manual - 上海肯特仪表股份有限公司this manual describes the functions, installation and...
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2
Notes
Thank you for purchasing the Intelligent Totalizing Recorder. This manual describes the functions, installation and wiring procedures, operating procedures, and handling precautions of the instrument. To ensure correct use, please read this manual thoroughly and have a clear understanding of the instrument before operation.
• This manual should be read by the end user. • We warrant goods of its manufactures being free of defective materials and faulty
workmanship. If warranted goods are returned to us or its representatives during the period of coverage of one year, we will repair or replace without charge any defective items. We guarantee all the goods with life maintenance.
• Every effort has been made in the preparation of this manual to ensure the accuracy of
its contents. However, should you have any questions or find any errors, please contact your nearest customer service.
• Specifications or other contents of this manual are subject to change without prior notice
for improvement. When there is a possibility that the foregoing change may result in serious accident or injury, we will give notice in advance.
• Do not modify this. We assume no liability for any loss or damage, direct or indirect,
caused by the user. • Copying or reproducing all or any part of the contents of this manual without our
permission is strictly prohibited.
3
Symbol Definitions
Danger
This symbol indicates a hazardous situation, which, if not avoided, could result in death, serious injury or property damage.
Caution This symbol indicates a potentially hazardous situation, which, if not avoided, might result in damage to the instrument, process or surroundings.
Attention This symbol indicates a situation, which will be very helpful to operate the instrument.
Warn This symbol indicates a hazardous situation, which, could result in vital problem if execution error.
Danger
• Do not operate the instrument in the presence of flammable liquids or vapors, since operation in such environments constitutes a safety hazard.
• When there is a possibility that the abnormality of the instrument may cause a major accident or damage to other equipments, externally install an adequate emergency stop circuit or protection circuit to prevent accidents.
• Ensure that the source voltage matches the voltage of the power supply before turning on
the power. • Make sure to connect the protective grounding to prevent electric shock,
incorrect operation, abnormal display and large error of measurement. • Make lightning protection facilities: equipotential earth, shielding, reasonable wiring
through common grounding network , using SPD if needed, etc. • The cover should be removed by the qualified personnel only. Opening the cover is
dangerous, because some areas inside the instrument have high voltages.
4
Symbol Definitions • Never turn on the power before all the mounting and wiring work are finished to prevent
electric shock, malfunction or failure of the instrument. • Never disassemble, remodel, modify, or repair this instrument. Otherwise malfunction,
electric shock, or failure may result. • Turn off the power before checking . Otherwise electric shock, malfunction or failure may
result. • Check periodically that the terminal screws and mounting screws are securely fastened.
Please fasten them before using. • Never disassemble, remodel, modify, or repair this instrument. Otherwise malfunction,
electric shock, or failure may result. • When cleaning the main unit, wipe with a dry cloth, never use alcohol, gasoline or other
organic solvents to prevent the liquid touching instrument. Turn off the power if it is immersed in water. Otherwise electric leak, electric shock, or fire may result.
• Check the state of protective grounding periodically. Do not operate if you think it is not
well. • Do not block the ventilation holes. Otherwise a failure, malfunction, shortened service life,
or fire may result. • Operating the instrument in a manner not described in this manual may damage its
protective structure.
Caution • Never use the instrument if it is found damaged or deformed when unpacked. • Never use interphone within 0.5m from instrument. • Turn off the power when connecting instrument with PC. • Operate the instrument paying attention to prevent foreign matters such as scraps, electric
wire chips, and iron powder from entering the instrument, or abnormal condition. • Should use three wires which of the resistance are same and less than 10Ω when
connecting hot resistance, or wrong display and abnormal condition. • When modifying the settings during the operation or forcibly outputting, starting or
stopping the instrument, be sure to check that safety is ensured. Improper operation may result in damage or failure of the instrument.
5
Symbol Definitions • Make sure to perform periodic maintenance for the safe and continuous use of this
instrument, because consumable parts or those which deteriorate with time are mounted in this instrument.
• Dispose the instrument as an industrial waste.
6
Chapter Review
• Chapter1 Overview Functions of the instrument in brief; The general parameters and input/output performance.
• Chapter2 Installation and Wiring
The Installation and wiring for the instruments.
• Chapter3 Key & Menu Describes the parts on the panel of instruments, the basic key operations, and how to login/logout.
• Chapter4 Basic Configuration The general setup such as system setup and configuration management to prepare for the further setup.
• Chapter5 Modes Settlement Settings and displays related to the Modes.
• Chapter6 Parameter Settlement Settings and displays related to the parameters
• Chapter7 Trade Settlement Settings related to the trade settlement.
• Chapter8 Other Function Settings and operations related to the alarm, analog output, communication, display and USB interface.
• Chapter9 History Data Settings and operations related to the record function of history data.
• Chapter10 Message Logs Message logs including alarm log, operation log, totalizer log and poweroff log of the instrument.
• Chapter11 Troubleshooting & Maintenance Troubleshooting and maintenance.
7
Contents
Chapter1 Overview 8 1.1 Main Performance 9 1.2 Input Signal 9 1.3 Output Signal 10 1.4 Selection Table 10 1.5 Others 11 Chapter2 Installation and Wiring 12
2.1 Unpack 12 2.2 Installation 12 2.2.1 Installation Location 12 2.2.2 Installation Dimension 13 2.2.3 Installation Method 14
2.3 Wiring 15 2.3.1 Arrangement of the Terminals 15 2.3.2 Power Supply Connection 16 2.3.3 Signal Connection 17 2.3.4 Communication Connection 18
Chapter3 Key & Menu 21 3.1 Parts on panel 21 3.2 Key Operation 21 3.2.1 Switching Monitoring Displays 21 3.2.2 How to Access Setup Menu 22 3.2.3 Parameter Type and Setup Method 23
Chapter4 Basic Configuration 25 4.1 System Setup 25 4.2 Reset Factory 25 4.3 Apply the Settings 26 4.4 Shortcut Menu Operation 26
Chapter5 Modes Setup 27 5.1 Flow model 27
5.5.1 Flow Model Paremeter Introduction 27 5.2 Density Compensation 28 5.2.1 Density Compensation Paremeter Introduction 29 5.3 Channel Setup 31 5.3.1 Channel Setup Paremeter Introduction 31
5.4 Enthalpy Setup 33 5.4.1 Enthalpy Setup Paremeter Introduction 33 5.4.2 Heat Flow Calculation 34 5.5 Related Monitoring Displays 34 5.5.1 Digital Display 34
5.5.2 Trend Display 35 Chapter6 Parameters Setup 36
8
Contents
6.1 Parameters Setup Parameter Introduction 36 Chapter7 Trade Settlement 38
7.1 Stop Steam Conditions 39 7.2 Related Displays 39
Chapter8 Other Functions 40 8.1 Alarm Setup 40
8.2 Output Setup 41 8.3 Communication Setup 42 8.4 Display Setup 42 8.5 USB Disk Operation 43 8.5.1 Format USB Disk 43 8.5.2 Save Logs 44 8.5.3 Save History Data 44 8.5.4 Save Settings 47 8.5.5 Save Monitoring Display 47
Chapter9 History Data 48 9.1 Related Monitoring Displays 48
Chapter10 Message Logs 49 10.1 Operation Log 49
10.2 Totalizer Log 49 10.3 Poweroff Log 50 10.4 Poweroff Totalize Time 50 10.5 Alarm Log 50 10.6 Logs Clearing 51
Chapter11 Troubleshooting & Maintenance 52 11.1 Periodic Inspection 52 11.2 Troubleshooting Flow Chart 52 11.2.1 When Nothing Operates (Nothing is displayed) 52 11.2.2 When Error Signal Data Displays 53 11.2.3 When Connection Link is Faulty 53
9
Chapter 1 Overview
Figure 1-1
Introduction
Intelligent Totalizing Recorder offers 3 analog inputs for flow, temperature and pressure
measurement, 2 alarm outputs, 1 analog output, and 2 transmitter power supply
channels. Meanwhile, it provides the RS-232C/RS-485 communication interface and
USB interface to be connected with computer.
