kronos 20 manual
TRANSCRIPT
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Heinzmann GmbH & Co. KGEngine & Turbine Controls
Am Haselbach 1D-79677 Schönau (Schwarzwald)Germany
Phone +49 7673 8208-0Fax +49 7673 8208-188Email [email protected]
V.A.T. No: DE145551926
HEINZMANN
Engine & Turbine Controls
KRONOS 20
Electronically controlled
Air Fuel Ratio Control System
for Gas Engines
with open / closed Control Loop
Copyright 2007 by Heinzmann GmbH & Co. KG All rights reserved. This publication may not be reproduced by any means whatsoever or passed on to any third parties.
Manual AFR 03 002-e / 01-08
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Read this entire manual and all other publications appertaining to thework to be performed before installing, operating or servicing yourequipment.
Practice all plant and safety instructions and precautions.
Failure to follow instructions may result in personal injury and/or dam-age to property.
HEINZMANN will refuse all liability for injury or damage which re-sults from not following instructions
Please note before commissioning the installation:
Before starting to install any equipment, the installation must have beenswitched dead!
Be sure to use cable shieldings and power supply connections meetingthe requirements of the European Directive concerning EMI .
Check the functionality of the existing protection and monitoring sys-tems.
To prevent damages to the equipment and personal injuries, it is
imperative that the following monitoring and protection systems
have been installed:
Overspeed protection acting independently of the speed governor
Overtemperature protection
HEINZMANN will refuse all liability for damage which results frommissing or insufficiently working overspeed protection
Generator installation will in addition require:Overcurrent protection
Protection against faulty synchronization due to excessive frequency,voltage or phase differences
Reverse power protection
Overspeeding can be caused by:
Failure of the voltage supply
Failure of the actuator, the control unit or of any accessory deviceSluggish and blocking linkage
Warning
Danger
Danger
Danger!High
Voltage
Danger
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The examples, data and any other information in this manual are in-tended exclusively as instruction aids and should not be used in any
particular application without independent testing and verification by
the person making the application.
Independent testing and verification are especially important in any ap- plication in which malfunction might result in personal injury or dam-age to property.
HEINZMANN make no warranties, express or implied, that the exam- ples, data, or other information in this volume are free of error, that
they are consistent with industry standards, or that they will meet therequirements for any particular application.
HEINZMANN expressly disclaim the implied warranties of merchant-ability and of fitness for any particular purpose, even if HEINZMANN have been advised of a particular purpose and even if a particular pur-
pose is indicated in the manual.
HEINZMANN also disclaim all liability for direct, indirect, incidentalor consequential damages that result from any use of the examples,data, or other information contained in this manual.
HEINZMANN make no warranties for the conception and engineeringof the technical installation as a whole. This is the responsibility of theuser and of his planning staff and specialists. It is also their responsibil-ity to verify whether the performance features of our devices will meetthe intended purposes. The user is also responsible for correct commis-sioning of the total installation.
Warning
Danger
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Contents
KRONOS 20
Contents
Page
1 Safety Instructions and Related Symbols............................................................................ 1
1.1 Basic Safety Measures for Normal Operation................................................................. 2
1.2 Basic Safety Measures for Servicing and Maintenance .................................................. 2
1.3 Before Putting an Installation into Service after Maintenance and Repair Works.......... 3
2 General ................................................................................................................................... 4
2.1 System Characteristics..................................................................................................... 4
2.2 Applications..................................................................................................................... 4
2.3 System Components ........................................................................................................ 52.4 System Specifications...................................................................................................... 5
2.5 Operational Principle ....................................................................................................... 6
2.6 General Application......................................................................................................... 7
2.7 Additional Functions ....................................................................................................... 8
2.8 Gas Train ......................................................................................................................... 9
3 Sensors.................................................................................................................................. 10
3.1 Overview Table ............................................................................................................. 10
3.2 Speed Pickup IA… ........................................................................................................ 103.2.1 Technical Data ....................................................................................................... 10
3.2.2 Mounting Position.................................................................................................. 11
3.2.3 Tooth Shape ........................................................................................................... 11
3.2.4 Distance of the Speed Pickup ................................................................................ 11
3.2.5 Dimensional Drawing............................................................................................ 12
3.2.6 ATEX Certification of Speed Pickups................................................................... 13
3.3 Double Sensor P/T-S-01 for Pressure and Temperature Measurement in Intake
Manifold .............................................................................................................................. 13
3.3.1 Technical Data ....................................................................................................... 133.3.2 Dimensional Drawing............................................................................................ 14
3.3.3 Mounting................................................................................................................ 14
3.3.4 ATEX Certification for Double Sensor P/T-S-01.................................................. 15
3.4 λ Sensor LSM 11 for Exhaust Gas Measurement (optional)......................................... 15
3.4.1 Technical Data ....................................................................................................... 15
3.4.2 Dimensional Drawing............................................................................................ 17
4 Control Unit KRONOS 20.................................................................................................. 18
4.1 Technical Data............................................................................................................... 18
4.1.1 General................................................................................................................... 18
4.1.2 Inputs and Outputs................................................................................................. 19
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Contents
KRONOS 20
4.2 Dimensional Drawing.................................................................................................... 20
4.3 Mounting Position ......................................................................................................... 22
5 Gas Valves E-LES ............................................................................................................... 23
5.1 Structure and Operating Principle ................................................................................. 235.2 Technical Data............................................................................................................... 24
5.2.1 Specifications for all E-LES Gas Valves............................................................... 24
5.2.2 Additional Specifications for Gas Valve E-LES 30 .............................................. 25
5.2.3 Additional Specifications for Gas Valve E-LES 50 .............................................. 25
5.2.4 Additional Specifications for Gas Valve E-LES 80 .............................................. 25
5.3 Dimensional Drawings .................................................................................................. 26
5.4 Mounting ....................................................................................................................... 29
5.5 ATEX Certification of E-LES… Gas Valves................................................................ 29
6 Electric Connection............................................................................................................. 31
6.1 Wiring Diagrams ........................................................................................................... 32
6.1.1 Wiring Diagram for KRONOS 20 with open Loop............................................... 32
6.1.2 Wiring Diagram for KRONOS 20 with closed Loop (power signal, CH4
signal).............................................................................................................................. 33
6.1.3 Wiring Diagram for KRONOS 20 with λ -Sensor Signal ...................................... 34
6.2 Cable Harness................................................................................................................ 35
6.3 Enclosed Cables............................................................................................................. 36
6.3.1 Cable W2 to Gas Valve E-LES.............................................................................. 366.3.2 Cable W3 to Pressure / Temperature Sensor P/T-S-01.......................................... 37
6.3.3 Cable W4 to Speed Pickup IA… ........................................................................... 38
6.3.4 Cable W5 to λ -Sensor LSM 11.............................................................................. 39
7 Parameter Settings for Control Unit KRONOS 20.......................................................... 40
7.1 Parametrization with the Hand Held Programmer 3 ..................................................... 40
7.2 Parametrization with the PC / Laptop ........................................................................... 40
8 General Mounting Instructions.......................................................................................... 41
9 Commissioning .................................................................................................................... 42
9.1 General Safety Information for Commissioning ........................................................... 42
9.2 General Information on the first Engine Start ............................................................... 42
9.3 Commissioning for OPEN LOOP (open control circuit) .............................................. 43
9.4 Further Commissioning for CLOSED LOOP (closed control circuit) with Output
Power 45
9.5 Further commissioning for CLOSED LOOP with λ1 control (KRONOS 20 version
with λ 1 sensor) 47
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Contents
KRONOS 20
10 Misfire Detection (optional).............................................................................................. 49
10.1 General ........................................................................................................................ 49
10.2 Putting into Operation ................................................................................................. 49
11 Operation ........................................................................................................................... 51
12 Maintenance and Service.................................................................................................. 52
13 Error Handling.................................................................................................................. 53
13.1 General ........................................................................................................................ 53
13.2 Categories of Errors und Emergency Operation after System Failure ........................ 53
13.3 Error Memories ........................................................................................................... 55
13.4 Bootloader ................................................................................................................... 56
13.4.1 Bootloader-Start Tests ......................................................................................... 5613.4.2 Bootloader Communication................................................................................. 57
13.5 Error Parameter List .................................................................................................... 58
14 Parameter Description...................................................................................................... 65
14.1 Synoptical Table .......................................................................................................... 65
14.2 List 1: Parameters ........................................................................................................ 70
14.3 List 2: Measurements .................................................................................................. 77
14.4 List 3: Functions .......................................................................................................... 89
14.5 List 4: Characteristics and Maps ................................................................................. 92
15 Figure List.......................................................................................................................... 94
16 EC Declaration of Conformity......................................................................................... 95
17 Order Form for KRONOS Systems ................................................................................ 96
18 Order Specifications for Manuals.................................................................................... 97
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1 Safety Instructions and Related Symbols
KRONOS 20 1
1 Safety Instructions and Related Symbols
This publication offers wherever necessary practical safety instructions to indicate inevitable
residual risks when operating the engine. These residual risks imply dangers to
persons
product and engine
environment.
