V I3
5.0 A 5.0 A 5.0 A
1 23 V
I
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75
SECTION 3 MENUS
(
).
3.2.3.6 D~g~tal Input Menu
Meters->Digital input
Counter 1
4
Counter 2
2
Counter 3
0
Counter 4
0
Counter 5
0
Counter 6
0
Counter 7
0
Refer to 3.2.1.1.4.1.2 Delay), Refer to 3.2.1.1.4.1.2 Delay),
3.2.3.7 Others Menu
In th s menu, cons st of on hour counter, run hour counter and power nterrupt
on counter. Only run hour counter can be deleted by users.
76
SECTION 3 MENUS
3.2.4 Alarms Menu
In this menu, alarms can be monitored. Alarms menu consists of Phase1′, Phase2′, Phase3′ andOther’ submenus.
In Klea MODBUS table, 50 alarm statuses can be saved (Refer to Table 4.3). If
the number of alarm statuses exceeds 50; 51st alarm is overwritten on the
first alarm.
An alarm status consists of the below information:
Alarm Time Stamp: Alarm time, 32 bit integer
Alarm Definition: Alarm flag bit number. Refer to the example below.
Alarm State: Alarm ON or alarm OFF state. Alarm ON and alarm OFF conditions
are both considered as records. As a result, both conditions are saved in
MODBUS table as different alarm statuses. 1 -> Alarm ON 0 -> Alarm OFF
Alarm Value: Value of the related alarm parameter
Example: Assume that, 100 VAC is assigned as low limit for V(L-N) (for phase1,
phase2 and phase3 V L-N voltages) and again assume that phase3 voltage falls
below 100VAC in the system. In such a case,
Alarm Definition; is the bitwise index number inside the alarm flags (4.5.1.1
Alarm flags) variable. That is, for the above situation, “alarm definition
value” will be 3. Shortly, alarm definition value can be used as an index in
alarm flag variable to reach the explanation for that alarm. Besides, this
way, operator will have the opportunity to match the alarm with the alarm
flag.
Alarms Analysis
Phase1
PVh1ase2 Phase3
0.0
Other
V2 220.0
V I1 V I2
V3 2 2 0 . 0 V I3
5.0 A 5.0 A 5.0 A
1 23 V
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Figure 3-90 Alarms Menu
77
SECTION 3 MENUS
3.2.4.1 Phase1 Menu
In Phase1 menu, phase1 alarm statuses are displayed.
“Normal” No alarm “Alarm” Alarm
Alarms->Phase1
V
I P Q S CosØ PF V harmonics THDV I harmonics THDI F
Alarm
Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal Normal
Figure 3-91 Phase1 Menu
In Phase1 menu, following alarm statuses are monitored. · V (phase-neutral
voltage) · I (current) · P (active power) · Q (reactive power) · S (apparent
power) · cos Ø · PF (power factor) · V harmonics (any of 3., 5., – 21.
harmonic alarm statuses ORed) · THDV (total harmonic distortion in voltage) ·
I harmonics (any of 3., 5., – 21. harmonic alarm statuses ORed) · THDI (total
harmonic distortion in current)
3.2.4.2 Phase2 Menu
“Phase2” menu consists of the same items as “Phase1” menu. Please refer to
3.2.4.1 Phase1 menu for details.
3.2.4.3 Phase3 Menu
“Phase3” menu consists of the same items as “Phase1” menu. Please refer to
3.2.4.1 Phase1 menu for details.
78
SECTION 3 MENUS
3.2.4.4 Other Menu
In “Other” menu, explanations are the same as in Phase1 menu.
Alarms->Other
VLL12 VLL23 VLL31 IN Temperature Battery
Normal
Normal Normal Alarm Normal Normal
Figure 3-92 Other Menu
In “Other” menu, following alarm statuses are monitored: · VLL12
(phase1-phase2 voltage) · VLL23 (phase2-phase3 voltage) · VLL31 (phase3-phase1
voltage) · IN (neutral current) · Temperature · Battery
When the battery voltage falls below 1.9 V value, Klea issues Battery alarm.
