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User Guide PMD 2450 Precision Microwave Detector (LDU 1000) Versions: PMD 2450-1, PMD 2450-2, PMD 2450-3, GTA 1000-1 Dual Energy Gamma Transmission Ash Analyzer with Am-241 and Cs-137 GTA 1000-2 Dual Energy Gamma Transmission Ash Analyzer with X-rays and Cs-137 GTA 2000 Triple Energy Gamma Transmission Ash Analyzer with X-rays, Am-241 and Cs-137 GTD 1000 Gamma Transmission Density Gauge with Am-241, Cs-137 or Co-60 Indutech GmbH Simmersfeld Germany INDUTECHprocess controls PMD 2450 Disclaimer Disclaimer Confidential!
This manual is intended for the use of Indutech GmbH, its representatives and customers. Distribution to others requires permission from Indutech. No responsibility is accepted for the correctness of the information in this user guide. The contents may change any time without prior notice. Copyright 2002 INDUTECH instruments GmbH All rights reserved. The content of this user guide was reviewed for conformity with the described hard- and software. Nevertheless, deviations cannot be ruled out. The information in this user guide is reviewed regularly and any corrections that may be required will be included in subsequent editions. We appreciate your suggestions for improvement. Indutech instruments GmbH, Ahornweg 6-8 72226 Simmersfeld, Germany Phone:
+49 (0)7484 / 9297-0 E-mail:
info@indutech.com Internet : www.indutech.com Rev. 1.2 / 2009-03-22 I PMD 2450 Disclaimer NOTICE / Licence Exempt:
This device complies with Part 15 of the FCC Rules and with Industry Canada licence-exempt RSS standard(s). Operation two Conditions. is subject following the to
(1) this device may not cause harmful interference, and
(2) this device must accept any interference received, including interference that may cause undesired operation of the device. Le prsent appareil est conforme aux CNR dIndustrie Canada applicables aux appareils radio exempt de licence. L'exploitation est autorise aux deux conditions suivantes :
(1) l'appareil ne doit pas produire de brouillage, et
(2) l'utilisateur de l'appareil doit accepter tout brouillage radiolectrique subi, mme si le brouillage est susceptible d'en compromettre le onctionnement. NOTICE :
Changes or modifications made to this equipment not expressly approved by Indutech instruments GmbH may void the FCC authorization to operate this equipment. NOTE: This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference in a residential installation. This equipment generates, uses and can radiate radio frequency energy and, if not installed and used in accordance with the instructions, may cause harmful interference to radio communications. However, there is no guarantee that interference will not occur in a particular installation. If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to try to correct the interference by one or more of the following measures:
Reorient or relocate the receiving antenna. Connect the equipment into an outlet on a circuit different from that to which the Increase the separation between the equipment and receiver. receiver is connected. Consult the dealer or an experienced radio/TV technician for help. WARNING! PROFESSIONAL INSTALLATION REQUIRED. Installation by professionals only!
Rev. 1.2 / 2009-03-22 II PMD 2450 Table of Contents Table of Contents DISCLAIMER TABLE OF CONTENTS LIST OF ILLUSTRATIONS 1. 1.1 1.2 1.3 1.4 INTRODUCTION Overview User Instructions Safety Instructions Radiation Protection Use and Function 2. BASICS 2.1 2.1.1 PMD Moisture meter 2.2 2.3 2.4 2.5 2.6 2.7 2.8 Microwave Measuring Principle Radiometric Measurement Scintillation Detector Radiation Source Shielding Evaluation Unit Horn Antenna General Operation Software Structure Input Menus Measurement Display Log-on via Password Entry Control Menu Menu Guidance 3. OPERATION 3.1 3.1.1 Applications 3.1.2 Measurements and Batch Runs 3.1.3 Hierarchical Menu Guidance 3.1.4 Control of External PC 3.2 3.2.1 Display with Touch Panel 3.2.2 Button Overview 3.2.3 3.3 3.3.1 Structure 3.3.2 Buttons 3.4 3.5 3.6 3.6.1 Structure 3.6.2 Buttons 3.6.3 Parameters 3.6.4 Service 3.6.5 Sampling 3.6.6 Zeroing 3.6.7 Calibrate 3.7 3.7.1 Start and Stop of Measurements and Batch Runs 3.7.2 Regular Measurement Process 3.7.3 Error and Alarm States 3.8 3.8.1 Overview 3.8.2 Telegram Types 3.9 Software Update Measurement Process Data Communication Rev. 1.2 / 2009-03-22 III I III V 1 2 3 4 5 7 8 8 10 13 14 15 16 17 18 19 21 21 22 23 24 24 24 24 25 27 27 29 30 33 34 34 35 36 41 47 47 50 57 57 58 59 61 61 62 67 PMD 2450 Table of Contents 69 70 70 70 70 70 71 72 72 72 72 75 75 76 76 76 76 76 80 81 83 84 84 85 85 85 86 86 87 89 89 91 91 91 91 91 Assembly Software Configuration 4. GETTING STARTED 4.1 4.1.1 Microwave Horn Antenna 4.1.2 Sources 4.1.3 Detector 4.1.4 Analog Sensors 4.1.5 Digital Switches 4.2 4.2.1 Language 4.2.2 Time and Date 4.2.3 System Parameters 4.2.4 Hardware Parameters 4.2.5 Display Configuration 4.2.6 Passwords 4.3 4.3.1 Basic Microwave Calibration 4.3.2 Zeroing 4.4 Sampling and Calibration Zeroing Microprocessor Module SE 0100 (CPU) Adapter Board SE 0006 5. TECHNICAL DATA 5.1 5.2 5.2.1 Analog Input of ADC for the Microwave Unit 5.2.2 Counter Inputs 5.2.3 Analog Inputs 5.2.4 Analog Outputs 5.2.5 Current Output for PT100 5.2.6 Digital Inputs 5.2.7 Digital Outputs 5.2.8 Connector Configuration 5.3 5.3.1 Serial Ports 5.3.2 Power Supply 5.3.3 Housing Dimensions 5.3.4 Protection Type 5.3.5 Ambient Temperature 5.3.6 Relative Humidity Connector Configuration on Connection Board SE 0008 Rev. 1.2 / 2009-03-22 IV PMD 2450 List of Illustrations List of Illustrations Figure 1: Principle of measurement ....................................................................................... 9 Figure 2: Configuration with two measuring points ...............................................................10 Figure 3: Scintillation detector ..............................................................................................15 Figure 4: Horn antenna for microwaves ................................................................................18 Figure 5: Menu for text entry ................................................................................................26 Figure 6: Numerical entry menu ...........................................................................................26 Figure 7: Selection list menu ................................................................................................27 Figure 8: Measurement display ............................................................................................28 Figure 9: Box displaying the measurable variable .................................................................28 Figure 10: User level selection menu ....................................................................................31 Figure 11: Control menu .......................................................................................................33 Figure 12: Main menu of PMD 2450 .....................................................................................34 Figure 13: Parameter menu ..................................................................................................37 Figure 14: Numbered fields in the measurement display ......................................................40 Figure 15: View all inputs menu ............................................................................................43 Figure 16: View Microwave data menu .................................................................................44 Figure 17: View Ash Data menu ...........................................................................................45 Figure 18: View Belt weigher data menu ..............................................................................46 Figure 19: Zeroing menu ......................................................................................................49 Figure 20: Measurement display of zero measurement ........................................................49 Figure 21: Control menu .......................................................................................................57 Figure 22: Connector configuration on circuit board SE 0008 in the cable chute ..................90 Rev. 1.2 / 2009-03-22 V PMD 2450 Introduction 1. Introduction Overview INTRODUCTION Overview User Instructions Safety Instructions Radiation Protection 1. 1.1 1.2 1.3 1.4 1 2 3 4 5 Rev. 1.2 / 2009-03-22 1 PMD 2450 Introduction 1.1 Overview This user guide describes how to work with LDU 1000 as the Precision Microwave Detector (PMD 2450), as GTA
(Gamma Transmission Ash) Analyzer or as GTD (Gamma Transmission Density) Gauge. You will find information on the basic principle of measurement as well as on the performance of the evaluation unit of the PMD 2450. Chapter 1: Introduction This introduction includes information on working with the instrument and information on the fields of applications of the PMD 2450, GTA and GTD. In addition, it includes codes of practice for handling radioactive sources. Chapter 2: Basics This chapter provides a summary of the theoretical basis of the principles of measurements, including the function of the microwave measurement for determination of the moisture content as well as the physical basis of radiometry. Chapter 3: Software This section of the user guide describes the structure and operation of the PMD software, in particular, the menu structure, the measurement operation and the service functions. Chapter 4: Getting Started Here you find important information on how to take the system into operation. Chapter 5: Technical Data In this chapter you will find all technical information relating to the hardware. Rev. 1.2 / 2009-03-22 2 PMD 2450 Introduction 1.2 User Instructions Purpose and Contents This user guide describes the LDU 1000 as PMD 2450 GTA or GTD and all product variants. Target Group The user guide has been written for users with a certain level of basic knowledge. User Guide Structure The user guide comprises 5 chapters. Each chapter describes a different subject matter. Document Guidance The following items in this manual provide user guidance:
Overall table of contents at the start of the user guide Overview about the content at the beginning of each chapture Availability The user guide is available as:
printout on paper PDF file
(download Adobe Acrobat Reader under http://www.adobe.de) Rev. 1.2 / 2009-03-22 3 PMD 2450 Introduction 1.3 Safety Instructions The PMD 2450 has been designed and manufactured for the on-line measurement of the water content in solid matter, powders and bulk goods density of aqueous solutions consistency of aqueous solutions residual carbon in flue ash The instrument is not suited for determining the water content of ice crystal water The GTA has been designed and manufactured to determine the ash content of coal. The GTD allows to determine the density of materials Documentation The user guide should be available to all employees in Installation Project planning Getting started Operation Before getting started and operating the components described in this user guide, please keep in mind:
Idle Status The instrument may be connected and modified by trained professional personnel only. National regulations and directives in the respective country of use have to be observed (installation, safety precautions ...). Disposal National regulations have to be observed to dispose off the instrument!