With display, alarm, compensation and other functions, the instrument can be acquire,
store data from kinds of industrial or civil process.
It can be used for trade settlement in Heat Supply or Gas Supply, also for plant
measuring control in kinds of industry such as Metallurgy, Petroleum, Chemical Industry,
Building Materials, Papermaking, Power Industry, Food Industry, Pharmacy, Water
Treatment, etc.
The measuring medium of the instrument include: superheated steam, saturated steam,
general gas, mixed gas, natural gas, coal gas, water, hot water and chemical liquids.
In application, the instrument can be used with vortex flowmeter, turbine flowmeter,
V-cone flowmeter, elbow meter, electromagnetic flowmeter, mass flowmeter, orifice
flowmeter, nozzle flowmeter and Venturi tube.
10
Chapter 1 Overview
1.1 Main Performance
Table 1-1 Main Performance
Item Explanation Display 128×64 lattice LCD with LED backlightBoundary dimensions 160mm×80mm×84.3mmPanel cut-out dimension mm74×mm152 1+
01+
0 Installed panel thickness (1.5~6.0)mmweight 1.45kg Power supply (200~240)VAC, 50HzInbuilt memory 16MB NAND Flash min.Removable media USB interfacePower consumption 10VA. Isolation Isolated for power to ground by simulated transformer: >
1500VACRelative humidity (10~85)%RH(non-condensing)Ambient temperature (0~50)
Transport and reserve Temperature : (-20~60)Humidity:(5~95)%RH (non-condensing) Altitude: <2000m Special specification is not included
1.2 Input Signal
Table 1-2 DC Voltage and DC Current Input
Type Accuracy (%FS) (1~5)V ±0.1
(4~20)mA ±0.2
Table 1-3 TC Input
Type Range () Accuracy () B 600~1800 ±2.4 E -200~1000 ±2.4 J -200~1200 ±2.4 K -200~-100 ±3.3
-100~1300 ±2.0
S -50~100 ±3.7 100~300 ±2.0
300~1600 ±1.5 T -200~-100 ±1.9
-100~380 ±1.6 N -200~1300 ±3.0
R -50~100 ±3.7 100~300 ±2.0
300~1600 ±1.5 Note: The accuracy here excludes cold junction error.
11
Chapter 1 Overview
Table 1-4 RTD Input
Type Range () Accuracy () Pt100 -200~800 ±1.0 Cu50 -50~140 ±1.0
Note: Special RTD such as Pt1000 can be ordered with additional instruction.
Table 1-5 Frequency Input
Pulse Value Amplitude Response Period Range Accuracy (Hz) PI Input 0~10 V 1s (0~10000)Hz ±2
Note: When the amplitude<1 V is low level, high level for >4.5 V and <10 V. 1.3 Output Signal
Table 1-6 Analog Output
Type Range Allowed Max Difference (% FS) Load Capacity
AO output (4~20)mA ±0.2 500Ω
Table 1-7 Alarm Output
Type Range Contact Type Capacity Response Period Alarm output
0/1 Normally open2A /250VAC
(resistive load)
Same as the sampling period
1.4 Selection Table
12
Chapter 1 Overview
For example: KDF-2100A-0410 Explanation: Flow measurement, without relay alarm output, with RS-485 communication interface, with 4-20mA analog quantity transmission output, without USB transmit data interface. 1.5 Others
Table 1-8 Other Performance
Item Explanation
Fuse specification 1A/250VAC, slow fusing
Distribution specification Two channels transmitter, 50mA, 24VDC. It is forbidden to short the terminals.
Insulating strength Insulation for power to ground is more than 1500VAC, for 1 min, leakage current is 3.5mA. Insulation for power to the cover is more than 1500VAC, for 1 min, leakage current is 1mA.
Power-off protection History data and configuration information are saved into inbuilt memory, which assures the data won’t be lost when power is off via cell in support.
Alarm output At most two channels, relay are often open contacts and its capacity is 2A/250VAC (resistive load)
Communication interface It offers two interfaces: RS-485 and RS-232C. Where, RS-485 interface is isolated with host and the isolated voltage is > 500VAC.
Communication protocol Adopt MODBUS communication protocol.
Sampling period 1s.
13
Chapter 2 Installation and Wring
Overview
This chapter will introduce the details about installation and wiring method of grapher, it is
necessary for technician to learn when first time using.
After goods arrived, the correct operating procedure as blew:
2.1 Unpack
First check to see whether the out packing is well when receiving instruments. Do not
press excessive force into box when unpacking, box should be up and opening from the
sealed part, take out instruments carefully to check whether the cover become deformed
or breakage. You can check the contents according to the packing list before operating
the instrument.
2.2 Installation • 2.2.1 Installation Site
The instrument operating environment can not only affect the normal usage but also maintenance and checking. The instrument operating environment should be conformed as blew:
14
Chapter 2 Installation and Wring
The instrument must be installed inside the room.
Operation temperature: (0~50).
Relative humidity: (10~85)% RH (non-condensing).
Well ventilated to prevent the instrument from temperature-rising.
Little mechanical vibration.
No excessive amount of soot, steam, dust, or corrosive gases.
Minimum induction, static, or magnetic-field and low electrical noise is desired.
Install the instrument so that the user can easily view and operate. When installing,
ensure the instrument put flatly.
Condensation may occur and the measurement precision may be reduced if the instrument is moved to another place where the ambient temperature changes rapidly. In this case, let the instrument adjust to the new environment for at least an hour before using it.
The useful life of LCD may be reduced if instrument working under high temperature for a long time, and the screen may be not clear also.
• 2.2.2 Installation Dimension Installation dimension of intelligent flow (heat) totalizer is shown in Figure 2-2.
Figure2-2 Installation Dimension
1520+1mm
740+1
mm
81.3mm
Mounting panel:3mm
73.5
mm
151.5mm
2 Mounting fixedslots
160mm
80m
m
Display ESC
A/M
15
Chapter 2 Installation and Wring
• 2.2.3 Installation Method Step 1: Insert the instrument into the panel from the front view. The thickness of mounting
panel is (1.5-6.0) mm. Step 2: Fit 2 fixation clamps into 2 fixed slots which are located above and below the
instrument. See Figure 2-3. Each top and bottom of instrument has 1 fixed slot. Step 3: Tighten the setscrews of fixation clamp with an adequate torque. Step 4: Connecting signal wire and power wire are available after installation.
Figure 2-3 Instrument installation
2.3 Wiring
To improve the stability of connection, cold-pressed terminal UT2.5-4 as shown in Figure
2-4 is recommended.
Figure 2-4 Cold-pressed terminal UT2.5-4
To prevent electric shock when wiring, confirm that the power supply is OFF.
Mounting panel:(1.5~6.0) mm
fixation clamp
16
Chapter 2 Installation and Wring
Keep the measurement circuit away from the power supply circuit and ground circuit.
It is desirable that the object under measurement is not a noise source. However, if this is not avoidable, insulate the object under measurement and the measurement circuit. In addition, ground the object under measurement.
