Hottinger Bruel and Kjaer T12S6 T12-S6 Torquemeter User Manual A1979 100
Hottinger Baldwin Messtechnik GmbH T12-S6 Torquemeter A1979 100
User Manual
Mounting Instructions Digital Torque Transducer T12 A1979−10.0 en 3 T12 Contents Page Contents Safety instructions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Markings used . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.1 Symbols on the transducer and / or Stator . . . . . . . . . . . . . . . . . . . 1.2 The markings used in this document . . . . . . . . . . . . . . . . . . . . . . . . 10 Scope of supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Application . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Signal flow . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 Structure and mode of operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 Mechanical installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1 Important precautions during installation . . . . . . . . . . . . . . . . . . . . 7.2 Conditions on site . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.3 Mounting position . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.4 Installing the slotted disc (rotational speed measuring system only) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.5 Installing the rotor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.6 Fitting the protection against contact (option) . . . . . . . . . . . . . . . . 7.7 Installing the stator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.7.1 Preparing with the mounting kit (included among the items supplied) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.7.2 Aligning the stator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.7.3 Stator installation over the protection against contact (option) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.8 Optical rotational speed/angle of rotation measuring system (option) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.8.1 Axial alignment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.8.2 Radial alignment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 16 17 17 LED status display . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.1 Measuring mode operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.2 Rotor clearance setting mode operation . . . . . . . . . . . . . . . . . . . . . 8.3 Rotational speed measuring system setting mode operation . . . 36 36 36 36 Electrical connection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.1 General information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.2 Shielding design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37 37 39 A1979−10.0 en 18 19 21 27 28 30 32 33 33 34 HBM 4 T12 9.3 9.4 Connector pin assignment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Supply voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39 43 10 Shunt signal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45 11 Load-carrying capacity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46 12 TEDS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47 13 Maintenance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54 14 Waste disposal and environmental protection . . . . . . . . . . . . . . . . . . 55 15 Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.1 Nominal (rated) torque 100 Nm to 1 kNm . . . . . . . . . . . . . . . . . . . 15.2 Nominal (rated) torque 2 kNm to 10 kNm . . . . . . . . . . . . . . . . . . . 56 56 63 16 Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.1 Rotor 100 Nm to 200 Nm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.2 Rotor 500 Nm to 10 kNm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.3 Stator 100 Nm to 200 Nm with rot.speed meas. system . . . . . . 16.4 Stator 100 Nm to 200 Nm with rot. speed meas. system . . . . . 16.5 Stator 100 Nm to 10 kNm with rot. speed meas. system . . . . . 16.6 Stator 100 Nm to 200 Nm with prot. against contact . . . . . . . . . 16.7 Stator 100 Nm to 200 Nm with prot. against contact . . . . . . . . . 16.8 Stator 500 Nm to 1 kNm with prot. against contact . . . . . . . . . . 16.9 Stator 2 kNm to 10 kNm with prot. against contact . . . . . . . . . . . 16.9.1 Protection against contact plates 100 Nm to 200 Nm . . . 16.9.2 Protection against contact plates 500 Nm to 10 kNm . . . 16.10 Mounting dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70 70 71 72 73 74 75 76 77 78 79 79 80 17 Supplementary technical information . . . . . . . . . . . . . . . . . . . . . . . . . . 81 18 Condition at the time of delivery . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 82 19 Ordering numbers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87 20 Accessories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88 HBM A1979−10.0 en 5 T12 Safety instructions FCC Compliance & Advisory Statement for Option 7, Code U This device complies with Part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) this device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation. The FCC identifier or the unique identifier, as appropriate, must be displayed on the device. Model FCC ID IC T12, 100 Nm, 200 Nm 2ADAT−T12S2 12438A−T12S2 T12, 500 Nm, 1 kNm 2ADAT−T12S3 12438A−T12S3 T12, 2 kNm, 3 kNm 2ADAT−T12S4 12438A−T12S4 T12, 5 kNm 2ADAT−T12S5 12438A−T12S5 T12, 10 kNm 2ADAT−T12S6 12438A−T12S6 The FCC ID number in dependence of measuring range: label example only on the Stator FCC ID and IC number range. Label example with FCC ID and IC number. Location on the stator of the device. FCC ID: 2ADAT-T12S2 IC: 12438AT12S2 This device complies with part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation. Fig 1.1: Example of the label Industry Canada for Option 7, Code U IC: 12483A−T12S2 This device complies with Industry Canada standard RSS210. This device complies with Industry Canada license−exempt RSS standard(s). Operation is subject to the following two conditions: (1) this device may not cause interference, and (2) this device must accept any interference, including interference that may cause undesired operation of the device. Cet appareil est conforme aux norme RSS210 d’Industrie Canada. A1979−10.0 en HBM 6 T12 Cet appareil est conforme aux normes d’exemption de licence RSS d’Industry Canada. Son fonctionnement est soumis aux deux conditions suivantes : (1) cet appareil ne doit pas causer d’interférence et (2) cet appareil doit accepter toute interférence, notamment les interférences qui peuvent affecter son fonctionnement. NOTE Any changes or modification not expressly approved by the party responsible for compliance could void the user’s authority to operate the device. Where specified additional components or accessories elsewhere defined to be used with the installation of the product, they must be used in order to ensure compliance with FCC regulations. Appropriate use The T12 torque flange is used exclusively for torque, angle of rotation and power measurement tasks within the load limits stipulated in the specifications. Any other use is not appropriate. Stator operation is only permitted when the rotor is installed. The torque flange may only be installed by qualified personnel in compliance with the specifications and with the safety requirements and regulations of these mounting instructions. It is also essential to observe the applicable legal and safety regulations for the application concerned. The same applies to the use of accessories. The torque flange is not intended for use as a safety component. Please also refer to the “Additional safety precautions” section. Proper and safe operation requires proper transportation, correct storage, siting and mounting, and careful operation. Load carrying capacity limits The data in the technical data sheets must be complied with when using the torque flange. In particular, the respective maximum loads specified must never be exceeded. For example, the values stated in the specifications must not be exceeded for limit torque, longitudinal limit force, lateral limit force or limit bending moment, torque oscillation width, breaking torque, temperature limits, the limits of the electrical load-carrying capacity. HBM A1979−10.0 en 7 T12 Use as a machine element The torque flange can be used as a machine element. When used in this manner, it must be noted that, to favor greater sensitivity, the transducer is not designed with the safety factors usual in mechanical engineering. Please refer here to the section “Load carrying capacity limits” and to the specifications. Accident prevention According to the prevailing accident prevention regulations, once the transducers have been mounted, a covering agent or cladding has to be fitted as follows: The covering agent or cladding must not be free to rotate. The covering agent or cladding should prevent squeezing or shearing and provide protection against parts that might come loose. Covering agents and cladding must be positioned at a suitable distance or be so arranged that there is no access to any moving parts