Rev. 1.2 / 2009-03-22 4 PMD 2450 Introduction 1.4 Radiation Protection Radiometric measurement methods are employed in many applications of the LDU 1000. Since these methods utilize radioactive sources, we will briefly discuss how to work with nuclear radiation. Overview Nuclear radiation acting on trigger chemical and biological reactions which, depending on the intensity, energy and action time, may modify, damage or destroy cells. living cells may To rule out health hazards, an international limit value has been stipulated for the highest permissible radiation exposure of the operating personnel of 1 mSv (100 mrem) per year as limit from the non-monitored area to the monitored in-plant area. The shielding design as well as the setup of the measuring system at the measurement point ensures that the radiation exposure will stay below this limit value in any case, provided the measuring system is handled properly. Radiation protection areas outside the shielding should be identified accordingly and secured, if necessary. Code of Practice Essentially, each employee has to endeavor through cautious behavior and adherence radiation protection regulations to keep the radiation exposure as low as possible, even within the legal limit values. the to The radiation absorbed by the body, and thus the harmful effect, is dependent on three factors, which are therefore important for the basic code or practice:
Distance The radiation intensity follows a square law of distance: doubling the distance to the radiation source reduces the intensity to one quarter. Always observe a fairly large distance to the source. Action time The longer the period of exposure to radiation, the higher the level of radiation exposure. Do not stay in the immediate vicinity of the source longer than absolutely necessary. This means that maintenance work or source replacement have to be planned thoroughly to ensure that work can be performed quickly and the Rev. 1.2 / 2009-03-22 5 PMD 2450 Introduction period of stay in the vicinity of the source is kept to a minimum. Shielding The source is shielded by the material surrounding it. There is an exponential relationship between the shielding effect and the product of thickness and density of the shielding material. Therefore, these materials have a high specific density and have to be sufficiently thick. Do not take the source out of its shielding. If necessary, the useful radiation beam has to be shielded as well. Radition Protection Officer A radiation protection officer has to be appointed in every factory. He or she is the contact for all issues relating to the measuring facility. He or she draws up the radiation protection rules tailored to the needs of the factory and defines codes of conduct which also may serve as basis of job instructions. Special incidents or accidents have to be reported to the radiation protection officer immediately who will then inform him/herself on the spot about the situation and take appropriate action, if safety or function of the facility is endangered. In addition, the radiation protection officer has to make sure that the regulations of the Radiation Protection Ordinance shall be complied with, in particular, the obligation of book-keeping and reporting special events as well as the duty of instructing other employees. Disposal of Radioactive Source All radioactive sources which are either not needed any more or which have decayed have to be disposed off at a governmental collection site or returned to the supplier. In particular, the national regulations for disposal of radioactive sources have to be observed. Rev. 1.2 / 2009-03-22 6 PMD 2450 Basics 2. Basics This chapter describes the principles of measurement, including the function of the microwave measurement for determining the moisture content as well as the physical basis of radiometry. theoretical basis of the Overview 2. BASICS 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 Use and Function Microwave Measuring Principle Radiometric Measurement Scintillation Detector Radiation Source Shielding Evaluation Unit Horn Antenna List of Illustration 7 8 10 13 14 15 16 17 18 Figure 1: Principle of measurement ....................................................................................... 9 Figure 2: Configuration with two measuring points ...............................................................10 Rev. 1.2 / 2009-03-22 7 PMD 2450 Basics 2.1 Use and Function 2.1.1 PMD Moisture meter The microwave moisture meter PMD 2450 is capable of measuring the water content of virtually any material noncontacting and on-line. Costly mechanical sampling devices and sample dividers are not needed. The material layer to be measured can be transmitted by microwaves directly on a conveyor belt, in a chute, a pipeline or a container made of nonconductive material. The measurement is carried out through the wall or the conveyor belt. Strongly varying layer thicknesses and bulk densities of the product being measured may be compensated for by an additional radiometric area weight measurement. Thus, the PMD 2450 works independent of the measurement geometry. Since measurement is performed in transmission, the entire material is evaluated, ensuring representative measurement at all times. transmitted Figure 1 shows the basic configuration of the moisture measurement. Microwaves are emitted by an antenna, pass through the material layer and are finally picked up by the antenna on the opposite side. The additional radiometric area weight measurement, which is not included with the basic version, consists of a radiation source in a shielding container and a scintillation detector. Both antennae as well as the scintillation detector are connected to the evaluation unit PMD 2450 using the connection cables supplied with instrument; the evaluation unit is set up directly next to the measuring point. the Rev. 1.2 / 2009-03-22 8 PMD 2450 Basics Figure 1: Principle of measurement Figure 1 shows the standard configuration. This configuration may be adapted to special measurement tasks. One PMD 2450 can manage two directly adjacent measuring points (see Figure 2); however, a microwave unit can be used only at one measuring point. GTA Ash measurement In addition to the Cesium transmission line the Ash measurement GTA has an Americium transmission line and/or a transmission with an X-ray tube as source. Because of the effect that the absorption of low energy gamma rays is dependent on the atomic number of the material and the fact, that the constituents of the ash have an higher atomic number than the constituents of coal, this method allows to determine the ash content of coal. GTD Density measurement For density measurement one gamma transmission line is necessary. As source Am, Cs or Co is used. Rev. 1.2 / 2009-03-22 9 Scintillation detector Gamma radiation source Microwave receiving antenna Microwave transmitting antenna Connection cable to measurement station PMD 2450 Basics Figure 2: Configuration with two measuring points In addition to measurements on conveyor belts, the PMD 2450 also offers the opportunity to determine the moisture in chutes, containers or pipelines. In pipelines one can measure the moisture or dry matter contents not only of bulk goods, but also of liquids. At variable product temperature, a temperature sensor may be used in each of to get a temperature-compensated measuring signal. two measuring channels in order the 2.2 Microwave Measuring Principle The material layer to be measured is transmitted by microwaves. The principle of measurement is based on the physical effect of phase shift (reduction of the propagation speed at high relative permittivity) attenuation (intensity decrease due to dielectric loss) of electromagnetic waves passing through moist material. Since water has a high relative permittivity, moist material Rev. 1.2 / 2009-03-22 10 Master-PC with evaluation software Conveyer belt 2 Microwave measuring path Radiometric measuring path Belt weigher Meas. point 1 Meas. point 2 Measuring system LDU 1000 Serial data line Conveyer belt 1 PMD 2450 Basics differs properties. from dry material due to changed dielectric Incident microwaves set free water molecules, which are not yet bound to dry matter, in rotation depending on the orientation of the electromagnetic field. This causes the phase shift and the attenuation. Thus, the PMD 2450 determines the amount of free water in the material being measured. Measurement of ice crystal water is not possible. Weakly bound water can be detected depending on the bond strength. Therefore, the measurement effect may depend on the particle-size distribution and the chemical composition of the product being measured if the binding of water to solid materials is changed. Conducting materials such as graphite or coke cannot be transmitted by microwaves. Likewise, the transmission of metal walls is not possible. The transmissionor metal-
reinforced conveyor belts is possible under specific conditions. Walls made of plastic, rubber or insulating materials having a fairly low relative permittivity and low dielectric the measurement. losses and have no influence on Phase measurements are additionally unambiguous only in the range of 360. Therefore the phase shift must be corrected by a multiple of 360. The phase shift is standardized on frequency. If we speak in the following about phase shift, always the stadardized value is meant, i.e. the dimension is degrees/GHz. The attenuation is expressed in a logarithmic scale. The dimension is dB. To get the phase shift and the attenuation caused by the material layer, a zero measurement i.e. a measurement without material must be done. The phase shift and the Rev. 1.2 / 2009-03-22 11 PMD 2450 Basics attenuation are the differences of the measurement with and without material. The water content W in the material being measured depends in good approximation linear on the occurring phase shift and the attenuation D according to the following equation
(1) taking into account that both, attenuation D and phase shift of the material. are proportional to the area weight refers to the bulk density and d to the layer thickness. A, B, C are the coefficients of the calibration function. Whereas conventional microwave moisture meters only use the attenuation, the PMD 2450 allows the moisture measurement using either the effects of phase shift attenuation combination of phase shift and attenuation of microwaves passing through the material. The microwave phase shift method is able to achieve a significantly higher accuracy than the generally used microwave attenuation method; this is true not only for a constant measurement geometry, but in particular on conveyor belts with varying material load. In contrast to the attenuation measurement, the phase measurement is hardly affected by material parameters such as temperature, salt content (electrolytic conductivity) and grain size. Moreover, the phase measurement is much less affected by disturbance variables (e.g. interferences) and by reflections. With a pure phase measurement one can, therefore, achieve an unequalled accuracy in on-line water content measurements for a variety of products. The phase method is exclusively employed for a majority of measurement tasks. A pure attenuation measurement may be carried out if the above mentioned disturbance variables are not an issue. In contrast to conventional microwave moisture meters, the PMD 2450 can utilize a wide variety of measuring frequencies for phase measurements as well as attenuation measurements. Thus, the influence of a variable measuring geometry frequency belt in a broad Rev. 1.2 / 2009-03-22 12 CdDBdAW****d*PMD 2450 Basics
(conveyor belts with varying reflections is significantly reduced. load) due to multiple A further increase of the measurement accuracy can be obtained through combination of attenuation and phase measurement for some special applications only. However, this is only meaningful if the attenuation is not distorted by additional other interferences or disturbance reflections in variable measurement geometries or varying salt contents and temperatures. A possibly remaining grain size influence, which may occur with pure phase measurements, may be reduced by a combined measurement. 2.3 Radiometric Measurement Equation (1) (see 2.2) shows that the influence of varying material layer thickness and bulk good density disappears through standardization relative to the transmitted area weight. The area weight is either determined by an additional radiometric measuring path or by an infrared sensor. is subject The radiometric transmission measurement is based on the physical effect that Gamma radiation passing through material being measured intensity decrease. The residual radiation having the intensity
, which is picked up by the scintillation detector, indicates the area weight, where the bulk density results in the transmission path. A constant distance between radiation source and scintillation detector is required. The intensity decrease may be described by the law of absorption to an
(2) refers to the intensity of the un-attenuated radiation and to the material-specific linear attenuation coefficient
(absorption coefficient). This coefficient is defaulted by the PMD 2450 depending on the radiation sources used. From equation (2) follows which simplifies the calculation (1) of the water content:
(3)
(4) Rev. 1.2 / 2009-03-22 13 I0IdoeIIdII0lnCIIDBIIAW00lnln PMD 2450 Basics In addition to the water content W in percent, the PMD
*d in g/cm2. This 2450 also displays the area weight value is calculated on the basis of the count rate ration according to (3), where deviations from the defaulted absorption coefficient can be corrected. The thickness of an addition wall to be transmitted or the conveyor belt only causes very minor constant radiation attenuation, i.e. it does not have any influence on the measurement effect. Thus, the radiometric measurement is extremely immune to interferences and is very reliable. The intensity of the radiation source decreases in the course of time. The time period in which it has decreased to half its original intensity is referred to as half-life period which differs depending on the type of radiation source. The PMD 2450 automatically compensates the radiation decomposition depending on the selected radiation source. for A radiometric area weight compensation need not be performed when layer thickness and bulk density are constant in a fixed measuring geometry. This is the case, for example, on conveyor belts transporting the same load all the time, or in pipelines or chutes which are always filled with the same material having a constant density. 2.4 Scintillation Detector A scintillation detector is used as radiation detector; its characteristic feature is its high specific sensitivity to Gamma radiation and a service life that is not affected by radiation exposure and is, therefore, not limited. Despite low source activities, the scintillation counter supplies a high count rate which simplifies result processing. The scintillation detector is equipped with a drift stabilization compensating for age and temperature related changes, thus ensuring high long-term stability. The scintillation detector consists of a NaI(Tl) crystal, a photomultiplier and an electronics module in a sturdy cylindrical stainless steel housing with integrated connection box. Rev. 1.2 / 2009-03-22 14 PMD 2450 Basics Figure 3: Scintillation detector to the is optically coupled frequency being proportional Gamma radiation triggers flashes of light in the crystal, their radiation intensity. The crystal to a photomultiplier. The flashes of light release electrons from the light-sensitive photomultiplier cathode. This flow of electrons is amplified by a so-called dynode system and, due to the high voltage applied, accelerated towards the anode, there generating an electrical pulse for each incident flash of light. These pulses are amplified in the electronics unit, then reduced by a division factor of 1, 2, 4, 8 and 16 and shaped into low-impedance square pulses of approx. 10V. The electronics unit also generates the high voltage required for operation of the photomultiplier. The +/- 15V supply voltage and standard pulses are transferred to the evaluation unit via the connection cable supplied. For ambient temperatures exceeding 50C, the scintillation counter may be equipped with a water cooling device which is available as an accessory. The standard version of the scintillation detector receives radiation from the front. On request, a special detector shielding may be supplied for radial irradiation. This shielding may also be installed later. 2.5 Radiation Source Gamma sources are used as radiation emitters. Typically, Cs-137, Am-241 or X-rays are used. The radiation emitted Rev. 1.2 / 2009-03-22 15 PMD 2450 Basics these isotopes is subject intensity by decrease. Each isotope has a characteristic half-life, i.e. the period after which only half of the original radiation intensity is still available. to a natural isotope frequently used The most for area weight compensation or density measurement is Cesium (Cs-
137), which is available as a point source. Its nuclear energy of 660 keV suffices to transmit normal pipe and chute walls. This nuclide is preferably used to transmit thicker layers. Cs-137 can be shielded very effectively. Its half-life is 30.3 years. The radiation absorption of Cs-137 is relatively uniform and virtually independent of the chemical composition of most common products being measured. Americium (Am-241) is available as a surface source, emitting radiation with 60 keV energy. It is used for measurements involving low area weights and thin layers. Due to its low energy, Am-241 can be shielded easily. Its half-life of 433 years is very long. Am-241 can be replaced by X-rays. These allows also to generate radiation with a lower energy. The radiation absorption depends on the atomic number of the chemical elements included in the product being measured. Therefore, its use is restricted to products of virtually constant chemical composition. 2.6 Shielding The radiation source is firmly installed in a shielding. The shielding container for Cs-137 is made of a sturdy cast iron or stainless steel housing filled with lead. The front of the container is closed by a metal plate. The radiation exit channel can be closed by a built-in rotating shutter. The shutter is operated from the rear via a lever which can be secured by a lock in open and closed position. A lock protects the source against unauthorized removal. The Am-241 area source is firmly installed into a shielding. The container front is also covered by metal plates. The shielding is provided with a lockable radiation exit channel with rotating shutter and lever. Rev. 1.2 / 2009-03-22 16 PMD 2450 Basics The X-ray tube is shielded. As an option X-ray tube is controlled by a thermal switch to avoid overheating and to switch the high voltage off in case of a fire. 2.7 Evaluation Unit The evaluation unit of the PMD 2450 is installed in a suitable wall housing. The microwave unit supplies the necessary high frequency and is directly connected to the horn antenna via cable. The high frequency connections are provided with HF-
sockets which are located on the left side wall of the housing. The PMD 2450 calculates the measured values, controls the microwave unit and supplies all control and operating voltages required the scintillation detectors. All inputs and outputs as well as the operating voltage are passed through PG bushings into the wall housing and connected to terminal strips inside the PMD 2450. for connection of The evaluation unit is operated via touch screen. Results and parameters are displayed on the LC display. Various displays can be selected with the arrow keys (see chapter 3.2). All system parameters can be selected and edited menu-