• 2.3.1 Arrangement of the Terminals
Terminals arrangement of the instrument is shown in Figure 2-5 , the definition and
explanation of terminal are shown in Figure 2-1.
Figure 2-5 Terminal arrangement
17
Chapter 2 Installation and Wring
Table 2-1 Explanation of Terminal Terminal No./ Label Explanation
L Phase line terminal. N Zero line terminal.
Protective earth terminal. Analog input/output
16, 17, 18 Differential pressure/Flow input channel for orifice
flowmeter, electromagnetic flowmeter, vortex flowmeter, etc.
19, 20, 21 Temperature signal input channel 22, 23, 24 Pressure signal input channel
3, 4 Frequency signal input channel for vortex flowmeter, turbine flowmeter, pulse flowmeter, etc.
5, 6 Current output channel Communication
13 (485+), 14 (485-) RS-485communication interface 13 (RXD), 14 (TXD), 15 (GND) RS-232Ccommunication interface
Transmitter power supply9, 10 Transmitter power supply channel 01 11, 12 Transmitter power supply channel 02
Digital output/Alarm output1, 2 Alarm output channel 01 7, 8 Alarm output channel 02
• 2.3.2 Power Supply Connection
Connect the power supply as shown in Figure 2-6 (a) (b). To ensure safety, please treat
the power cord as shown in Figure 2-6 (c).
Figure 2-6 Power supply connection
18
Chapter 2 Installation and Wring
Step 1: Be shown as 2-6 (c), peeling off the plastic sheath of insulated three-core power
wires 1 cm with wire stripper, then screw the copper core that within the power
wire toward the same direction to connect.
Step 2: Contra-rotating and unscrewing the bolt of L, N terminal, then inserting the
insulated three-core power wires to the , N terminal and tightening them.
Make sure it is correct and locked-in, the terminal should be grounded well.
Step 3: Turn on power to check whether instrument is normal, do not connect signal wire
if not.
Step 4: Make sure instrument can work normally, then turn off power to connect signal
wire.
• 2.3.3 Signal Connection Connect analog input signal, pulse input signal to the terminals as shown in Figure 2-7
(a). Connect power supply output, current output, alarm output of the terminals as
shown in Figure 2-7 (b). Connect transmitter power supply to the terminals as shown in
Figure 2-7 (c) (d).
(a) Analog Input Connection
T Input
RTD
19 20 21
-
+
Flow Input
Voltage 16 17 18
-
+
Flow Input
Current
16 17 18
-
+
P Input
Current
22 23 24
-
+
T Input
Current
19 20 21
3 4 -
+Frequency Input
-
+
P Input
Voltage 22 23 24
-
+
T Input
TC
19 20 21
19
Chapter 2 Installation and Wring
Power Supply, Current, Alarm Output t Connection
(C) Transmitter Power Supply Connection
(d) Transmitter Power Supply (External 24VDC) Connection
• 2.3.4 Communication Connection 2.3.4.1 RS-232C communication The RS-232C communication interface at the rear of the instrument can be applied to
exchange data with computer. The connection is shown in Figure 2-8. Use the
Shielded Twisted Pair (STP) cable which is less than 15 meters.
5 6 -
+
Analog Output
1 2 -
+
Alarm Output
9 10 -
+
24VDC Output
2-wire transmitter
+
-9
10
(4~20)mA
22 23 24
Tran
smitt
er
24
4-wire transmitter
+
-
(4~20)mA
9
10
(4~20)mA
22 23
Tran
smitt
er
4-wire transmitter
+
-
(4~20)mA
24V
DC
+
-
22 23 24
2-wire transmitter
+
-(4~20)mA
Tran
smitt
er
24V
DC
+
-
22 23 24 Tr
ansm
itter
20
Chapter 2 Installation and Wring
2.3.4.2 RS-485 communication
When several instruments are connected with one computer, as shown in Figure 2-9,
communication converter between the instrument and the computer is necessary,
Connect communication converter to serial ports of computer. Connect 485+ internal of
instrument to DATA+ terminal of communication; connect 485- terminal to DATA-
terminal of communication converter. Connection between the converter and computer
is shown in Figure 2-10.
The communication cables should be STP and the cables should be less than 1000
meters. For long transmission cables, two 120Ω termination resistors must be fitted to
the last slave in the chain.
Figure 2-9 RS-485 Communication between Computer and Several Instruments
Converter
Termination resistor
Termination resistor
①
②
③
④
⑤
⑥
⑦
⑧
⑨
13 14 15
GND (Black)
RXD (Red)
TXD (Blue)
Red
PC Side (Female) Instrument Side
Blue Black
21
Chapter 2 Installation and Wring
Figure 2-10 Connection between Computer and the Communication Converter
Shielding earth should be single point grounding in RS-485 and the grounding point should be located in controlling room.
2.3.4.3 Printer Connection
Connection between instrument and mini-printer is to provide print output function.
Connection between instrument and panel printer is shown as Figure 2-11, using the
Shielded Twisted Pair (STP) cable less than 10 meters.
Figure 2-11 Connection between Panel Printer and Instruments
①
②
③
④
⑤
⑥
⑦
⑧
⑨
13 14 15
GND (Black)
RXD (Red)
TXD (Blue)
Red
Printer Side (Female) Instrument Side
Blue
Black
PC Side (Female) Converter Side (male)
RXD (Red)
TXD (Blue)
GND (Black)
RXD (Red)
TXD (Blue)
①
②
③
④
⑤
⑥
⑦
⑧
⑨
①
②
③
④
⑤
⑥
⑦
⑧
⑨ GND (Black)
22
Chapter 3 Key & Menu
Overview
The instrument panel layout is shown in Figure 3-1.
[
Figure 3-1 Parts on Panel 3.1 Parts on panel
LCD: Used for the display of monitoring and configuration.
USB Interface: Used to insert USB Disk.
Keys: Different panel keys execute different functions in each display.
3.2 Switching Monitoring Displays
• 3.2.1 Monitor picture switching
USB Interface
LCD
ESC
A/M
23
Chapter 3 Key & Menu
• 3.2.2 Configuration Setup
Procedure This is The Display You Should See
1. Long press to enter the login display from any monitoring displays.
2. Press to activate the input box, press or to move cursor, then input the password1 by or .
3. Press to confirm.
4. Use to move focus frame to [Login], then press to enter [CONFIG] menu.
Note1: Change the password in [system] after enter setup menu.
CONFIG Mode Parameter
Trade Function System Clear
Version: v1.00 Password: 000000
Login
24
Chapter 3 Key & Menu
• 3.2.3 Parameter Type and Setup Method 3.2.3.1 Enumerated Parameters
Table 3-1 Enumerated Parameters Setup
Do This This is The Display You Should See
1. Press to pop up drop-down list. 2. Press or to select parameters,
and press to confirm.
Press ↓
3.2.3.2 Numerical Parameters
Table 3-2 Numerical Parameters Setup (一)
Do This This is The Display You Should See
1. Press to activate the input box. 2. Press or to move cursor. 3. Press or to increase or
decrease the value; Press to input sign for the parameter.