within. Covering agents and cladding must still be attached, even if the moving parts of the torque flange are installed outside people’s movement and working range. The only permitted exceptions to the above requirements are if the torque flange is already fully protected by the design of the machine or by existing safety precautions. Additional safety precautions The torque flange cannot (as a passive transducer) implement any (safety-relevant) cutoffs. This requires additional components and constructive measures, for which the installer and operator of the plant is responsible. The electronics conditioning the measurement signal should be designed so that measurement signal failure does not subsequently cause damage. The scope of supply and performance of the transducer covers only a small area of torque measurement technology. In addition, equipment planners, installers and operators should plan, implement and respond to safety engineering considerations in such a way as to minimize residual dangers. Pertinent national and local regulations must be complied with. General dangers of failing to follow the safety instructions The torque flange corresponds to the state of the art and is reliable. Transducers can give rise to residual dangers if they are incorrectly operated or inappropriately mounted, installed and operated by untrained personnel. Every person involved with siting, starting-up, operating or repairing a torque flange must have read and understood the mounting instructions and in particular the technical safety instructions. The transducers can be damaged A1979−10.0 en HBM 8 T12 or destroyed by non-designated use of the transducer or by non-compliance with the mounting and operating instructions, these safety instructions or any other applicable safety regulations (BG safety and accident prevention regulations), when using the transducers. Transducers can break, particularly in the case of overloading. The breakage of a transducer can also cause damage to property or injury to persons in the vicinity of the transducer. If the torque flange is not used according to the designated use, or if the safety instructions or specifications in the mounting and operating instructions are ignored, it is also possible that the transducer may fail or malfunction, with the result that persons or property may be adversely affected (due to the torques acting on or being monitored by the torque flange). Conversions and modifications The transducer must not be modified from the design or safety engineering point of view except with our express agreement. Any modification shall exclude all liability on our part for any damage resulting therefrom. Selling on If the torque flange is sold on, these mounting instructions must be included with the torque flange. Qualified personnel Qualified personnel means persons entrusted with siting, mounting, starting up and operating the product, who possess the appropriate qualifications for their function. This includes people who meet at least one of the three following requirements: − Knowledge of the safety concepts of automation technology is a requirement and as project personnel, you must be familiar with these concepts. − As automation plant operating personnel, you have been instructed how to handle the machinery. You are familiar with the operation of the equipment and technologies described in this documentation. − As system startup engineers or service engineers, you have successfully completed the training to qualify you to repair the automation systems. You are also authorized to ground and label circuits and equipment and place them in operation in accordance with safety engineering standards. HBM A1979−10.0 en 9 T12 Markings used 1.1 Symbols on the transducer and / or Stator Symbol: Meaning: Read and note the data in this manual Symbol: Meaning: CE mark The CE mark enables the manufacturer to guarantee that the product complies with the requirements of the relevant EC directives (the Declaration of Conformity can be found on the HBM website at www.hbm.com under HBMdoc). Lable example with FCC ID and IC number. Location on the stator of the device. FCC ID: 2ADAT-T12S2 IC: 12438AT12S2 This device complies with part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation. Symbol: Meaning: Statutory waste disposal mark The electrical and electronic devices that bear this symbol are subject to the European waste electrical and electronic equipment directive 2002/96/EC. The symbol indicates that, in accordance with national and local environmental protection and material recovery and recycling regulations, old devices that can no longer be used must be disposed of separately and not with normal household garbage, see also Chapter 14, page 55. A1979−10.0 en HBM 10 T12 1.2 The markings used in this document Important instructions for your safety are specifically identified. It is essential to follow these instructions in order to prevent accidents and damage to property. Symbol Significance WARNING This marking warns of a potentially dangerous situation in which failure to comply with safety requirements can result in death or serious physical injury. CAUTION This marking warns of a potentially dangerous situation in which failure to comply with safety requirements can result in slight or moderate physical injury. NOTE This marking draws your attention to a situation in which failure to comply with safety requirements can lead to damage to property. Important This marking draws your attention to important information about the product or about handling the product. Tip This marking indicates application tips or other information that is useful to you. This marking draws your attention to information about the product or about handling the product. Emphasis HBM Italics are used to emphasize and highlight texts. A1979−10.0 en 11 T12 Scope of supply Digital torque transducer (rotor and stator) T12 mounting instructions T12 system CD Mounting kit Manufacturing certificate Tape wound core (toroidal core) only with Option 9, Code U Tape wound core (toroidal core) only with Option 9, Code U Optional: − A rotational speed measuring system, comprising an optical rotational speed sensor and a rotational speed kit (slotted disc, screwdriver, threadlocker, screws) − Protection against contact − A mounted coupling Operation The supplied T12 system CD contains the “T12 Assistant” control software. You can use this software to: monitor the correct installation of the torque transducer set the signal conditioning (zero balance, filters, scaling) protect your settings or load the factory settings display and evaluate the measured values Instructions for installing the T12 Assistant on your PC can be found in the “T12 Assistant Control Software” Quick Start Guide (pdf file on the T12 System CD and included in the “Setup Toolkit for T12” accessory). Instructions for operating the T12 Assistant can be found in the program’s online Help, which is called with function key F1 or via the menu bar. Instructions for connecting to fieldbus systems can be found in the “T12 CAN Bus/PROFIBUS” operating manual (pdf file on the T12 system CD). A1979−10.0 en HBM 12 T12 Application The T12 digital torque transducer acquires static and dynamic torque at stationary or rotating shafts, determines the rotational speed or angle of rotation while specifying the direction of rotation, and calculates the power. It is designed for: highly dynamic torque measurements when testing the power and functionality of engines and compound sets high-resolution rotational speed and angle of rotation measurements fast, dynamic power measurements on engine and transmission test rigs and roll test stands Designed to work without bearings and with contactless digital signal transmission, the torque measuring system is maintenance-free. The torque transducer is supplied for nominal (rated) torques of 100 Nm to 10 kNm. Depending on the nominal (rated) torque, maximum rotational speeds of up to 18 000 rpm are permissible. The T12 torque transducer is reliably protected against electromagnetic interference. It has been tested according to harmonized European standards and complies with US and Canadian standards. The product carries the CE mark and / or FCC label. HBM A1979−10.0 en 13 T12 Signal flow Low pass LP1: 0.05 Hz to 4000 Hz Low pass LP2: 0.05 Hz to 100 Hz Low pass LP: 0.1 Hz to 80 Hz Fig. 4.1: Signal flow diagram The torque and the temperature signal are already digitized in the rotor and transmission is noise-free. , scaled (2-point scaling) and The torque signal can be zeroed filtered via two low passes (LP1 and LP2). A further scaling of the frequency output and the analog output is then possible. Important Scaling at position (see Fig. 4.1) changes the internal calibration of the torque transducer. The rotational speed signal can be filtered and also scaled for analog output. The angle of rotation signal, the power signal (low-pass filter LP) and the