guided. Standard parameters are defaulted by the manufacturer, which significantly simplifies system calibration. Unauthorized manipulation of parameters can be prevented by entering a password. The measured data supplied by a connected scintillation detector, temperature sensor or tachometer are computed together with the microwave data obtained. The natural intensity decrease of is automatically compensated for nuclide-specifically. the radiation source used The system function is permanently monitored. In case of power failure or if the instrument is turned off, all parameters and the time remain stored. In its basic version the PMD 2450 is equipped with the following Euro cards:
SE 0100 CPU SE 0006 adapter card with counter in, analog I/O, digital I/O VNA 2750 microwave cassette power supply unit Rev. 1.2 / 2009-03-22 17 PMD 2450 Basics 2.8 Horn Antenna Horn-shaped emitters made of stainless steel are used as microwave antenna. The openings of the horn-shaped emitters are finished dust-tight with a plastic window. The radiation exit windows should be cleaned regularly because dust deposits may distort the results depending on area weight and water content. The antennae do not contain any electronic components; however, they should be protected against mechanical damage. Transmitting and receiving antenna are of equal design. They are connected to the HF-sockets on the housing. Figure 4: Horn antenna for microwaves Rev. 1.2 / 2009-03-22 18 PMD 2450 Operation 3. Operation This chapter of the user guide describes the structure and operation of software. Hereby the structure is explained for the moisture meter PMD 2450. The operation of the functions of the LDU 1000 follows the same structure and rules. Overviev 19 21 21 22 23 24 24 24 24 25 27 27 29 30 33 34 34 35 36 41 47 47 50 57 57 58 59 61 61 62 67 General Operation Software Structure Input Menus Measurement Display Log-on via Password Entry Control Menu Menu Guidance 3. OPERATION 3.1 3.1.1 Applications 3.1.2 Measurements and Batch Runs 3.1.3 Hierarchical Menu Guidance 3.1.4 Control of External PC 3.2 3.2.1 Display with Touch Panel 3.2.2 Button Overview 3.2.3 3.3 3.3.1 Structure 3.3.2 Buttons 3.4 3.5 3.6 3.6.1 Structure 3.6.2 Buttons 3.6.3 Parameters 3.6.4 Service 3.6.5 Sampling 3.6.6 Zeroing 3.6.7 Calibrate 3.7 3.7.1 Start and Stop of Measurements and Batch Runs 3.7.2 Regular Measurement Process 3.7.3 Error and Alarm States 3.8 3.8.1 Overview 3.8.2 Telegram Types 3.9 Software Update Measurement Process Data Communication Rev. 1.2 / 2009-03-22 19 PMD 2450 Operation List of Illustration Figure 6: Numerical entry menu ...........................................................................................26 Figure 7: Selection list menu ................................................................................................27 Figure 8: Measurement display ............................................................................................28 Figure 9: Box displaying the measurable variable .................................................................28 Figure 10: User level selection menu ....................................................................................31 Figure 11: Control menu .......................................................................................................33 Figure 12: Main menu of PMD 2450 .....................................................................................34 Figure 13: Parameter menu ..................................................................................................37 Figure 14: Numbered fields in the measurement display ......................................................40 Figure 15: View all inputs menu ............................................................................................43 Figure 16: View Microwave data menu .................................................................................44 Figure 17: View Ash Data menu ...........................................................................................45 Figure 18: View Belt weigher data menu ..............................................................................46 Figure 19: Zeroing menu ......................................................................................................49 Figure 20: Measurement display of zero measurement ........................................................49 Figure 21: Control menu .......................................................................................................57 Rev. 1.2 / 2009-03-22 20 PMD 2450 Operation 3.1 Software Structure 3.1.1 Applications The software of the LDU 1000 is designed as a modular system. Basically, following parameters can be measured at two measuring points:
the Measuring point 1 MW values Thermal value Ash Belt weigher Density Measuring point 2 Ash Belt weigher Density By upgrading the hardware by the microwave module VNA 2700 and the necessary software components, the LDU 1000 becomes a PMD 2450, which supports microwave measurements (MW values), e.g. to determine the moisture. installation of The microwave measurement measuring point 1. is available only at Microwave measured values The PMD 2450 is a microwave measuring system determining the phase shift and attenuation by the product being measured according to the principle of transmission. From these two measurable variables one can calculate certain physical measured values, e.g. the water or salt content of a product. Thermal value The thermal value is composed of the moisture and the ash content of a product being measured. Since the moisture content can be measured only at measuring point 1, the thermal value can also be measured at this measuring point only. Rev. 1.2 / 2009-03-22 21 PMD 2450 Operation Ash The ash content e.g. of coal is measured radiometrically using an Americium source. Optionally, the measuring point can be supplemented by an X-ray measuring path. Belt weigher The PMD 2450 is capable of measuring the mass flow on a conveyor belt with up to 5 radiometric measuring paths. Area weight compensation Compensation of layer thickness and bulk density is carried out via a counter or analog input, depending on the selected compensation method. In most cases, the radiometric measuring path with Cs-
137 is set up. Temperature compensation Using a temperature sensor, e.g. a PT100, the bulk good temperature can be determined and taken into account for calculation of the microwave value. Belt speed The belt speed is measured by a tachometer, whose pulses are fed into a counter input. Note Upon delivery of the instrument, the software components are configured depending on the application. The sensors to be connected are allocated to the inputs, as shown in the wiring diagram. 3.1.2 Measurements and Batch Runs Often one needs to know the mean value of measured values over a certain time. To this end, so-called batches or batch runs can be performed. The current measured values are averaged and displayed according to the Rev. 1.2 / 2009-03-22 22 PMD 2450 Operation counter-timer method (sum of all measured values divided by the elapsed measuring time). Batch runs can be started and stopped any time, just like regular measurements, see also chapter 3.5. A batch run always refers to an entire measuring point, i.e. when starting a batch all measurable variables of a measuring point are averaged. The current batch and the last batch are displayed in the measurement display, i.e. one sees the value of the current averaging and also the mean value of the previous batch run. When a batch is stopped, the current batch value is added to the value of the last batch value and the current batch value is reset to 0. Note Batch operation is meaningful only with on-going measurement. Therefore, starting a batch while a measurement has been stopped will initiate a measurement start. Accordingly, when a measurement is stopped while a batch is running, the batch is stopped as well. 3.1.3 Hierarchical Menu Guidance Parameters and service functions are included in a hierarchically structured, clearly arranged user-friendly menu. Rev. 1.2 / 2009-03-22 23 PMD 2450 Operation This menu is operated by means of softkeys which can be pushed directly on the display. This allows very intuitive user guidance. Chapter 3.6 contains a detailed description of the main menu with all submenu items. 3.1.4 Control of External PC The LDU 1000 can be remote-controlled via the serial port of an external PC. A special communication protocol has been defined which is send and received via the specially designed PC program LDU Communication. Thus, for example, important measurements can be started and stopped via PC. Moreover, all parameters can be set via PC. The port can either be configured as RS232 or RS485. For more details on data communication please refer to chapter 3.8. 3.2 General Operation 3.2.1 Display with Touch Panel The evaluation unit LDU 1000 is operated by means of softkeys which can be pushed directly on the display. This allows very fast and clear user-guidance. 3.2.2 Button Overview A button is depicted as a rounded black rectangle with a symbol or text printed on it. Rev. 1.2 / 2009-03-22 24 PMD 2450 Operation If a button is pushed, the position on the touch panel is evaluated and the respective function is triggered. button is needed to go to a selected menu or to The edit a parameter. ESC button: exit menu, cancel parameter entry. Note Entered parameters will be stored only when you return from the menu to the measurement display. Otherwise, the old parameters are still valid when you turn the instrument off and on again. With the Arrow keys the cursor bar is moved into the menu and parameters are entered via selection lists. Push the Key button to log on to the system before you can make any changes. To protect the system against unauthorized access, you should log off again by pushing the Key button before you exit the instrument. Push the Ctrl button to open the control menu to start and stop measurements and batch runs. Push the Start button to start a certain measurement, and the Stop-button to stop a measurement. Push the Menu button to open the main menu from within the measurement display. The Values button opens a submenu and you can view the measured values of a special measurement, e.g. the zeroing. 3.2.3 Input Menu Text entry Texts such as password or belt name are entered via alphanumeric keyboard. Each alphanumeric button contains three characters. Occasionally, one button has to be pushed several times or it has to be kept pushed until the desired letter appears. Rev. 1.2 / 2009-03-22 25 PMD 2450 Operation Figure 5: Menu for text entry About one second after the last button stroke, the flashing cursor bar advances to the next position and you may enter the next character. Push DEL to delete the last character. Push ESC to cancel the entry sequence. Push at the end to confirm entries. Figure 5 shows the keyboard for input of a password. Note When entering the password, the character entered last is replaced by an asterisk after about one second. Numerical entry Figure 6 shows the menu for entering numbers. Push DEL to delete the last digit. Push ESC to cancel the entry sequence. Push to confirm the entered number. Figure 6: Numerical entry menu Certain input limits have been defined for each parameter. If the entered value is outside these limits, an error message appears and the value is not accepted. Rev. 1.2 / 2009-03-22 26 ESCTEXT ENTRY:ABCDEFGHIJKLMNOPQRSTUVWXYZ1234567890/.DELG_ESCNUMERICAL ENTRY1234567890-.EDEL12.3456789_Value <= 10!PMD 2450 Operation These input menus are primarily needed for definition of the calibration coefficients, but are also used for other parameters. Selection lists Some parameters cannot be set as you like, but can only be set to certain default values which are chosen from selection lists. Figure 7 shows the selection list for definition of the language. On the left side you see a list of items you may choose (here: German or English), on the right side you see the currently selected item. Figure 7: Selection list menu Push the Arrow keys to browse through the selection list and push to select the desired item. Push ESC to cancel the selection process. 3.3 Measurement Display 3.3.1 Structure After power on of the instrument the measurement display is displayed (see Figure 8). Rev. 1.2 / 2009-03-22 27 ESCLANGUAGE1/1DeutschEnglishCurrent value:DeutschMenuCtrlM e a s. P o i n t 1M o i s t u r e% 8 . 7 9 00 . 00 . 0n o t c o n f i g.n o t c o n f i g.M e a s. P o i n t 1D e n s i t yg / c m 3 0 . 7 4 30 . 00 . 0 PMD 2450 Operation Figure 8: Measurement display The measurement display shows 4 fields, each displaying the values of one measurable variable. If the instrument is in the logged-on status (see chapter 3.4), you can go to the second page of the measurement display by pushing the Arrow key. The second page is structured in the same manner as the first one. In total, the measured values of 8 measurable variables can be displayed, 4 on each page of the measurement display. Figure 9: Box displaying the measurable variable As shown in Figure 9, each field displays the designation of the measuring point, the designation of the measurable variable with the respective unit, the currently measured value as well as the values of the current and last batch. Note The displayed unit of the belt weigher t/h (tons per hour) refers here only o the currently measured value. The unit of the batch value is tons. The configuration of the measurement displays, i.e. the definition which measured value is to be displayed in which field, is described in chapter 3.6.3 (Display). A measurement starts automatically upon power on of the instrument if at least one counter or analog input has been configured. See chapter 3.7 measurement process. for a detailed description of the Rev. 1.2 / 2009-03-22 28 M e a s. P o i n t 1M o i s t u r e% 8 . 7 9 00 . 00 . 0Designation ofmeasuring pointDesignation ofmeasurablevariableUnit ofmeasurablevariablecurrentmeas. valuecurrentbatchlastbatch PMD 2450 Operation 3.3.2 Buttons In the logged-off status, only one button is active in the measurement display at first, i.e. the log-on button (Key button). To have access to various functions, you have to log on to the system first by pushing this button. This process is described in detail in the following chapter. After you have logged on correctly, you get back to the measurement display. The instrument is now in the processing mode (see Figure 8). In the bottom line of the display you see next to the Key button the Menu and Ctrl (Control) buttons as well as two Arrow keys. With the Key button you can log on again and protect the instrument against unauthorised access. The current function is symbolized by the padlock. An open padlock stands for log-on, a closed padlock for log off. Push the Menu button to return to the main menu, where all parameters are set and many service functions are available (see chapter 3.6). Rev. 1.2 / 2009-03-22 29 PMD 2450 Operation Push the Ctrl button to open the control menu, where you can start and stop the measurement and the batch for both measuring points, see also chapter 3.5. With both Arrow keys you may move from the first page of the measurement display to the second one (and back). 3.4 Log-on via Password Entry Protection against unauthorized access During regular operation, the user interface of the PMD 2450 instrument against unauthorized access. To have access to the menu, you have to log on to the instrument. to protect locked the is For safety reasons you should log off as soon as you have completed your entries. If no button is pushed for 15 minutes, the user is automatically logged off by the program. Four user levels We distinguish 4 groups or levels of users in ascending order; the lowest group has the fewest, the highest group the most rights in the system. Depending on the selected user level, more or less instrument functions are available. Each level is protected by a separate password. These user groups are from bottom to top:
User
(fewest rights) Rev. 1.2 / 2009-03-22 30 PMD 2450 Operation Sampler Administrator Service
(most rights) Log-on process If the instrument is in the logged-off state, you have to push the Key button to go from the measurement display to the user level selection menu. Figure 10: User level selection menu Select the desired user level with the Arrow keys and confirm your selection by pushing the button. An input menu with an alphanumeric keyboard appears
(see chapter 3.2.3) and you can enter the password. Each character entered is replaced by an asterisk after about one second. You have to push the button to confirm the password. If your entry is correct, you get back to the measurement display. If not, an error message will be displayed
(Password wrong!), the entered character chain is deleted and you can enter the password again. Push the ESC button to cancel the log-on process and you get back to the measurement display. Default password All user levels are protected ex factory by the following passwords:
User Sampler Administrator You may change Parameters Passwords (chapter 3.6.3). this default setting
= A
= D
= G in the menu Rev. 1.2 / 2009-03-22 31 ESCLOG-ON AS:1/1UserSamplerAdministratorService PMD 2450 Operation With the function Factory setting in the Service menu
(chapter 3.6.4) you may reset the passwords again to the above values. Rev. 1.2 / 2009-03-22 32 PMD 2450 Operation 3.5 Control Menu Push the Ctrl button in the measurement display to get to the Control menu to start and stop measurements and batches for both measuring points. the left-hand side you see control buttons On for measuring point 1, on the right-hand side those for measuring point 2. Push a Start button to start a measurement; the Start button turns into a Stop button. On the other hand, a measurement is stopped by pushing a Stop button and the Start button appears again in place of the Stop button. Figure 11: Control menu Note Batch mode makes sense only while a measurement is running. Therefore, starting a batch while a measurement is stopped will also start a measurement. Accordingly, when a measurement is stopped while a batch is running, the batch is stopped as well. Note If you would like to make entries on a larger scale, it is advisable to stop all measurements in order to speed up the reaction of the display. The evaluation of microwave data is very time-consuming and may therefore slow down the presentation on the display. Rev. 1.2 / 2009-03-22 33 ESC1: ALIASMeasurement:2: ALIASBatch:Batch:StartStartStopStopMeasurement:PMD 2450 Operation 3.6 Menu Guidance 3.6.1 Structure The PMD 2450 menu is structured hierarchically, i.e. from the main menu you have access to various submenus which in turn provide access to further submenus. Figure 12: Main menu of PMD 2450 Note We will describe the menu items which are available to the instrument administrator. Users on a lower level do not have access to some parts of these menus. Push the Menu button in the measurement display to call the main menu (Figure 12). The main menu comprises six submenus:
Parameters This menu includes important system parameters, for example, parameters for the overall configuration or parameters which define certain hardware properties. Service This menu is particularly important during start-up and to identify errors; it includes many hardware test functions and shows the calculated measurable variables. intermediate results of Display Push the Display button to return to the measurement display. Note All parameters entered will be saved only when you return to the measurement display!