4. After modifying the value, press to confirm.
5. Press to modify the decimal point before activating the input box.
Press ↓
Table 3-3 Numerical Parameters Setup (二)
Do This This is The Display You Should See
1. Press or to select characters; Press to insert the selected character.
2. Press to delete the character. 3. Press to confirm the input and exit.
Press ↓
ESC
Sig Adj: 0/5 0 1 2 3 4 5 6 7 8 9 . -
Sig Adj: 3/5 1.0
0 1 2 3 4 5 6 7 8 9 . -
ΔP High: 100.0 ΔP Low: 0.0 ΔP Urgt: 0.0 T High: 500.0
ΔP High: 100.0 ΔP Low: 0.0 ΔP Urgt: 0.0 T High: 500.0
ΔP Sig: (4~20)mA Sig Adj: 0.0 T Sig: Pt100 T Unit:
ΔP Sig: (4~20)mA Sqrt: Yes
Sig Adj: 0.0 T Si Pt100
(4~20)mA (0~10)kHz (1~5)V
25
Chapter 3 Key & Menu
3.2.3.2 Time Parameters
Table 3-4 Time Parameters Setup
Do This This is The Display You Should See
1. Press or to move cursor. 2. Press or to modify date or time.3. After modifying, press to confirm
and exit. 4. Press to exit directly without
modifying.
YY-MM-DD: Year-Month-Day HH:MM:SS: Hour-Minute-Second
3.2.3.3 Mixed Character Parameters
Table 3-5 Mixed Character Parameters Setup
Do This This is The Display You Should See
1. Letter and numerical input is as seen in Table 3-3.
2. Press or to move cursor. 3. Press to confirm. 4. Press to delete the character. 5. Press to switch among different
character input boxes. 6. Press to confirm the input and exit.
Press ↓
Name: Save Load
State: Ready All 1935M Free 1911M 0/7 123
0 1 2 3 4 5 6 7 8 9 # - ESC
Name: Save Load
State: Ready All 1935M Free 1911M 0/7 ABC
A B C D E F G H I J K L M N O P Q R S T U V W X Y Z
Set Clock YY-MM-DD HH:MM:SS
12–03–07 09:16:17
ESC
26
Chapter 4 Basic Configuration
Overview
This section describes the universal information about System setup, Configuration
management, Shortcut menu operation and so on.
4.1 System Setup
Figure4-1 [System] Setup
Table 4-1 [System] Parameters
Name Description Selections Default Password To set the login password 000000~999999 000000
Rec. Period To select the record interval for the history data. 1s~60h 1s
Time To set the time for the instrument, please refer to 3.2.3.3.
Date mode To select the date format. YY-MM-DD/ DD-MM-YY/ MM-DD-YY
YY-MM-DD
CJC Temp To set the cold junction compensation temperature. -12.7~12.7 0.0
Std P (kPa) To input local standard atmosphere pressure. 0.00~300.00 101.32
Reset Factory To restore the factory defaults.
4.2 Reset Factory
Press [Reset Factory] to pop up a dialog box shown as Figure4-2. Press [OK] to restore the
factory defaults and press [Cancel] or to give up the reset operation.
Figure4-2 Dialog Box of Reset Settings
Do you want to restorefactory settings?
OK Cancel
ESC
Datemode: YY-MM-DDCJC Temp: 28.4 Std P: 101.32kPa
Reset Factory
Password: 000000 Rec. Period: 1s Time 11-07-20 15:08:04
27
Chapter 4 Basic Configuration
4.3 Apply the Configuration
Configuration compile is provided by the instrument.
Once configurations are modified, a ‘Save & Apply’ dialog box will be pop up before exit,
as shown in Figure4-3. Press [Cancel] to return the configuration display to setup
continually; Press [Exit] to return the monitoring display without enabling the settings;
Press [Enable] to enable the configuration and return the monitoring display. If there are
some errors in settings, compile display will be shown as Figure4-4 after pressing
[Enable].
It will show the error configuration or warning configuration in the compile display if
configuration is not correct. You can modify the configuration according to the prompt
until it is correct.
Figure4-3 Dialog Box of Apply Settings
Figure4-4 Configuration Compile Display
4.4 Shortcut Menu Operation
Press to pop up the shortcut menu in any monitoring displays. Adjust the brightness
of LCD as shown in Figure3-2. [Opr. Log], [Total Log], [Poweroff], [Alarm Msg.] please
refer to Chapter9; [USB Opr.] please refer to section 7.5.
Figure 4-5 Brightness Adjustment
Press twice
Brght Middle High Middle Low
Opr. Log Total LogPoweroff Alarm Msg Bright USB Opr.
ESC
- - - - -Compile- - - - -ERROR: Unit not match. 0 warnings, 1 errors. Apply failed!
Do you want to apply the new settings? Enable Exit Cancel
28
Chapter 5 Modes & Parameter
Overview
This section describes the Formula, Density compensation, Channel setup and Enthalpy
compensation.
Figure5-1 [Mode] Display 5.1 Flow Mode
Figure5-2 [Formula] Display
• 5.1.1 Mixed Character Parameters
Table5-1 [Mode] Parameters
Name Description Selections Default
Flow Mode To select the flow mode. See Table5-2.
Orifice, Vortex (Hz), Vortex (mA), Elec Magnetic, Pulse,
Disable Orifice
Flow Unit1 To select the flow unit. L/h, L/min, t/h, t/min, kg/h, kg/min, m3/h, m3/min t/h
ΣF Unit1 To select the flow totalizer unit. L, t, kg, m3 t
Note: the dimensions of [Flow Unit] and [ΣF Unit] should be homogeneous, or else compilation may be failure when enabling the settings.
Table5-2 Mode for flowmeters
Flow Mode Signal (Unit) Equation Orifice Differential pressure (kPa) ρ•PΔK=Q
Vortex (Hz) Frequency (Hz) Q=3.6·f·ρ/K
Vortex (mA) Current (mA) Q=f·ρ·K
ElecMagnetic Current (mA) Q=f·ρ·K Pulse Frequency (Hz) Q=f·ρ·K
Disable Current (mA) No
Formula Formula: Orifice Flow Unit: t/h ΣF Unit: t
Mode
Formula DensityChannel Enthalpy
29
Chapter 5 Modes & Parameter
Note 1: In above formula, Q: Mass flow value; K: Flow coefficient; ρ: Fluid density; ΔP: Differential pressure from input channel; f: Output frequency of velocity flowmeter. Note 2: In formula Q=3.6·f·ρ/K (when [Vortex (Hz)] is selected), [t/h] should be selected for [Flow Unit] when the unit of K is m-3; [kg/h] should be selected for [Flow Unit] when the unit of K is L-1.
K for [Orifice] is got by the formula designmaxmax ρ•PΔK=Q , while K for
other formula is set according to the practical application.
5.2 Density Compensation
The above equations show that the mass flow develops proportional to the density of
flow or the square-rooted one. Taking into consideration the fact that the density of
almost all kinds of flow varies according to variation of temperature and pressure,
compensation for temperature and pressure variations must be done to ensure accurate
measurements of mass flow. There are different kinds of compensation models serving
corresponding flow. 7 kinds of compensation modes are provided in the instrument
including [Set ρ], [SH Steam T&P] (superheated steam), [ST Steam T] (saturated steam),
[ST Steam P] (saturated steam), [GAS T&P] (ideal gas), ρ=AP+B (linear pressure
compensation) and ρ=AT+B (linear temperature compensation).
Figure5-3 [Density] Display
Density Comp. Type: GAS T&P
S.F Unit: Nm3/h S. ΣF Unit: kNm3
30
Chapter 5 Modes & Parameter
• 5.2.1 Density Compensation Introduction
Table5-3 [Density] Parameters
Name Description Selections Default Comp. Type To select the compensation type. See Table 5-4 Set ρ
S.F Unit To select the unit for flow in standard condition. To set when [GAS T&P] is selected in [Comp. Type].
Nm3/h, kNm3/h Nm3/h
S. ΣF Unit To select the unit for flow totalizer in standard condition. To set when [GAS T&P] is selected in [Comp. Type].
