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User reviews and opinions
|ttraub||4:02am on Friday, October 29th, 2010|
|Nice and easy to use and a solid build The keys are a bit to loose but nothing major|
|sliderule||10:30pm on Monday, September 20th, 2010|
|I have had 5 Toshiba laptops and loved them all. They are all still going strong after 5-10 years.|
|loom001||12:02am on Sunday, July 25th, 2010|
|This is my second laptop computer. My first computer was a Dell laptop and it lasted me three years until it died.|
|ynaras||3:36pm on Sunday, July 11th, 2010|
|Feels crappy I looked at the specifications and the price seemed really good. Anyway.|
|narkar1||11:59pm on Saturday, June 26th, 2010|
|this is a very quick and easy laptop to use and well worth buying considering the price tag and it is quick and very easy toset up A very good, well built and reliable laptop. Has pretty impressive specs for under 500 quid and can handle everything I throw at it.|
|uwork||7:55am on Sunday, June 13th, 2010|
|I have had 5 Toshiba laptops and loved them all. They are all still going strong after 5-10 years.|
|gmv||12:59am on Sunday, March 21st, 2010|
|"Having just received as a xmas prezzy i just have to say like other reviews superb product great value and im looking forward to what windows 7 can o... Brand Toshiba Model Satellite L500-13C PC Type Notebook Processor Processor Type Intel Core 2 Duo Processor Model Intel Core 2 Duo T6500 / 2.|
|Gebriel||7:35pm on Saturday, March 13th, 2010|
|Great!! Excellent value and spec Am really, really pleased with my purchase of the Toshiba L500-19z. It has a great spec - 4gb ram.|
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Bypass max. 120 Nl/h Exhaust gas max. 15 Nl/h
Gas inlet pressure 0.5-3.0 bar
Ventilblock 4. Filter 5. Pressure regulator 6. Sensors 7. Flow resistor 8. Pressure transmitter 9. Pressure gauge 10. CO2 sensor
1. Stop valve 2. Solenoid valve (block and bleed configuration) 3. Flow meter with control valve
Operating Instructions for the EMC 500
Construction of the explosion-protected (Ex) design
Hole pattern for wall mounting hole 10 mm
1.) Measuring element with valve control explosion-proof enclosure. 2.) EEx e connection box 3.) Variable-area flow meter for bypass - measuring gas 4.) Inlet pressure gauge for measuring gas, reference gas and test gas 5.) Stop valve for measuring gas, reference gas and test gas 6.) Mounting plate with fixtures for wall mounting 7.) Inlet filter
Connections: A: Measuring gas inlet Inlet pressure 0.5 to 3.0 bar B: Calibration gas inlet 1/8 pipe connection with Swagelok joint C: Test gas inlet E1, E2: Outlet pipes with 6 mm pipe connections with Swagelok joints
Construction of the not explosion-protected (Non Ex) design
1.) Measuring element with valve control 2.) Connection box 3.) Variable-area flow meter for bypass - measuring gas 4.) Inlet pressure gauge for measuring gas, reference gas and test gas 5.) Stop valve for measuring gas, reference gas and test gas 6.) Mounting plate with fixtures for wall mounting 7.) Inlet filter
Measuring and electronic unit
Measuring gas outlet
Calibration gas inlet
Measuring gas inlet
1. 2. 3. 4. 5.
Sensor, heated and insulated Pressure reducer (stage 1) Pressure transducer Infrared sensor (CO2) Solenoid valve block with 3/2-way solenoid valve
6. Line filter type SS-2F-2 7. Mounting plate 8. Power supply unit (only active in 230 V version) 9. Electronic board
Gas inlet Pressure reducer (stage 2) Connection of pressure compensation
Capillary tube spiral (flow resistor)
Cover for gas preheating plate, all-round welded to be gas-tight. Flow sensor p pressure sensor
Heating mat Gas preheating plate
The complete system consists of the measuring element and the analytical computer GC 9000 (for control and evaluation of the analysis). The analytical computer includes the following functions: Measurement of superior calorific value, standard density and CO2 content for custody transfer applications. Determination of Wobbe index, inferior calorific value and relative density as well as monitoring of the nitrogen content. Bus interface (DSfG or Modbus ASCII) Operation as with the process gas chromatograph.