The symbols used in this publication are in the first place intended to direct your attention to
the safety instructions!
This symbol is to indicate that there may exist dangers to the engine, to the
material and to the environment.
This symbol is to indicate that there may exist dangers to persons. (Danger
to life, personal injury)
This symbol is to indicate that there exist particular danger due to electri- cal high tension. (Mortal danger).
This symbol does not refer to any safety instructions but offers important notes for
better understanding the functions that are being discussed. They should by all
means be observed and practiced. The respective text is printed in italics.
The primary issue of these safety instructions is to prevent personal injuries!
Whenever some safety instruction is preceded by a warning triangle labelled “Danger” this is
to indicate that it is not possible to definitely exclude the presence of danger to persons, en-
gine, material and/or environment.
If, however, some safety instruction is preceded by the warning triangle labelled “Caution”
this will indicate that danger of life or personal injury is not involved.
The symbols used in the text do not supersede the safety instructions. So please do not
skip the respective texts but read them thoroughly!
Note
Warning
Danger
Danger!High
Voltage
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1 Safety Instructions and Related Symbols
2 KRONOS 20
In this publication the Table of Contents is preceded by diverse instructions that
among other things serve to ensure safety of operation. It is absolutely imperative
that these hints be read and understood before commissioning or servicing theinstallation.
1.1 Basic Safety Measures for Normal Operation
• The installation may be operated only by authorized persons who have been duly
trained and who are fully acquainted with the operating instructions so that they are
capable of working in accordance with them.
• Before turning the installation on please verify and make sure that
- only authorized persons are present within the working range of the engine;
- nobody will be in danger of suffering injuries by starting the engine.
• Before starting the engine always check the installation for visible damages and make
sure it is not put into operation unless it is in perfect condition. On detecting any faults
please inform your superior immediately!
• Before starting the engine remove any unnecessary material and/or objects from the
working range of the installation/engine.
• Before starting the engine check and make sure that all safety devices are working
properly!
1.2 Basic Safety Measures for Servicing and Maintenance
• Before performing any maintenance or repair work make sure the working area of the
engine has been closed to unauthorized persons. Put on a sign warning that mainte-
nance or repair work is being done.
• Before performing any maintenance or repair work switch off the master switch of the
power supply and secure it by a padlock! The key must be kept by the person perform-
ing the maintenance and repair works.
• Before performing any maintenance and repair work make sure that all parts of engine
to be touched have cooled down to ambient temperature and are dead!
• Refasten loose connections!
• Replace at once any damaged lines and/or cables!
• Keep the cabinet always closed. Access should be permitted only to authorized per-
sons having a key or tools.
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1 Safety Instructions and Related Symbols
KRONOS 20 3
• Never use a water hose to clean cabinets or other casings of electric equipment!
1.3 Before Putting an Installation into Service after Maintenance and Repair
Works
• Check on all slackened screw connections to have been tightened again!
• Make sure the control linkage has been reattached and all cables have been recon-
nected.
• Make sure all safety devices of the installation are in perfect order and are working
properly!
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2 General
4 KRONOS 20
2 General
2.1 System Characteristics
• Affordable and trustworthy electronic Lambda control system
• Improved starting, idling, synchronizing and load behaviour
• Freely parametrizable, load and speed dependent mixing ratio map
• Cold start enrichment possible
• Easy adaptation to different engine and gas types, requiring only minor parametermodifications
• Only three sensors are required accordingly simple installation and reliable operation
• Simple and easy parameter setting and diagnosis with HEINZMANNDcDesk 2000 communications software
Optional:
- Communication with handheld programmer HEINZMANN HP-03
or the optional integrated programmer
- CAN communication
• Extends application range of existing gas mixers mixing inserts therefore may be usedfor different gas qualities within a certain range
• The mixture control systems as a trimming system is largely self-regulating on basis ofBernoulli’s Law, thus avoiding constant movement of the regulating valve, to best ad-
vantage of control stability.
• In case of error, the mixture control system can be operated by hand in the conventionalway.
• The closed-loop version may be regulated via the power signal, an oxygen sensor or viaa CH4 signal.
• Optional misfire detection is possible.
2.2 Applications
• Lean-burn engines
• Lambda 1 engines
• Stationary engines and vehicles
• Engines with fixed and variable speed
• Fuels: propane, natural gas, sewage gas, landfill gas, carburetted hydrogen vapour
• Fuels with changing gas quality
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2 General
KRONOS 20 5
2.3 System Components
• Gas control valve E-LES 30 / E-LES 50 / E-LES 80
• Control unit KRONOS 20
• Intake manifold pressure sensor with integrated temperature sensor P/T-S-01
• Speed pickup IA…
• Cable harness cable to the digitally controlled main adjusting screwsensor cable for P-/T sensor
speed pickup cable
communication cable between control unit and PC
• Communications software DcDesk 2000
• Optional λ sensor
• Optional gas mixer from KRONOS 10
This system components may only be combined with gas mixers that meet
the HEINZMANN specifications. If a different gas mixer shall be used con-
sult HEINZMANN.
2.4 System Specifications
All ATEX certified components are suitable for zone 2.
Supply voltage 12 V DC or 24 V DC,
Min. supply voltage 10 V DC (E-LES 30/50)
18 V (E-LES 80)
Max. supply voltage 32 V DC
Residual ripple 10 % maximum at 100 Hz
Current consumption max. 2 A
Admissible voltage drop at max. max. 10 %
current drawing
Fuse (external) 6 A
λ - range: 0.9..2.3
System is ready 10 s after energizing
Reaction time 100% deviation control in 0.3 s
Note
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2 General
6 KRONOS 20
Resolution 1250 steps (E-LES 30)
2000 steps (E-LES 50)
3800 steps (E-LES 80)
λ map 100 pointsCalorific value range 4..200 MJ/m³
Gas filter requirement max. mesh size 50 µm
Admissible concentration of (H2S)
hydrogen sulphide max. 0.1 %
Fuels might not hold any corrosive constituents. If in doubt consult HEINZMANN
See below for detailed specifications of single components.
Performance Range:
E-LES 30-x: 80 kW (landfill gas) ... 250 kW (propane)
E-LES 50-x: 250 kW (landfill gas) ... 800 kW (propane)
E-LES 80-x: 800 kW (landfill gas) ... 2500 kW (propane)
The indicated performance ranges are based on an assumed engine efficiency of 35%.
assumed calorific value (Hu): natural gas: 34 MJoule/nm³landfill gas: 18 MJoule/nm³
propane: 90 Mjoule/nm³
The volume flow rate of the E-LES gas valve depends on the gas mixer and its design. The
indicated performance range is valid only if the gas valve design is done by
HEINZMANN. For applications combined with other gas mixers the volume flow rate can
be 50% lower.
2.5 Operational Principle
The basic components of a conventional gas mixing system are:
• Gas mixer
• Main Adjusting Screw (MAS)
• Zero pressure regulator (ZPR)
Gas-air-fuel-ratio is determined essentially by the configuration of the gas mixer. On con-
dition that the output pressure of the zero governor (ZPR) always corresponds to the air in-
put pressure of the gas mixer, the air-fuel-ratio remains constant for different volume flowrates or engine loads. In practice, gas bores are chosen slightly greater than theoretically
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2 General
KRONOS 20 7
necessary. This results in a greater influence of the main adjusting screw which is able to
regulate the air-fuel-ratio within a limited range.
Theoretically it is possible fit gas bores on a Venturi tube in a way to cover the whole calo-
rific value range for an application, e.g. from propane to landfill gas, as long as there is a possibility to compensate the differences relating to calorific value, air-fuel-ratio and gas
density with the volume flow control.