Nm3, kNm3 kNm3
Table5-4 Density Compensation Type
Comp. Type Density (ρ) Note Set ρ Set in [Parameter]. See 5.5
SH Steam T&P / ST Steam T / ST Steam P /
GAS T&P1 ρ=P/(T·Z) P: Absolute pressure. T: Absolute temperature. Z: Gas constant.
ρ=AP+B Linear pressure compensation. To set [A] and [B] in [Parameter]. See 0.
P: Absolute pressure (Gauge pressure + atmospheric pressure), unit: MPa.
ρ=AT+B Linear temperature compensation. To set [A] and [B] in [Parameter]. See 0.
T: Measured temperature (Not absolute temperature), unit:
Note 1: The gas constant z is got according to ( )( )15.273+T×ρ
1000×P+1000×P=z
designdesign
0design .
Pdesign, ρdesign and Tdesign should be set in [Parameter], please refer to chapter 6.
Set ρ
Set density in [Parameter] when [Set ρ] is selected. Please refer to chapter 6.
SH Steam T&P
The steam after heat treatment called superheated steam has features as below:
Superheated steam that has no water present and exists requires temperature and
pressure. Its enthalpy becomes a function of temperature and is relatively independent
of pressure. To determine density, both temperature and pressure must be measured.
Actually, for superheated steam, it is easier to be measured relative to the saturated
steam.
31
Chapter 5 Modes & Parameter
The scope of applicability: Pressure (0.2~16)MPa (absolute pressure), Temperature
(140~560). Calculating method need to look-up table if taking configuration about
pressure and temperature.
ST Steam T/ ST Steam P
Steam without heat treatment called saturated steam which with heavy heat energy
density, it is widely used in actual boiler system as a good heat carrier. The features as
below:
Pressure and temperature are not independent of one another, so there is only one
independent variable between them; date heat loss starts condensation; heat addition
superheats; pressure loss superheats; pressure gain starts condensation. Instrument
can only be used to measure dry saturated steam and cannot be used to precisely
measure wet saturated steam.
The scope of applicability: Pressure (0.1~16)MPa (absolute pressure), Temperature (98~348)
Calculating needs to look-up table if taking configuration about pressure. Unit of
pressure is MPa and temperature is .
GAS T&P
General gas requires temperature, pressure and gas constant. For the gas constant getting, please adopt equation to calculate. Therein, P is absolute pressure, T is absolute
temperature, Z is gas constant, ρ=P/(T·Z), therein, ( )
( )15.273+T×ρ1000×P+1000×P
=zdesigndesign
0design
.Pdesign, ρdesign and Tdesign should be set in [Parameter], please refer to chapter 6.
ρ=AT+B
Linear pressure compensation is used in following fields: The temperature is almost
stable; The fluid density is little affected on the temperature and is linear to the pressure.
Compensated density resulted from formula ρ=A×P+B needs to be set correctly, Where,
P in this formula means the absolute pressure whose unit is MPa.
ρ=AT+B
Linear temperature compensation is used in following fields: The pressure is almost
32
Chapter 5 Modes & Parameter
stable; The fluid density is little affected on the pressure and is linear to the temperature.
Compensated density resulted from formula ρ=A×T+B needs to be set correctly, Where,
T in this formula means the measured temperature whose unit is .
5.3 Channel Setup
Figure5-4 [Channel] Display
5.3.1 Channel setup parameter introduction
Table5-5 [Channel] Parameters
Name Description Selections Default
ΔP Sig To select signal type, this is related to flow model, details refer to tale 5-2.
Refer to table5-7 (4~20)mA
Sqrt To select square root or not for [ΔP Sig]. Appear only in [Flow Model]. No/Yes Yes
Period To select sampling period for [Freq Sig]. Appear only when pulse / vortex (Hz) is selected in [Flow Model].
1s~10s 1s
Sig Adj
To set the constant B for signal correct equation Y=X+B. To adjust different parameter for different signal type: adjusting frequency for frequency signal; adjusting different pressure for different pressure signal; adjusting volumetric flow for flow signal.
-9999~99999 0.0
T Sig To select temperature signal type. Refer to table5-7 Pt100T Unit To show the temperature unit.
T Adj To set the constant B for [T Sig]correct equation Y=X+B. -9999~99999 0.0
P Sig To select pressure signal type. Refer to table5-7 (4~20)mAP Unit To show the pressure unit. MPa MPa
P Adj To set the constant B for [P Sig]correct equation Y=X+B. -9999~99999 0.0
T Adj: 0.0 P Sig: (4~20)mA Unit: MPa
P Adj: 0.0
T Unit: T Adj: 0.0 P Sig: (4~20)mA P Unit: MPa
ΔP Sig: (4~20)mA Sqrt: Yes
Sig Adj: 0.0 T Sig: Pt100
33
Chapter 5 Modes & Parameter
Additional Notes • Sig Adj / T Adj / P Adj
The correct equation Y=X+B is used for linear modification to the measurement value.
Where, B means zero modification, and X is the engineering value before modification
while Y is the modified value. By default, B=0, which means no modification.
The corresponding table related with flow model
Note: By default, different pressure signal is KPa.
Table 5-7: Signal type for choosing
34
Chapter 5 Modes & Parameter
5.4 Enthalpy Setup
Instrument can display heat flow totalizer and realize the compensation type of six kinds
of heat flows such as set enthalpy, temperature and pressure compensation of
steam-gas, temperature compensation of saturated steam, pressure compensation of
saturated steam, h=AP+B and h=AT+B. [Enthalpy] must be corresponding to the
[Density], or else compilation may be failure when enabling the settings. Heat related
display will be shown in monitoring display when [Enthalpy] is activated unless volume
flow unit such as m3 or L is selected in [Formula] display.
Figure5-5 [Enthalpy] Display
• 5.4.1 Enthalpy Parameter Description
Table5-8 [Enthalpy] Parameters
Name Description Selections Default
Comp. Type To select the compensation type.
Disable, set enthalpy, temperature and pressure
compensation of steam-gas, temperature compensation
of saturated steam, pressure compensation of saturated steam, h=AP+B, h=AT+B
Disable
SHeat Unit To select the unit for heat flow. kJ/h, MJ/h, GJ/h, kW MJ/h
ΣH Unit To select the unit for heat flow totalizer. kJ, MJ, GJ, kW.h MJ
35
Chapter 5 Modes & Parameter
Table5-9 Enthalpy Compensation Model
Enthalpy Comp. Type Density Comp. Type Set H.E. For all density comp. type
SH Steam T&P For [SH Steam T&P] density comp. typeST Steam T For [ST Steam T] density comp. type ST Steam P For [ST Steam P] density comp. type
h=AP+B For [GAS T&P] or [ρ=AP+B] density comp. typeh=AT+B For [GAS T&P] or [ρ=AT+B] density comp. type
• 5.4.2 Heat Flow Calculation
HKQHEAT ••= Q
Where, K: Heat coefficient
Q: Mass flow value;
H: Heat flow value; Note: [Heat Unit] will be taken into account when heat flow calculating. 5.5 Related Displays • 5.5.1 Digital Display
Figure5-6 [Flow Pic]
Figure5-7 [Density Pic] / [Heat Pic]
Figure5-8 [S. Flow Pic]
S.F 15.96 Nm3/hT 120.0 P 0.3 MPaS. ΣF 61.87 Nm3
This picture will beshown only when[GAS T&P] isselected in [Density].
Flow 1.8 t/h Heat 4951.2 MJ/h H.E. 2737.7 kJ/kg ΣH 118224.6 MJ
Flow 2.9 8 t /hΔP 4.25 kPaρ 2.16 kg/m3
ΣF 37.2 t
The density unit isfixed as kg/m3 andenthalpy unit isfixed as kJ/kg.