Configuration with analytical computer GC 9000
GAS CHROMATOGRAPH GC 9000
Transducer of calorific value, standard density and carbon dioxide
Type EMC 500
Coordinate Fault Clear Enter
Cal. Val. GC-Status S.Density Wobbe
PHOENIX PSM-ME-RS232/RS485-P CONTACT Ord.-No.: 27 44416
D(A) D(B) T(A) T(B)
Hs,n Coupling element n CO2
Operating Instructions for the Explosion-Protected Design
The explosion-protected design of the EMC 500 superior salorific value, standard density and Wobbe index measuring device is an explosionprotected electrical apparatus of the explosion-proof encapsulation type of protection with a terminal compartment of the increased-safety type of protection. Code: II 2G EEx de IIB T4 The device complies with the provisions of Guideline 94/9/EG (ATEX 100a). It can be installed in areas subject to explosion hazards in zone 1 which are endangered by gases and vapours classified under danger class IIB and temperature class T4. For installation and operation, the appropriate ordinances and regulations must always be observed. With regard to explosion protection, the device has been approved for an ambient temperature range of -20 to +60C. For custody transfer measuring purposes, however, the ambient temperature must be between -20 to +50C! The device has to be protected against the weather.
GND RS 232 5
Terminal diagram of the measuring element for digital transmission
In order to obtain reliable measured values, the EMC 500 must warm up like any other measuring instrument. This is mainly due to the following reasons: - The sensor block of the EMC 500, where the sensors and the pressure regulators are located, is heated at a constant temperature of approx. +65C. The warming-up phase is necessary to heat up the interior. - The pressure regulators and the pressure sensor need this time to stabilize. A warming-up phase of approx. 30 minutes must be observed when starting up the EMC 500 for the first time or after separating it from the measuring gas or the voltage supply for a prolonged period of time. During this warming-up phase, the measuring gas should be connected to the EMC 500, so that the pressure regulators and the pressure sensor can stabilize. The warming-up phase is monitored by the device itself. During this time, the text Starting operation is displayed together with the specified temperature and the current sensor block temperature. As soon as the specified temperature has been reached, the device starts, if specified in field D 2, to perform a calibration run automatically. After the calibration run has been completed successfully, the measuring operation will start.
First you must connect a calibration gas to the EMC 500. Then you must enter the specified values of the calibration gas (values for the superior and inferior calorific values, Wobbe index and standard density as listed in the certificate of the calibration gas) via the keyboard of the EMC 500. As soon as the EMC 500 has reached its operating temperature after the warming-up phase and the pressure regulators and the pressure sensor have stabilized, a calibration run is performed automatically. Another calibration run will be performed after 3 hours. Press the GC-Status key to select the appropriate column. Press the key to reach the fields into which you want to enter the specified values (A 13, A 16, A 19, A 22 and A 25). A more detailed description of this procedure is given in the chapter "Analytical Computer" of this manual. After you have entered the specified values, you can start a calibration in field A 2 pressing the * key, while the slide switch is in its Input position.
Using the automatic recalibration feature, you can calibrate the EMC 500 either by pressing the appropriate key or at selectable intervals via its internal clock. For custody transfer applications the calibration interval may not exceed 4 weeks. The following settings are relevant for automatic recalibration: Column A D D D D D Example: Line(s) 13, 16, 19, 22, 24 25
Specified values of the calibration gas Setting to automatic calibration Weekday of first calibration Time of automatic calibration Selection of calibration intervals (min / h / days / week) Repetition rate for calibration intervals
D 22 Monday D 23 06:00:00 D 24 day(s) D In this case, automatic calibration is performed every 10 days at 6 a.m starting next Monday. During automatic recalibration, the last values of superior calorific value, standard density, CO2 content, Wobbe index, inferior calorific value and relative density, measured before starting calibration are maintained.
The manual start of a calibration takes place in the following way: 1. Input code number for user access (see page 21). 2. Press key "0" (GC-Status) 3. Start calibration with key "*" (display text: "Start with key *")
Sequence of calibration
The sequence of automatic recalibration, whether activated by pressing the appropriate key or via the internal clock, is always the same and lasts approx. 8 minutes. Start (clock or key) Connecting the calibration gas Purging the device (waiting time) Taking measured values/ finding a mean value Calculating the new parameters Connecting the measuring gas Purging the device (waiting time) Accepting the current measured value
Test gas analysis
For the analysis of an external test gas connect the test gas cylinder to the gas inlet "C" (s. drawing). To start the test gas analysis select the mode "Man. Test Gas" in coordinate M 12 and set it back to "Test Gas OFF" for completion. In any case a test gas analysis can maximally last as long as specified in coordinate M 13 as time limit (in minutes). Afterwards the EMC 500 switches back to measuring gas analysis. The results of the test gas analysis are displayed in M 14 to M 24.
The EMC 500 is basically maintenance-free. As in the case of every measuring instrument, you must make sure that it is supplied with clean and dry gas only. Drying and filtration units are available as options.