temperature signal are only available on fieldbuses. The torque signal and the rotational speed signal can be filtered via two low passes connected in series, with filter outputs also being available separately. The scaled, unfiltered torque signal is used to calculate power. The resultant, highly-dynamically calculated power signal is filtered via a further low pass. A1979−10.0 en HBM 14 T12 For settings over 100 Hz (torque low-pass filter 1 only), phase delay compensation is run for the angle of rotation signal. This ensures that torque and angle of rotation values that are measured simultaneously are also output simultaneously. Two pulse strings, offset by 90, are also available as RS422-compatible signals for rotational speed and angle of rotation. Structure and mode of operation The torque transducer comprises two separate parts: the rotor and the stator. Strain gages (SGs) are installed on the rotor for torque calculation. Carrier-frequency technology (19.2 kHz carrier frequency) is used for the SG evaluation. The rotor temperature is acquired at two measuring points and averaged. The electronics for transmitting the bridge excitation voltage and the measurement signal are located centrally in the rotor. The coils for the contactless transmission of excitation voltage and measurement signal are located on the outer circumference of rotor side A. The signals are sent and received by a transmitter head. The transmitter head is mounted on the stator, which houses the electronics for voltage adaptation and signal conditioning. Connector plugs for inputs and outputs (for pin assignment, see Chapter 9.3) are located on the stator. The transmitter head encloses the rotor over a segment of about 120 and should be mounted concentrically around the rotor (see Chapter 7). In the case of the rotational speed measuring system option, the rotational speed sensor is mounted on the stator and the customer attaches the associated slotted disc on the rotor. Rotational speed measurement is optical, using the infrared transmitted light principle. HBM A1979−10.0 en 15 T12 Side A Side B Transmitter head Rotor Stator Slotted disc (option) Rotational speed sensor (option) Housing Fig. 5.1: Mechanical structure, exploded view A1979−10.0 en HBM 16 T12 Mechanical installation 7.1 Important precautions during installation NOTE A torque flange is a precision measuring element and therefore needs careful handling. Dropping or knocking the transducer may cause permanent damage. Make sure that the transducer cannot be overloaded, including while it is being mounted. Handle the transducer with care. Check the effect of bending moments, critical rotational speeds and natural torsional vibrations, to prevent the transducer being overloaded by resonance sharpness. Make sure that the transducer cannot be overloaded. WARNING There is a danger of the transducer breaking if it is overloaded. This can cause danger for the operating personnel of the system in which the transducer is installed. Implement appropriate safety measures to avoid overloads and to protect against resulting dangers. Use a threadlocker (medium strength, e.g. LOCTITE) to glue the screws into the counter thread to exclude prestressing loss due to screw slackening, in the event of alternating loads. Comply with the mounting dimensions to enable correct operation. An appropriate shaft flange enables the T12 torque flange to be mounted directly. It is also possible to mount a joint shaft or relevant compensating element directly on the rotor (using an intermediate flange when required). Under no circumstances should the permissible limits specified for bending moments, lateral and longitudinal forces be exceeded. Due to the T12 torque flange’s high torsional stiffness, dynamic shaft train changes are kept to a minimum. HBM A1979−10.0 en 17 T12 Important Even if the unit is installed correctly, the zero point adjustment made at the factory can shift by up to approx. 3% of the sensitivity. If this value is exceeded, we advise you to check the mounting conditions. If the residual zero offset when the unit is removed is greater than 1% of the sensitivity, please send the transducer back to the Darmstadt factory for testing. 7.2 Conditions on site The T12 torque transducer is protected to IP54 according to EN 60529. Protect the transducer from coarse dirt, dust, oil, solvents and moisture. During operation, the prevailing safety regulations for the security of personnel must be observed (see “Safety instructions”). There is wide ranging compensation for the effects of temperature on the output and zero signals of the T12 torque transducer (see specifications on page 56). This compensation is carried out at static temperatures. This guarantees that the circumstances can be reproduced and the properties of the transducer can be reconstructed at any time. If there are no static temperature ratios, for example, because of the temperature differences between flange A and flange B, the values given in the specifications can be exceeded. Then for accurate measurements, you must ensure static temperature ratios by cooling or heating, depending on the application. As an alternative, check thermal decoupling, by means of heat radiating elements such as multiple disc couplings. 7.3 Mounting position The transducer can be mounted in any position. With clockwise torque, the output frequency is 10 to 15 kHz (Option 4, code DF1/DU2: 60 kHz to 90 kHz). In conjunction with HBM amplifiers or when using the voltage output, a positive output signal (0 V to +10 V) is present. With counterclockwise torque, the output frequency is 5 kHz to 10 kHz (Option 4, code DF1/DU2: 30 kHz to 60 kHz). In the case of the rotational speed measuring system, an arrow is attached to the head of the sensor to clearly define the direction of rotation. When the transducer rotates in the direction of the arrow, a positive rotational speed signal is output. A1979−10.0 en HBM 18 T12 7.4 Installing the slotted disc (rotational speed measuring system only) To prevent damage to the rotational speed measuring system’s slotted disc during transportation, it is not mounted on the rotor. The customer must attach it to the mounting ring before installing the rotor in the shaft train. The mounting ring and the associated rotational speed sensor are already mounted at the factory. The requisite screws, a suitable screwdriver and the threadlocker are included among the components supplied. Slotted disc Fastening screw Fig. 6.1: Mounting ring Installing the slotted disc Important When carrying out the installation, be careful not to damage the slotted disc! Installation sequence 1. Push the slotted disc onto the mounting ring and align the screw holes. 2. Apply some of the threadlocker to the screw thread and tighten the screws (tightening torque < 0.15 Nm). HBM A1979−10.0 en 19 T12 7.5 Installing the rotor Tip Usually the rotor type plate is no longer visible after installation. This is why we include with the rotor additional stickers with the important characteristics, which you can attach to the stator or any other relevant test-bench components. You can then refer to them whenever there is anything you wish to know, such as the shunt signal. To explicitly assign the data, the identification number and the size are engraved on the rotor flange, where they can be seen from outside. NOTE Make sure during installation that you do not damage the measuring zone marked in Fig. 6.2 by using it to support tools, or knocking tools against it when tightening screws, for example. This can damage the transducer and produce measurement errors, or even destroy the transducer. Flange B Identification number and measuring range Measuring zone Fastening screw Fig. 6.2: Screw connections, flange B A1979−10.0 en HBM 20 T12 1. Prior to installation, clean the plane faces of the transducer flange and the counter flange. For safe torque transfer, the faces must be clean and free from grease. Use a piece of cloth or paper soaked in solvent. When cleaning, make sure that you do not damage the transmitter coils. 2. For the flange B screw connection, use hexagon socket screws DIN EN ISO 4762 of property class 10.9 (measuring ranges 3 kN@m to 10 kN@m: 12.9) of the appropriate length (depending on the connection geometry, see Table 6.1). We recommend fillister-head screws DIN EN ISO 4762, blackened, smooth-headed, permitted size and shape variance as per DIN ISO 4759, Part 1, product class A. 3. First tighten all the screws crosswise with 80% of the prescribed tightening torque (Table 6.1), then tighten again crosswise, with the full tightening torque. 