When Klea issues battery alarm, contact your local authorized dealer (or the
nearest authorized dealer).
3.2.5 Analysis Menu
It consists of submenus shown in Figure 3-93. Analysis menu parameters can
also be reached from MODBUS (Refer to 4.5.3 Archive Records).
Analysis
Minimum
2 2 0 . 0 MV1aximum
Average
V I1
Energy
V2 2 2 0 . 0 V I2
V3 2 2 0 . 0 V I3
5.0 A 5.0 A 5.0 A
1 23 V
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Figure 3-93 Analysis Menu
Analysis menu parameters are not stored in permanent memory. As a result, all
of analysis menu parameters will be cleared when Klea is turned-off.
79
SECTION 3 MENUS
3.2.5.1 Minimum Menu
It consists of hourly, daily and monthly submenus.
Analysis
Minimum
Hourly
2 2 0 . 0 MV1aximum
Average
Daily V I1 Monthly
Energy
V2 2 2 0 . 0 V I2
V3 2 2 0 . 0 V I3
5.0 A 5.0 A 5.0 A
1 23 V
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3.2.5.1.1 Hourly Menu
Figure 3-94 Minimum Menu
This menu displays the minimum “instantaneous” values measured/calculated from the beginning of current hour up to present time.
Analysis
Minimum
Hourly
2 2 0 . 0 MV1aximum
Average
Daily V I1 Monthly
Energy
V2 2 2 0 . 0 V I2
V3 2 2 0 . 0 V I3
Phase1
5 . 0 Phase2
A
Phase3
Other
5.0 A
5.0 A
1 23 V
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3.2.5.1.1.1 Phase1 Menu
Figure 3-95 Hourly Menu
Voltage(V), current(I), active power(P), reactive power(Q), apparent power(S), cos Ø, power factor(PF), and frequency(F) values are displayed.
3.2.5.1.1.2 Phase2 Menu
Voltage(V), current(I), active power(P), reactive power(Q), apparent power(S),
cos Ø, power factor(PF), and frequency(F) values are displayed.
3.2.5.1.1.3 Phase3 Menu
Voltage(V), current(I), active power(P), reactive power(Q), apparent power(S),
cos Ø, power factor(PF), and frequency(F) values are displayed.
80
SECTION 3 MENUS
3.2.5.1.1.4 Other
VLL12(phase1-phase2 voltage), VLL23(phase2- phase3 voltage), VLL31(phase3-
phase1 voltage).
3.2.5.1.2 Daily Menu
This menu displays the minimum instantaneous values measured/calculated from
start of day (Refer to 3.2.1.1.3.4) up to present time. Its submenus are the
same as “Hourly menu”.
3.2.5.1.3 Monthly Menu
This menu displays the minimum instantaneous values measured/calculated from
start of month (Refer to 3.2.1.1.3.5) and start of day (Refer to 3.2.1.1.3.4)
up to present time. Its submenus are the same as “Hourly menu”.
3.2.5.2 Maximum Menu
Submenus and explanations of “Maximum” menu are the same as “Minimum” menu.
The values measured in the “Maximum” menu are also “instantaneous” maximum
values.
3.2.5.3 Average Menu
Submenus and explanations of “Maximum” menu are the same as “Minimum” menu. In
“Average” menu, hourly, daily and monthly average values are displayed.
3.2.5.4 Energy Menu
In this menu, daily and monthly meter values, which are “measured when Tariff
1 is active”, are displayed.
Analysis
Minimum
Hourly
2 2 0 . 0 MV1aximum
Average
Daily V I1 Monthly
Energy
V2 2 2 0 . 0 V I2
V3 2 2 0 . 0 V I3
5.0 A 5.0 A 5.0 A
1 23 V
I
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Figure 3-96 Energy Menu
Energy Menu is active only when Tariff 1 is active. 81
SECTION 3 MENUS
3.2.5.4.1 Hourly Menu
This menu consists of index values measured from the beginning of current hour
up to present time. kWh (import active), kWh E.(export active), kVArh
I.(import reactive), kVArh E.(export reactive) index values can be monitored.