Rev. 1.2 / 2009-03-22 34 SAMPLINGDISPLAYCALIBRATESERVICEPARAMETERSZEROINGMAIN MENU02.09.2000 PMD 2450 Operation If you turn the instrument off after you have edited parameters and before you have pushed the Display button, the values you have changed will be lost and after power on you will again work with the previously set values. Sampling Sampling is important for calculation of the calibration coefficients. Presently, this calculation is exclusively performed by a PC program; therefore, the Sampling button is not yet used. Zeroing Separate zeroing is performed for both measuring points to take the influence of the conveyor belt on the measurements into account. Calibrate In determined through sampling. this menu you enter all calibration parameters Moreover, here you may define alarm thresholds for the individual measurable variables. With the exception of some special items on the Service menu, all submenus have the same structure:
The menu name appears in the left-hand side of the menu header, the current page number and the total number of pages of the menu on the right-hand side. Below that appear the menu data, i.e. various parameters and / or submenus. If the menu date is a parameter, the parameter name is left-justified, the value of the parameters right-justified in the same row. A submenu is also left-justified and is identified by three dots at the end of the name. The footer includes buttons to scroll through the menu, to open submenus, to enter parameters or to quit the menu. 3.6.2 Buttons Push any of the large buttons on the main menu to open the respective submenu. Push the menus to edit a parameter. button to open further submenus and input Rev. 1.2 / 2009-03-22 35 PMD 2450 Operation With the Arrow keys you can scroll through individual menu rows. Pushing the key in the bottom menu row will take you to the next the menu page, if the menu comprises several pages. Otherwise you get back to the first menu row. With the key you always jump from the first menu row into the last row on the previous page of the menu. Push ESC to exit a menu or to cancel an entry sequence. Push the Start or Stop button to start and stop special measurements, e.g. the zeroing. Push the Values button to open a submenu and to view the data of a special measurement, for example the zeroing. 3.6.3 Parameters This menu contains important system parameters, for example, parameters for the overall configuration or parameters which define certain hardware properties. Rev. 1.2 / 2009-03-22 36 PMD 2450 Operation Figure 13: Parameter menu System The System menu comprises the following parameters and submenus:
Port Configuration Allocation of inputs and outputs and serial port configuration. These functions are accessible to the service engineers only. This menu is not available to all lower user levels. Virtual Ports Virtual ports are used to simulate measured value transmitters which are needed for the measurement configuration, but which are not available. For example, a tachometer can be simulated at constant belt speed. The PMD 2450 can simulate 6 virtual counters, 4 analog inputs and 8 virtual digital inputs. At the counter and analog inputs you may enter values for the zeroing, in addition to the current values. These are needed to ensure that the software treats the virtual inputs in the same manner as the hardware inputs. Integration Times Here you can enter the integration times Int2 for measuring point 1 and measuring point 2 separately. Int2 defines for each measuring point the number of measured values which are included in the averaging. Rev. 1.2 / 2009-03-22 37 ESCSYSTEM PARAMETERS1/2Hardware...Display...Passwords...System time:System...10:15:32 PMD 2450 Operation The moving average calculation over N seconds is valid for all applications of the respective measuring point. The integration time Int1 (averaging of raw data) which is valid for both measuring points cannot be changed. Send to PC The LDU 1000 provides different data telegrams to the PC:
raw values (as phase shift attenuation, countrates or analog and digital inputs, etc.) measuring values (as moisture, ash, density etc.) both, raw and measuring values response. This frequency telegram transmits the microwave data for each frequency. This telegram is used for start-up and service only and can be received with a terminal program of the PC. Here you select which telegram is sent by the LDU 1000. Hardware In this menu the hardware of the measurement sequence and its components are described in more detail, for example, the belt positions of the respective detectors or the half-life times of the radioactive source. The measurement geometry, i.e. the distances of the sensors, are defined as follows. The last sensor, viewed in conveying direction, serves as reference point and has the distance 0. All other distances are measured from this zero point and are indicated in meters. For all detectors you can define a lower failure threshold which, if it is not reached, triggers a collective failure message and if configured is sent to a digital output. If both measuring points have been configured, first the inputs of measuring point 1 are listed in the respective submenu and then those of measuring point 2. Counter The respective tachometer constant has to be Rev. 1.2 / 2009-03-22 38 PMD 2450 Operation entered for the tachometer. Moreover, you can define a failure threshold. For all other counters you may define the belt position as well as the half-life time of the radioactive source in addition to the failure threshold. If the half-life time is 0, no half-life time correction of the counter pulses takes place. Analog inputs Enter the belt position for the analog inputs and define a failure threshold. Digital inputs If this Here you define the delay time of the digital inputs. the immediately respective digital evaluated, but only after the time entered here in seconds has elapsed. is unequal is not to 0, input time Microwave In addition to the belt position, three special parameters are entered here for the microwave measurement:
The MW mode defines the measurement mode for the microwave. We distinguish between:
measurement with constant fixed frequency
(CW normal), measurement at different fixed frequencies
(CW-swept) and measurement with several frequencies and best fit (sweep). The CW frequency defines the frequency used for measurement at constant fixed frequency. The third parameter defines if an internal attenuation element should prevent a too high microwave output. This attenuation element can either always be turned off, always be turned on or turned on or off automatically depending on the attenuation of the product being measured. Display The measurement display is configured here. For each measuring point you can enter a belt name with max. 13 characters via alphanumeric keyboard (see chapter 3.2.3). This belt name then appears in the Rev. 1.2 / 2009-03-22 39 PMD 2450 Operation instead of individual measurement Measuring point 1 or Measuring point 2. fields the term The individual measurement fields are configured via selection list where the number of a measurement field is allocated to a certain measurable variable. Figure 14 shows the numbering of the measurement field in the measurement display from right to left and from top to bottom: field 1 is in the upper left corner, next to it is field 2, below those fields 3 and 4. Fields 5 8 are arranged in the same manner on the second page of the measurement display (push the Arrow keys to go this page). Figure 14: Numbered fields in the measurement display Passwords On passwords to the various user levels. the Passwords menu you may assign new The User and the Sampler can only change their own password. The instrument administrator is entitled to change all passwords. With the Arrow keys, select the user level whose password you want to change and confirm your entry with the button. Now enter the new password on the alphanumeric keyboard and confirm it with the button. You have to enter the new password a second time and confirm it with . Time and date Enter the system time and the system date. Push the button to open the numerical entry window. Enter the current time or the current date and confirm your entry with the button. Rev. 1.2 / 2009-03-22 40 1 (5)3 (7)4 (8)2 (6) PMD 2450 Operation The new time is now written into the battery-buffered real-
timer clock on the microprocessor insert card. The time is retained even after power off of the instrument and you need not enter it new after every system start. Language Select the desired language from a selection list (see chapter 3.2.3). Presently, German and English are available, with English being the default language. Program version Shows the version number of the current software. The instrument administrator may perform a software update via this menu item. Chapter 3.9 describes the individual steps in detail. Last parameter change Shows when the parameters of the measuring system have been changed last. Note Date and time of the last parameter change serve only for your information and cannot be changed! They are updated automatically, as soon as a parameter is changed. 3.6.4 Service The Service menu includes many functions to test the hardware, to display intermediate result when calculating the measured values as well as quality criteria for assessment of the microwave measured values. Test Hardware Test of the hardware inputs and outputs of the adapter card SE0006 as well as the microwave cassette. To test the microwave cassette, the measurement for measuring point 1 has to be running; all other inputs can also be carried out with stopped measurement. test the outputs To the measurements first, so that the manually set values will not be overwritten by the measurement routine. is advisable to stop it The button is used to set a certain value for the outputs; on the other hand, it is without function for the inputs. Rev. 1.2 / 2009-03-22 41 PMD 2450 Operation Test Microwave 360) of The attenuation D and the phase shift phi (0 phi the measured microwave radiation is displayed while a measurement is running. The correction for calculation of the correct phase shift, which may be larger than 360 and which is calculated according to phicorr = n * 360 + phi. Delta phi the difference between the measured phase shift and a phase shift calculated according to plausibility criteria. important factor n indicates finally is Test Counter Inputs Here you see the count rates of the 6 counter inputs, measured in cps. Test Analog Inputs Values of both current inputs in mA. Test Digital inputs Shows the logical states (0 / 1) of the 8 digital inputs. Test Analog Outputs With the button you can set the 4 current outputs each to a value between 0 mA and 20 mA. The current is then set accordingly and can be measured using an Ampere meter. Test Digital Outputs Set / Reset the 4 digital outputs with the button and measure the set values again using a Voltmeter. Note The digital outputs are wired such that relays connected to it pick up in the normal state and are released in case of alarm. For this reason, a voltage of 5 V is applied at the logical 0, 0 V at the logical 1. Rev. 1.2 / 2009-03-22 42 PMD 2450 Operation View All Inputs In this menu all values of the hardware inputs averaged over the integration time Int2 are displayed. If a measurement is running, these values are updated each second. Figure 15: View all inputs menu Calculation Steps Intermediate results for calculation of the measurable variables are displayed in this menu. The results for each measuring point are display in a separate submenu. Both submenus basically have the same structure. Below, only the submenu of measuring point 1 will be discussed. The software supports all applications. However, if not all applications have been implemented, the respective submenus are missing. Tacho Displays the current belt speed [m/s] calculated according to Tacho constant * count rate. If no tachometer is available, the respective row shows the info Tacho not configured. Area weight Current area weight determined either radiometrically or by an analog sensor. Rev. 1.2 / 2009-03-22 43 ESCVIEW ALL INPUTSM i c r o w a v eA t t:0 . 0 1 6Phi:- 1 . 7 1 3A n a l o g I n1:0.02:0.0C o u n t e r s1 :0 . 02 :0 . 03 :0 . 04 :0 . 05 :0 . 06 :0 . 0D i g I n1 :12 :13 :14 :15 :16 :17:18:1 PMD 2450 Operation Microwave data Figure 16: View Microwave data menu the On left-hand side you see various intermediate values, on the right-hand side several assessment criteria for the measured values. Where:
Att:
attenuation Int2-averaged corrected by zeroing Phi:
m:
Att/m:
Phi/m:
MW1:
MW2:
Int2-averaged corrected by zeroing phase shift Int2-averaged area weight Attenuation respect to the area weight standardized with Phase shift standardized with respect to the area weight Microwave value 1 determined with coefficient set 1 Microwave value 1 determined with coefficient set 2 Phi-check: Phase shift calculated according to plausibility criteria n:
Rev. 1.2 / 2009-03-22 44 Correction the number of 360 shifts of the phase indicating factor ESCVIEW MICROWAVE DATAA t t:0 . 0 1 6P h i:- 1 . 7 1 3m:1 . 0 0 0A t t / m:- 0 . 0 1 4P h i / m:- 2 . 0 3 4M W 1:- 2 . 0 7 0M W 2:- 0 . 0 1 1P h i - c h e c k:0 . 0n:0D e l t a P h i:- 5 . 5 9 0C h i - S q:0 . 0O f f s e t:0 . 0 PMD 2450 Operation Delta Phi: Difference of measured phase shift to Phi-check. Chi-Sq:
Offset:
Only in sweep mode:
Square of fit error Chi at best fit due to the phase values measured at 10 different frequencies Only in sweep mode:
Phase shift determined according to the best fit at frequency 0Hz. Ash data This menu shows important intermediate values for calculation of the ash content. the most Figure 17: View Ash Data menu The signal flow occurs from left to right:
The left column lists the raw data, i.e. the count rates of the Americium source (Am) and the X-
ray rube (X) averaged over the integration time Int2 as well as the area weight m averaged over Int2. The averaged count rates serve only for your information and do not enter directly into the calculation formula. the natural The center column shows logarithms averaged over Int2 of the count rates referring to the zeroing, i.e. ln(I/Io)Am and ln(I/Io)X. In the right column, finally, the values of the center column are standardized with respect to the area weight, i.e.:
Q1 = ln(I/Io)Am / m Rev. 1.2 / 2009-03-22 45 ESCVIEW ASH DATA MP1R a w d a t aA m:0 . 0X:- - -m:0 . 0l n ( I / I o )A m:0 . 0X:- - -F a c t o r sQ 1:0 . 0Q 2:0 . 0Q 3:0 . 0A s h :0 . 0 PMD 2450 Operation Q2 = ln(I/Io)X / m Q3 = [ ln(I/Io)X ] / m The factors Q1 Q3 are inserted in the calculation formula for the ash content. The ash content calculated according to this formula appears at the bottom of this page. Belt weigher data Figure 18 shows the menu for the belt weigher calculation. Figure 18: View Belt weigher data menu Up to 5 measuring paths can be installed vertically to the belt moving direction to ensure fairly accurate calculation of the throughput. As with the ash data, the signal flow occurs from left to right. In the left column appear the count rates of the belt weigher counters 1 5 averaged over Int2. However, these values serve only for your information and do not enter directly into the calculation of the throughput. The center column shows the natural logarithms averaged over Int2 of the count rates referring to the zero rate, i.e. ln(I/Io)counter 1 to ln(I/Io)counter 5. To the very right you see the mean value of the data in the center column. This value is inserted into the calculation formula to calculate the throughput. Moreover, the belt speed averaged over Int2 appears in this column. At the bottom of this page you see the throughput calculated on the basis of the above data. Rev. 1.2 / 2009-03-22 46 ESCVIEW BELT WEIGHER MP1R a w d a t a1:0 . 02:- - -3:- - -4: - - -5:- - -l n ( I / I o )1:0 . 02:- - -3:- - -4: - - -5:- - -A v e r a g e:0 . 0T a c h o :0 . 0B e l t w . :0 . 0 PMD 2450 Operation Set Factory Defaults All instrument parameters are reset to their default settings. Caution Factory setting should be selected only in exceptional cases, because all parameters differing from the factory setting have to be entered new!