This means that a MAS with a definite relation between valve position and opening cross-
section may be placed in a way to obtain a desired air-fuel-ratio. But usually mixers for a
specific gas quality are designed to give the gas control valve only limited adjusting au-
thority.
A digitally controlled MAS like the HEINZMANN E-LES (digital lambda adjustment
screw) that receives its inputs from a speed and load dependent map and reacts to gas pres-
sure and mixture temperature variations, makes it possible to obtain an ideal gas-air mix-
ture under all operating conditions.
Based on measured signals such as engine speed, inlet manifold pressure, mixture tempera-
ture as well as on programmed parameters such as engine displacement and volumetric ef-
ficiency the mixture flow may be calculated. The stored gas data and the mixer and gas
valve characteristics allow to calculate current pressure conditions and gas flow. This al-
lows a mixture control according to the physical model of a Venturi based system.
The valve cross-sectional area calculated by the control unit and the according valve posi-
tion are adjusted accordingly by a stepping motor.For engines of the same type no different parameter settings are required. In case of differ-
ent gas quality only the gas bores must be adapted.
2.6 General Application
The gas valve E-LES may be used for the following applications:
• As conventional MAS
In this application, the parameters relating to the desired valve position / gas valvecross-sectional opening area are set to the desired parameter value. Different settings
may be implemented and reproduced simply by changing the parameter. Non mechani-
cal adjustments are required. This mode of operation can be convenient when gas type
changes frequently. The right to effect changes may be limited by assigning specific
permissions. The settings may be changed via a remote connection.
• As Positioner The desired valve position / gas valve cross-sectional opening area are adjusted by the
control unit according to a set value derived from an external control (current / voltage
signal). This allows to include the system in an external lambda regulating system.
• As stand-alone Gas Mixture Control System
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2 General
8 KRONOS 20
In connection with the gas mixer, the valve functions as an ideal lambda control system,
with a freely programmable lambda map in dependence of speed and load. In an ex-
tended closed-loop version it allows compensation for changes in gas quality and envi-
ronmental factors. This makes it possible to use biogas with minimal emissions.
Figure 1: KRONOS 20 System
2.7 Additional Functions
• Engine Stop On activation of the digital input for engine stop, the gas valve will be completely
closed in dependence of the parameter settings until the engine stops. But usually the
engine will be stopped by closing the gas shut-off valve on the gas train.
• Overspeed Protection Overspeed may be set in a parameter. If this overspeed is exceeded the control unit
emits an alarm and closes the gas valve.
• Operating Hours Counter Sums up the hours during which the engine runs (speed is recognized). In addition the
number of engine starts is registered.
• Error Diagnosis and Error Messages
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2 General
KRONOS 20 9
In case of sensor error, an alarm is given and, if necessary, the system goes in emer-
gency operation or closes the valve, thereby stopping the engine. Internal errors are also
recognized and are saved like all other errors. All errors can be extracted with an exter-
nal handheld programmer or, if the communications software is installed and a cable
available, read out to a PC / laptop computer.
• Communication Serial interface for the HEINZMANN communications programme DcDesk 2000 or for
a handheld programmer (HEINZMANN communications cable required).
A CAN interface is available for communication with other HEINZMANN control units
and, if adequately configured, allows communication with external devices such as SPS.
In this way the system may be integrated flexibly in a comprehensive engine manage-
ment solution.
• Optional Misfire Detection As an option, expanded software for misfire detection is available.
2.8 Gas Train
The components of the gas train such as magnetic valve, gas filter and, in particular, zero
pressure regulator constitute a unity in an optimally working system of gas regulation.
HEINZMANN is very experienced in this context and able to design and deliver according
gas train with the according certificate.
In principle, a standard zero pressure regulator may be used. The starting pressure of the
governor must be adjustable within a range from 0 to +25 mm water column (2.5 mbar).
The ideal starting pressure is usually determined with start tests. A good starting value is 5
mm water column. The determined value must be entered in the list of parameters. The
unit of the value to enter is Pa (25 mm H2O = 250 Pascal).
Most pressure regulators are subject to wear and sensitive against vibrations. Therefore
HEINZMANN recommends to attach the governor not to the engine but to the frame. The
pressure governor is not included in the standard scope of delivery of the KRONOS 20
system. On request, it can be delivered by HEINZMANN or a specific pressure regulatorcan be recommended by HEINZMANN.
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3 Sensors
10 KRONOS 20
3 Sensors
3.1 Overview Table
Sensor SpeedIntake Mani-
fold Pressure
Intake Manifold
Temperature
λ Sensor
(optional)
HZM name IA .. P/T-S-01 LSM 11
Connection SV 6-IA-2K2 pin
Pressure sensor connector 4 pins
Measuringmethods
inductive,active
piezo resistance,active
NTC, passive electrochemical
Measuring range 50..9,000 Hz 0.2..3.0 bar abs. -40 to +130°C 1.00..2.00
Power supplyrange
4.5..5.5 V DC 12..13 V AC/DC
Output signalrange
0..10 V AC 0.3..4.8 V 0..50 kOhm 0..900 mV
Operating tem- perature range
-8 to +120°C -40 to + 130°C up to + 800°C
In order to allow sufficient flexibility and comparability of sensors, the min./max. values of
pressure sensors and temperature sensors are programmable.
3.2 Speed Pickup IA…
3.2.1 Technical Data
Operating principle inductive sensor
Distance from measuring wheel 0.5 to 0.8 mm
Output 0 V to 12 V AC
Signal type sine (depending from tooth shape)
Resistance approx. 52 Ohm
Temperature range
housing -8°C to +120°C
cable -5°C to +80°C
Protection grade IP 55
Vibration < 10g, 10 to 100 Hz
Shock < 50g, 11 ms half sine
Connector used SV 6 - IA - 2K (EDV-No: 010-02-170-00)
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3 Sensors
KRONOS 20 11
3.2.2 Mounting Position
The mounting position of the speed pickup must be such as to allow a frequency as high
as possible. The HEINZMANN digital control of the KRONOS 20 series is normally
designed for a frequency of max. 9,000 Hz. Frequency may be calculated as follows:
f (Hz) =n z( / min) *1
60
z = number of teeth on impulse wheel
Example:
n = 1,500
z = 160
f = 60
160*1500 = 4,000 Hz
In addition, attention should be paid that the sensor can pick up the speed
without alteration, e.g. by being mounted on the starter gear of the flywheel.
The pickup wheel must be made of magnetic material (e.g. steel or cast iron).
3.2.3 Tooth Shape
Tooth shape is optional. The top width of the tooth should be 2.5 mm minimum, the
width and depth of the gap at least 4 mm. For a perforated disk the same measurements
apply.
A radial position of the speed pickup is preferable for tolerance reasons.
3.2.4 Distance of the Speed Pickup
Distance of the speed pickup to the top of the teeth should be approx. 0.5 to 0.8 mm.
(the speed pickup can be screwed onto the top of the tooth and screwed back approx.
half a revolution.)
Note
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3 Sensors
12 KRONOS 20
mind.4mm
mind. 2.5mm
mind. 4mm
0.5-0.8mm
Figure 2: Distance of the Speed Pickup
3.2.5 Dimensional Drawing
G
L 35
19
Figure 3: Dimensions of the Speed Pickup
UnitType
L(mm) G Notes
01 - 38 38 M 16 x 1.5
02 - 76 76 M 16 x 1.5 connector
03 - 102 102 M 16 x 1.5 used
11 - 38 38 5/8"-18UNF-2A SV6-IA-2K
12 - 76 76 5/8"-18UNF-2A (010-02-170-00)
13 - 102 102 5/8"-18UNF-2A
The according name for ordering is e.g., IA 02-76.
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KRONOS 20 13
3.2.6 ATEX Certification of Speed Pickups
All speed pickups described in the previous chapters are ATEX-certified according to
EN 50021:1999 flame proof protection type "n". If the speed pickups are used in such
an ambient and require an ATEX certificate, the wiring of the pickup must be done anddelivered by HEINZMANN too. In this case, HEINZMANN will attach the following
information sign to the wire close to the speed pickup plug:
HEINZMANN GmbH & Co. KG Germanywww.heinzmann.de Tel.: +49 7673 8208-0Type: z.B. IA 02-76, II3G Ex nA II T4
Tcable: -5°C to +80°C, Thousing: -8°C to +120°CTÜV 06 ATEX 552893
WARNING - EXPLOSION HAZARD -DO NOT DISCONNECT WHILE CIRCUIT
IS LIVE UNLESS AREA IS KNOWNTO BE NON-HAZARDOUS
Figure 4: Information Sign on Speed Pickup Cable, Front and Back
3.3 Double Sensor P/T-S-01 for Pressure and Temperature Measurement in
Intake Manifold
3.3.1 Technical Data
Power supply 5±0.5 V
Current consumption 6..12.5 mA at 5 V
EMI 100 V/m
Operating temperature range -40°C to +130°C
Storage temperature -40°C to +130°C
Protection grade IP 55
Part-no.: 600-00-082-00
Used cable pressure sensor cable
(part-no.: 600-81-045-..)