Analytical Computer GC 9000
The operating concept: The operating concept has been chosen in such a way that the operator can easily use the device without wasting too much time reading a manual. The function keys: The most important data for the operator can be directly selected via function keys. There are function keys for Date Mean values Mode Outputs Inputs Maximum values Status Superior Calorific Value, Standard Density, Wobbe Index The system of coordinates: A system of coordinates makes it easy for the operator to access all configuration data, measured values and operands by means of a table. The system of coordinates is based on 21 columns and 52 lines. Columns are marked A to Y, while lines run from 1 to 52. The operator can reach every value in this system of coordinates via cursor keys (arrows). The display field: An alphanumeric 2-line display with 20 characters per line enables data and measured values to be indicated together with their short designations and units. The display field consists of a fluorescent display in blue and is easily readable even from a distance. The system: A complete Flow Computer System has been developed taking the size of a Eurocard as a basis and using the most advanced SMD technology with large-scale integrated components. A fully assembled printed circuit board incorporates all inputs required for a complex corrector. The GC model incorporates a second CPU card to increase the computing power. This CPU mainly performs arithmetic operations and gives interface reports, whereas the standard CPU continues to carry out all measuring tasks. An interface module has been plugged onto the back of this CPU in order to provide the device with another four data interfaces. Measured data archive: There are two different software versions available: - The data logger version (without DSfG interface) has an archive for the measured values of superior calorific value, standard density and CO2 content. 15 minute average values are generated, the memory depth is 18 months. - With the DSfG version no storage of the measured values takes place. For storage of the measured values the data logger MRG 2202, approved for custody transfer application, is available. The software of this device is specifically adapted to the EMC 500. The software version is to be read in Y 24.
GC 9000 Front panel
GAS CHROMATOGRAPH GC9000
RS 232 C port
Sealable slide switch
2-line display Keypad for with 20charac- directly ters per line accessing the various device functions
ID plate with basic data; all other data can be accessed via the ID function key
On the ID plate you find, among other things the serial number of the measuring element. Since the operating parameters are adjusted to the measuring element and stored in the analytical, operation is only possible if the analytical computer is connected to the appropriate measuring element!
Operating the GC 9000
Description of the function keys
Indication of the TIME
Indication of the DATE
Indication of the calibration modes and when pressing the to the calibration mode (except set values)
keys further values related
Indication of the current output No. 1 and when pressing the this current output. Press the key to switch over to current outputs 2, 3 and 4.
keys all values related to
Indication of data for sensor 1 (measured value and parameters) Press the key to reach data for sensor 2, pressure and temperatur values.
Selection of calculated values (e.g. Hs,n, n,.) and units
Version parameter and test values (to check the calculations)
Indication of superior calorific value, Wobbe index, standard density, relative density, inferior calorific value and CO2 content incl. appropriate default values
Indication calibration status and when pressing the calibration status incl. start and results
keys all values related to the
Calibration report, data report, revision report
Special Function keys
Clear, Enter, Select Arrow up / down To scroll up or down by lines within a column or in selection mode between operating modes.
Arrow right / left
To scroll to the right or left by columns within a line. If you press the key, you can jump via the first column to the last column. If you press the key, you can jump via the last column to the first column. These keys fulfill a special function in the mean-value column. The following applies to cursor keys in general: Unoccupied line fields within a column and unoccupied columns within a line are automatically skipped. If the column jumped to is occupied but the line field is empty, the line number is automatically increased until an occupied field is found. When you jump to the next column, the initial line number is selected again.
Clear / Fault
a) b) c)
To indicate faults in the normal mode Special function (clear fault) To clear incorrect inputs in the programming mode. The state prior to inputting the first digit is restored.
To initiate and complete a data input. All data inputted are accepted.
To switch over from short designations to coordinates and vice versa. Switching over is possible in almost all fields (also in the programming mode). Release of special functions (according to instructions on the display)
Display fault / Clear Fault Function
Display fault The occurrence of a fault is indicated by the Fault LED on the front panel of the device or by an isolated contact at the terminal block. The LED flashes if faults are pending. If faults are no longer pending, the LED turns to steady light. To display fault texts, you must press the CLEAR / FAULT key. After you have pressed this key, the display field shows error and the bottom line shows the fault texts at 3-second intervals. All messages are consecutively shown in the display field. As long as the Fault LED flashes, there is still at least one fault pending. If the Fault LED shows steady light, all indicated fault messages are no longer valid and the device has returned to fault-free operation. Clear fault The time and date of the fault occurred are shown in the fields R3 and R4. If there is more than one fault pending, the time and date of the first fault occurred are shown.