Moreover, all calibration and zeroing data will be lost!
It is therefore advisable to send all parameters to the PC via the serial port, before selecting factory setting, in order to be able to enter certain parameter groups again quickly. At least the hardware calibration should be put into intermediate storage on these calibrations can only be carried out new by service engineers!
the PC, because Note You may reset the instrument to the factory setting at system start by pushing the upper left corner of the display while turning on the instrument. Sampling is possible by means of a PC program and is not implemented in the PMD 2450. Zero measurements are performed this menu separately for both measuring points. Therefore, we will only describe zeroing of measuring point 1, zeroing for measuring point 2 is done in the same manner. in In addition, this menu includes the basic microwave-
calibration (provided the software supports the microwave application). MW Basic Calibration Basic calibration is necessary for all following microwave measurements. Therefore, it has to be performed and stored before the zero measurement. Any zero measurement of the microwave which may have been carried out earlier will be deleted and has to be repeated after basic microwave calibration!
Basic calibration is always performed with empty belt, just like the zero measurement!
3.6.5 Sampling 3.6.6 Zeroing Rev. 1.2 / 2009-03-22 47 PMD 2450 Operation This measurement is independent of the microwave measurement mode and, it need not be repeated after a change-over, for example, from CW-
normal to sweep. therefore, To perform basic calibration, call the respective submenu and push the Start button. The measurement takes only one second and terminated. The for all 10 adjustable attenuations and phase shifts frequencies are displayed in a result menu. is automatically You can repeat the measurement by pushing the Start button again. Save the values at the end by pushing the Save button or push the ESC button to discard the measured values. Push the Values button to view stored measured values of the last basic calibration. Zero measurement Zero measurement is necessary to take influences of the conveyor belt on into account. Therefore, it always has to be performed without the product being measured, i.e. with empty belt. the measurement Zero measurement is performed separately for both measuring points. Thus, it is possible, for example, to continue regular measurements at one of the measuring points, while a zero measurement is running at the other measuring point. To perform a zero measurement, select the respective measuring point on the Zeroing menu and confirm your choice by pushing the button. You will get to a submenu, where you can enable or disable the individual inputs which are to be selected with the Arrow key and the button. Selected inputs are identified by a checkmark (x). Only these inputs are zeroed after the start. Which inputs are to be displayed in this menu is dependent on the applications supported by the software. In individual cases, the menu contents may therefore differ from the one depicted in Figure 19. Rev. 1.2 / 2009-03-22 48 PMD 2450 Operation Figure 19: Zeroing menu After you have selected all inputs which are to be zeroed, push the Start button to start the zero measurement. The individual inputs will now be listed in a result menu;
the zero value stored last and below it the current zero value is displayed for each input. The current zero value is averaged according to the counter-timer method (sum of all measured values divided by the elapsed measurement time) and updated each second. If more than two inputs are zeroed at the same time, the result menu covers several pages; with the Arrow keys you can go to the various pages. Figure 20: Measurement display of zero measurement Push the Stop button to stop the zero measurement. Push the Start button again to repeat the measurement. Push the Save button to save the measured values as zero values. Not only the zero value is stored for each input, but also the current date. This is important for half-
life time correction of the counter. However, push ESC to exit the menu if you want to discard the measured values. Rev. 1.2 / 2009-03-22 49 ESCZEROING MP 11/1Area weight (A):Microwave:XValuesStartMEASURED VALUES MP11/1Attenuation (old):Phase (old):Phase (new):001.03Attenuation (new):0.06Stop PMD 2450 Operation Push the Values button (see Figure 19) to view the stored zero values and the date of the zero measurement any time. If you know the zero values e.g. from comparative measurements you may also enter them here manually. To do this, select the respective zero value with the Arrow keys. Then push the button to open the Numerical entry menu and type in the desired zero value. If you exit the Numerical entry menu by pushing the button, the entered value is accepted and the date of the zero measurement of the respective input is set to the current date. Note The zero measurement of the microwave is dependent on its measurement mode and, therefore, it has to be performed in the same mode as the later measurement. If you want to change the microwave measurement mode later, you, the zero measurement. therefore, have repeat to 3.6.7 Calibrate Coefficients for calculation of the measurable variables are entered and different alarm limits are defined on the Calibrate menu. The menu is divided into a submenu for measuring point 1 and one for measuring point 2. These submenus have an identical structure, apart from the fact that there are no microwave parameters for measuring point 2. Below we will therefore only describe the submenu for measuring point 1. MW phase calculation Here you enter the coefficients for calculation of the corrected phase shift regarding the multiple of 360. If the measurerd phase shift is standardized on the frequency, a 360 jump is displayed as a jump of about 133/GHz in the calculation steps submenu of the Service menu. Coefficients 4 values must be entered to calculate Phicheck from attenuation and area weight:
k1: slope of attenuation k2: slope of area weight Rev. 1.2 / 2009-03-22 50 PMD 2450 Operation k3: offset x: this value is normally 0 The measured phase shift phi is then shifted by a multiple of 360, so that:
phicheck 180 These coefficients are usually determined only during start up. Therefore, details to find the proper values for k1, k2 and k3 are given in chapter 4: Getting started. phi phicheck + 180. Parameters for calculation of Delta Phi (max) indicates the largest permitted difference between the corrected phase shift phi and the calculated phase phicheck. Delta Phi
(max) may be max. 180. If the measured difference Delta Phi is larger than Delta Phi (max), the measured value is discarded and the last valid measured value is used the measurable variables. In the sweep mode a best fit is drawn through the phase values measured at 10 different frequencies. Quality criteria of this best fit are the square of the fit error Chi-Sq and the so-
called offset, which indicates the phase shift at the frequency 0 Hz determined according to the best fit. Chi-square
(max) each indicate the largest value permitted for these quality criteria. If the measured fit error or the offset are greater than the maximum value entered here, the microwave value is rejected and the last valid measured value is used for calculation of the measurable variables.
(max) and Offset Calibration parameters Here you enter the coefficients for calculation of the measurable variables. Most of these coefficients are the result of sampling. Analog inputs The type defines if the input is a 0-20 mA input, or a 4-20 mA input or an input for temperature measurement using a PT100. Rev. 1.2 / 2009-03-22 51 PMD 2450 Operation The value at the bottom is the measured value, corresponding to the smallest current value:
with 0-20 mA input to the value at 0 mA, with 4-
20 mA input to the value at 4 mA. The value at the top corresponds to the measured value at 20 mA. If it is a PT100 input, the value at the bottom and the value the top have no meaning. The number of is also displayed for you information, but this number cannot be changed here. the analog input Analog outputs The type determines the current range of all four analog outputs. You may select the ranges 0-20 mA and 4-20 mA. The value in case of error defines the behavior of the analog outputs: either the outputs keep their last valid value before the error has occurred or they are set to the smallest value permitted (depending on the type, 0 mA or 4 mA). An error always exists if a hardware input fails or a belt alarm (including belt standstill or minimum load) occurs at one of both measuring points. Again, a bottom value and a top value are defined here, each indicating the value at the smallest output current permitted (0 mA / 4 mA) and the value at 20 mA. The number of is also displayed for you information, but this number cannot be changed here. the analog input Area weight You need three coefficients (A C) to calculate the area weight. The last one (C) is a constant. Measurement value = X1 A = Gradient X1 B = Gradient X C = Offset Calorific value The Calorific value is a Combination of Ash and Moisture content. Sampling provides four Rev. 1.2 / 2009-03-22 52 PMD 2450 Operation Ash coefficients (A D) for calculation. The last one (D) is a constant. A = Gradient Ash B = Gradient Moisture C = Ash Moisture D = Offset The ash content is calculated using a formula with nine coefficients (A I); coefficient I is a constant. At measuring point 1 the water content of the product being measured can be taken into account as well. To do this, enter the moisture content determined during sampling under mean value moisture. A = Gradient Americium B = Gradient X-Ray tube C = Gradient X-Ray tube square D = Load correction E = Moisture compensation F = Moisture compensation X-Ray G = Moisture compensation X-Ray H = Moisture compensation Load correction I = Offset Moisture The moisture content is calculated using a formula with eight coefficients
(A H);
coefficient H is a constant. A = Gradient Attenuation B = Gradient Phase shift C = Load correction D = Temperature compensation Attenuation E = Temperature compensation Phase shift F = Ash kompensation Attenuation G = Ash compensation Phase shift H = Offset Rev. 1.2 / 2009-03-22 53 PMD 2450 Operation Density The density content is calculated using a formula with
(A C);
coefficient C is a constant. three coefficients A = Gradient material layer B = Gradient material layer square C = Offset Material layer thickness The material layer thickness is calculated using a formula with three coefficients (A C);
coefficient C is a constant. The calculation is based on the difference of the reading from the belt weighter in relation to a zero measurement. Temperature compensation The temperature compensation is calculated using a formula with three coefficients (A C);
coefficient C is a constant. Measurement value = X1 A = Gradient Temperature B = Gradient Temperature square C = Offset Belt weigher The formula for calculation of the throughput has three coefficients (A C), the last one being a constant. Potash content You need four coefficients (A D) to calculate Rev. 1.2 / 2009-03-22 54 PMD 2450 Operation the potassium content. Coefficient D is a constant. MW-Value 1 and 2 From the microwave raw data attenuation and phase one can determine different measurable variables, such as moisture content, pH-value, salt content and others. Under MW measured value you may therefore select from a list which physical variables are to be calculated with the following coefficients. This name then appears in the measurement display instead of the term MW-value. There are eight coefficients (A H) for calculation of the desired microwave value;
coefficient H is a constant. For compensation of the material temperature as well as for ash compensation, enter the value determined during sampling under mean value material temperature or mean value ash. Alarm Meas. Values Here you can define a lower and upper alarm threshold for each measurable variable. In this manner you may set a window for each measurable variable, within which the measured value should lie. Moreover, you may enter a switching hysteresis in % for each measurable variable. The lower alarm will be reset only when the measured value exceeds the value
(1 + hysteresis[%] / 100) * limitlow. Accordingly, the upper alarm is reset only when the measured value drops below the value
(1 - hysteresis[%] / 100) * limithigh. A digital output can be assigned to each alarm. These outputs are wired such that a relay connected to them Rev. 1.2 / 2009-03-22 55 PMD 2450 Operation picks up during operation and is released if an alarm is triggered. Alarm Belt A belt alarm occurs if either the minimum load or the minimum speed of the belt is not reached. In this menu you can define a minimum load as well as a minimum speed. Again, there is also a switching hysteresis, so that the belt alarm will be reset only when the value
(1 + hysteresis [%] / 100) * limitlow is exceeded. With active belt alarm, the measurement continues to run;
however, averaging over the Int2-time is stopped and continues only after the belt alarm is over. Therefore, the measured value does not change during belt alarm. Following a belt alarm, the Int2-averaging does not start new, but continues regularly, as if averaging has never been interrupted. Example The Int2-time is 10 seconds. In the first second after the end of the belt alarm the last 9 values before the alarm has been triggered and the first value after the end of the alarm are used for averaging. Rev. 1.2 / 2009-03-22 56 PMD 2450 Operation 3.7 Measurement Process 3.7.1 Start and Stop of Measurements and Batch Runs Push the Ctrl button in the measurement display to get to the control menu where you can start and stop measurements and batches for both measuring points. On the left-hand side you see the control buttons for measuring point 1, on the right-hand side those for measuring point 2. Push the respective Start button to start a measurement;
the Start button turns into a Stop button. On the other hand, push a Stop button to stop a measurement; the Start button appears again in place of the Stop button. Figure 21: Control menu Note Batch mode makes sense only during on-going measurement. Therefore, starting a batch while a measurement is stopped will also start a measurement. Accordingly, when a measurement is stopped while a batch is running, the batch is stopped as well. Note If you would like to make entries on a larger scale, it is advisable to stop all measurements in order to increase the reaction of the display. Evaluation of the microwave data is very time-consuming and may therefore slow down the presentation on the display. Rev. 1.2 / 2009-03-22 57 ESC1: ALIASMeasure:2: ALIASBatch:Batch:StartStartStopStopMeasure:PMD 2450 Operation 3.7.2 Regular Measurement Process The measurement process is the same for both measuring points, except that no microwave evaluation is available for measuring point 2. Below we will therefore only describe measurement process for measuring point 1. Readout of hardware inputs All hardware inputs of the instrument are read out every 250 ms and saved for later averaging. A special feature is the microwave measurement at measuring point 1:
the internal attenuation element If switching of is dependent on the attenuation of the product being measured, it will be examined prior to each microwave measurement if the attenuation element should be turned on or off for the following measurement. In the CW mode a measurement is performed every 250 ms. In the normal CW mode one always measures using the same frequency, in the swept CW-mode, however, the frequency changes with each measurement. In the sweep mode 10 measurements at 10 different frequencies are performed once per second, the measured attenuations are averaged and the search for phase shift is determined by a best fit. Processing raw data Before processing the raw data any further, the zero measurement is subtracted first or, in the case of counters, standardized with the zero measurement. respect to If a tachometer has been configured, the raw data are now correlated, i.e. the belt distance between the individual measuring stations is taken into account. The data processed in this manner is then averaged over the Int2-time, i.e. the mean value of the last Int2 values is calculated. Calculating measurable variables The individual measurable variables are now calculated using the Int2-averaged raw data. If a batch is running in addition to the measurement, the calculated measurable variables for the batch value are averaged accordingly. Rev. 1.2 / 2009-03-22 58 PMD 2450 Operation Sending a data telegram A data telegram including the current measured values is sent to an external PC every second. In the menu Parameters System (see chapter 3.6.3) you can define if the instrument should send measured raw data or calculated measured data to the PC. Setting hardware outputs After calculation of the alarm thresholds are checked and the digital outputs are set accordingly. the measured data, Moreover, the configured current outputs of the measured values are set accordingly. 3.7.3 Error and Alarm States This chapter briefly describes how the instrument behaves if errors and active alarms occur. Hardware failure Hardware failure occurs when a measured raw value falls below the failure threshold of the respective hardware input. In this case a collective failure message may be generated and output as error to a digital output. Measurements continue to run, however, until they are stopped manually. lower and upper alarm Alarm of measurable variable A threshold defining a measurement display can be entered for each measurable variable. If the measured value is outside this permitted range, an alarm is triggered which can be sent to a digital output. Belt alarm A belt alarm occurs if either the minimum load or the minimum speed of the belt is not reached. As with the alarm thresholds of the measurable variables, there is also a switching hysteresis, so that the belt alarm will be reset only when the value
(1 + hysteresis [%] / 100) * limitlow is exceeded. With active belt alarm, the measurement continues to run;
however, averaging over the Int2-time is stopped and continues only after the belt alarm is over. Therefore, the measured value does not change during belt alarm. Rev. 1.2 / 2009-03-22 59 PMD 2450 Operation Following a belt alarm, the Int2-averaging does not start new, but continues regularly, as if averaging has never been interrupted. Example The Int2-time is 10 seconds. In the first second after the end of the belt alarm the last 9 values before the alarm has been triggered and the first value after the end of the alarm are used for averaging. Rev. 1.2 / 2009-03-22 60 PMD 2450 Operation 3.8 Data Communication 3.8.1 Overview PMD 2450 system The measuring supports communication with a PC via the RS232 / RS485 port and thus allows remote control of the measuring system. To this end, a special PC program has been designed to retrieve and edit parameters and send them again to the PMD 2450. Moreover, measurements can be started and stopped from the PC. The serial port parameters are set the menu Parameters System Port Configuration Serial Port. However, this menu is accessible only to service engineers. in The hardware has to be adapted to the configuration accordingly:
RS 232 Setup Jumper J1 on circuit board SE 0008 has to be set to open Screened, 5 wire cable, max. 30 m long RS 485 Setup Jumper J1 on circuit board SE 0008 has to be set to closed Screened, twisted cable Terminate both ends with 120 Ohm each (close J2 on circuit board SE 0008, do not forget terminating resistor on PC side). Rev. 1.2 / 2009-03-22 61 PMD 2450 Operation 3.8.2 Telegram Types Special data strings have been defined for data communication between PMD 2450 and external PC to transfer parameters or to send commands to the PMD 2450. These telegrams are divided into the following four groups:
Communication The communication in both directions: the PC sends commands to the PMD 2450 via this telegram, the PMD 2450 sends its answer to the PC. telegram can be sent Command telegram The PC can request all other telegrams individually via the communication telegram and thus send all parameters of the system to the PC. Moreover, measurement, batch run and zero measurement can be started and stopped separately for both measuring points. Answer telegram the communication The PMD 2450 sends telegram as an answer to telegrams received, which otherwise do not expect any further data string. The answer telegram is sent when a measurement has been started or stopped from the PC or if parameters have been set via a telegram from the PC. In this manner, you can check from the PC if a command has really been executed or parameters have been received correctly. Command and answer telegrams basically have the same structure;
start measurement at measuring point 1 and the answer that measurement at measuring point 1 has been started are identical. for example, command the to Rev. 1.2 / 2009-03-22 62 PMD 2450 Operation System The system parameters group comprises three telegrams which define the hardware parameters as well as the system configuration. Each of these telegrams can be sent in both directions. PMD 2450 hardware Hardware calibration analog inputs Hardware calibration analog outputs Isolation measurement of the microwave Attenuation and phase of internal attenuation element Configuration System date and time Send raw or measured data each second?
Port assignment of counter inputs Port assignment of analog inputs Port assignment of analog outputs Port assignment of digital inputs Port assignment of digital outputs Averaging times Int 1 and Int 2 Microwave measurement mode Microwave fixed frequency Execute phase check (with phicheck)?
Delay times of digital inputs Configuration of measurement display Language Peripherals hardware Tacho constants for both measuring points Belt positions Fail thresholds Half-life times Attenuation and phase of basic microwave calibration Zero microwave measurement Zero measurement (value / date) of real counters Zero measurement and measured value of virtual counters Zero measurement (value / date) of real analog inputs Zero measurement and measured value of virtual analog inputs Values of virtual digital inputs Calibration The telegrams Coefficients and Thresholds are Rev. 1.2 / 2009-03-22 63 PMD 2450 Operation summarized under Calibrate. Both telegrams can be sent from the PMD 2450 to the PC and vice versa. Coefficients Calibration of analog inputs Calibration of analog outputs Parameters for phicheck Parameters for area weight of measuring point 1 Parameters for microwave value 1 Parameters for microwave value 2 Parameters for ash of measuring point 1 Parameters for belt weigher of measuring point 1 Parameters for density of measuring point 1 Parameters for thermal value of measuring point 1 Parameters for area weight of measuring point 2 Parameters for ash of measuring point 2 Parameters for belt weigher of measuring point 2 Parameters density of measuring point 2 Thresholds Speed of measuring point 1, lower alarm threshold and hysteresis Area weight of measuring point 1, lower alarm threshold and hysteresis Microwave value 1, lower and upper alarm threshold as well as hysteresis Microwave value 2, lower and upper alarm threshold as well as hysteresis Ash of measuring point 1, lower and upper alarm threshold as well as hysteresis Belt weigher of measuring point 1 lower and upper alarm threshold as well as hysteresis Density of measuring point 1, lower and upper alarm threshold as well as hysteresis Thermal value of measuring point 1, lower and upper alarm threshold as well as hysteresis Speed of measuring point 2, lower alarm threshold and hysteresis Area weight of measuring point 2, lower alarm threshold and hysteresis Ash of measuring point 2, lower and upper alarm threshold as well as hysteresis Belt weigher of measuring point 2 lower and upper alarm threshold as well as hysteresis Density of measuring point 2, lower and upper alarm threshold as well as hysteresis Rev. 1.2 / 2009-03-22 64 PMD 2450 Operation Data There are a total of three data telegrams; raw data and measured data the PMD 2450, the telegram with the values of the analog output only by the PC. telegram can only be sent by Raw data Values of real and virtual counter Values of real and virtual analog inputs Values of real and virtual digital inputs Attenuation and phase of the microwave Phase offset of best fit (in the sweep mode) Fit error Chi-Sq of best fit (in the sweep mode) Delta phi Correction factor n Temperature of PT100 Area weight of measuring point 1 Area weight of measuring point 2 Measured data Microwave value 1, Current measured value as well as current and last batch value Microwave value 2, Current measured value as well as current and last batch value Ash of measuring point 1, Current measured value as well as current and last batch value Belt weigher of measuring point 1, Current measured value as well as current and last batch value Density of measuring point 1, Current measured value as well as current and last batch value Thermal value of measuring point 1, Current measured value as well as current and last batch value Ash of measuring point 2, Current measured value as well as current and last batch value Belt weigher of measuring point 2, Current measured value as well as current and last batch value Density of measuring point 2, Current measured value as well as current and last batch value Rev. 1.2 / 2009-03-22 65 PMD 2450 Operation Frequency response The content if the telegram is:
telegram adress telegram adress frequeny [Mhz]
attenuation [dB]
attenuation*f(x) Phi [/Ghz]
PhiCheck [/GHz]
Delta (Phi-PhiCheck) []
area weight Analog outputs This telegram allows you to set the analog output directly from the PC. However, this is allowed only if the analog output is not used by the measurement routine!
Value of analog output 1 Value of analog output 2 Value of analog output 3 Value of analog output 4 Rev. 1.2 / 2009-03-22 66 PMD 2450 Operation 3.9 Software Update A software update of the PMD 2450 can easily be performed by a service engineer. The required tools as well as the individual steps are described in detail below. Tools PC with free serial port (e.g. COM1) and Windows operating system Normal zero modem cable, each TxD and RxD or RTS and CTS crossed Terminal program to send the new software to the instrument We recommend using the terminal program TeraTerm
(TTerm), because transfer is much faster with this program terminal program the Windows hyper than with New program version Vx_x.hex (e.g. V2_5.hex) Preparation All system and the calibration parameter telegrams have to be sent to the PC and should be saved temporarily, since the parameters contained therein may get lost during update An update always has to be performed in the RS232 mode. If a RS485 line is being used normally, open jumper J1 on circuit board SE 0008 and replace the twisted two-wire connection cable to the PC by a 5-
wire data cable (zero modem cable) Now start the terminal program ttermpro.exe (or another one) and check the following settings (in Tera-
Term in Setup menu Serial Port) Port:
Baud rate:
Data:
Parity:
Stop:
Flow control: Hardware COM1 (or correspondingly) 9600 8 none 1 bit In the Parameters submenu of the PMD 2450, select the item Program version and confirm with the -
button. Answer the prompt that comes up with Yes and then confirm it once more. Now call the boot program (Boot loader), which deletes the current program and then prompts you to send the new program. Rev. 1.2 / 2009-03-22 67 PMD 2450 Operation Note The boot program can also be started directly at system start. To do this, push the upper right corner of the LCD display during power on. Start transfer Select the menu item File Send File in the TeraTerm program (or in another terminal program) Search for the file with the new program version Vx_x.hex
(e.g. V2_5.hex) and select this file by double-clicking on it. Now starts the transfer of the new programs. During transfer, dots are depicted in the TeraTerm program window and Downloading appears on the PMD 2450 display. The transfer takes about 7 10 minutes. (Please do not move the window of the terminal program during this time). Then the new program is started immediately. Parameter transfer Parameters may get lost during program update. Please check during the first system start immediately following the update if the parameters have been loaded correctly. In case of error, the following message is displayed:
Loading Parameters... Cannot load Parameters!
Restarting for Defaults!
ERROR In this case, all parameters are set to the default setting. To restore the original configuration again, send all system and calibration parameter telegrams from the PC to the PMD 2450. Rev. 1.2 / 2009-03-22 68 PMD 2450 Getting Started 4. Getting Started This chapter describes how to take the PMD 2450 into service. Start-up always has to be performed by a service engineer, since some submenus and parameters are accessible only to the highest user level. Overview 69 70 70 70 70 70 71 72 72 72 72 75 75 76 76 76 76 76 Assembly Software Configuration 4. GETTING STARTED 4.1 4.1.1 Microwave Horn Antenna 4.1.2 Sources 4.1.3 Detector 4.1.4 Analog Sensors 4.1.5 Digital Switches 4.2 4.2.1 Language 4.2.2 Time and Date 4.2.3 System Parameters 4.2.4 Hardware Parameters 4.2.5 Display Configuration 4.2.6 Passwords 4.3 4.3.1 Basic Microwave Calibration 4.3.2 Zeroing 4.4 Sampling and Calibration Zeroing Rev. 1.2 / 2009-03-22 69 PMD 2450 Getting Started 4.1 Assembly 4.1.1 Microwave Horn Antenna 4.1.2 Sources The horn antennas are fixed at the measuring frame rectangular to the material with the supplied mounting adapters. The two antennas must be in line, but the beam of the antennas is so wide, that a fine-adjustment is not necessary. The shielding container are supplied filled with the ordered sources. The shieldings are fixed at the mounting frame with the supplied fixing adapters at the provided places.