Pressure Sensor
Pressure range 0.2..3 bar abs.
Tolerance ±1,5 %
Signal voltage 0.3..4.8 V linear
Response time10/90 1 ms
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The sensor housing is connected to the negative pin of the sensor
output. In unfavourable conditions, ground circuit loops may hap-
pen that falsify the output signal considerably and thus disturb con-
trol activity. This must be taken into account during commissioning.
It may be necessary to optimize the wiring or to use a galvanic sepa-
ration.
Warning
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KRONOS 20 17
3.4.2 Dimensional Drawing
12
22,6
M18x1,5
1 0 , 5
2 8 , 2
21,8
SW 22
6 6
2 5 0 0
2 3 0 0
7 3
Figure 7: Dimensional Drawing λ Sensor LSM 11
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4 Control Unit KRONOS 20
18 KRONOS 20
4 Control Unit KRONOS 20
4.1 Technical Data
4.1.1 General
Power supply 12 V DC or 24 V DC
Min. voltage 10 V DC
Max. voltage 32 V DC
Residual ripple max. 10 % maximum at 100 Hz
Current consumption max. 1 A
Admissible voltage drop
at max. power consumption max. 10 % at control unit
Fuse 6 A
Storage temperature -40°C to +85°C
Operating temperature -40°C to +80°C
Air humidity up to 98 % at 55 °C
Vibration max. 2 mm at 10..20 Hz
max. 0.24 mm at 21..63 Hz
max. 9 g at 64..2000 Hz
Shock 50 g, 11 ms, half sine
Protection grade IP 00
Isolation resistance > 1 MOhm at 48 V DC
Weight approx. 0.5 kg
EMC 89/336/EEC and 95/54/EEC
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4 Control Unit KRONOS 20
KRONOS 20 19
4.1.2 Inputs and Outputs
All inputs and outputs are reverse polarity protected and short-circuit-proof against bat-
tery plus and minus.
Temperature input (terminal 4) for PT1000 / Ni1000 sensors
Tolerances: < ±2°C at 0°C to 130°C,
otherwise < ±4°C
Reference voltage for P-/T sensor Uref = 5 V ±1 %, Iref < 30 mA
(terminal 6)
Closed loop input (terminal 7) U = 0..5 V, R e = 100 k Ω, f g = 15 Hz
or I = 4..20 mA
Digital input (terminal 9) U0 < 2 V, U1 > 6.5 V, R pd = 100 k Ω
Digital input engine stop U0 < 2 V, U1 > 6.0 V R pd = 4.75 k Ω
(terminal 11) or R pu = 4.75 k Ω or R pd = 150 k Ω
Speed input (terminal 13) for inductive sensors, with
f i = 25 to 9000 Hz, Ui = 0.5 to 30 V AC
MAP pressure input (terminal 16) U = 0..5 V, R e = 100 k Ω, f g = 15 Hz
Control outputs for gas valve Isink < 0.3 A, Urest < 1.0 V, Ileak < 0.1 mA
(terminals 1 and 2) R pu = 4.75 k Ω or R pu = ∞, low-side switching
Digital output error lamp Isink < 0.3 A, Urest < 1.0 V, Ileak < 0.1 mA
(terminal 10) R pu = 4.75 k Ω or R pu = ∞, low-side switching
Serial interface ISO 9141, variable from 2.4 kbit/s to 57.6 kbit/s
Standard 9.6 kbit/s
CAN bus (terminals H and L) HEINZMANN-CAN or customer specification
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4 Control Unit KRONOS 20
20 KRONOS 20
4.2 Dimensional Drawing
84,5
1 6
1 6 5
112
3 0
Am Haselbach 1
D-79677 Schönau/Germany
Phone: +49 (7673) 8208-0
Fax: +49 (7673) 8208-188
R
1 9
1 8
T
1 7
1 5
1 4
1 3
1 2
1 1
1 0
9
8
7
6
5
4
H
L
1
2
3
1 6
2 0
2 1
C A NH
C A NL
P 2
P 1
0 V
T m p
0 V
+ 5 V
S pA
0 V
S pD
E r r
S t p
0 V
P u
0 V
F b C
F b M
F b R
0 V
+ A c t -
-B a t t +
GND
GND
GND
REF
GND
GND
MAP
GND
STOP/DI
+
-
CANH
CANL
6 A
S e r i a l N o .
T y p e - N o . V
PH 2
PH 1
MAT
CL-IN
4 5
118,5
5
4 0
K R O
N O S 2 0 -A 2 2
2 1
2 0
1 9
1 7
1 6
1 5
1 4
1 3
1 2
1 1
1 0
9
8
7
6
1
2
3
4
5
1 8
2 3
2 4
c l o s e
d l o o pv er s i on
Figure 8: Dimensional Drawing of Control Unit KRONOS 20 with Power Signal Input
The fastening element for top-hat-rail in the above drawing is available on re-
quest.Note
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4 Control Unit KRONOS 20
KRONOS 20 21
84,5
1 6
1 6 5
112
3 0
Am Haselbach 1
D-79677 Schönau/Germany
Phone: +49 (7673) 8208-0
Fax: +49 (7673) 8208-188
R
1 9
1 8
T
1 7
1 5
1 4
1 3
1 2
1 1
1 0
9
8
7
6
5
4
H
L
1
2
3
1 6
2 0
2 1
C A NH
C A NL
P 2
P 1
0 V
T m p
0 V
+ 5 V
S pA
0 V
S pD
E r r
S t p
0 V
P u
0 V
F b C
F b M
F b R
0 V
+ A c
t -
-B a t t +
GND
GND
GND
REF
GND
GND
MAP
GND
STOP/DI
+
-
CANH
CANL
6 A
S e r i a l N o .
T y p e - N o . V
PH 2
PH 1
MAT
CL-IN
4 5
118,5
5
4 0
K R O
N O S 2 0 -A -sensor
Heating 2 2
2 1
2 0
1 9
1 7
1 6
1 5
1 4
1 3
1 2
1 1
1 0
9
8
7
6
1
2
3
4
5
1 8
2 3
2 4
1 - c l
o s e d l o o pv er s i on
Figure 9: Dimensional drawing of control unit KRONOS 20 with λ sensor input
The fastening element for top-hat rail in the above drawing is available on re-
quest.Note
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4 Control Unit KRONOS 20
22 KRONOS 20
4.3 Mounting Position
When the mounting position is chosen, attention should be paid to easy accessibility of the
connection terminals and to the possibility of having to substitute the unit on site. Mount-
ing position is optional. When the unit is mounted directly on the engine, it must be fas-tened to vibration dampeners.
The control unit is available with or without fastener for top-hat rail mounting.
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5 Gas Valves E-LES
KRONOS 20 23
5 Gas Valves E-LES
5.1 Structure and Operating Principle
The stepping motor drives a spindle with external thread. The teflon-coated aluminium pis-ton with internal thread moves in line with the rotation of the spindle. The special thread-
ing prevents play between spindle and piston threads. The piston moves within a coated
bushing. This bushing features three exponentially shaped intake openings. This profile al-
lows a gas flow change linear to the stepping motor position. Due to this design, only the
forces of friction of the valve itself act on the piston. The shaft of the stepping motor is
sealed against gas leakage.
The control electronics of the stepping motor is mounted directly onto the gas valve and is
controlled by the KRONOS control unit with a special bit pattern via 2 digital outputs. This
type of control in principle allows the use of different HEINZMANN control units for dif-
ferent purposes.
Immediately after energizing the system or after a reset the stepping motor carries out a
reference run towards stop to determine the zero position. This may take up to 8 seconds,
depending on the system’s dimensions. The system is ready for operation only after the
reference run is completed.
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5 Gas Valves E-LES
24 KRONOS 20
5.2 Technical Data
All inputs and outputs are reverse polarity protected and short-circuit-proof against battery
plus and minus.