4. There are relevant tapped holes on flange A for continuing the shaft train mounting. Again use screws of property class 10.9 (measuring ranges 3 kNm to 10 kNVm: 12.9), and tighten them with the prescribed moment as specified in Table 6.1. Flange A Fastening screw Z Fastening screw Z Fig. 6.3: HBM Screw connections, flange A A1979−10.0 en 21 T12 Important Use a threadlocker (medium strength, e.g. LOCTITE) to glue the screws into the counter thread to exclude prestressing loss due to screw slackening, in the event of alternating loads. NOTE Comply with the maximum thread reach as per Table 6.1. Otherwise significant measurement errors may result from torque shunt, or the transducer may be damaged. Measuring range Fastening screws Prescribed tightening moment NVm Z1) 100 / 200 M8 500 M10 1k M10 2k M12 115 3k M12 135 5k M14 10 k M16 Property class NVm 34 10.9 12.9 67 67 220 340 Table 6.1: Fastening screws 1) DIN EN ISO 4762; black/oiled/m = 0.125 tot Important Dry screw connections can result in different friction factors (see VDI 2230, for example). This means a change to the required tightening moments. The required tightening moments can also change if you use screws with a surface or property class other than that specified in Table 6.1, as this affects the friction factor. 7.6 Fitting the protection against contact (option) The protection against contact comprises two side parts and four cover plates. It is screwed onto the stator housing. A1979−10.0 en HBM 22 T12 Important Use a threadlocker (medium strength, e.g. LOCTITE) to glue the connecting screws into the counter thread. 1. Remove the side cover plates on the stator housing (see Fig. 6.4.) Cover plate Cover plate Fig. 6.4: Cover plates on the stator housing 2. Only for measuring ranges 500 N@m to 3 kN@m and subsequently ordered protection against contact: some of the tapped holes for the locking screws are covered by attached film. Make a semicircular cutout in the film here, with a minimum radius of 6 mm (use a cutter, as shown in Fig. 6.5, for example). Now remove the threaded pins from the tapped holes on both sides of the stator. HBM A1979−10.0 en 23 T12 Threaded pin Fig. 6.5: Cut out the film 3. For 5 kN@m and 10 kN@m measuring ranges only: remove the threaded pins from the tapped holes on both sides of the stator. Screw the spacing bolt into the tapped hole on the side of the rotational speed sensor (see Fig. 6.6). Threaded pin Spacing bolt Fig. 6.6: Fit the spacing bolt (for 5 kN@m and 10 kN@m only) A1979−10.0 en HBM 24 T12 4. Screw the cover plate onto the side parts (screws with hexagon socket 2 a.f.; tightening torque MA = 1 N@m). Note that the cover plate with cutouts must be fitted onto the side with countersunk holes! (see Fig. 6.7). Side part Cover plate with holes Cover plate with cutouts 2 a.f. Countersunk hole Fig. 6.7: Fit the cover plates Important With the 5 kN@m and 10 kN@m measuring ranges, the cover plates of the rotational speed sensor side must be angled at the bottom and fitted as shown in Fig. 6.8. HBM A1979−10.0 en 25 T12 Fig. 6.8: Angled cover plates (5 kN@m and 10 kN@m measuring ranges) 5. Attach each of the side parts to the stator housing with two M6x25 hexagon socket screws (5 a.f.). Hand-tighten the screws. 6. Screw the side parts together at the top, by hand (two M6x30 hexagon socket screws; 5 a.f.). A1979−10.0 en HBM 26 T12 M6 x 30 M6 x 25 M6 x 25 Fig. 6.9: Fit the protection against contact halves 7. Align the protection against contact in such a way that its end face is parallel to the stator housing. Locking screw (on both sides) Parallel surfaces Fig. 6.10: Check for parallelism HBM A1979−10.0 en 27 T12 8. Now tighten all the screws with a tightening torque MA of 14 N@m. 9. Screw in the cover plate locking screws and tighten them at 2 N@m. 7.7 Installing the stator On delivery, the stator has already been installed and is ready for operation. There are four tapped holes on the base of the stator housing for mounting the stator. Externally, two with a metric M6 thread, internally, two with a UNF 1/4” thread (closed with a plastic threaded pin). We recommend using two metric thread DIN EN ISO 4762 fillister-head screws with hexagon sockets of property class 10.9 of the appropriate length (depending on the connection geometry – not included among the components supplied; tightening torque = 14 N@m). Tip To allow the stator to be aligned to the rotor, make sure that repositioning is possible (e.g. oblong holes). The stator can be mounted radially in any position (an “upside down” installation is possible, for example). You can also install the stator over the protection against contact (option), see Chapter 7.7.3 . Fig. 6.11: Mounting holes in the stator housing (viewed from below) With the T12/5 kN@m and T12/10 kN@m torque transducers, we recommend additionally supporting the stator at the protection against contact. Fig. 6.12 shows an example of how to attach an angle bracket with a bolt (A) or with a threaded rod (B). Note that in this case, the cover plates cannot be fitted. A1979−10.0 en HBM 28 T12 11 6.6 Section through the countersunk hole in the protection against contact Fig. 6.12: Supporting the stator with an angle bracket (5 kN@m and 10 kN@m) 7.7.1 Preparing with the mounting kit (included among the items supplied) The supplied mounting kit contains self-adhesive spacers, to make it easier for you to align the stator to the rotor. Use the spacers to align the rotor and the stator radially and axially. Remove the protective film Fig. 6.13: Mounting kit spacer HBM A1979−10.0 en 29 T12 Radial alignment with spacers The spacers should preferably be attached to the transmitter head, offset by 90, as shown in Fig. 6.14. If your stator is equipped with a rotational speed measuring system, you must either shorten the spacers to an appropriate length or attach them slightly offset, next to the rotational speed measuring system. 90 Spacers Fig. 6.14: Radial position of the spacers Axial alignment with spacers The red line on the spacers is used for axial alignment. Align the spacer in such a way that the outer edge of the transmitter head is in line with the red line (see Fig. 6.15). A1979−10.0 en HBM 30 T12 Outer edge of transmitter head Red line Fig. 6.15: Axial position of the spacers Now remove the protective film and attach the spacers to the transmitter head, as described. Important Remove the spacers after installation. 7.7.2 Aligning the stator 1. Position the stator on an appropriate mounting base in the shaft train, so that there are sufficient opportunities for horizontal and vertical adjustments to be made. 2. Should there be any misalignment in height, compensate for this by inserting adjusting washers. 3. Only tighten the fastening screws by hand, initially. 4. Use the spacers to radially align the stator to the rotor. 5. Use the spacers to axially align the stator to the rotor. The rotor should be in line with the edge of the red spacer, see Fig. 6.16. HBM A1979−10.0 en 31 T12 Alignment line Transmitter rotor Spacer Fig. 6.16: Axial alignment to the rotor 6. Connect the power line (plug 1 or plug 3). Notice the LED to the right of plug 4. The stator is correctly aligned, when the LED successively flashes red for about 10 seconds flashes yellow for about 10 seconds then stays permanently green (CAN Bus) or yellow or green (PROFIBUS). When data are being exchanged via the CAN Bus or the PROFIBUS, the LED flashes green. You can also use the T12 Assistant to check for the correct alignment. The LED must stay green in the “Rotor clearance setting mode”. 7. Now fully tighten the fastening screws (tightening torque 14 N@m). 8. Remove the spacers, by first removing the adhesive strip and then the red plastic strip. 9. Make sure that the air gap between the rotor and stator is free from electrically conductive and other foreign matter. A1979−10.0 en HBM 32 T12 7.7.3 Stator installation over the protection against contact (option) You can also axially flange the stator over the protection against contact (material: aluminum). Holes are provided in the side parts of the protection against contact for this purpose. For this mounting, we recommend M6 fillister-head screws with hexagon sockets in accordance with DIN EN ISO 4762; black/oiled/mtot=0.125, of the appropriate length. Fig. 6.17: Mounting holes in the protection against contact b2 b8 11 6.6 Customer adaptation Measuring range Dimensions in mm (1 mm = 0.03937 inches) b2 b8 100 Nm to kNVm 56 43 5 kNm 78 65 10 kNm 86 73 Table 6.2: Mounting hole dimensions HBM A1979−10.0 en T12 33 Fig. 6.18: Face-mounting on the engine shielding 7.8 Optical rotational speed/angle of rotation measuring system (option) As the stator with the optical rotational speed sensor only partially encloses the slotted disc, if there is sufficient space available for installation, you can subsequently move the stator tangentially over the ready-mounted rotor. For perfect measuring mode, the slotted disc of the rotational speed measuring system must rotate at a defined position in the sensor pickup. 