.
Flow 2.98 t/h T 200.0 P 0.3 MPaΣF 37.2 t
!Urgt symbol: Indicatesthe urgent value.
Volume flow value in working condition will be shown here, when [GAS T&P] is selected in [Density] and volume flow unit is selected in [Formula].
36
Chapter 5 Modes & Parameter
Figure5-9 [InsFlow Pic] / [ΣFlow Pic]
Flow in standard condition will be shown in [Ins Flow Pic] and totalizer flow in standard
condition will be shown in [Σ Flow Pic] when [GAS T&P] is selected in [Density]. See
Figure5-9.
Figure5-10 [Std Flow Pic] / [Std ΣFlow Pic]
[Ins Heat Pic] and [ΣHeat Pic] will be shown in monitoring display unless [Disable] is
selected in [Enthalpy]. See Figure5-11.
Figure5-12 [InsHeat Pic] / [ΣHeat Pic]
• 5.5.2 Trend Display
Figure5-12Trend Display
The curve will be zoomed automatically according to the data in the current screen.
Therefore, maximum display accuracy is got in limited resolution. The percentage in the
screen means the percent that the dotted line indicates.
Totalizer Heat MJ
118224.6Heat Flow MJ/h
20.8
Std Totalizer Nm3
61.87Std Flow Nm3/h
15.96
Totalizer Flow t
37.2Flow t/h
2.98
Flow 35.2 kg/h
Lo ∑=254.0
10:16:35
10%
90%
37
Chapter 6 Parameter Setup
Overview
This section describes the related parameter setup of flow calculation such as the bound
of various signal range, set density, flow/heat parameter etc.
6.1 Parameters Setup
Figure 6-1 [Parameter] Display
Table 6-1 [Parameter] Description
Name Description Selections Default
ΔP High To set the range for differential pressure. The item name varies according to the [Formula], see Table 5-2.
-99999~99999 100.0
ΔP Low 0.0
ΔP Urgt
To set the signal value shown in the monitoring display when emergency condition is met. It can be set as 0 if needn’t.
0~9999999 0.0
T High To set the range for temperature signal. -99999~99999 500.0
T Low 0.0
T Urgt
To set the temperatureshown in the monitoring display when emergency condition is met. It can be set as [T High] if needn’t.
-999999~9999999 500.0
P High To set the range for pressure signal. -99999~99999 2.0
P Low 0.0
P Urgt To set the pressure shown in the monitoring display when emergency condition is met. It can be set as 0 if needn’t.
-999999~9999999 0.0
Set ρ To set the density when [Set ρ] is selected in [Density] →[Compensation].
0~9999999 1
Flow K To set the coefficient for flow. 0~9999999 1
T High: 500.0 T Low: 0.0 T Urgt: 500.0 P High: 2.0
Flow K: 1 View High: 100.0 View Low: 0.0 Low Cutoff: 0.0%
ΔP High: 100.0 ΔP Low: 0.0 ΔP Urgt: 0.0 T High: 500.0
P High: 2.0 P Low: 0.0 P Urgt: 0.0
Flow K: 1
38
Name Description Selections Default
View High To set the range for the flow shown in the monitoring display. [Low Cutoff] and [Alarm] is also based on this range.
-99999~99999 100.0
View Low 0.0
Low Cutoff To set the cut off range for small flow. (0.0~25.0)% 0.0%
K A To set the coefficient for [ρ=AP+B] and [ρ=AT+B] in [Density] →[Compensation].
-999999~9999999 1
K B 0
Design T [Design T], [Design P] and [Design ρ] is set for Z getting in [GAS T&P], and [Std ρ] is used for volume flow in standard condition. T unit is , P unit is MPa and ρ unit is kg/m3.
-999999~9999999
100 Design P 2 Design ρ 1
Std ρ 1
Set H.E. To set the enthalpy when [Set H.E.] is selected in [Enthalpy] →[Compensation].
-999999~9999999 1
Heat K To set heat coefficient and will appear when [Set H.E.] → [Compensation] are turn on.
-999999~9999999 1
Heat A To set the coefficient for [h=AP+B] and [h=AT+B] in [Enthalpy] →[Compensation].
-999999~9999999 1
Heat B 0
Note : Preset urgent values will be shown in monitoring display, when input signals are within the emergency range shown as follows:
Signal Type mA V Hz RTD/TC Emergency Condition
(0~1)mA
(0~0.1)V 0Hz Burnout
Hot resistance/ hot couple: Break off
39
Chapter 7 Trade Settlement
Overview
This section describes the parameter setup of trade settlement.
Figure7-1 [Trade] Display
Table7-1 [Trade] Parameters
Name Description Selections Default
Small Flow It will accumulated as [S.F. SV] when measured flow is less than [Small Flow]. [Small Flow] must set less than [Over Flow].
-999999~9999999 0.0
S.F. SV -999999~9999999 0.0
Over Flow That the overplus will be accumulated after multiplying [O.F. Fact] when measured flow is greater than [Over Flow].
-999999~9999999 100.0
O.F. Fact -999999~9999999 1.0
ΣF Stop T It will stop totalizing when “Stopping Steam” conditions are met. [ΣF Stop T] () and [ΣF Stop P] (MPa) are just two of the major conditions.
-999999~9999999 0.0
ΣF Stop P -999999~9999999 0.0
Flow Cal A Flow after calibrating = [Flow Cal A] × Flow before calibrating + [Flow Cal B]
-999999~9999999 1.0Flow Cal B -999999~9999999 0.0
Flow Pw off It will make up the loss during the power off after restarting. Complementary flow totalizer = [Flow Pwoff] × Power off time. Complementary heat totalizer = [Heat Pwoff] × Power off time. The units are the same as the flow and the heat.
0~9999999 0.0
Heat Pw off 0~9999999 0.0
ΣF Factor To select the multiple rate for ΣF, S. ΣF and ΣH.
0~9999999 1.0 ΣH Factor 0~9999999 1.0
Small Flow: 0.0 S.F. SV: 0.0
Over Flow: 100.0 O.F. Fact: 1.0
ΣF Stop T: 0.0 ΣF Stop P: 0.0Flow Cal A: 1.0 Flow Cal B: 0.0
Flow Pwoff: 0.0 Heat Pwoff: 0.0 ΣF Factor: 1.0 ΣH Factor: 1.0
40
Chapter 7 Trade Settlement
7.1 Stop Steam Conditions
• For [SH Steam T&P] and [GAS T&P]
Stopping steam may be taken place when following conditions are met for [SH Steam
T&P] and [GAS T&P] compensated type.
① Displayed temperature < [ΣF Stop T]
② Displayed pressure < [ΣF Stop P]
• For [ST Steam T]
Stopping steam may be taken place when following conditions are met for [ST Steam T]
compensated type.
① Displayed temperature < [ΣF Stop T]
• For [ST Steam P]
Stopping steam may be taken place when following conditions are met for [ST Steam P].
① Displayed pressure < [ΣF Stop P]
7.2 Related Displays
Flow 0.0 t/hT 37.5 P 0.1 MPaΣF 37.2 t
Stop symbol: Indicatesstopping steam status.
41
Chapter 8 Other Functions
Overview
This section describes the Alarm, Current Output, Communication, Monitoring Display
and USB Disk Operation.
Figure 8-1 [Function] Display
8.1 Alarm Setup
Figure 8-2 [Alarm] Display
The alarm state can be output by up to 2 DO contacts. When [None] is selected in alarm
submenu, the alarm state will only shown in the monitoring display but won’t output by
DO contacts.