5.2.1 Specifications for all E-LES Gas Valves
Power supply 12 V DC or 24 V DC
Min. voltage 10 V DC
Max. voltage 32 V DC
Residual ripple max. 10 % at 100 Hz
Current consumption max. 1.5 A
Admissible voltage drop max. 10 %at max. power consumption
Fuse 6 A
Stepping motor frequency 500 Hz
Storage temperature -40°C to +85°C
Ambient temperature during operating -20°C to +80°C
Air humidity up to 98 % at 55°C
Admissible pressure of fuel supply max. 0.1 barAdmissible concentration of
hydrogen sulphide (H2S) in fuel max. 0.1 %
Vibration max. 2 m/s at 10..20 Hz
max. 0.24 m/s at 21..63 Hz
max. 9 g at 64..2000 Hz
Shock 50 g, 11 ms, half sine
Protection grade IP 55
EMC 89/336/EEC and 95/54/EEC
Connection DIN 45321; 7 pin male
Gas valves E-LES might only be used as control valves!
Never use as shut-off valve!Warning
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5 Gas Valves E-LES
KRONOS 20 25
5.2.2 Additional Specifications for Gas Valve E-LES 30
Valve resolution 1200 steps at 6 revolutions
Positioning time for 0..100% 2.5 seconds
Weight approx. 1 kg
5.2.3 Additional Specifications for Gas Valve E-LES 50
Valve resolution 2000 steps at 10 revolutions
Positioning time for 0..100% 4 seconds
Weight approx. 1.8 kg
5.2.4 Additional Specifications for Gas Valve E-LES 80
Min. voltage 18 V DC
Valve resolution 3800 steps at 19 revolutions
Positioning time for 0..100% 8 seconds
Weight approx. 12 kg
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5 Gas Valves E-LES
26 KRONOS 20
5.3 Dimensional Drawings
6 0
1
2
34
5
6
7
GND
+UB
Ph1
Ph2
M 5
M 5 M5 M5
4832
138
4 8
4 8
94
32
48
60
4 2 , 5
10
DO NOTDISCONNECT WHILE CIRCUIT IS LIVE UNLESS AREA IS KNOWN TO
BE NON-HAZARDOUS!
WARNING - EXPLOSION HAZARD
BEFORE REMOVING THE COVER, SWITCH OFF THE POWER SUPPLYANDWAIT AT MINIMUM 5 SECONDSTO DISCHARGE THEENERGY OF
THE CAPACITIES!
Figure 10: Dimensional Drawing E-LES 30
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28 KRONOS 20
1
2
34
5
6
7
GND
+UB
Ph1
Ph2
8 0
2 0 0
3 3 6
1 0 5
1 2 5
130
76
226
Connection flange fitting towelding-neck flange accordingto DIN 2633 PN 16 DN 80
Figure 12: Dimensional Drawing E-LES 80
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5 Gas Valves E-LES
KRONOS 20 29
5.4 Mounting
The gas fittings of E-LES 50 have 2" B.S.P. threads. The gas valve may therefore option-
ally be screwed directly onto the gas mixer. The used standard pipe threads allow easy
connection to all common gas pipes. To reduce vibration it is recommended to mount thegas valve at the end of the gas piping and to connect it to the gas mixer with a flexible
tube. The passage between gas piping and gas mixer must always be flexible.
The axial connection of the valve is usually used as gas inlet, the radial connection as gas
outlet.
The type E-LES 80 features connection flanges as shown in the above drawing. They cor-
respond to standard flanges, as they are common for pipe diameters greater than 2".
The type E-LES 30 also has flange fastenings. They can be extended with threaded flanges.
To safeguard error-free and low-wear operation, a gas filter with maximum mesh of 50 µmmust be installed in the gas piping.
All work on the valves must be carried out exclusively by trained per-
sonnel and in conformity with current standards and requirements.
The mounting position must be chosen in a way to avoid vibration and pulsation as much
as possible.
In addition, the valve’s mounting position must be chosen depending on the protection
type.
In general, mounting position is optional. But it should be avoided to mount the valves up-
side down with the step motor directed downward. If this mounting position should be
necessary consult HEINZMANN.
The gas valve must be equipped with sufficient equipotential bonding. On the gas valve a
screw with M6 thread is provided for the this kind of connection.
5.5 ATEX Certification of E-LES… Gas Valves
E-LES gas valves are ATEX certified according to EN 50021:1999, type of protection "n".
If the gas valves are used in such a context and require an ATEX certificate, the wiring of
the gas valve must be done and delivered by HEINZMANN too.
The inside of the gas-containing parts has not been taken into account for the
ATEX valuation.
On the housing of the E-LES gas valves two stickers have been applied. An additional
warning sign has been applied to the cover of the stepping motor control.
Warning
Note
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5 Gas Valves E-LES
30 KRONOS 20
Sign 1 shows the general and ATEX-relevant information.
HEINZMANN GmbH & Co. KGGermany Tel.: +49 7673 8208-0
www.heinzmann.com
II3G EEx nA II T4Tamb: -20°C to +80°CTÜV 07 ATEX xxxxxx
Figure 13: Sign bearing general and ATEX-relevant Information
Sign 2 bears the exact type designation and serial number.
Type: z.B. E-LES 50Serial No: yy mm xxxx-zz
Figure 14: Sign with Type Designation and Serial Number
Sign 3 on the control cover contains warnings about disconnecting the plug and re-
moving the cover.
DO NOT DISCONNECT WHILE CIRCUIT IS LIVE UNLESS AREA IS KNOWN TO
BE NON-HAZARDOUS!
WARNING - EXPLOSION HAZARD
BEFORE REMOVING THE COVER, SWITCH OFF THE POWER SUPPLYAND WAIT AT MINIMUM 5 SECONDS
TO DISCHARGE THE ENERGY OF THE CAPACITIES!
Figure 15: Warning Sign on E-LES Stepping Motor Control Cover
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6 Electric Connection
KRONOS 20 31
6 Electric Connection
All wiring must be carried out exclusively by trained personnel and in
conformity with current norms and regulations.
The electric connection must be done in accordance with the wiring diagrams provided by
HEINZMANN and by the plant builder. Only specified cable types may be used for wiring.
All indicated cable cross-sections must be adhered to at all costs.
The control valve is controlled by a HEINZMANN control unit. In special
cases the control valve may be connected to a third party control unit of
the plant builder. In this case an express authorization by HEINZMANN
is required. The specification provided by HEINZMANN must be adhered
at all costs.
Warning
Warning
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6 Electric Connection
32 KRONOS 20
6.1 Wiring Diagrams
6.1.1 Wiring Diagram for KRONOS 20 with open Loop
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21
12/24 V
21
5
6
KRONOS 20
E-LES
Electronicallycontrolled MAS
Battery
Fuse6 A
Governor on
Control Unit
Engine Stop
Common Alarm
3
4
7
3
2
4
1
Boost Pressure Sensor
Temperature Sensor
A
B
Magnetic Pickup IA ..
542 3
T x D
R x D
24V0V
Connection toProgrammer
or PC
1
SUB-D plug 9-pole
TH L
Figure 16: Wiring Diagram for KRONOS 20 with open Loop
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6 Electric Connection
KRONOS 20 33
6.1.2 Wiring Diagram for KRONOS 20 with closed Loop
(power signal, CH4 signal)
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21
12/24 V
2
1
5
6
KRONOS 20
E-LES
Electronicallycontrolled MAS
Battery
Fuse6 A
Governor on
Control Unit
Engine Stop
Common Alarm
34
7
3
2
4
1
Boost Pressure Sensor
Temperature Sensor
A
B
Magnetic Pickup IA ..
Load Signalor CH4-Signal
542 3
T x D
R x D
24V0V
Connection toProgrammer
or PC
1
SUB-D plug 9-pole
2
1
TH L
Figure 17: Wiring Diagram for KRONOS 20 with closed Loop
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6 Electric Connection
34 KRONOS 20
6.1.3 Wiring Diagram for KRONOS 20 with λ -Sensor Signal
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21
12/24 V
2
1
5
6
KRONOS 20
E-LES
Electronicallycontrolled MAS
Battery
Fuse6 A
Governor on
Control Unit
Engine Stop
Summenalarm
3
4
73
2
4
1
Boost Pressure Sensor
Temperature Sensor
A
B
Magnetic Pickup IA ..