3.2.5.4.2 Daily Menu
This menu consists of index values measured from start of day’ (Refer to 3.2.1.1.3.4) up to present time. kWh (import active), kWh E.(export active), kVArh I.(import reactive), kVArh E.(export reactive) index values can be monitored. 3.2.5.4.3 Monthly Menu This menu consists of index values measured fromstart of month (Refer to
3.2.1.1.3.5) and `start of day’ (Refer to 3.2.1.1.3.4) up to present time. kWh
(import active), kWh E.(export active), kVArh I.(import reactive), kVArh
E.(export reactive) index values can be monitored.
82
Energy Analyzer
SECTION 4 MODBUS PROTOCOL
83
SECTION 4 MODBUS PROTOCOL
SECTION 4 MODBUS PROTOCOL
4.1 RS485 Wiring Diagram
RS485 WIRING DIAGRAM
120~
120~
Terminating resistor
Any device
Terminating resistor
4.2 Computer Connection
Figure 4-1 RS485 Wiring Diagram
KLEA can communicate with PCs via USB-RS85 or RS232-RS485 converters.
PC
USB-RS485 or RS232-RS485
converter
Figure 4-2 Connection of KLEA to a PC
84
SECTION 4 MODBUS PROTOCOL
4.3 Message Format and Data Types of MODBUS-RTU Protocol
KLEA implements modbus RTU protocol. Modbus RTU message format is as follows.
Start 3.5 byte
Table 4-1 Message Format
Address
Function
1 byte
1 byte
Data
CRC
0-252 byte 2 byte
End 3.5 byte
There should be a time gap, which is at least 3.5 characters wide, between RTU messages.
For instance, when client device requests any information, server device should reply after at least a 3.5 character wide time gap. Following the response of the server, client device should wait 3.5 characters long period, before requesting information again.
Data types used in KLEA are as follows.
Table 4-2 int (32 bit) data type
b31 (Bit 31)
———————————– b0 (Bit 0)
MSB (Most Significant Bit) ———————————— LSB (Least Significant Bit)
int: 32-bit integer value. Byte order starts from the lowest byte address as b0, b1, b2 and so on.
flo t: It is a 32-bit floating-point number in IEEE 754 standard.
string: Character array in ASCII standard. It is only used for Klea device name and Klea configuration name variables.
4.4 Implemented functions for MODBUS-RTU Protocol
Table 4-3 Implemented functions for MODBUS RTU Protocol
Function Name Read Holding Registers Write Single Register Write Multiple Registers Read file record
Function Code 03H (decimal value 3) 06H (decimal value 6) 10H (decimal value 16) 14H (decimal value 20)
85
SECTION 4 MODBUS PROTOCOL
4.5 Data and Setting Parameters for KLEA 4.5.1 Measured and Calculated Data
Calculated and measured data are “read-only” values.
Operator/programmer can reach all measured and calculated data via MODBUS RTU
protocol. Starting address for measured and calculated data is 0.
Example:
Three phase average voltage is read via the 0th and 1th registers (16 bits + 16 bits = 32 bit).
PC (or PLC) Request
Slave ID
01h
Function code
03h
Register address high 00h
Register address low 00h
Number of registers high 00h
Number of registers low 02h
CRC high
C4h
CRC low
0Bh
KLEA Response
Slave ID
01h
Function code
03h
Byte counts
04h
Register value – high (0) 43h
Register value – low (0)
5DH
Register value – high (1) 36H
Register value – low (1)
E0h
CRC high
68h
CRC low
4Dh
The “Byte counts” information of KLEA response is two times “Number of registers” value of “PC request” (1 register = 2 bytes).