Figure 8-3 No DO Contact Selected
The same contact can be selected for different alarm types and different alarm channels.
For example, if DO01 is selected for both [Hi] and [Lo], DO01 will close once [Hi] or [Lo]
occurs.
When the measured value fluctuates near the alarm value, it will activate and
de-activate alarm relays frequently, resulting in alarm contacts malfunction.
AR3100/AR4100 provides alarm hysteresis to avoid this case.
Following is the illustration of the high/low limit of alarm. Set the flow alarm as shown in
Figure 8-4.
Flow Hi 100.0 None Lo 0.0 None Hysteresis: 0.0
Function Flow Temperature Pressure
Function Alarm Output Comm. Display USB Opr.
42
Chapter 8 Other Functions
Figure 8-4 Alarm Example
For high limit alarm, if the alarm value is set as 75.00 and hysteresis is 5.00; when the
measured value increases and reaches 75.00, the alarm relay will be activated; If the
measured value decreases below 75.00, alarm relay will not be de-activated
immediately, unless the measured value reaches 70.00, see Figure8-5
Figure8-5 [Hi Alarm] Hysteresis
Alike, for low limit alarm, if the alarm limit is set as 30.00 and hysteresis is 5.00; when
the measured value decreases and reaches 30.00, the alarm relay will be activated; If
the measured value rises above 30.00, alarm relay will not be de-activated immediately,
unless the measured value reaches 35.00, see Figure 8-6.
Figure 8-6 [Lo Alarm] Hysteresis
8.2 Output Setup
One current output which has different sources is supplied by the instrument.
Figure 8-7 [Output] Display
Type: (4~20)mA High: 100.0 Low: 0.0
Correct: 0.000mA
Source: Flow Type: (4~20)mA High: 100.0 Low: 0.0
Flow Hi 75.0 DO01 Lo 30.0 DO02 Hysteresis: 5.0
43
Chapter 8 Other Functions
Table8-1[Output] Parameters
Name Description Selections Default
Source To select the source for output. Flow/Heat Flow/Std Flow Flow
Type To show the output signal. (4~20)mA (4~20)mAHigh To set the range and decimal point. -99999~99999 100.0Low -99999~99999 0.0
Correct To set the value for zero correction. (-2.500~2.500)mA 0.000
8.3 Communication Setup
Instrument provides the communication with PC to realize monitoring to instrument and
history data.
• 8.3.1 Communication Parameter
Figure 8-8 [Comm.] Display
Table 8-1 [Comm.] Parameters
Name Description and Selections Default Protocol Modbus Modbus
Model RS232/RS485 Up to the ordering code, cannot be changed
Baudrate 1200/9600/19200/57600/115200 9600 Address 6~254 6 Data Bit 8 8 Stop Bit 1/2 1 Parity None/Odd/Even None
Flt Endian 0123/1032/2301/3210 1032
8.4 Display Setup
The display set as [Cycle] will display in cycle following the [View Cycle], while the
display set as [Skip] will be skipped when in cycle.
Data Bit: 8 Stop Bit: 1
Parity: None Flt Endian: 1032
Protocol: Modbus Comm.Mode: RS232Baudrate: 9600 Address: 6
44
Chapter 8 Other Functions
Figure 8-9 [Display.] Display
Table 8-2 [Display] Parameters
Name Description Selections Default
View Cycle To select the cycle time. 0s/3s/5s/10s/15s/30s 0s (Not Cycle)
[Monitoring Pic] Display/Hide pic Cycle/Skip By default, [Trend Pic] and [History Pic] are skip, others are cycle
8.5 USB Disk Operation
Over view Up to 2G USB Disk is accepted to transfer the history data, the configuration and the
logging data from the instrument to computer. For the settings, it also can load
configuration data from USB Disk to the instrument. The type of USB Disk is specified
when ordering.
• 8.5.1 Format USB Disk
Do This This is The Display You Should See
1. Press in any monitoring display to pop up the shortcut menu.
2. Press or to focus on [USB Opr.] and press to enter the USB disk operation display.
3. Press to exit.
4. Press or to focus on [Format] and press to pop up the format dialog box.
5. Press [OK] to format while press [Cancel] or to exit.
Message Format
State: Ready All 1935M Free1911M
Opr. Log Total Log
Poweroff Alarm Msg
ESC
ESC
ESC
Format the disk?
OK Cancel
History Pic: Skip Total Pic: Skip OffTime Pic: Skip
Total OffTime Pic: Cycle
View Cycle: 0s Flow Pic: Cycle
Density Pic: Cycle S.Flow Pic: Cycle
Heat Pic: Cycle InsFlow Pic: Cycle ΣFlow Pic: Cycle
InsHeat Pic: Cycle
ΣHeat Pic: Cycle Trend Pic: Skip History Pic: Skip
OffTime Pic: Cycle
45
Chapter 8 Other Functions
• 8.5.2 Save Logs
Do This This is The Display You Should See
1. Press [Message] → [Poweroff] to pop up the dialog box.
2. Press [OK] to save the power off logs while press [Cancel] or to exit.
Press ↓
3. “Save File” will appear when saving Log and [Total Log] as saving [Poweroff].
• 8.5.3 Save History Data
Do This This is The Display You Should See
1. Press [His. Data] to enter history data saving display.
2. Press to pop up the dialog box to select the saving type: [Save All], [Save Part] or [Save Timing].
[Save All] 3. Select [Save All] and press [Save] to pop
up the dialog box. 4. Press [OK] to save all history data while
[Cancel] to exit. 5. “Save File” will appear when saving history
data.
Save 110116H0.HDA?
Type: Save All
Save
Save SYS_0244.CSV?
OK Cancel
ESC
Poweroff
Alarm Msg
SYS 0244.CSV
SYS: [Poweroff] ALM: [Alarm Msg] OPT: [Opr.Log] ACC: [Total Log]
Minute
Second
File format. Use
EXCEL or text to
open.
46
[Save Part] 6. Select [Save] to entry parts of history data
saving display. 7. Set [Start Time] and [End Time]. 8. Press [Save] to pop up the dialog box.
Then operation as [Save All]. 9. Press [Cancel] entering operate display to
check the saving progress.
[Save Timing] 10. Select [Save Timing] to entry save timing
display. 11. Select [Save Timing] and select [Yes] for
[Enable]. Then set the [Start Time] for timing record.
12. Press to exit automatic saving history data display.
13. The allowed range of [Start Time] is 00:00:00~23:59:59. When [Start Time] is arrived, the instrument will save 24 hours history data.
14. For any saving type, once having been saved, the [Start Time] in [Save Part] will be updated to the latest [End Time] automatically.
Type Save Timingt
Enable No
ESC
Type Save Part Start Time 11/07/16 15:21:26 End Time 11/07/16
15:45:04 Save
110116H0.HDA
MonthDay
File format. Use
Host Data
Management
Software to open.
Year
Sequence number, up
to 10 history data files
can be saved in one
file in one day by a
card.
47
Chapter 8 Other Functions
Do This This is The Display You Should See
15. Press [His. Data] to enter history data saving display.16. Press to pop up the dialog box to select the
saving type: [Save All], [Save Part] or [Save Timing].
[Save All] 17. Select [Save All] and press [Save] to pop up the
dialog box. 18. Press [OK] to save all history data while [Cancel] to
exit. 19. “Save File” will appear when saving history data.
[Save Part] 20. Select [Save] to entry parts of history data saving
display. 21. Set [Start Time] and [End Time]. 22. Press [Save] to pop up the dialog box. Then
operation as [Save All]. 23. Press [Cancel] entering operate display to check the
saving progress.