Displaying measured values, constants and modes
Press key 9 (Cal. Val.) EMC-Messwerte *Hs 10,123 Press EMC-Messwerte *rho,n 0,6478 Press EMC-Messwerte Ws 13,254 Press EMC-Konstanten d-EMC Ein Press EMC-Konstanten Hi-EMC Ein kWh/m3 kg/m3 kWh/m3
Enabling programming a ) Code number to enable user access Press key 8 (Max. Values) und one time Code Press the Enter key Code EMC - 9000 ???????? EMC - 9000 ********
The digits inputted remain invisible. Each digit is marked with an asterisk. All eight digits have to be inputted. Input the appropriate digits Code EMC - 9000 ****????
Press the Eingabe key to complete the data input Code EMC - 9000 ******** (for correct code number)
If the code number is correct, the POWER / STANDBY LED on the front panel starts to flash at onesecond intervals and the bottom line of the display turns bright. If the code number is not correct, the display changes back to the input mode and keeps dark. Code EMC - 9000 ? ? ? ? ? ? ? ?(for incorrect code number)
Repeat the operation using the correct code number! The computer enables you to access user data. To change data, you must select the desired coordinate on the bottom line of the display and press the ENTER key. The brightness of the bottom line is reduced to indicate that access to the coordinate field is enabled. If you want to lock the computer again after having completed your programming, press the CLEAR / FAULT key twice quickly. If you forget to do so, the computer itself disables access after approx. 30 minutes. It is possible to change the code number if the sealable slide switch is in its "Input" position.
Abbreviation of the coordinate (Display of the GC 9000)
Data protection level: D = Display value C = Data which the user can modify using a code number S = Data which can be modified via the slide switch (sealable) Designation of the line in a column. The headline is not displayed in coordinate representation.
Explanatory notes on the coordinate
Bold text shows important fields!
Description of Individual Columns
D D D D D D D D S D D S D D S D D S D D S D D S D D S STATUS PurgT-1 HsCal WsCal rnCal dCal HiCal CO2Cal HsSpec HsLast HsDiff WsSpec WsLast WsDiff rnSpec rnLast rnDiff dSpec dLast dDiff HiSpec HiLast HiDiff CO2Spec CO2Last CO2Diff TB
Description of coordinates
Heading EMC calibration Display of the current calibration run in seconds Calibration value EMC superior calorific value Calibration value EMC Wobbe index Calibration value EMC standard density Calibration value EMC relative density Calibration value EMC inferior calorific value Measured carbon dioxide content at calibration time Specified calibration value for superior calorific value Actual calibration value for superior calorific value Specified/actual deviation for superior calorific value Specified calibration value for Wobbe index Actual calibration value for Wobbe index Specified/actual deviation for Wobbe index Specified calibration value for standard density Actual calibration value for standard density Specified/actual deviation for standard density Specified calibration value for relative density Actual calibration value for relative density Specified/actual deviation for relative density Specified calibration value for inferior calorific value Actual calibration value for inferior calorific value Specified/actual deviation for inferior calorific value Specified calibration value for carbon dioxide content Actual calibration value for carbon dioxide content Specified/actual deviation for carbon dioxide content Temperature at base conditions 0C /15C / 20C / 25C Temperature at base cond. sup. calorif. value 0C /15C / 20C / 25C
s s. K/21 s. K/22 kg/m3 s. K/23 s. K/24 s. K/21 s. K/21 % s. K/22 s. K/22 % kg/m3 kg/m3 %
% s. K/23 s. K/23 % % % %
In this field a manual calibration can be started with the "*" key if the code number has been inputted before (see display text).