7.8.1 Axial alignment There is a mark (orientation line) in the sensor pickup for axial alignment. When installed, the slotted disc should be exactly above this orientation line. Divergence of up to "2 mm is permissible in measuring mode (total static and dynamic displacement). A1979−10.0 en HBM 34 T12 Slotted disc Flange B Alignment lines Sensor pickup Fig. 6.19: Position of the slotted disc in the rotational speed sensor 7.8.2 Radial alignment The rotor axis and the optical axis of the rotational speed sensor must be along a line at right angles to the stator platform. A conical machined angle (or a colored mark) in the center of flange B and a vertical marker line on the sensor pickup serve as aids to orientation. HBM A1979−10.0 en 35 T12 Centering point for aligning the rotor Marking Fig. 6.20: Alignment marks on rotor and stator Connect the power line (plug 1). Switch the LED display mode of the T12 Assistant to “optical rotational speed system” setting mode and turn the rotor. Notice the LED to the right of plug 4; this must stay green if the setting is correct (also see Chapter 8.3). Important Angle of rotation measurement is not suitable for static and quasi-static applications! A1979−10.0 en HBM 36 T12 LED status display The LED in the stator housing (next to device plug 4) has three display modes: standard (measuring mode), rotor clearance setting mode and setting mode for the optical rotational speed system. 8.1 Measuring mode operation LED color Significance Flashing green (fast) SDO transfer taking place Flashing green CAN device has operational status Green For PROFIBUS option only: Data exchange taking place1) Flashing yellow (slow) Rotor communication taking place Yellow For PROFIBUS option only: Searching for the baud rate, or parameterization or configuration taking place, or no data exchange taking place1) Flashing red Overflow for measured value (amplifier input, measured value ovfl.), frequency or analog output Red Error situation 1) When PROFIBUS option exists: Messages to the PROFIBUS take precedence over messages to the CAN Bus. 8.2 Rotor clearance setting mode operation LED color Significance Green Rotor-stator alignment is OK Yellow Rotor-stator alignment is borderline Red Rotor-stator alignment is not OK 8.3 Rotational speed measuring system setting mode operation LED color Significance Green The position of the two sensors is OK, the signals (F1/F2) are 90 or 270 phase-shifted and can be correctly evaluated Yellow The phase relation of the two sensor signals is not optimum, there is a variation of 10 to 30 Red The phase relation of the two sensor signals is not correct, there is a variation of more than 30 For more information on setting mode, look in the T12 Assistant online Help. HBM A1979−10.0 en 37 T12 Electrical connection 9.1 General information Detailed instructions for connecting the T12 to the CAN Bus or the PROFIBUS can be found in the “T12 CAN Bus/PROFIBUS” interface description (in pdf format) on the T12 system CD. To make the electrical connection between the torque transducer and the measuring amplifier, we recommend using shielded, low-capacitance measurement cables from HBM. With extension cables, make sure that there is a proper connection with minimum contact resistance and good insulation. All plug connections or swivel nuts nuts must be fully tightened. Do not route the measurement cables parallel to power lines and control circuits. If this cannot be avoided (in cable pits, for example), maintain a minimum distance of 50 cm and also draw the measurement cable into a steel tube. Avoid transformers, motors, contactors, thyristor controls and similar stray-field sources. Consider longer cable of approximately 40cm due to the installation of the wounded core (toroidal core). Important Transducer connection cables from HBM with plugs attached are identified in accordance with their intended purpose (Md or n). When cables are shortened, inserted into cable ducts or installed in control cabinets, this identification can get lost or become concealed. If this is the case, it is essential for the cables to be re-labeled! Tape wound core (toroidal core): To suppress high frequencies a tape wound core (toroidal core) on the power cable has to be used. Use at least 3 loops of the cable. A1979−10.0 en HBM 38 T12 3 loops Fig. 6.21: Installation Example If the core has to be removed for any purpose (e.g. for maintenance), it must be replaced on the cable. Use only wounded core (toroidal core) of the correct type. Type: Vitroperm R Model No.: T60006−22063W517 Size: external diameter x internal diameter x height = 63 x 50 x 25 The core should be placed as close as possible to the connector. However, prevent stress on the connector due to the extra weight of the cable. NOTE For US stator Version Option 9, Code U the use of a tape wound core (toroidal core) on the power cable (plug 1 or plug3) is mandatory to ensure compliance with FCC regulations. Important For US Version Option 9, Code U the use of a tape wound core (toroidal core) on the signal cable is mandatory to ensure compliance with FCC regulations. The cables and plugs for connectors 1, 2 and 3 are compatible with the T10FS torque flange. HBM A1979−10.0 en 39 T12 9.2 Shielding design The cable shield is connected in accordance with the Greenline concept. This encloses the measurement system (without the rotor) in a Faraday cage. It is important that the shield is laid flat on the housing ground at both ends of the cable. Any electromagnetic interference active here does not affect the measurement signal. Special electronic coding methods are used to protect the purely digital signal transmission between the transmitter head and the rotor from electromagnetic interference. In the case of interference due to potential differences (compensating currents), supply voltage zero and housing ground must be disconnected on the amplifier and a potential equalization line established between the stator housing and the amplifier housing (copper conductor, 10 mm2 wire crosssection). Should differences in potential between the machine rotor and stator cause interference, because of unchecked leakage, for example, this can usually be overcome by connecting the rotor definitively to ground, by a wire loop, for example. The stator should be fully grounded in the same way. 9.3 Connector pin assignment Assignment for plug 1: Supply voltage and frequency output signal. Plug Assignment Color code D-Subplug pin pin Binder 423 device plug Torque measurement signal (frequency output; 5 V1)/0) wh 13 Supply voltage 0 V; bk Supply voltage 18 V 30 V bu Torque measurement signal (frequency output; 5 V1)V) rd 12 Measurement signal 0 V; symmetrical gy Shunt signal trigger 5 V 30 V and TEDS for torque gn 14 Shunt signal 0 V; gy Top view Shielding connected to housing ground 1) RS−422 complementary signals; with cable lengths exceeding 10 m, we recommend using a termination resistor R=120 ohms between the wires (wh) and (rd). A1979−10.0 en HBM 40 T12 Important If plug 1 is used to power the device a tape wound core (toroidal core) is neccessary to suppresse high frequencies in order to ensure compliance with FCC regulations NOTE Torque transducers are only intended for operation with a DC supply voltage (separated extra-low voltage), see page 43. Assignment for plug 2: Rotational speed measuring system Plug pin Binder 423 device plug Top view Assignment Color code Sub-D plug pin Rotational speed measurement signal (pulse string, 5 V1); 0) rd 12 Not in use bu Rotational speed measurement signal (pulse string, 5 V1); phase-shifted 90 ) gy 15 Not in use bk TEDS for rotational speed vt Rotational speed measurement signal (pulse string, 5 V1); 0) wh 13 Rotational speed measurement signal (pulse string, 5 V1); phase-shifted 90) gn 14 Measurement signal 0 V bk2) Shielding connected to housing ground 1) 2) RS−422 complementary signals; with cable lengths exceeding 10 m, we recommend using R=120 ohms termination resistors between wires (rd) and (wh), as well as (gy) and (gn). Color code brown (br) for Kab 163 and Kab 164. HBM A1979−10.0 en 41 T12 Assignment for plug 2: Rotational speed measuring system with reference signal Plug pin Binder 423 device plug Assignment Color code Sub-D plug pin Rotational speed measurement signal (pulse string, 5 V1); 0) rd 12 Reference signal (1 pulse/rev., 5 V1)) bu Rotational speed measurement signal (pulse string, 5 V); phase-shifted 90 ) gy 15 Reference signal (1 pulse/rev., 5 V1)) bk TEDS for rotational speed vt Rotational speed measurement signal (pulse string, 5 V1); 0) wh 13 Rotational speed measurement signal (pulse string, 5 V); phase-shifted 90 ) gn 14 Measurement signal 0 V bk2) Top view Shielding connected to housing ground 1) 2) RS−422 complementary signals; with cable lengths exceeding 10 m, we recommend using R=120 ohms termination resistors between wires (rd) and (wh), (bu and (bk), (gy) and (gn). Color code brown (br) for Kab 163 and Kab 164. Assignment for plug 3: Supply voltage and voltage output signal. Plug pin Binder 423 device plug Torque/rotational speed measurement signal (voltage output; 0 V or rotational speed measurement signal (0 V) Supply voltage 0 V; Supply voltage 18 V to 30 V DC Torque