Register value high(0) and low(0) together with register value high(1) and low(1) constitute a 32-bit value. This value should be converted (typecasted) to a float value. The float value of the mentioned 32-bit variable is 221.2143555.
86
SECTION 4 MODBUS PROTOCOL
Address Parameter
0
V ave.
2
I tot.
4
P tot.
6
Q tot.
8
S tot.
10 CosØ ave.
12 PF ave.
14 VLL1
16 VLL2
18 VLL3
20 VLL ave.
22 IN
24 THDV tot.
26 THDI tot.
28 L1 V 30 L1 I 32 L1 P 34 L1 Q 36 L1 S 38 L1 CosØ 40 L1 PF 42 L1 F 44 L1 THDV 46 L1 THDI 48 L1 V Harmonics1 50 L1 V Harmonics3 52 L1 V Harmonics5 54 L1 V Harmonics7 56 L1 V Harmonics9 58 L1 V Harmonics11 60 L1 V Harmonics13 62 L1 V Harmonics15 64 L1 V Harmonics17 66 L1 V Harmonics19 68 L1 V Harmonics21 70 L1 V Harmonics23 72 L1 V Harmonics25 74 L1 V Harmonics27 76 L1 V Harmonics29 78 L1 V Harmonics31 80 L1 V Harmonics33 82 L1 V Harmonics35
Table 4-4 Read-only Data
Description
R/W Unit
Average voltage of three phases
RO V
Total current of three phases
RO A
Total active power of three phases
RO W
Total reactive power of three phases
RO VAr
Total apparent power of three phases
RO VA
Average CosØ of three phases
RO –
Average PF of three phases
RO –
Voltage V1-2
RO V
Voltage V2-3
RO V
Voltage V3-1
RO V
Average of line to line voltage of three phases RO V
Neutral current
RO A
Total har. distortion of voltage for three phases RO %
Total har. distortion of voltage for three phases RO %
PHASE 1
Phase1 voltage
RO V
Phase1 current
RO A
Phase1 active power
RO W
Phase1 reactive power
RO VAr
Phase1 apparent power
RO VA
Phase1 CosØ
RO –
Phase1 power factor
RO –
Phase1 frequency
RO Hz
Phase1 total har. distortion of voltage
RO %
Phase1 total har. distortion of current
RO %
Phase1 voltage first harmonic
RO %
Phase1 voltage third harmonic
RO %
Phase1 voltage 5th harmonic
RO %
Phase1 voltage 7th harmonic
RO %
Phase1 voltage 9th harmonic
RO %
Phase1 voltage 11th harmonic
RO %
Phase1 voltage 13th harmonic
RO %
Phase1 voltage 15th harmonic
RO %
Phase1 voltage 17th harmonic
RO %
Phase1 voltage 19th harmonic
RO %
Phase1 voltage 21st harmonic
RO %
Phase1 voltage 23rd harmonic
RO %
Phase1 voltage 25th harmonic
RO %
Phase1 voltage 27th harmonic
RO %
Phase1 voltage 29th harmonic
RO %
Phase1 voltage 31st harmonic
RO %
Phase1 voltage 33rd harmonic
RO %
Phase1 voltage 35th harmonic
RO %
Data Type 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32
bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32
bit float 32 bit float 32 bit float
32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float
32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float
32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float
32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float
32 bit float 32 bit float 32 bit float 32 bit float
87
SECTION 4 MODBUS PROTOCOL
Address Parameter 84 L1 V Harmonics37 86 L1 V Harmonics39 88 L1 V Harmonics41
90 L1 V Harmonics43 92 L1 V Harmonics45 94 L1 V Harmonics47 96 L1 V
Harmonics49 98 L1 V Harmonics51 100 L1 I Harmonics1 102 L1 I Harmonics3 104 L1
I Harmonics5 106 L1 I Harmonics7 108 L1 I Harmonics9 110 L1 I Harmonics11 112