Lambda-Signal
542 3
T x D
R x D
24V0V
Connection toProgrammer
or PC
1
SUB-D plug 9-pole
black +
grey -
TH L
white
whiteHeater for Lambda-Sensor
Figure 18: Wiring Diagram for KRONOS 20 with closed Loop and λ -Sensor Signal
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6 Electric Connection
KRONOS 20 35
6.2 Cable Harness
W1
Battery
E-LES
Temperature- / Pressure Sensor
Magnetic Pickup
Closed Loop Input
Digital Inputs
Error Indicators
Communication
W2
W3
W4
W6
W7
W10
+ -
M
Control Unit
KRONOS 20
W5
Figure 19: Cable designations
W 1 power supply max. length 15 m 2 x 1.50 mm²
W 2 gas valve control max. length 15 m 4 x 0.75 mm²
W 3 pressure / temperature sensor max. length 15 m 4 x 0.75 mm²
W 4 speed pickup 2 x 0.75 mm²
W 5 actual power signal or λ -sensor signal max. length 15 m 2/4 x 0.75 mm²
W 6 motor stop switch 1 x 0.75 mm²
(the switch must be powered with +24V)
W 7 error message 1 x 0.75 mm²
(the switch must be powered with +24V)
W 10 communication max. 20 m (at 9600 baud) 4 x 0.14 mm²
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36 KRONOS 20
6.3 Enclosed Cables
The following cables will be provided by HEINZMANN in the required length.
6.3.1 Cable W2 to Gas Valve E-LES
1
2
34
5
6
7
GND
+UB
Ph1
Ph2
L e n g t h o n r e q u e s t ( m a x . 1 5 m )
Housing
2
1
21
20 1
2
4
5
Ground
+UB
Phase 2
Phase 1
Screen
brown
green
yellow
white
Terminal Plug Pin Function Colour
Terminal Assignment of Cable
Figure 20: Cable W2
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6 Electric Connection
KRONOS 20 37
6.3.2 Cable W3 to Pressure / Temperature Sensor P/T-S-01
L e n g t h o n r e q u e s t ( m a x . 1 5 m )
Housing
166
4
15 1
2
34
Ground
NTC Signal
+ 5VPressure Signal
Screen
brown
white
greenyellow
Terminal Plug Pin Function Colour
Terminal Assignment of Cable
Figure 21: Cable W3
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38 KRONOS 20
6.3.3 Cable W4 to Speed Pickup IA…
L e n g t h o n r e q u e
s t ( m a x . 1 5 m )
Housing
1312 A
B SignalGround
Screen
12
Terminal Plug Pin Function No.
Terminal Assignment of Cable
Figure 22: Cable W4
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6 Electric Connection
KRONOS 20 39
6.3.4 Cable W5 to λ -Sensor LSM 11
19
18
8
7 Sensor +
Sensor -
Heater
Heater
yellow
green
white
black
Terminal Function Colour
Terminal Assignment of Cable
yellow white brown
A
A
green
L e n g t h o
n r e q u e s t ( m a x . 1 5 m )
1 5 0
6 0
Figure 23: Cable W5 for λ -Control
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HEINZMANN®
Fehler! Verweisquelle konnte nicht gefunden werden. Fehler! Verweisquelle konnte nicht gefunden werden.
40 KRONOS 20
7 Parameter Settings for Control Unit KRONOS 20
The software for the HEINZMANN digital controllers conceived so that parametrizing can be
done either by the engine manufacturer or by the final customer if the necessary instruments
(communications tool) are available. Only a few basic parameters are pre-set in theHEINZMANN factory. This means that the digital governor usually gets its definitive set of
data from a source external to HEINZMANN.
An exception is made for control units delivered in greater numbers. If HEINZMANN has
been provided in advance with a definitive set of data, this data can be trasferred to the units
in the factory.
As a principle, initial programming should always be conducted by experienced personnel and
must be checked before first commissioning the engine.
How parameter are adjusted and what meaning they have is explained in detail in the manual"Basic information 2000".
The following sections describe the possibilities of parametrizing the control unit:
7.1 Parametrization with the Hand Held Programmer 3
All parametrization can be done by means of the hand held programmer ‘Programmer 3’.
This handy device is particularly suited for development and series calibration as well as
for servicing. This unit needs no external power supply.
7.2 Parametrization with the PC / Laptop
Parametrization can also be conducted using a PC and the comfortable HEINZMANN
communication software DcDesk 2000. As compared with the hand held programmer, it
offers the great advantage of having various curves graphically represented on the screen
and being at the same time able to introduce changes as well as of having time diagrams
displayed without an oscilloscope when commissioning the control unit on the engine. Fur-
thermore, the PC offers a better overview as the PC programme has a menu structure and
allows to have several parameters continuously displayed.
Besides, the PC programme permits to save and download the operational data to and from
data mediums. Additional there is the following usefull application:
Once parameterization has been completed for a specific engine type and its application,
the data set can be stored to disk. For future applications of similar type, the data sets
can be downloaded and re-used with the new control units.
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KRONOS 20 41
8 General Mounting Instructions
All components must be mounted in a vibration-free manner.
All screws must be tightened.
All components must be connected to equipotential bonding.
All components must be installed only in the allowed areas.
All components must be installed in a way to protect their connectors from impact damage.
The inside of the components (gas containing parts) is not part of the ATEX speci-
fication.
Note
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9 Commissioning
42 KRONOS 20
9 Commissioning
9.1 General Safety Information for Commissioning
All commissioning tasks must be carried out exclusively by trained per-
sonnel and in conformity with current standards and regulations.
The operator is also responsible for putting the technical installation as a whole into opera-
tion correctly.
Before commissioning the installation, please note:
• Before starting to install any equipment, the installation must have been switched off!
• Check the function ability of the existing protection and monitoring systems.
The system may be put into operation only if the terminal box cover is mounted.
9.2 General Information on the first Engine Start
• Adjust speed pickup distance according to the instructions.
• Verify that the software is correct and the main parameters: engine data, number ofteeth, mixer data, gas valve data, sensor data, gas data, lambda data etc.!
• If required, adjust sensors.
• Before the engine is started, test the electric connections and the basic functioning ofthe system in positioning mode (parameters 5705 and 5706)!
• It is recommended to begin by starting the engine first without connecting a controlunit.
Ensure adequate overspeed protection!
• Start the engine after pre-setting according to the description below.
• Optimization of lambda map and correction values as described below.
Knock protection must be active or attention must be paid to audible
knocking.
Warning
Warning
Danger
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9 Commissioning
KRONOS 20 43
9.3 Commissioning for OPEN LOOP (open control circuit)
In order to obtain a satisfactory control behaviour of the AFR system in an open control
circuit the set lambda values must not necessarily be equal to the actual measured values.
The same holds true for other values, such as calculated gas flow and pressure in relationto the respective measured values. The control quality of the open loop system as a whole
is not prejudiced by these differences. Example: If there is no measuring device for lambda
measuring but a measuring device for the adjustment of NOx content in the exhaust gas is
available instead, the commissioning personnel does not need to know the actual lambda
value in order to carry out a satisfactory adjustment of the system.
Still in Open Loop too, it is advisable to carry out the correct adjustment of the AFR sys-
tem if the required devices are available. The clear structures of the respectively relevant
parameters allows an easy and understandable commissioning and fine-tuning and reduces
errors.
For a correct diagnosis, state monitoring and for the operation with a closed loop a com-
plete calibration is necessary. The actual measured values must correspond to the variables
and set values of the mixture control. For this calibration the following devices are re-
quired:
• A universal lambda sensor or an oxygen analyzer for exhaust gas in connection with avalid conversion table from O2 % to lambda.
• A gas flowmeter for the measurement of nm3/h (standardized measurement at 1013.25mbar and 0° C). If gas quality and engine efficiency are known, the produced electric
power may be used instead to approximately determine gas flow. Qgas [nm3/h] =
(power [kW] x 3600)/(ηset x Hu[kJ/nm3]).
After the parameters have been determined and set, the engine may be started and load ap-
plied gradually. In order to avoid misfiring, ingnition failures and knocking and to adjust
the desired NOx value, continuous corrections of the set lambda value in dependence of
load and speed are necessary.
Adequate adjustment of the zero pressure regulator is particularly important during start-
up! Pressure offset should not normally be higher than + 2..3 mbar to ensure a safe enginestart. Experience shows that this is where errors frequently happen.