measurement signal (voltage output; "10 V) or rotational speed measurement signal ("10 V) Not in use Shunt signal trigger 5 V to 30 V and TEDS for torque Shunt signal 0 V; Top view Assignment Shielding connected to housing ground A1979−10.0 en HBM 42 T12 Important If plug 3 is used to power the device a tape wound core (toroidal core) is neccessary to suppresse high frequencies in order to ensure compliance with FCC regulations. NOTE Do not use cable KAB149 to connect the voltage output signal at AP01i to ML01B of the MGCplus system! This cable is only suitable for connecting the frequency output signal. The analog output is designed as a monitoring output. The power transmission of the torque transducer can cause interference on the connected cable of up to 40 mV at 13.56 MHz. This interference can be suppressed by connecting a 100 nF capacitor in parallel, directly at the connected measuring instrument. Assignment for plug 4: Standard CAN Bus; A-coded, black washer Binder 713 (M12x1) Top view HBM Plug pin Assignment Color code Shield − Not in use − CAN ground − CAN HIGH-dominant high wh CAN LOW-dominant low bu Shielding connected to housing ground A1979−10.0 en 43 T12 Assignment for plug 5: CAN Bus; second device plug; A-coded, black washer Binder 713 (M12x1) Plug pin Assignment Color code Shield − Not in use − CAN ground − CAN HIGH-dominant high wh CAN LOW-dominant low bu Shielding connected to housing ground Top view Assignment for plug 5: PROFIBUS (option); B-coded, violet washer Binder 715 (M12x1) Top view Plug pin Assignment 5 V (typ. 50 mA) PROFIBUS A PROFIBUS ground PROFIBUS B Shield Shielding connected to housing ground 9.4 Supply voltage The transducer must be operated with a separated extra-low voltage (nominal (rated) supply voltage 18 to 30 VDC). You can supply one or more torque flanges within a test bench at the same time. Should the device be operated on a DC voltage network1), additional precautions must be taken to discharge excess voltages. The notes in this section relate to the self-contained operation of the T12 without HBM system solutions. The supply voltage is electrically isolated from signal outputs and shunt signal inputs. Connect a separated extra-low voltage of 18 V to 30 V to pin 3 (+) and pin 2 ( ) of plug 1 or 3. We recommend that you use HBM cable KAB 8/00−2/2/2 and the relevant Binder sockets, that at nominal (rated) A1979−10.0 en HBM 44 T12 voltage (24 V) can be up to 50 m long and in the nominal (rated) voltage range, 20 m long (see Accessories, page 88). If the permissible cable length is exceeded, you can feed the supply voltage in parallel over two connection cables (plugs 1 and 3). This enables you to double the permissible length. Alternatively, install an on-site power supply. If you feed the supply voltage through an unshielded cable, the cable must be twisted (interference suppression). We also recommend that a ferrite element should be located close to the connector plug on the cable, and that the stator should be grounded. Important The instant you switch on, a current of up to 4 A may flow and this may switch off power supplies with electronic current limiters. 1) Distribution system for electrical energy with greater physical expansion (over several test benches, for example) that may possibly also supply consumers with high nominal (rated) currents. HBM A1979−10.0 en 45 T12 10 Shunt signal The T12 torque transducer supplies a shunt signal, at either 50% or 10% of the nominal (rated) torque, as selected. Activate this function via the T12 Assistant or the shunt signal trigger on plug 1 or plug 3 (see Section 9.3). The last shunt selected in the T12 Assistant is then triggered. The internal signal conditioning may cause a delay in triggering of about 5 seconds. To obtain stable conditions, we recommend activating the shunt signal only once the transducer has been warming up for 15 minutes. The framework conditions for reproducibility (e.g. the mounting conditions) must be established in order to reproduce the measured values in the manufacturing certificate. Important The transducer should not be under load when the shunt signal is being measured, as the signal is applied additively. After about 5 minutes, the shunt signal is automatically deactivated. A1979−10.0 en HBM 46 11 T12 Load-carrying capacity Nominal (rated) torque can be exceeded statically up to the limit torque. If the nominal (rated) torque is exceeded, additional irregular loading is not permissible. This includes longitudinal forces, lateral forces and bending moments. Limit values can be found in the “Specifications” chapter (Chapter 15, page 56). Measuring dynamic torque The torque transducer is suitable for measuring static and dynamic torques. The following apply to the measurement of dynamic torque: The T12 calibration run for static measurements is also valid for dynamic torque measurements. The natural frequency f0 of the mechanical measuring system depends on the moments of inertia J1 and J2 of the connected rotating masses and the T12’s torsional stiffness. Use the equation below to approximately determine the natural frequency f0 of the mechanical measuring system: f0 + 1 · 2p Ǹ ǒ Ǔ cT · 1 ) 1 J2 J1 f0 = natural frequency in Hz J1, J2 = mass moment of inertia in kgm2 cT = torsional stiffness in Nm/rad The maximum oscillation width is 200% (measuring range 3 kN@m to 10 kN@m: 160%) of the typical nominal (rated) torque for the T12 (see “Specifications”, page 56) The oscillation width must lie between the maximum upper and lower torques of the defined loading range. The same also applies to transient resonance points. Upper maximum torque 100% Lower maximum torque 100% Oscillation width 200% Mnom (3 kNm to 10 kNm: 160%) Fig. 10.1: Permissible dynamic loading HBM A1979−10.0 en 47 T12 12 TEDS TEDS (Transducer Electronic Data Sheet) allows you to store the transducer data (characteristic values) in a chip, that can be read out by a connected measuring instrument. There are two TEDS blocks in the T12 digital torque transducer: TEDS 1 (torque): a choice of voltage sensor or frequency sensor/pulse sensor TEDS 2 (rotational speed/angle of rotation): frequency sensor/pulse sensor The data are written automatically into the TEDS blocks by the T12 Assistant, when the parameters are stored. The same menu is used to select whether the device should be presented as a voltage sensor or as a frequency sensor or as a frequency or pulse sensor. A template is also stored, which provides the conversion factors for the different physical units. The T12 is a transducer, that is to say, the T12 does not read the TEDS blocks, it only writes them. (We therefore strongly advise against editing the values with the HBM TEDS Editor, for example!) You can read the data of the TEDS block with the TEDS Editor. Important To ensure that the data of the TEDS blocks correspond to the properties of the T12 torque transducer, you must not overwrite the information from the measuring amplifier. For more information on TEDS, look in the T12 Assistant online Help. Content of the TEDS memory as defined in IEEE 1451.4 The information in the TEDS memory is organized into areas, which are prestructured to store defined groups of data in table form. Only the entered values are stored in the TEDS memory itself. The amplifier firmware assigns the interpretation of the respective numerical values. This places a very low demand on the TEDS memory. The memory content is divided into three areas: Area 1: An internationally unique TEDS identification number (cannot be changed). A1979−10.0 en HBM 48 T12 Area 2: The base area (basic TEDS), to the configuration defined in standard IEEE1451.4. The transducer type, the manufacturer and the transducer serial number are contained here. Example: TEDS content of a T12/1 kN@m transducer TEDS Manufacturer Model Version letter Version number Serial number HBM (31) T12 (15) 2 first position of stator ident no. 7 first position of stator ident no. Area 3: Data specified by the manufacturer and the user are contained in this area. Typical values for an HBM T12/1 kN@m torque transducer are shown in the “Value” column of the table below. Torque HBM has already written the “Frequency/Pulse Sensor” and “High Level Voltage Output Sensor” templates for the torque measurand. HBM A1979−10.0 en 49 T12 Template: Frequency/Pulse Sensor Parameter Value Unit Explanation Transducer Electrical Signal Type Minimum Torque Pulse Sensor 0.000 Require d user rights ID N@m CAL Maximum Torque 1000 N@m CAL The physical measurand and unit are defined when the template is created, after which they cannot be changed. Pulse Measurement Type Frequency Minimum Electrical Value Maximum Electrical Value Mapping Method Discrete Signal Type Discrete Signal Amplitude Discrete Signal Configuration Transducer Response Time Excitation Level nom Excitation Level min Excitation Level max Excitation Type Excitation Current draw Calibration Date 10000 Hz CAL 15000 Linear