indirect GC-Status and once right
Column C Description of coordinates
63 D S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S S CON_HS Hs-C1 Hs-C2 Hs-C3 Hs-C4 Hs-C5 Hs-C6 Hs-C7 Hs-A0 Hs-A1 Hs-F0 Hs-Z0 Ws-C1 Ws-C2 Ws-C3 Ws-C4 Ws-C5 Ws-C6 Ws-C7 Ws-A0 Ws-A1 Ws-F0 Ws-Z0 rn-C1 rn-C2 rn-C3 rn-C4 rn-C5 rn-C6 rn-C7 rn-A0 rn-A1 rn-F0 rn-Z0 d-C1 d-C2 d-C3 d-C4 d-C5 d-C6 d-C7 d-A0 d-A1 d-F0 d-Z0 Hi-C1 Hi-C2 Hi-C3 Hi-C4 Hi-C5 Hi-C6 Hi-C7 Hi-A0 Hi-A1 Hi-F0 Hi-Z0 CH-C1 CH-C2 CH-C3 CH-C4 CH-C5 CH-C6 CH-C7 Heading EMC constants Parameter C1 EMC superior calorific value Parameter C2 EMC superior calorific value Parameter C3 EMC superior calorific value Parameter C4 EMC superior calorific value Parameter C5 EMC superior calorific value Parameter C6 EMC superior calorific value Parameter C7 EMC superior calorific value Parameter A0 EMC superior calorific value Parameter A1 EMC superior calorific value Parameter F0 EMC superior calorific value Parameter Z0 EMC superior calorific value Parameter C1 EMC Wobbe index Parameter C2 EMC Wobbe index Parameter C3 EMC Wobbe index Parameter C4 EMC Wobbe index Parameter C5 EMC Wobbe index Parameter C6 EMC Wobbe index Parameter C7 EMC Wobbe index Parameter A0 EMC Wobbe index Parameter A1 EMC Wobbe index Parameter F0 EMC Wobbe index Parameter Z0 EMC Wobbe index Parameter C1 EMC standard density Parameter C2 EMC standard density Parameter C3 EMC standard density Parameter C4 EMC standard density Parameter C5 EMC standard density Parameter C6 EMC standard density Parameter C7 EMC standard density Parameter A0 EMC standard density Parameter A1 EMC standard density Parameter F0 EMC standard density Parameter Z0 EMC standard density Parameter C1 EMC relative density Parameter C2 EMC relative density Parameter C3 EMC relative density Parameter C4 EMC relative density Parameter C5 EMC relative density Parameter C6 EMC relative density Parameter C7 EMC relative density Parameter A0 EMC relative density Parameter A1 EMC relative density Parameter F0 EMC relative density Parameter Z0 EMC relative density Parameter C1 EMC inferior calorific value Parameter C2 EMC inferior calorific value Parameter C3 EMC inferior calorific value Parameter C4 EMC inferior calorific value Parameter C5 EMC inferior calorific value Parameter C6 EMC inferior calorific value Parameter C7 EMC inferior calorific value Parameter A0 EMC inferior calorific value Parameter A1 EMC inferior calorific value Parameter F0 EMC inferior calorific value Parameter Z0 EMC inferior calorific value Parameter C1 EMC hydrocarbons Parameter C2 EMC hydrocarbons Parameter C3 EMC hydrocarbons Parameter C4 EMC hydrocarbons Parameter C5 EMC hydrocarbons Parameter C6 EMC hydrocarbons Parameter C7 EMC hydrocarbons
s. K/21 s. K/22 kg/m3 s. K/23 %
direct Cal. Val.
Column M Description of coordinates
78 D D D D D D D D D D C S D D D D D D D D D D S S C S D S S C S D S S C S D S S C S D S S C S D S S C S S S C S S S C S S S Result *Hs *rho,n Ws d Hi *CO2 N2 CH MNumber T-Gas TGasTo THs TWs Trho,n Td THi TCO2 TN2 TCH TMNumber HsA0c Hsmin Hsmax Hs-def Hs-af WsA0c Wsmin Wsmax Ws-def Ws-af rnA0c rnmin rnmax rn-def rn-af dA0c dmin dmax d-def d-af HiA0c Himin Himax Hi-def Hi-af CO2A0c CO2min CO2max CO2-def CO2-af N2min N2max N2-def N2-af CHmin CHmax CH-def CH-af MN-min MN-max Heading result column Calculated superior calorific value (EMC) Calculated standard density (EMC) Calculated Wobbe index (EMC) Calculated relative density (EMC) Calculated inferior calorific value (EMC) Carbon dioxide content Nitrogen content Hydrocarbon content Methane number EMC test gas: Test Gas OFF / Man. Test Gas / Auto. Test Gas Maximum duration of test gas operation Calculated superior calorific value (EMC) test gas Calculated Wobbe index (EMC) test gas Calculated standard density (EMC) test gas Calculated relative density (EMC) test gas Calculated inferior calorific value (EMC) test gas Carbon dioxide content test gas Nitrogen content test gas Hydrocarbon content test gas Methane number test gas Actual A0 value for superior calorific value Lower limiting value (fault) for superior calorific value (EMC) Upper limiting value (fault) for