(See figure 1: Principle of measurement.) The sources are locked when supplied, i.e. the useful beam is blocked. The source is allowed to open only in coordination with the radiation protection officer. The useful beam is strongly collimated, typical 5. Therefore it is necessary, that the detector is adjusted on the beam. (see the chapter Detector). 4.1.3 Detector The szintillation detector has to be mounted with the supplied fixing adapter to the mounting frame at the provided place. (see Fig.1: Principle of measurement) The adapter has slotted holes and is adjustable in x- and y-
direction. A fine adjustment is necessary because of the narrow collimated useful beam (typical 5). The fine-
adjustment is done with opened shielding. This work is therefore to be done during start up by trained personal only in cooperation with the radiation protection officer. The adjustment is to be done with a hand held radiation detector. The adjustment is fine, if at all sides of the detector window the same radiation level is detected. Then the center of the beam is exactly adjusted to the detector. 4.1.4 Analog Sensors Sensors with analog 0/4-20 mA outputs are optionally used according the customer specific installation. The LDU 1000 provides 2 analog inputs. One of them can alternatively configured to connect directly a PT 100 temperature temperature measurements are performed with infrared temperature sensors. Optical, laser or ultrasonic distance sensors are Contactless sensor. Rev. 1.2 / 2009-03-22 70 PMD 2450 Getting Started used for distance measurements. The area weight can be determined by a belt scale as an alternative to the nuclear method. 4.1.5 Digital Switches Digital switches can be options of the supplied system, e.g. the sampling switch or supplied by the customer and are possibly installed far away from the installation point, e.g. a set of switched for the type selection, which is installed in the control room. In general, the digital inputs of the LDU 1000 are controlled by potential free contacts. They can be switched manually, by relays or directly by the PLC. The cabling for the external contacts must be taken in account before the start up. The following functions are controlled by digital switches:
sampling beltstop measurement start / stop batch start / stop zero measurement start / stop type selection (4 Bit) These functions are available for both measuring points. The LDU 1000 provides 8 digital inputs, i.e. not all functions provided by the software can be realized. A selection must be done during the engineering of the installation. Rev. 1.2 / 2009-03-22 71 PMD 2450 Getting Started 4.2 Software Configuration Once all measuring units as well as possible outputs have been connected to the LDU 1000, connect the instrument to mains supply and turn it on. Since the instrument has a wide range input of 90 260 VAC, the standard voltage ranges 110V AC (60 Hz) and 230 V (50 Hz) are covered. Different country-specific supply voltages need not be observed. The program jumps directly to the measurement display. Log on to the system as a service engineer and then push the Menu button to go to the main menu. Note All settings, calibration and zero values will be written into the non-volatile memory only after you have closed the main menu and returned to the measurement display!
However, if you turn the instrument off before you have changed over to the measurement display, the changes made up to that point will be lost!
4.2.1 Language 4.2.2 Time and Date Select the language you want to work with in the Parameters submenu. You may choose either German or English; English is the default setting. In the Parameters submenu, check the system time and the system date and correct this data, if necessary. 4.2.3 System Parameters Now select the submenu Parameters System. Rev. 1.2 / 2009-03-22 72 PMD 2450 Getting Started Port Configuration Assignment of In- and Outputs In Port Configuration you define the functions of the individual in- and outputs by allocating the number of the respective input or output to a function. The configuration is defined on the following menus:
Counter / analog inputs Analog outputs Digital inputs and Digital outputs A certain port is selected from a selection list. Virtual inputs are identified in the selection list by a (V). Serial port Three parameters are defined on the Serial Port submenu for communication with an external PC. important which are The instrument ID indicates the PMD 2450 instrument address which is sent to the PMD 2450 along with each telegram. This address is important particularly if several PMD 2450s are combined to a network, because in this manner each individual instrument of the network can be addressed via PC. The baud rate indicates the data transfer rate;
the default setting is 9600 baud. The mode, finally, defines if connection with the PC has been established via RS232 or via RS485 line. The hardware has configuration accordingly:
to be adapted to the Rev. 1.2 / 2009-03-22 73 PMD 2450 RS 232 Getting Started Jumper J1 on circuit board SE0008 has to be open Screened, 5-wire cable, max. 30 m long RS 485 Jumper J1 on circuit board SE0008 has to be closed Screened, twisted cable Terminate both ends with 120 Ohm each (close J2 on circuit board SE0008) For more information on serial communication please refer to chapter 3.8. Virtual ports Here you enter the values for the virtual signal transmitter. To make sure these virtual inputs are treated in the same manner as the real ones, you may also enter values for the zeroing for the counter and analog inputs. Integration times Integration time 1 defines how many raw data will be averaged for calculation of the area weight. It is defined as a multiple value of the so-called dead-time, which is 250 ms. The Int-1 time is presently 4, i.e. the calculated area weight is average over one second. Presently, this value cannot be changed. In addition to the fixed Int-1 time, there is a second integration time Int-2 for each measuring point. Int-2 defines over how many seconds (rather: values averaged over how many Int-1) the raw data for calculation of the actual measured values will be averaged. Telegram type Here you define if the PMD 2450 should each second send the current raw data or the already calculated measurable variables to an external PC during measurement. Rev. 1.2 / 2009-03-22 74 PMD 2450 Getting Started 4.2.4 Hardware Parameters Go to the following settings in the menu Parameters Hardware. Note Depending on the applications, some submenus described below may not be available. Counter inputs Enter the belt position as well as a failure threshold for each counter;
the tachometer constant instead of the belt position. tachometers, you enter the for Analog inputs Here you define the belt position and a failure threshold. Digital inputs Here you may define a delay time for the digital inputs. In this case, is not evaluated immediately, but only after the time defined here is over. respective input the Microwave In addition three microwave measurement parameters are defined here: measurement mode, fixed frequency in case of a CW-measurement and the mode of operating the internal attenuation element. the belt position, to Note The last measuring station in moving direction of the conveyor belt has belt position 0. All other positions are defined relative to this reference point. 4.2.5 Display Configuration Here you choose from a selection list which measurable variable the measurement displays. to be displayed in which field of is If needed, you may assign each measuring point a unique name. Rev. 1.2 / 2009-03-22 75 PMD 2450 Getting Started 4.2.6 Passwords We recommend changing the default setting of the passwords in order to rule out any unauthorized access to the instrument. in any case, 4.3 Zeroing Once you have configured the system, you may now perform the required zero measurements to take the influence of the conveyor belt on the measurement into account. To do this, call the Zeroing menu on the main menu. Zero measurements are always carried out without any product, i.e. with empty belt. 4.3.1 Basic Microwave Calibration Before carrying out the actual zeroing, you have to perform a basic calibration of the microwave cassette. Basic calibration for all subsequent measurements and, therefore, has to be carried out prior to the zeroing. important is 4.3.2 Zeroing This measurement is independent of the microwave measurement mode and, therefore, need not be repeated after changing from CW-normal to sweep. Following the basic microwave calibration, a zero measurement is performed separately for both measuring points, as described in detail in chapter 3.6.6 (Zeroing). 4.4 Sampling and Calibration After the zero measurement the sampling can be started for all systems apart form the PMD 2450. Here some special settings are necessary to eliminate ambiguity of the phase measurement. Additional settings for the PMD 2450. During startup it must be checked, if the multiple of 360 is proper selected. Otherwise the whole sampling work is useless. Therefore this step is extremely important. Rev. 1.2 / 2009-03-22 76 PMD 2450 Getting Started The multiple of 360 is selected by proper coefficients k1, k2 , k3 and x to calculate Phicheck. The following measurements are performed with a running belt with a constant load. If it is impossible to get a constant load, the full belt can be stopped. Select the telegram frequency response and visualize the reading with a terminal program on the PC. Displayed are the readings of at 10 frequencies, as described in chapter 3.8. The telegram has no header, but the readings are transmitted in the order as described here. At first a proper value for x must be selected: x can be selected in the range between 0 and 2. To find a proper value for x in the frequency telegram the attenuation*f(x) must be observed. This value should be independent of frequency. For comparable dry materials the value is 0. For materials with a higher moisture x becomes higher. In the second step proper values for k1, k2 and k3 must be determined. The phase shift versus frequeny must be observed: If the phase shift versus frequency is more or less constant the multiple of 360 is correct. If the slope is negative, the multiple of 360 is to high. If the slope is positive the multiple of 360 to small. Therefore the curve with the smallest positive or negative slope must be found. At first we set k1=0 and k2=0. We work with k3 only. Check at first if within the frequency response is no phase jump. If a phase jump is observed set k3 to a positive value, that no phase jump happens. If this is achieved, set k3 to an approximately average value of Phi. If the slope of Phi versus frequency is now positive, increase k3 by 133. Repeat this step until the slope becomes negative. Reduce K3 by 133 and check, if this is the smallest positive or negative slope, which can be obtained. If this slope is obtained, set again K3 to the average of Phi. Calculate now k1 and k2:
k1 = 0,1 * k3 /attenuation*f(x) k2 = 0,9 * K3 / area weight frequency Enter now the values for k1 and k2 and set k3=0. Observe the if approximately Phi = Phicheck. Maybe, a little change of k3 is necessary. Now we have start-values for k1 to k3, which must be approved. telegram and check, response Rev. 1.2 / 2009-03-22 77 PMD 2450 Getting Started In the first step change the load within minimum and maximum of the normal use and check, if the phase shift has no phase jumps. After this check switch the telegram to raw and measured data. Sampling can be started and stopped directly at the PC or with an optional the sampling switch, which is installed near the place, where the samples are taken. The switch is connected to the digital input of the LDU 1000, which is defined as sampling trigger. In the first step sampling is started and stopped. The load as well as the moisture content should vary within the full range. In this stage it is not necessary to take samples for the laboratory analysis. These samples are stored in the sampling table of the PC. With sufficient samples a regression can be started on the PC to calculate new values for k1, k2 and K3, as described in the manual of the IT-RQDS LDU Acquisition. Input these values in the LDU. The system is now calibrated for k1, k2, k3 and x. From time to time the coefficients should be checked based on the samples taken recently. Determination of the calibration coefficients. Now sampling can be started measures together, e.g. moisture, ash and calorific value. implemented for all Sampling is carried out exclusively via the PC program IT-