Bipolar Single Hz CAL secon ds Calibration Initials HBM or PTB Calibration Period (Days) Measurement location ID A1979−10.0 en 24 18 30 DC 0.5 1-Nov-2006 The difference between these values is the nominal (rated) sensitivity. ID CAL CAL days CAL USR Date of the last calibration or creation of the manufacturing certificate (if no calibration carried out), or of the storage of the TEDS data (if only nominal (rated) values from the data sheet were used). Format: day-month-year. Abbreviations for the months: Jan, Feb, Mar, Apr, May, Jun, Jul, Aug, Sep, Oct, Nov, Dec. Initials of the calibrator or calibration laboratory concerned. Time before recalibration, calculated from the date specified under Calibration Date. Identification number for the measuring point. Can be assigned according to the application. Possible values: a number from 0 to 2047. HBM 50 T12 Template: High Level Voltage Sensor Parameter Value Unit Minimum Torque 0.000 N@m Required user rights CAL Maximum Torque 1000 N@m CAL Minimum Electrical Value CAL Maximum Electrical Value 10 CAL Discrete Signal Type Discrete Signal Amplitude Discrete Signal Transducer Response Time Excitation Level nom Excitation Level min Excitation Level max Excitation Type Excitation Current draw Calibration Date Bipolar Single Calibration Initials HBM or PTB Calibration Period (Days) Measurement Location ID HBM 24 18 30 DC 0.5 1-Nov-2006 Explanation The physical measurand and unit are defined when the template is created, after which they cannot be changed. The difference between these values is the nominal (rated) sensitivity. ID CAL CAL days CAL USR Date of the last calibration or creation of the manufacturing certificate (if no calibration carried out), or of the storage of the TEDS data (if only nominal (rated) values from the data sheet were used). Format: day-month-year. Abbreviations for the months: Jan, Feb, Mar, Apr, May, Jun, Jul, Aug, Sep, Oct, Nov, Dec. Initials of the calibrator or calibration laboratory concerned. Time before recalibration, calculated from the date specified under Calibration Date. Identification number for the measuring point. Can be assigned according to the application. Possible values: a number from 0 to 2047. A1979−10.0 en 51 T12 Rotational speed/angle of rotation HBM has already written the “Frequency/Pulse Sensor” template for the rotational speed measurand. Template: Frequency/Pulse Sensor Parameter Value Unit Explanation Transducer Electrical Signal Type Minimum Frequency Pulse Sensor 0.000 Required user rights ID Hz CAL Maximum Frequency 108.000 k Hz CAL The physical measurand and unit are defined when the template is created, after which they cannot be changed. Pulse Measurement Type Minimum Electrical Value Maximum Electrical Value Mapping Method Discrete Signal Type Discrete Signal Amplitude Discrete Signal Configuration Frequency 108.000 k Linear Bipolar Double phase plus zero index Hz Hz CAL CAL Transducer Response Time Excitation Level nom Excitation Level min Excitation Level max Excitation Type Excitation Current draw Calibration Date 24 18 30 DC 0.5 1-Nov-2006 Calibration Initials HBM or PTB Calibration Period (Days) A1979−10.0 en ID seco nds CAL CAL days CAL Date of the last calibration or creation of the manufacturing certificate (if no calibration carried out), or of the storage of the TEDS data (if only nominal (rated) values from the data sheet were used). Format: day-month-year. Abbreviations for the months: Jan, Feb, Mar, Apr, May, Jun, Jul, Aug, Sep, Oct, Nov, Dec. Initials of the calibrator or calibration laboratory concerned. Time before recalibration, calculated from the date specified under Calibration Date. HBM 52 T12 Template: Frequency/Pulse Sensor Parameter Value Measurement location ID Transducer Electrical Signal Type Minimum Frequency Pulse Sensor 0.000E+000 Maximum Frequency 3.6E+002 Pulse Measurement Type Minimum Electrical Value Unit Required user rights USR ID degr ees degr ees CAL Count 0.0 Imp CAL Maximum Electrical Value 360 Imp CAL Mapping Method Discrete Signal Type Discrete Signal Amplitude Discrete Signal Configuration Linear Bipolar Double phase plus zero index Transducer Response Time Excitation Level nom Excitation Level min Excitation Level max Excitation Type Excitation Current draw Calibration Date HBM 24 18 30 DC 0.5 1-Nov-2006 CAL Explanation Identification number for the measuring point. Can be assigned according to the application. Possible values: a number from 0 to 2047. The physical measurand and unit are defined when the template is created, after which they cannot be changed. The difference between these values is the nominal (rated) sensitivity. ID seco nds CAL Date of the last calibration or creation of the manufacturing certificate (if no calibration carried out), or of the storage of the TEDS data (if only nominal (rated) values from the data sheet were used). Format: day-month-year. Abbreviations for the months: Jan, Feb, Mar, Apr, May, Jun, Jul, Aug, Sep, Oct, Nov, Dec. A1979−10.0 en 53 T12 Template: Frequency/Pulse Sensor Parameter Value Calibration Initials HBM or PTB Calibration Period (Days) Measurement location ID A1979−10.0 en Unit days Required user rights CAL CAL USR Explanation Initials of the calibrator or calibration laboratory concerned. Time before recalibration, calculated from the date specified under Calibration Date. Identification number for the measuring point. Can be assigned according to the application. Possible values: a number from 0 to 2047. HBM 54 13 T12 Maintenance The T12 torque transducer without a rotational speed measuring system is maintenance-free. Cleaning the rotational speed measuring system During operation and depending on the ambient conditions, the slotted disc of the rotor and the associated optical system of the stator sensor can get dirty. This becomes noticeable, for example: in transducers with a reference pulse, when an increment error is displayed in the “Rotational speed signal” status in the T12 Assistant. in transducers without a reference pulse, when there are cyclic intrusions into the rotational speed signal. Remedy: 1. Use compressed air (up to 6 bar) to clean the slotted disc. 2. Carefully clean the optical system of the sensor with a dry cotton bud or one soaked with pure spirit. NOTE Do not use any other solvent to clean the optical system of the sensor! It could alter the optical properties (make plastic cloudy). Fig. 12.1: HBM Cleaning points on the rotational speed sensor A1979−10.0 en 55 T12 14 Waste disposal and environmental protection All electrical and electronic products must be disposed of as hazardous waste. The correct disposal of old equipment prevents ecological damage and health hazards. Symbol: Meaning: Statutory waste disposal mark The electrical and electronic devices that bear this symbol are subject to the European waste electrical and electronic equipment directive 2002/96/EC. The symbol indicates that, in accordance with national and local environmental protection and material recovery and recycling regulations, old devices that can no longer be used must be disposed of separately and not with normal household garbage. As waste disposal regulations may differ from country to country, we ask that you contact your supplier to determine what type of disposal or recycling is legally applicable in your country. Packaging The original packaging of HBM devices is made from recyclable material and can be sent for recycling. Store the packaging for at least the duration of the warranty. In the case of complaints, the torque flange must be returned in the original packaging. For ecological reasons, empty packaging should not be returned to us. A1979−10.0 en HBM 56 15 T12 Specifications 15.1 Nominal (rated) torque 100 NVm to 1 kNVm Type Accuracy class Torque measuring system Nominal (rated) torque Mnom Nominal (rated) rotational speed nnom Option 3, code L 1) Option 3, code H 1) Non-linearity including hysteresis, related to nominal (rated) sensitivity Fieldbuses, frequency output 10 kHz/60 kHz For a max. torque in the range: between 0% of Mnom and 20% of Mnom > 20% of Mnom and 60% of Mnom > 60% of Mnom and 100% of Mnom Voltage output For a max. torque in the range: between 0% of Mnom and 20% of Mnom > 20% of Mnom and 60% of Mnom > 60% of Mnom and 100% of Mnom Relative standard deviation of repeatability per DIN 1319, related to the variation of the output signal Fieldbuses/frequency output Voltage output Temperature effect per 10 K in the nominal (rated) temperature range on the output signal, related to the actual value of the signal span Fieldbuses/frequency output Voltage output on the zero signal, related to the nominal (rated) sensitivity Fieldbuses/frequency output Voltage output Nominal (rated) sensitivity (span between torque = zero and nominal (rated) torque) Frequency output 10 kHz/60 kHz Voltage output Sensitivity tolerance (deviation of the actual output quantity at Mnom from the nominal (rated) sensitivity) Frequency output