After engine warm-up the AFR control must be verified in open loop (5400 ClosedOrO-
penLoop=0) and with different load-points according to the following procedure:
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44 KRONOS 20
A) The desired lambda value must correspond roughly to the measured lambda
value
(calibration of 1424 VenturiEfficiency)
Due to variations in the engine and the gas train the venturi suction pressure not alwaysgenerates the same gas flow in relation to air flow. The measured lambda value therefore
not always corresponds to the set lambda value, although the mixture in not too rich or too
lean for the engine. The adjustment should be carried out with an upper load point.
If λ mea (measured value) = λ des (3462 LambdaDesiredValue),
(within ± 2 %), then continue with B)
If λ mea < λ des then:
1. Increase ηvent (1424 VenturiEfficiency) until λ mea = λ des or until the engine misfires orthe engine power drops.
2. λ mea increases (engine runs on leaner mixture). Example: was λ mea =1.70 and nowchanges to λ mea =1.75
3. Change λ set (7400-7599 LambdaMap) in the respective load/speed point. Example:was λ set = 1.75 and is now changed to λ set = 1.70
4. Verify the lambda values
5. If λ mea < λ des repeat steps 1 to 4
When λ mea > λ des then:
1. Reduce ηvent (1424 VenturiEfficiency) until λ mea = λ des or to the lower ignition limit.Attention, danger of knocking!
2. λ mea is reduced (engine runs on richer mixture). Example: was λ mea=1.70 and nowchanges to λ mea=1.65
3. Change λ set (7400-7599 LambdaMap) in the respective load/speed point. Example:was λ set =1.65 and now is changed to λ set = 1.70
4. Verify the lambda values
5. If λ mea > λ des repeat steps 1 to 4
B) Measured gas flow must correspond roughly to calculated gas flow
(calibration of 9420 - 9483 VolEffMap or 1412 VolEfficiencyConst )
Depending on different engine settings and operational conditions, volumetric efficiency
and therefore the calculated mixture flow may vary. This may lead to a difference between
the effective and the calculated gas flow. There is a fixed relation between calculated mix-
ture flow and calculated gas flow. This relation is based on the gas data and the desired
lambda. The calibration is started with rated power and repeated at three other load points.
It is advisable to calibrate the map.
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If Qgasmea (measured value) = Qgascal (3453 GasFlowRateDesired ),
(within ± 2 %), then continue with C)
If Qgasmea < Qgascal then:1. Reduce ηvol (9420 - 9483 VolEffMap or 1412 VolEfficiencyConst) at the current loadand speed point of the map until Qgascal = Qgasmea.
If Qgasmea < Qgascal then:
1. Increase ηvol (9420 - 9483 VolEffMap or 1412 VolEfficiencyConst) at the current loadand speed point of the map until Qgascal = Qgasmea
2. Repeat this calibration for the other three load points, e.g., 80 %, 60 % and 40 % load.
3. Interpolate the missing values in the volumetric efficiency map (9420 - 9483 VolEff-
Map) at rated speed and verify and, if necessary, calibrate the values at other speeds.By changing Venturi efficiency (A) or volumetric efficiency (B) the quantity and the mix-
ing ratio of the gas mixture have been calibrated.
9.4 Further Commissioning for CLOSED LOOP (closed control circuit)
with Output Power
In order to obtain a good regulation of the mixture control in a closed control circuit the
desired lambda values (λ des (3462 LambdaDesiredValue)) must not necessarily correspond
to the actual measured values (λ cal (3463 LambdaActualValue)). Variations up to± 20 % are acceptable. This is also true for other values, such as calculated gas flow rate
(Qgascal (3453 GasFlowRateDesired )), calculated generator power (Pcal (3411 Calculated-
Power )) and mechanical generator efficiency (ηset (9500-9583 MechEffMap or 1413
MechEfficiencyConst )) in relation to the respective measured values. The quality of the
open loop and of the closed loop systems as a whole is not prejudiced by these differences.
Example: If no measuring device is available for measuring the λ value, but measuring de-
vices for the adjustment of NOx emissions and/or oxygen content ratio are available in-
stead, a satisfactory adjustment of the system is possible without knowing the effective λ
value.
The parameter values pre-set by HEINZMANN usually lead to a satisfactory control result
both for open loop and for closed loop and constitute a good starting point for fine tuning.
C) Measured generator output power must correspond roughly to effective genera-
tor output
(calibration of 2914 MeasuredPower )
If Pmea (measured value) = Pact (2914 MeasuredPower),
(within ± 2 %), then continue with D)
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If the variation is greater:
change the reference values (988 MeasPowerSensorLow and 989 MeasPowerSensorHigh)
of the power sensor input signal at different loads so that Pmea = Pact
D) The calculated lambda value must correspond roughly to the desired lambda
value
(calibration of 9500 - 9583 MechEffMap or 1413 MechEfficiencyConst )
If λ cal (3463 LambdaActualValue) = λ des (3462 LambdaDesiredValue),
(within ± 1 %), then continue with E)
Whenλ
cal <λ
des then:1a. Increase ηset (9500 - 9583 MechEffMap or 1413 MechEfficiencyConst ) at the according
load point in the generator efficiency table until λ cal = λ des
When λ cal > λ des then:
1b. Decrease ηset (9500 - 9583 MechEffMap or 1413 MechEfficiencyConst) at the accord-
ing load point in the efficiency table (engine with generator) until λ cal = λ des
2. Repeat this calibration for the other three load points, e.g., 80 %, 60 % and 40 % load.3. When “Closed Loop” is active, the system switches automatically to “Open Loop” as
soon as output is inferior to e.g. 40 % (depending on 1400 ClosedLpPowerMinRate).
4. Increase load until rated output is reached. For all loadpoints λ cal = λ des = λ mea should
hold true.
5. Measured exhaust gas values should correspond to desired exhaust gas values for all
loads. Corrections must be made in the λ table.
6. If this is the case, the AFR control is now ready to be switched in Closed Loop opera-
tion (5400 ClosedOrOpenLoop).
E) Verification of the closed control circuit
1. Verify the adjustment of I-parameter for Closed Loop Control (1401 ClosedLoop-Gov:I ) and, if necessary, change the value to obtain the desired control characteristics
and stability. Observe that the speed of the AFR control is approx. 25 times slower
than the speed of the speed control circuit.
2. Switch on Closed Loop Mode (5400 ClosedOrOpenLoop = 1).
3. Mark the position of the adjustment spindle of the zero governor.
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4. Count the number of counter-clockwise revolutions required to achieve gas output pressure drop. The mixture change resulting from this forced disturbance should lead
to a leaner operation and the closed loop should then correct this effect.
5. Go back to the starting point.6. Turn a few clockwise revolutions to repeat the test for a richer mixture.
7. Go back to the original position of the zero governor adjustment spindle.
8. A further disturbance can be brought about by opening the compensating line.
9. Working with a biogas plant or landfill gas plant, ask the plant operator to change gascomposition in order to check the dimensioning of the fuel system (control reserve)
and the control system (correction quality).
9.5 Further commissioning for CLOSED LOOP with 1 control
(KRONOS 20 version with λ 1 sensor)
General:
Commissioning of λ1 control is carried out in two steps:
- adjustments for open loop
- adjustments for closed loop
Open loop operation is active when the engine starts, as long as the lambda sensor is not
ready for operation yet, when the sensor has failed or if closed loop operation has not been
activated yet (5400 ClosedOrOpenLoop). During calibration of the open loop, closed loop
operation may not be active.
Correct calibration in open loop guarantees that closed loop operation achieves an ap-
proximate λ1 ratio straight away and the corrections for closed loop remain small under all
operating conditions. This allows a good starting behaviour and, due to the relatively small
lambda trim values (3464 LambdaTrim Value), also a good dynamic behaviour in closed
loop. In addition, the trim value range may be limited to a small range (1464 LambdaT-
rimValueLimit ). This avoids major variations in case the sensor fails.In closed loop, fine tuning is done by a pre-setting a default control voltage for the λ sensor
within the voltage jump range. For λ1 this value is usually set between 0.1 and 0.7 Volt.
This procedure allows a very precise lambda control
Settings for open loop:
1. First, disable (5400 ClosedOrOpenLoop). Verify the load and speed dependent
λ adjustment values (7400-7599 LambdaMap). To begin with, all map values should
be set to 1 (this table serves only for later correction purposes here).
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2. Verify other important parameter settings for engine, mixer and gas data before start-ing the engine.