RQDS. To get the required raw data, you have to start a regular measurement in the PMD 2450 and send the raw data or the raw and measured data telegram to the PC each second. These values are then processed for sampling by the PC program. During the sampling periods samples are taken for the laboratory. The length of the sampling period depends on the conditions at the installation site. If an mechanical sampling system is determined by the frequency of the sampler to get a representative sample according the national or international standards, which must be applied. However, the sampling time should not be to long to avoid, that the sampling is available time extreme high of low values are averaged. Therefore it is maybe necessary to increase the frequency of the sampler, if possible. If no mechanical sampling system is available the samples must be taken manually and the sampling time will be comparably short to reduce the laborious work. Typical is a sampling period of 10 minutes with a sampling frequency of two sub-samples per minute. Rev. 1.2 / 2009-03-22 78 PMD 2450 Getting Started If a sampling according Iso/Dis 15239 or similar standards is required, the frequency of sub- samples should be doubled and the sub-samples are collected alternating to a sample A and sample B to calculate the sampling and laboratory error. If the laboratory results are available the results are manually entered in the sampling table of IT-RQDS LDU Acquisition. If a A- and B-sample is available, use the avarage. With a sufficient number of samples the calibration coefficients are determined with the calibration part of the IT-RQDS LDU Acquisition, which are later used to convert the raw data into measured values. The values of the measures should be spread over the full range. A typical number of samples is 30. The Calculation of the coefficients is described in the manual of the IT-RQDS LDU Acquisition. The result is displayed in a graphic and it is easy to determine and exclude out-layers. The coefficients must be transferred to the LDU 1000. This can be done manually or over the RS232/ RS 485 data link. With the new calibration coefficients the LDU 1000 displays and transmits the calibrated measures over analog and digital outputs. Rev. 1.2 / 2009-03-22 79 PMD 2450 Technical Data 5. Technical Data In this section you will find all technical information on the hardware. Overview Microprocessor Module SE 0100 Adapter Board SE 0006 5. TECHNICAL DATA 5.1 5.2 5.2.1 Analog Input of ADC for the Microwave Unit 5.2.2 Counter Inputs 5.2.3 Analog Inputs 5.2.4 Current Output for PT100 5.2.5 Analog Outputs 5.2.6 Digital Inputs 5.2.7 Digital Outputs 5.2.8 Connector Configuration 5.3 5.3.1 Serial Ports 5.3.2 Power Supply 5.3.3 Housing Dimensions 5.3.4 Protection Type 5.3.5 Ambient Temperature 5.3.6 Relative Humidity Connector Configuration on Connection Board SE 0008 80 81 83 84 84 85 85 85 85 86 87 89 89 91 91 91 91 91 List of Illustration Figure 22: Connector configuration on circuit board SE 0008 in the cable chute ..................90 Rev. 1.2 / 2009-03-22 80 PMD 2450 Technical Data 5.1 Microprocessor Module SE 0100 (CPU) The functions described here are implemented on the CPU board SE0100, but not all functions are available via the connections. See also Adapter Board SE 0006. Microprocessor Motorola MC68340 with 32 bit central processor unit; max. 25 MHz, programmable. Memory Two flash EPROMs with up to 1 MByte memory each;
one static RAM with 512 Kbyte. Real timer clock Integrated crystal, frequency tolerance (< 50 ppm, ageing effect (< 5 ppm / year. RS 232 ports Two asynchronous serial ports with hardware handshake;
baud rate 40 to 76.8 k baud adjustable, V 24 electrical driver. RS 485 port RS485 driver module can be activated alternatively for second RS232 port via jumper. Digital inputs Three digital for status monitoring; standard CMOS level; input filter with pull-up resistors. inputs via 25 pole socket Open collector outputs Three open collector outputs via 25 pole socket for connection of external relays, + 12 V, max. 100 mA. Counter inputs Six counter inputs via 25 pole socket, CMOS level, Rev. 1.2 / 2009-03-22 81 PMD 2450 Technical Data positively edge-triggered, pulse width > 100 ns, input impedance 1 kOhm, max. count rate up to 8 MHz, dependent on readout rate of counter modules. Acoustic Piezo signal transmitter, 83 dB in 10 cm distance. Data lines Via 64 pole connector, buffered with bus driver, D8 to D15. Address lines Via 64 pole connector, buffered with bus driver, A0 to A7. Chipselect outputs Via 64 pole, buffered with bus driver, CS4 to CS10, active in low status. Read / Write outputs Via 64 pole, buffered with bus driver, active in low status. Interrupt inputs Four inputs via 64 pole connector, active low, with pull-up resistors. Digital I/O Seven digital I/Os programmable as in/outputs; via 64 pole connector; with pull-up lines alternatively as interrupt inputs. resistor. Four Reset outputs Two outputs via 64 pole connector, pos. and neg. logic. BDM connector Motorola-specific 10 pole BDM connector for program development. Power supply
+5V, +12V, -12V; 64 pole connector Rev. 1.2 / 2009-03-22 82 PMD 2450 Technical Data Mechanical size Eurocard format, 160 mm x 100 mm, 4 TE. Ambient conditions Operating temperature range: 0C humidity: 10 to 90%, no condensation. to 50C, relative 5.2 Adapter Board SE 0006 The following functions are accessible via the connector in the cable chute. The ADC input is not lead out but it is connected to the microwave cassette via the back panel. Rev. 1.2 / 2009-03-22 83 PMD 2450 Technical Data 5.2.1 Analog Input of ADC for the Microwave Unit
(only internally) ADC Polarity Pulse height Input impedance Input capacity Input leakage current Conversion time Integral non-linearity 14 bit resolution Positive 0V 5 V 150 kOhm 20 pF 1 A Max. 3.33 s Max. 1 LSB Differential non-linearity Max. 1 LSB Unipolar offset error Full-scale error Max. 4 LSB Max. 4 LSB Level Pulse width Count rate Input impedance Input Positive, > 3.5 V
> 0.5 s Max. 250 000 cps Approx. 300 Ohm With current limiting and over voltage protection 5.2.2 Counter Inputs Rev. 1.2 / 2009-03-22 84 PMD 2450 Technical Data 5.2.3 Analog Inputs Channel 1 as current input Jumper J5 closed 0 mA 20 mA Channel 1 as voltage input Jumper J5 open 0 V 5 VDC Channel 2 as current input Jumper J6 closed 0 mA 20 mA Channel 2 as voltage input Jumper J6 open Input filter ADC 0 V 5 VDC RC, differential amplifier 10 bit resolution Differential non-linearity Zero-scale error Full-scale error 1 LSB 1 LSB 1 LSB Conversion time 21 s 5.2.4 Analog Outputs Range Load DAC 0 mA 20 mA Max. 350 Ohm 12 bit resolution, internal reference: 4.095 V Over voltage protection 16 V varistors Differential non-linearity 0.2 LSB Integral non-linearity Zero-Scale error Offset error 2 LSB 3 mV 2 mV 5.2.5 Current Output for PT100 Constant-current source Load 10 mA, adjustable via poti R86 Max. 500 Ohm, corresponding to 5 V voltage drop Rev. 1.2 / 2009-03-22 85 PMD 2450 Technical Data 5.2.6 Digital Inputs Level Pulse width Input Active at pull-down on GNDA (electr. isolated)
> 50 ms Optocoupler, 10 mA, protective circuit Open collector output Voltage output Output Jumper J1 J4 open, max. 100 mA, max. +12V ext. supply Jumper J1 J4 closed, low = 0.3 V, high = 5 V, 4.7 kOhm electrically isolated, recovery diode, protective circuit 5.2.7 Digital Outputs Rev. 1.2 / 2009-03-22 86 PMD 2450 Technical Data 5.2.8 Connector Configuration Pin configuration of connector ST1
(64 pole (32 x A/C), only for internal purposes) Pin 1A 1C 2A 2C 3A 3C 4A 4C 5A 5C 6A 6C 7A 8A 8C 9A 9C 10A 10C 11A 11C 12A 12C 13A 13C 14A 14C 15A 15C 19A 19C 20A 20C 21A 21C 22A 22C 23A 23C 24A 24C 25A 25C 26A 26C 27A 27C 28A 28C 29A 29C 30A 30C 31A 31C 32A 32C Designation Power supply. +5V Power supply. +5V Ground (GND) Ground (GND) Read (negated) Write (negated) Cardselect CS4 (neg) Cardselect CS5 (neg) Cardselect CS6 (neg) Cardselect CS7 (neg) Cardselect CS8 (neg) Cardselect CS9 (neg) CSP Address A0 Address A1 Address A2 Address A3 Address A4 Address A5 Address A6 Address A7 Data D0 Data D1 Data D2 Data D3 Data D4 Data D5 Data D6 Data D7 V2 RES\
RES A-signal microwave Gnd A-signal V1 P/M R/I R/T Gnd Gnd N/Test Hi/Lo Lock1 Lock2 LE2 LE1 CLK Data CSPLL2 CSPLL1
+15V
+15V
-15V
-15V Ground (Gnd) Ground (GND) Rev. 1.2 / 2009-03-22 87 PMD 2450 Technical Data Pin configuration of connector ST2
(Front side of SE0006, only internally) Pin Designation 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46
+12 V A
+12 V A Gnd-A
-12 V A Gnd-A
+5 V A Gnd-A Digital input 1 Digital input 2 Digital input 3 Digital input 4 Digital input 5 Digital input 6 Digital input 7 Digital input 8 Gnd-A Digital output 1 Digital output 2 Digital output 3 Digital output 4 Gnd-A Counter 1 ( - ) Counter 1 ( + ) Gnd-A Counter 2 ( - ) Counter 2 ( + ) Gnd-A Counter 3 ( - ) Counter 3 ( + ) Gnd-A Counter 4 ( - ) Counter 4 ( + ) Gnd-A Counter 5 ( - ) Counter 5 ( + ) Gnd-A Counter 6 ( - ) Counter 6 ( + )
+12 V A Analog output 1 Analog output 2 Analog output 3 Analog output 4
+12 V A Current outp. (-) for PT100 Gnd-A Rev. 1.2 / 2009-03-22 88 PMD 2450 Technical Data 47 48 49 50 Analog input 2 ( - ) Analog input 2 ( + ) Analog input 1 ( - ) Analog input 1 ( + ) 5.3 Connector Configuration on Connection Board SE 0008 5.3.1 Serial Ports The connection board SE 0008 accommodates the electrically isolated port, which works as RS232 with jumper J1 open, and as RS485 port with jumper J1 closed. The type has to be set in the software. The configuration has to be adapted in accordance with the hardware as follows:
RS 232 Setup Jumper J1 on circuit board SE 0008 has to be open Screened, 5 wire cable, max. 30 m long RS 485 Setup Jumper J1 on circuit board SE 0008 has to be close Screened, twisted cable Terminate both ends with 120 Ohm each (close J2 on circuit board SE 0008, do not forget terminating resistor on the PC side) Pin configuration The serial port is connected to connector ST3 on the connection board SE 0008, see also Pin 1 2 3 4 5 6 7 8 Function Electrically isolated ground TxD (RS232) RxD (RS232) RTS (RS232) CTS (RS232) A (RS485) B\ (RS485) Electrically isolated ground Rev. 1.2 / 2009-03-22 89 PMD 2450 Technical Data Figure 22: Connector configuration on circuit board SE 0008 in the cable chute Rev. 1.2 / 2009-03-22 90 PMD 2450 Technical Data 5.3.2 Power Supply Long range input for 110 VAC (60 Hz) or 230 VAC (50 Hz) The measuring system is firmly connected (fixed) to the external supply via a three-wire cable (type 3 x 0.75 mm2). Please observe the correct allocation of the 3 wires. (PH, MP and protective conductor). The terminals of the external power supply have to be clearable and before being wired they have to be cleared. For power supply, the left PG next to the fuse should be used. Connect the cable provided with wire end sleeves to connector ST6 (front left) to terminals 1, 2 and 3 (yellow-
green cable to terminal 3). Fuse:
At 230 VAC: 2 A, T At 110 VAC: 4 A, T 5.3.3 Housing Dimensions Width:
30.5 cm Height:
37.5 cm Depth:
24.0 cm 5.3.4 Protection Type IP65 5.3.5 Ambient Temperature
-20C +50C 5.3.6 Relative Humidity 0 90%, no condensation Rev. 1.2 / 2009-03-22 91
frequency | equipment class | purpose | ||
---|---|---|---|---|
1 | 2011-10-22 | 2905 ~ 2940 | DXT - Part 15 Low Power Transceiver, Rx Verified | Original Equipment |
app s | Applicant Information | |||||
---|---|---|---|---|---|---|
1 | Effective |
2011-10-22
|
||||
1 | Applicant's complete, legal business name |
InduTech instruments GmbH
|
||||
1 | FCC Registration Number (FRN) |
0021126040
|
||||
1 | Physical Address |
Ahornweg 6-8
|
||||
1 |
Simmersfeld, 72226
|
|||||
1 |
Germany
|
|||||
app s | TCB Information | |||||
1 | TCB Application Email Address |
m******@cetecom.com
|
||||
1 | TCB Scope |
A2: Low Power Transmitters (except Spread Spectrum) and radar detectors operating above 1 GHz
|
||||
app s | FCC ID | |||||
1 | Grantee Code |
ZYL
|
||||
1 | Equipment Product Code |
PMD2450-3
|
||||
app s | Person at the applicant's address to receive grant or for contact | |||||
1 | Name |
D**** K********
|
||||
1 | Title |
Managing Director
|
||||
1 | Telephone Number |
+ 49 ********
|
||||
1 | Fax Number |
+ 49 ********
|
||||
1 |
i******@indutech.com
|
|||||
app s | Technical Contact | |||||
n/a | ||||||
app s | Non Technical Contact | |||||
n/a | ||||||
app s | Confidentiality (long or short term) | |||||
1 | Does this application include a request for confidentiality for any portion(s) of the data contained in this application pursuant to 47 CFR § 0.459 of the Commission Rules?: | Yes | ||||
1 | Long-Term Confidentiality Does this application include a request for confidentiality for any portion(s) of the data contained in this application pursuant to 47 CFR § 0.459 of the Commission Rules?: | No | ||||
if no date is supplied, the release date will be set to 45 calendar days past the date of grant. | ||||||
app s | Cognitive Radio & Software Defined Radio, Class, etc | |||||
1 | Is this application for software defined/cognitive radio authorization? | No | ||||
1 | Equipment Class | DXT - Part 15 Low Power Transceiver, Rx Verified | ||||
1 | Description of product as it is marketed: (NOTE: This text will appear below the equipment class on the grant) | Moisture Measurement System | ||||
1 | Related OET KnowledgeDataBase Inquiry: Is there a KDB inquiry associated with this application? | No | ||||
1 | Modular Equipment Type | Does not apply | ||||
1 | Purpose / Application is for | Original Equipment | ||||
1 | Composite Equipment: Is the equipment in this application a composite device subject to an additional equipment authorization? | No | ||||
1 | Related Equipment: Is the equipment in this application part of a system that operates with, or is marketed with, another device that requires an equipment authorization? | No | ||||
1 | Grant Comments | Device must be professional installed. | ||||
1 | Is there an equipment authorization waiver associated with this application? | No | ||||
1 | If there is an equipment authorization waiver associated with this application, has the associated waiver been approved and all information uploaded? | No | ||||
app s | Test Firm Name and Contact Information | |||||
1 | Firm Name |
CTC advanced GmbH (former CETECOM ICT Services )
|
||||
1 | Name |
G**** S********
|
||||
1 | Telephone Number |
49-68********
|
||||
1 | Fax Number |
49-68********
|
||||
1 |
t******@ctcadvanced.com
|
|||||
Equipment Specifications | |||||||||||||||||||||||||||||||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Line | Rule Parts | Grant Notes | Lower Frequency | Upper Frequency | Power Output | Tolerance | Emission Designator | Microprocessor Number | |||||||||||||||||||||||||||||||||
1 | 1 | 15C | 2410 | 2480 | |||||||||||||||||||||||||||||||||||||
1 | 2 | 15C | 2520 | 2680 | |||||||||||||||||||||||||||||||||||||
1 | 3 | 15C | 2905 | 2940 |
some individual PII (Personally Identifiable Information) available on the public forms may be redacted, original source may include additional details
This product uses the FCC Data API but is not endorsed or certified by the FCC