superior calorific value (EMC) Default value for superior calorific value (EMC) Averaging factor (damping) for superior calorific value (EMC) Actual A0 value for Wobbe index Lower limiting value (fault) for Wobbe index (EMC) Upper limiting value (fault) for Wobbe index (EMC) Default value for Wobbe index (EMC) Averaging factor (damping) for Wobbe index (EMC) Actual A0 value for standard density Lower limiting value (fault) for standard density (EMC) Upper limiting value (fault) for standard density (EMC) Default value for standard density (EMC) Averaging factor (damping) for standard density (EMC) Actual A0 value for relative density Lower limiting value (fault) for relative density (EMC) Upper limiting value (fault) for relative density (EMC) Default value for relative density (EMC) Averaging factor (damping) for relative density (EMC) Actual A0 value for inferior calorific value Lower limiting value (fault) for inferior calorific value (EMC) Upper limiting value (fault) for inferior calorific value (EMC) Default value for inferior calorific value (EMC) Averaging factor (damping) for inferior calorific value (EMC) Actual A0 value for carbon dioxide content Lower limiting value (fault) for carbon dioxide content Upper limiting value (fault) for carbon dioxide content Default value for carbon dioxide content Averaging factor (damping) for carbon dioxide content Lower limiting value (fault) for nitrogen content Upper limiting value (fault) for nitrogen content Default value for nitrogen content Averaging factor (damping) for nitrogen content Lower limiting value (fault) for hydrocarbon content Upper limiting value (fault) for hydrocarbon content Default value for hydrocarbon content Averaging factor (damping) for hydrocarbon content Lower limiting value (fault) for methane number Upper limiting value (fault) for methane number
s. K/21 kg/m3 s. K/22 s. K/23 s. K/24 Mol% Mol%
min s. K/21 s. K/22 kg/m3 s. K/23 s. K/24 Mol% Mol% s. s. s. s. s. s. s. s. K/21 K/21 K/21 K/21 K/22 K/22 K/22 K/22
kg/m3 kg/m3 kg/m3 kg/m3 kg/m3 kg/m3 kg/m3 kg/m3 s. s. s. s. s. s. s. s. K/23 K/23 K/23 K/23 K/24 K/24 K/24 K/24
Mol% Mol% Mol% Mol% Mol% Mol%
For fiscal metering in the mode EMC 500 (see Y25)
Column O Description of coordinates
13 D D D C MODE-TT ManR. ChanR. LPT-1 Heading EMC print column Heading EMC manual report Heading EMC channel report EMC print mode 1 Manual / Automatic EMC data report Hs, Ws, rn, d, Hi, CO2 Print OFF / Mean Values / 15-Min.Data / Hourly Data EMC calibration report Hs, Ws, rn, d, Hi Print OFF / Print ON EMC revision report Hs, Ws, rn, d, Hi, CO2 Print OFF / Print ON EMC data report sensors Print OFF / Print ON EMC automatic print repetition rate EMC revision print repetition rate Time of last EMC printout
C LPT-Dat. C LPT-Cal. C LPT-Rev. C LPT-EMC C AutoRep C Rev-Rep D L-P
Column P Description of coordinates
3 D Date C Date: C Day: Heading of date display Date display Weekday
Column Q Description of coordinates
D C D D Time Time: UnixS UnixZ Heading of time display Time display Unix seconds since 01.01.1970 00:00 Date and time of Unix Time
Column R Description of coordinates
46 D D D D D D D D D D D D D FAULT F. F.-Time F.-Date Reset Warn-fl Fault-fl E-idx E-Arch. Heading fault Fault indication at one-second intervals Time of the first fault occurring Date of the first fault occurring Time of last fault clearing Measuring element error, bit string 1 Measuring element error, bit string 2 Measuring element error, bit string 3 Measuring element error, bit string 4 Warning flag Fault flag Index event archive Event archive
EMC Sensor 1
D D D D S S S S S S S S S S D D D D S1-EMC S1 S1-in S1-Oc S1min S1max S1-af S1-Trm S1D1 S1G1 S1K1 S1-Spec S1-Tol S1-dfO Off-G1 Off-D1 S1-1112 S1-1012
Heading EMC sensor 1 EMC sensor 1 Input value EMC sensor 1 Current offset sensor 1 Lower limiting value (fault) for EMC sensor 1 Upper limiting value (fault) for EMC sensor 1 Averaging factor (damping) for EMC sensor 1 Mode EMC sensor 1 EMC Correction factor for differential pressure EMC sensor 1 Correction factor for pressure EMC sensor 1 Correction factor for temperature EMC sensor 1 Specified value calibration gas EMC sensor 1 Max. permissible deviation from specified value EMC sensor 1 Set value offset EMC sensor 1 Sensor 1 offset, base calibration Sensor 1 diff. with regard to base calib. Measured value sensor 1, read from EMC Analog value sensor 1, read from EMC