[Save Timing] 24. Select [Save Timing] to entry save timing display. 25. Select [Save Timing] and select [Yes] for [Enable].
Then set the [Start Time] for timing record. 26. Press to exit automatic saving history data
display. 27. The allowed range of [Start Time] is
00:00:00~23:59:59. When [Start Time] is arrived, the instrument will save 24 hours history data.
28. For any saving type, once having been saved, the [Start Time] in [Save Part] will be updated to the latest [End Time] automatically.
Type Save Timingt
Enable No
ESC
Type Save Part Start Time 11/07/16 15:21:26 End Time 11/07/16
15:45:04 Save
Save 110116H0.HDA?
OK Cancel
Type: Save All
Save
110116H0 HDA
MonthDay
File format. Use Host
Data Management
Software to open.
Year
Sequence number, up to 10
history data files can be
saved in one file in one day
by a card.
48
Chapter 8 Other Functions
• 8.5.4 Save Settings
Do This This is The Display You Should See
1. Login the setup menu, entry [U Plate] press to exit.
2. Input the configuration name and press [Save] to save current settings.
3. Press [Load] to enter the configuration select display
4. Press or to select the settings, and press to load the selected settings.
Press ↓
Press to load
• 8.5.5 Save Monitoring Display
In any monitoring displays, long press to copy the screen into USB Disk. It will be
saved in properties of PICTURES.
110716A
110716B
110716C
ESC
Name: 110116A
Save Load
State: Ready
Function Alarm Output Comm. Display USB Opr.
49
Chapter 9 History Data
Overview
Data of flow, temperature and pressure can be record automatically. For 16MB inbuilt
memory, up to 704 record blocks is provided. The relationship between recording period
and recordable capacity is shown as Table 9-3.
Table 9-3 Recordable Capacity Recording Period Recordable Capacity
1s 3 days 20 hours 9 minutes 36 seconds 1min 230 days 9 hours 36 minutes 1hour 13824 days
• Rec. Period
Rec. Period = Rec. Int × Factor. The [Rec. Int] can be 1s, 1min or 1hour and the [Factor]
should be integer type with range 1~60.
Figure 910 Recording Period Setup
9.1 Related Monitoring Displays
Figure9-11 History Display
1. Press and to move the cursor line forth or back to review the history curves.
The moving distance of the cursor line is determined by the scale and record period.
2. Press and to page among the displays shown different record channels.
3. Press to switch the recall modes: Auto [A] or Manual [M]. Long press it to pop up
the dialog box to set recall time. After setting and then press to be positioned to
the recall time automatically. If the recall time is earlier than the earliest record time, it
will be positioned to the earliest time; If later than the current system time, it will be
positioned to the current time.
4. Press to modify the range of data displayed on each screen, which can enlarge
or reduce the curve spread to make it easy to observe.
Flow 11-07-06 10:16:35
1 M 35 210%
90%
Password: 000000 Rec. period: 1s Time 11-01-16 15:08:04
Rec.Int: 1s
Factor: 1 Press
50
Chapter 10 Message Logs
Overview
Four message logs including opreation log, power off log, alarm log and totalizer log are
provided.
10.1 Operation Log
Operation log records the configuration information (as apply, reset settings) and
clearing information. Up to 32 pieces can be record. When it is out of 32, the instrument
will delete the earliest one for the latest.
Figure10-12 Operation Log
Press and to page up and page down.
10.2 Totalizer Log
Instrument with the 1/3600 of current value to totalize per second and will re-totalize
when it was 999,999,999. There are up to 24, 45, 12 and 12 pieces of logs for hourly,
daily, monthly and yearly respectively. When it is out of the limit, the instrument will
delete the earliest one for the latest.
Figure10-13 Totalizer Log
1. Press to switch among the hourly, daily, monthly and yearly logs.
2. Press and to page up and page down in one log.
3. Press and to switch among the Totalizer Flow, Totalizer Heat and Std
Totalizer (totalizer in standard condition).
Totalizer Flow Hourly 01 01-16 09:00~ 0:00
253.0Kg02 01-16 08:00~09:00
150.0K
Opr. Log 1/18
Type Apply new settings
Time 11-07-15 09:58:09
51
Chapter 10 Message Logs
10.3 Poweroff Log
Poweroff log records the time of power ON/OFF and the total poweroff time. Up to 128
pieces can be record. When it is out of 128, the instrument will delete the earliest one for
the latest.
Figure10-14 Poweroff Log
Press and to page up and page down.
10.4 Poweroff Total Time
Users can entry the clear display to clear poweroff total time if necessary.
10.5 Alarm Log
Alarm log records the information of alarm channel, alarm type, alarm activated time and
alarm de-activated time. Up to 24 pieces can be record. When it is out of 24, the
instrument will delete the earliest one for the latest.
Figure10-5Alarm Log
Press and to page up and page down.
Alarm Msg 1/22
Ch. T Hi
ON 11-07-14 13:29:58
Poweroff Total Time
0072h 08m 25s
Poweroff 1/4
OFF 12-03-14 09:57:11
ON 12-03-14 09:58:09
ΣT 0016h 35m 12s
52
Chapter 10 Message Logs
10.6 Logs Clearing
Instrument can clear the total value, total message, poweroff record, alarm message and operation log.
Figure10-6 [Clear] Diaplay
Do This This is The Display You Should See 1. Login the setup menu. 2. Press and to scroll to [Clear],
and press to enter the logs clearing display.
3. Press to exit. Press ↓
ESC
Reset Total
Clear Total Log
Clear Poweroff Log
Clear Alarm Msg
Reset Total
Clear Total Log
Clear Poweroff Log
Clear Total Log
Clear Poweroff Log
Clear Alarm Msg
Do you want to reset
the total?
OK Cancel
53
Chapter 11 Troubleshooting & Maintenance
Overview
When regular error occurs, settle it with the means introduced by this manual. Check the
operation and replace the parts of the instrument periodically to keep it in good working
order.
11.1 Periodic Inspection
• Check if the parts of the instrument have been damaged or cauterized, and make
instrument’s surface clear;
• Check if parts become flexible;
• Check the grounding protection to make sure the safeguard is perfect;
• Keep the bores clear and ventilated; high temperature may lead to the breakdown,
abnormal performance, short life-span or fire.
11.2 Troubleshooting Flow Chart
• 11.2.1 When Nothing Operates (Nothing is displayed)
Supply power of the voltage/frequency according to the specifications.
Check wiring on the power supply terminals. Pleaserefer to 错误!未找到引用源。.
Is the power supply properly connected?
Is the power supplied properly?
Contact our customer service.
NO
YES
NO
YES
54
Chapter 11 Troubleshooting & Maintenance
• 11.2.2 When Error Signal Data Displays
• 11.2.3 When Connection Link is Faulty
If you couldn’t manage the trouble, please contact our customer service.
Check the configuration for communication.
Check the communication wiring and serial interface. Please refer to . Is the hardware correct?
Is the configuration set properly?
Contact our customer service.
NO
NO
YES
YES
Is the input signal properly connected?
Is the configuration set properly?
Contact our customer service.
Connect it properly. Please refer to 错误!未找到引用
源。.
Check the correction of configuration [Signal], [Range], [Cutoff] and other related setups.
NO
YES
NO
YES
55
SHANGHAI KENT INSTRUMENT CO., LTD.
Add: #169 Kangfa Rd., Tinglin,Jinshan,Shanghai 201504, China Tel: 86-21-56027777 Fax: 86-21-56026666
E-mail: [email protected] Http: //www.shanghaikent.com