L1 I Harmonics13 114 L1 I Harmonics15 116 L1 I Harmonics17 118 L1 I
Harmonics19 120 L1 I Harmonics21 122 L1 I Harmonics23 124 L1 I Harmonics25 126
L1 I Harmonics27 128 L1 I Harmonics29 130 L1 I Harmonics31 132 L1 I
Harmonics33 134 L1 I Harmonics35 136 L1 I Harmonics37 138 L1 I Harmonics39 140
L1 I Harmonics41 142 L1 I Harmonics43 144 L1 I Harmonics45 146 L1 I
Harmonics47 148 L1 I Harmonics49 150 L1 I Harmonics51
152 L2 V 154 L2 I 156 L2 P 158 L2 Q 160 L2 S 162 L2 CosØ 164 L2 PF 166 L2 F
168 L2 THDV
Description Phase1 voltage 37th harmonic Phase1 voltage 39th harmonic Phase1
voltage 41st harmonic Phase1 voltage 43rd harmonic Phase1 voltage 45th
harmonic Phase1 voltage 47th harmonic Phase1 voltage 49th harmonic Phase1
voltage 51st harmonic Phase1 current first harmonic Phase1 current third
harmonic Phase1 current 5th harmonic Phase1 current 7th harmonic Phase1
current 9th harmonic Phase1 current 11th harmonic Phase1 current 13th harmonic
Phase1 current 15th harmonic Phase1 current 17th harmonic Phase1 current 19th
harmonic Phase1 current 21st harmonic Phase1 current 23rd harmonic Phase1
current 25th harmonic Phase1 current 27th harmonic Phase1 current 29th
harmonic Phase1 current 31st harmonic Phase1 current 33rd harmonic Phase1
current 35th harmonic Phase1 current 37th harmonic Phase1 current 39th
harmonic Phase1 current 41st harmonic Phase1 current 43rd harmonic Phase1
current 45th harmonic Phase1 current 47th harmonic Phase1 current 49th
harmonic Phase1 current 51st harmonic
PHASE 2 Phase2 voltage Phase2 current Phase2 active power Phase2 reactive
power Phase2 apparent power Phase2 CosØ Phase2 power factor Phase2 frequency
Phase2 total har. distortion of voltage
R/W Unit RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO % RO %
Data Type 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float
RO V RO A RO W RO VAr RO VA RO RO RO Hz RO %
32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float
88
SECTION 4 MODBUS PROTOCOL
Address Parameter 170 L2 THDI 172 L2 V Harmonics1 174 L2 V Harmonics3 176 L2 V Harmonics5 178 L2 V Harmonics7 180 L2 V Harmonics9 182 L2 V Harmonics11 184 L2 V Harmonics13 186 L2 V Harmonics15 188 L2 V Harmonics17 190 L2 V Harmonics19 192 L2 V Harmonics21 194 L2 V Harmonics23 196 L2 V Harmonics25 198 L2 V Harmonics27 200 L2 V Harmonics29 202 L2 V Harmonics31 204 L2 V Harmonics33 206 L2 V Harmonics35 208 L2 V Harmonics37 210 L2 V Harmonics39 212 L2 V Harmonics41 214 L2 V Harmonics43 216 L2 V Harmonics45 218 L2 V Harmonics47 220 L2 V Harmonics49 222 L2 V Harmonics51 224 L2 I Harmonics1 226 L2 I Harmonics3 228 L2 I Harmonics5 230 L2 I Harmonics7 232 L2 I Harmonics9 234 L2 I Harmonics11 236 L2 I Harmonics13 238 L2 I Harmonics15 240 L2 I Harmonics17 242 L2 I Harmonics19 244 L2 I Harmonics21 246 L2 I Harmonics23 248 L2 I Harmonics25 250 L2 I Harmonics27 252 L2 I Harmonics29 254 L2 I Harmonics31 256 L2 I Harmonics33
Description Phase2 total har. distortion of current Phase2 voltage first harmonic Phase2 voltage
References
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