mV mV mV mV %
EMC Sensor 2
indirect Input and once right
D D D D S S S S S S S S S S D D D D S2-EMC S2 S2-in S2-Oc S2min S2max S2-af S2-Trm S2D1 S2G1 S2K1 S2-Spec S2-Tol S2-dfO Off-G2 Off-D2 S2-1114 S2-1014 Heading EMC sensor 2 EMC sensor 2 Input value EMC sensor 2 Current offset sensor 2 Lower limiting value (fault) for EMC sensor 2 Upper limiting value (fault) for EMC sensor 2 Averaging factor (damping) for EMC sensor 2 Mode EMC sensor 2 EMC Correction factor for differential pressure EMC sensor 2 Correction factor for pressure EMC sensor 2 Correction factor for temperature EMC sensor 2 Specified value calibration gas EMC sensor 2 Max. permissible deviation from specified value EMC sensor 2 Set value offset EMC sensor 2 Sensor 2 offset, base calibration Sensor 2 diff. with regard to base calib. Measured value sensor 2, read from EMC Analog value sensor 2, read from EMC
indirect Input and twice right
Column V Description of coordinates
D D D D D D S S S S S S S S S S S S S S D D D D D D P1-EMC P1 P1-in CO2 CO2-in CO2-Oc P1min P1max P1-def P1-af P1-Trm p1-C1 CO2C1 CO2G1 CO2-Tol CO2-dfO dp-spec dp-dev p2-min Co2OP CO2-1100 CO2-1000 p1-1102 p1-1002 dp-1104 dp-1004 Heading EMC pressure 1 EMC pressure 1 Input value EMC pressure 1 EMC CO2 Input value EMC CO2 Current offset CO2 Lower limiting value (fault) for EMC pressure 1 Upper limiting value (fault) for EMC pressure 1 Default value EMC pressure 1 Averaging factor (damping) for EMC pressure 1 Mode EMC pressure 1 EMC Correction factor for temperature pressure 1 Correction factor for temperature CO2 Correction factor for pressure CO2 Max. permissible deviation from specified value CO2 Set value offset EMC carbon dioxide CO2 Lower limiting value differential pressure Upper limiting value differential pressure Switch off limit pressure 2 Fixed carbon dioxide offset Measured value carbon dioxide CO2, read from EMC Analog value carbon dioxide CO2, read from EMC Measured value output pressure P1, read from EMC Analog value output pressure P1, read from EMC Measured value differential pressure DP, read from EMC Analog value differential pressure DP, read from EMC
mbar mA Mol% mA % mbar mbar mbar
EMC Case Temperature
indirect Input and three times right
Column W Description of coordinates
37 D D D S S S S S tC-EMC tC tC-in tCmin tCmax tC-def tC-af tC-Trm Heading EMC case temperature EMC case temperature Input value EMC case temperature Lower limiting value (fault) for EMC case temperature Upper limiting value (fault) for EMC case temperature Default value EMC case temperature Averaging factor (damping) for EMC case temperature Mode EMC case temperature EMC Specified value EMC case temperature Measured value case temperature TG, read from EMC Analog value case temperature TG, read from EMC
C ohm C C C
S tC-Spec D tC-1106 D tC-1006
EMC Block Temperature
indirect Input and four times right
Column X Description of coordinates
37 D D D S S S S S S S S S S S tB-EMC tB tB-in tBmin tBmax tB-def tB-af tB-Start tB-spec tB-Hyst tB-Smin tB-Smax tB-SCyc tB-Time1 Heading EMC block temperature EMC block temperature Input value EMC block temperature Lower limiting value (fault) for EMC block temperature Upper limiting value (fault) for EMC block temperature Default value EMC block temperature Averaging factor (damping) for EMC block temperature Start temp. for target regulation of EMC block temperature Specified value EMC block temperature Hysteresis value for EMC block temperature Min. deviation from specified value of EMC block temperature Max. deviation from specified value of EMC block temperature Start cycles EMC block temperature Start time EMC block temperature Permissible values: 2 and 99 minutes Start time 2. Calibration of EMC block temperature Measured value block temperature TB, read from EMC Analog value block temperature TB, read from EMC