3. Start the engine with the pre-set parameters in open loop mode.
4. Check the voltage signal of the lambda sensor after the start (2915 LamdaProbe).Voltage should have dropped below 1 Volt within 40 seconds (cold start test of sen-
sor).
5. Calibration of Venturi efficiency (1424 VenturiEfficiency):
Run the engine in a range of 50 – 100 % load and increase or reduce Venturi effi-
ciency until the voltage signal of the lambda sensor (2915 LambdaProbe) is in a range
between 0.1 and 0.7 Volt (measured lambda is approx. 1).
6. Calibration of lambda map for other operating points:
Change load in several steps between 0 and 100 % and set the respective map values
(for speed and intake manifold pressure) so that they result in a voltage signal of the
lambda sensor (2915 LambdaProbe) between 0.1 and 0.7 V (measured lambda is
approx. 1). Repeat these settings for low and high idle speed.
7. To achieve optimal starting behaviour, the respective map values for the motor startrange (pressure is 1 bar at low speed) are corrected in order to have the engine starting
correctly in all conditions. Please note that the neighbouring values must be adapted
accordingly.
8. Now the effective lambda value at all loads is always approximately 1. Verify the set-ting for several operating points.
Settings for closed loop:
1. Check (1464 LambdaTrimValueLimit ) to adjust the control range. Start with ±0.05.
2. Enable the closed loop with (5400 ClosedOrOpenLoop = 1).
3. Operate the engine with varying loads and observe the exhaust gas values. Set (1471
LambdaProbeSetPoint ) for lambda fine tuning so as be within the required exhaust gasvalue range.
4. Check the measured value parameter (3664 LambdaTrimValue) over the completeload range. Note that this value is limited by (1464 LambdaTrimValueLimit ). To
achieve a sufficiently ample control range (1464 LambdaTrimValueLimit ) must be set
to a correspondingly high value. On the other hand, it should guaranteed that in case of
sensor failure the engine still runs within a safe range.
5. To conclude, check the open loop settings once more.
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10 Misfire Detection (optional)
KRONOS 20 49
10 Misfire Detection (optional)
10.1 General
Misfire detection is available as an optional function in KRONOS 20. It is based on the ob-
servation of the speed variation caused by each ignition. Since only speed and power sig-
nals are used, no additional sensor is required.
When (4050 SpeedVarDetectOn) is active, the control unit calculates a value for speed
variance on the basis of (2000 Speed ) and the sampling value (50 SpeedVarSampleSize)
while the engine is running and indicates it as (2050 SpeedVariance). The value changes if
single cylinders misfire. Since speed change is load-dependent even if the engine ignites
correctly, for the error message both a warning and a shutdown characteristic are defined,
both of which are load-dependent.To determine the parameters for Misfire Monitoring, single cylinders must be switched off
on the engine test stand and the sampling value (50 SpeedVarSampleSize) must be deter-
mined in relation to (2050 SpeedVariance).
10.2 Putting into Operation
1. Let the engine run at rated speed and rated load under normal conditions. All cylindersmust ignite correctly. The function (4050 SpeedVarDetectOn) must be active and the
functions (4055 MisfireWarnCurveOn) and (4056 MisfireEcyCurveOn) must be dis-abled.
2. Raise parameter (50 SpeedVarSampleSize) step by step from 3 to max. 20. Record thevalue of (2050 SpeedVariance) for each step.
3. Switch off one cylinder, maintaining the load as far as possible.
4. Repeat step 2 for this load and this switched-off cylinder. In doing so, optimize the fil-ter constant (51 SpeedVarFilterConst ) used for determining (2050 SpeedVariance).
The value of (2050 SpeedVariance) must increase as much as possible in comparison
to normal conditions to achieve maximum sensitivity.
5. Record the value of (50 SpeedVarSampleSize) for which the relative increase of (2050SpeedVariance) is highest. The best sensibility is found when the relation between
(2050 SpeedVariance) and misfiring and normal ignition is highest.
6. Now determine parameter (50 SpeedVarSampleSize) for the other switched-off cylin-ders and, if required, for different loads by repeating steps 2 to 5.
7. Choose the value of parameter (50 SpeedVarSampleSize) which yields the clearestrelative variation in (2050 SpeedVariance) under all conditions and represents the best
compromise for the measurements taken under different loads and with different inac-tive cylinders.
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50 KRONOS 20
Filtering of speed signals for misfire monitoring must always be done over two
crankshaft rotations.
To determine the thresholds for monitoring and error messages proceed as follows:
1. Using the identified value for (50 SpeedVarSampleSize), run the engine to several load points both under normal conditions and with selected cylinders switched-off. Two
different load-dependent curves for (2050 SpeedVariance) result, one representing the
"good" and the other the "bad" operating conditions. Pay attention that the curves dif-
fer noticeably from each other at all chosen load points.
2. Record the load value in (6000 MisfireWarn:P(x)) and (6020 MisfireEcy:P(x)). Drawthe warning characteristic and shutoff characteristic between the two limit characteris-
tics and record the respective values in (6010 MisfireWarn:nVar(x)) and (6030 Mis-
fireEcy:nVar(x)). Enable the functions (4055 MisfireWarnCurveOn) and/or (4056 Mis-
fireEcyCurveOn).
3. Determine the delay times for (55 MisfireWarnDelay) and (56 MisfireEcyDelay). Onlywhen the current value of (2050 SpeedVariance) has exceeded the warning and/or the
shutoff characteristic for at least the respective time indicated the errors (3046 ErrMis-
fireWarn) / (3047 ErrMisfireEcy) are triggered. When the value of (2050 SpeedVari-
ance) falls below the load-dependent trigger level by relative 15 % the error (3046
ErrMisfireWarns) is cleared. The emergency shutoff signal (3047 ErrMisfireEcy) onthe other hand can be cleared only by a reset or by an error clearing through a commu-
nication module or switch function.
Note
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11 Operation
KRONOS 20 51
11 Operation
The system must be operated in a way to reliably exclude damage of any type.
In particular, the system may be operated only within the electrical and technical ranges indi-
cated in the specification.
Correct operation, damages and wear of all components should be checked regularly.
Concentration of hydrogen sulphide (H 2S) in fuel must not exceed 0.1 %!
The gas must be dry!
When using biogasis used as fuel, gas bearing components and sections of
the system must be inspected twice a year!
To high residual concentration of hydrogen sulphide (H2S)or too much
residual humidity may cause corrosive effects that might block mechani-
cal componets. This might result in overspeed and serious damage to the
engine!
Gas valves E-LES might only be used as control valves!
Never use as shut-off valve!
Warning
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12 Maintenance and Service
52 KRONOS 20
12 Maintenance and Service
Repairs of HEINZMANN devices must always be carried out at the manu-
facturer’s factory.
Always switch off the power before cleaning the system.
The KRONOS 20 system is designed to require no maintenance and needs no specific upkeep
actions. Still, the state of all components such as cables, connectors, sensors and gas valves
must be checked regularly for damages, wear and correct functioning. In particular, for opera-tion under normal strain conditions it is recommended to check that the gas valve once a year
at least. When using aggressive fuels valves should be checked more frequent. Check whether
the valve runs smooth when turning the handwheel while the engine is still.
The state of pistons and cylinder face should additionally be checked with dismounted valve.
If strain is heavier, for instance due to vibration or dirt, the test must be carried out corre-
spondingly more often. If the valve is noticeably worn out, the complete gas valve must be
replaced.
The control valve must be in perfect exterior condition. Its surface may not be impaired me-chanically or by chemical substances. The surface must be kept from getting dirty also in or-
der to avoid heat accumulation.
Only cleaning procedures allowed for the respective protection type may be used.
The devices may in no case be opened by the customer.
Warning
Warning
Danger
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13 Error Handling
KRONOS 20 53
13 Error Handling
13.1 General
The HEINZMANN Digital Controls of the KRONOS 20 series include an integrated errormonitoring system by which errors caused by sensors, speed pickups, etc., may be detected
and reported. By means of a permanently assigned digital output the error types can be
output via some visual signal.
The different errors can be viewed by the parameters 3001..3094. A currently set error pa-
rameter will read the value “1”, otherwise the value “0”.
Generally, the following errors types can be distinguished:
Errors in configuring the control and adjusting the parameters
These errors are caused by erroneous input on the part of the user and cannot be in-
tercepted by the HEINZMANN diagnosis tool. They do not occur with