C ohm C C C C C C C C min min
S TB-Time2 D tB-1108 D tB-1008
The changed setting is only accepted after a restart of the analytical computer
direct Max. Values
Column Y Description of coordinates
D D D D S D C C C S S S S S S S D D S S EMC9000 RMG TstS1 CntS1 Code Opr.Hrs. Year Commis. DispLev SetCO2 SetP1 Setdp SetTC SetTB SetS1 SetS2 ERZ-CS Ver-ERZ ERZ-No. Reset Heading EMC device type Heading manufacturer Test value sensor 1 Test counts sensor 1 Code number to enable parameter input Indication of operating hours since startup Year of manufacture Time of startup Display level EMC Level 1 / Level 2 / Level 3 / Level 4 Test value CO2 Test value output pressure Test value differential pressure Test value case temperature Test value block temperature Test value sensor 1 Test value sensor 2 Checksum ERZ Software version ERZ Serial number ERZ Reset EMC OFF / Offset-Reset / Set A0 / EMC-Default / Hourly D. Arch. / Daily D. Arch. / Monthly D. Arch. / Min. D. Arch. / Event Reset Checksum EMC Software version EMC Memory version EMC Gas-type mode EMC 500 / EMC 500-L Calibration gas type mode Methane / Air Lamp test of top line (all segments on) Lamp test of bottom line (all segments on) GC-9000-EMC number (equal to field Y-30!) EMC No. (must be identical with field Y-29) Status front interface Status number of characters C1 interface Status number of characters C2 interface Status number of characters C3 interface Status number of characters C4 interface Status number of characters C5 interface Transmit/receive number of characters Front Transmit/receive number of characters C1 Transmit/receive number of characters C2 Transmit/receive number of characters C3 Transmit/receive number of characters C4 Transmit/receive number of characters C5 Test OFF / Static ON / Ramp ON Status user access (code number) Calibration switch position Available memory DSfG
D D D S
EMC-CS Ver-EMC DataLogg AirMode
S CGasmod D D S D D D D D D D D D D D D D S Lamp-Top Lamp-Bot Mfr-No. EMC-No. ST-FR ST-C1 ST-C2 ST-C3 ST-C4 ST-C5 TR-FR TR-C1 TR-C2 TR-C3 TR-C4 TR-C5 Test
D User-S. D Cal-S. D AM
C4 C4 Interface card in GC 9000 Using RMG-Bus: set all switches to ON or internal supply and bus termination! DIL switch Using DSfG: switches 2,3 = ON est = OFF, external bus ermination necessary. RS 485 inactive
RS 485 RS 232 RMG bus
RS 232 Printer
RS 232 Modbus
Default configurations for GCI Cable to rear panel: C2 C1 C3 C4
C4 needs external terminating resistors and a bus supply voltage (+5 V). Select the mode for the interface C4 by the DIL switch 5 on the CPU card: DIL 5 ON: RS 485 DIL 5 OFF: RS 232
Assembly Instructions for Pipe Connections
Cut pipe perpendicularly and remove fins. Insert pipe into fitting until stop is reached. Tighten nut with fingers only.
Prior to tightening the SWAGELOK nut, mark it in the 6 o'clock position.
Then tighten nut with 1 turns* until marking reaches the 9 o'clock position.
* For pipe connections sized 2, 3, 4 mm or 1/16", 1/8", 3/16", you must tighten the nut with a turn during initial assembly.
Insert pipe with clamping rings into fitting until stop is reached. Tighten nut with fingers only, then use wrench to tighten it with approximately turn.
HX500S GC4430 Newforce R1 Avant 1000F Voicemail RX-558R CQC1323NW JBL CS12 MD-MT888 TX-SR707 DVD-LX9 Thinkpad T41P G12LH V-2620DE B31322 D-E200 RC600PMD Magic IX 760-779 1490LMT Speed 7820 RTH7500D PNA 3215 Review - 1999 R1245AV XR-C540RDS XV-DV656 Observatory Zanussi F505 LX 700 PT-LC55E DCM-500AE Photo R800 D-108 OT-106 Asko 1555 DB246 CS300 ACD-12 AVH-P7500dvdii LX-1170II WK-3300 32PW9509 Impressa E20 WD-14700RD Deluxe HST-SE581 MAX XL DR125SM Bake Oven MP-9485SA V Plus CQ-RX400N AW4416 Zire 72 RK-ORA-E Tourist GYM 1000 VP-W75 Roland GT-8 E-TEN X800 DM1001X HDS-5X EP15A 32PFL5522D 05 EH777501E 35 PL UF-580 Portative LE37S62B 1000 DVX9700 Essential Chassis B2230H NV-7200 DV-RW260H S75398KG38 XVS1100A-2003 Siemens A51 CT-600J BE325 72145 Installation DCD-700AE 157-1 X-500 ECM-673 Soft Wave Z7590 MZ-42PZ44S Kameleon DG45ID SH-L32WBP CE107MST SR3NA-S AD-mscf1 CTZ-D6758 Cabriolet
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