Voltage output 1) T12 0.03 Nm kNm rpm rpm 100 200 500 15 000 18 000 12 000 16 000 <"0.006 (optional <"0.004) <"0.013 (optional <"0.007) <"0.02 (optional <"0.01) <"0.015 <"0.035 <"0.05 "0.01 "0.03 "0.03 "0.1 "0.02 (optional "0.01) "0.1 kHz 5/30 10 "0.05 "0.1 See page 87. HBM A1979−10.0 en 57 T12 Nominal (rated) torque Mnom Output signal at torque = zero Frequency output 10 kHz/60 kHz Voltage output Nominal (rated) output signal Frequency output with positive nominal (rated) torque 10 kHz/60 kHz with negative nominal (rated) torque 10 kHz/60 kHz Voltage output with positive nominal (rated) torque with negative nominal (rated) torque Scaling range Frequency output/voltage output Resolution Frequency output 10 kHz/60 kHz Voltage output Residual ripple Voltage output Maximum modulation range 3) Frequency output 10 kHz/60 kHz Voltage output Load resistance Frequency output Voltage output Long-term drift over 48 h Voltage output Measurement frequency range Frequency output/voltage output −1 dB Frequency output/voltage output −3 dB 2) 3) Nm kNm 200 500 kHz 10/60 kHz 15/90 (5 V symmetrical 2)) kHz 5/30 (5 V symmetrical 2)) +10 −10 10 to 1000 (of Mnom) Hz mV 0.03/0.25 0.33 mV kHz 4 to 16/24 to 96 −10.2 to +10.2 k k 2 10 mV "3 Hz Hz 0 to 4000 0 to 6000 0.05 to 4000 (fourth-order Bessel, −1 dB); factory setting 1000 Hz 0.05 to 100 (fourth-order Bessel, −1 dB); factory setting 1 Hz Low-pass filter LP1 Hz Low-pass filter LP2 Hz Group delay (low pass LP1: 4 kHz) Frequency output 10 kHz/60 kHz Voltage output Energy supply Nominal (rated) supply voltage (DC) (separated extra-low voltage) Current consumption in measuring mode Current consumption in startup mode Nominal (rated) power consumption Maximum cable length Shunt signal Tolerance of the shunt signal, related to Mnom 100 s s 320/250 500 18 to 30 < 1 (typ. 0.5) <4 < 18 50 50% of Mnom or 10% of Mnom "0.05 RS−422 complementary signals, note termination resistance. Output signal range in which there is a repeatable correlation between torque and output signal. A1979−10.0 en HBM 58 T12 Nm kNm Rotational speed/angle of rotation measuring system Optical, using infrared light and a metallic slotted disc Mechanical increments number Positional tolerance of the increments mm Tolerance of the slot width mm Pulses per revolution (adjustable) number Pulse frequency at nominal (rated) rotational speed nnom Option 3, code L 4) kHz 4) Option 3, code H kHz Minimum rotational speed for sufficient pulse rpm quality Group delay s Hysteresis of direction of rotation reversal in the case of relative vibrations between rotor and stator degree Torsional vibration of the rotor Radial vibrations of the stator mm Permitted degree of contamination, in the optical path of the sensor pickup (lenses, slotted disc) Nominal (rated) torque Mnom 100 200 500 360 "0.05 "0.05 360; 180; 90; 60; 45; 30 90 108 72 96 < 5 (typ. 2.2) < approx. 2 < approx. 2 < 50 Effect of turbulence on the zero point, related to the nominal (rated) torque Option 3, code L 4) Option 3, code H 4) Output signal for frequency/pulse output Load resistance Rotational speed Fieldbuses Resolution System accuracy (with torsional vibrations of max. 3% of the current rotational speed at 2x rotational frequency) Max. rotational speed variation at nominal (rated) rotational speed (100 Hz filter) Voltage output Measuring range Resolution Scaling range Overload limits Load resistance Linearity error Nominal (rated) power consumption Maximum cable length 4) 5) k < 0.05 < 0.03 < 0.03 < 0.02 < 0.08 < 0.04 < 0.03 < 0.02 5 5) symmetrical; two square-wave signals, approx. 90_ out-of-phase 2 rpm 0.1 ppm 150 rpm 1.5 mV k "10 0.33 10 to 1000 "10.2 > 10 < 0.03 < 18 50 See page 87. RS−422 complementary signals, note termination resistances. HBM A1979−10.0 en 59 T12 Nominal (rated) torque Mnom Temperature effect per 10 K in the nominal (rated) temperature range on the output signal, related to the actual value of the signal span on the zero signal Residual ripple Angle of rotation Accuracy Resolution Correction of runtime deviation between torque LP1 and the angle of rotation for filter frequencies Nm kNm 100 200 500 mV < 0.03 < 0.03 <3 degrees degrees 1 (typ. 0.1) 0.01 Hz 4000; 2000; 1000; 500; 200; 100 degrees 0 to 360 (single-turn) to "1440 (multi-turn) Performance Measurement frequency range Resolution Hz 80 (−1 dB) Full scale value Measuring range Temperature effect per 10 K in the nominal (rated) temperature range on the power signal, related to the full scale value Non-linearity including hysteresis, related to the full scale value Sensitivity tolerance (deviation of the actual measurement signal span of the power signal related to the full scale value) Temperature signal of the rotor Accuracy Measurement frequency range Resolution Physical unit Data rate A1979−10.0 en P max + M nom @ n nom @ p 30 [Mnom] in Nm [nnom] in rpm "0.05@n/nnom "0.02@n/nnom "0.05 Hz − Meas. values/ 5 (−1 dB) 0.1 C 40 HBM 60 Fieldbuses CAN Bus Protocol Data rate Hardware bus link Baud rate Maximum line length Connector PROFIBUS DP Protocol Baud rate PROFIBUS Ident Number Input data , max. Output data, max. Diagnostic data Connector T12 − Meas. values/ kBit/s − − MBaud − bytes bytes bytes − Update rate 6) Configuration entries v2 v4 Meas. v8 values/ v 12 v 16 u 16 Limit value switches (on fieldbuses only) Number − Reference level − Hysteresis Adjustment accuracy Response time (LP1 = 4000 Hz) TEDS (Transducer Electronic Data Sheet) Number 6) digits ms − TEDS 1 (torque) − TEDS 2 (rotational speed/angle of rotation) − CAN 2.0B, CAL/CANopen-compatible max. 4800 (PDO) as per ISO 11898 1000 500 250 125 100 25 100 250 500 600 5-pin, M12x1, A-coding per CANopen DR−303−1 V1.3, electrically isolated from power supply and measurement ground PROFIBUS DP Slave, per DIN 19245-3 max. 12 096C (hex) 152 40 18 (2@4-byte module diagnosis) 5-pin, M12x1, B-coding, electrically isolated from power supply and measurement ground 4800 2400 1200 600 300 150 4 for torque, 4 for rotational speed Torque low pass 1 or low pass 2 Rotational speed low pass1 or low pass 2 0 to 100 typ. 3 A choice of voltage sensor or frequency sensor Frequency/pulse sensor When CAN PDOs are activated simultaneously, the update rate on the PROFIBUS is reduced. HBM A1979−10.0 en 61 T12 Nominal (rated) torque Mnom General information EMC Emission (per FCC 47 Part 15, Subpart C) Emission (per EN61326−1, Table 3) RFI voltage RFI power RFI field strength Immunity from interference (EN61326−1, Table A.1) Electromagnetic field (AM) Magnetic field Electrostatic discharge (ESD) Contact discharge Air discharge Fast transients (burst) Impulse voltages (surge) Conducted interference (AM) Degree of protection per EN 60529 Reference temperature Nominal (rated) temperature range Operating temperature range Storage temperature range Impact resistance, test severity level according to DIN IEC 68; Part 227; IEC 682271987 Number Duration Acceleration (half sine) Vibration in 3 directions according to EN 60068−2−6: IEC 68-2-6-1982 Frequency range Duration Acceleration (amplitude) Load limits7) Limit torque, (static) " Breaking torque, (static) " Longitudinal limit force (static) " Longitudinal limit force (dynamic) amplitude Lateral limit force (static) " Lateral limit force (dynamic) amplitude Limit bending moment (static) " Limit bending moment (dynamic) amplitude Oscillation width per DIN 50100 (peak-to-peak) 8) 7) 8) Nm kNm 100 200 500 − − − − Class A Class A Class A V/m A/m 10 30 kV kV kV kV C C C C IP 54 23 +10 to +60 −10 to +60 −20 to +70 ms m/s2 1000 650 Hz m/s2 5 to 65 1.5 50 % of Mnom % of Mnom kN kN kN kN Nm Nm 2.5 0.5 50 25 10 100 50 16 200 100 19 8.5 2.5 220 110 Nm 200 400 1000 2000 200 > 400 Each type of irregular stress (bending moment, lateral or longitudinal force, exceeding nominal (rated) torque) can only be permitted up to its specified limit provided none of the others can occur at the same time. If this condition is not met, the limit values must be reduced. If 30% of the limit bending moment and lateral limit force occur at the same time, only 40% of the longitudinal limit force is permissible and the nominal (rated) torque must not be exceeded. The effects of permissible bending moments, longitudinal and lateral forces on the measurement result are v"0.3% of the nominal (rated) torque. The nominal (rated) torque must not be exceeded. A1979−10.0 en HBM 62 Nominal (rated) torque Mnom T12 Nm kNm 100 200 500 Mechanical values Torsional stiffness cT Torsion angle at Mnom Stiffness in the axial direction ca Stiffness in the radial direction cr Stiffness during the bending moment round a radial axis cb Maximum deflection at longitudinal limit force Additional max. radial deviation at lateral limit force Additional plumb/parallel deviation at limit bending moment (at j dB) Balance quality level per DIN ISO 1940 Max. limits for relative shaft vibration (peak-to-peak)9) Undulations in the connection flange area, based on ISO 7919−3 kNm/ rad degree kN/mm kN/mm kNm/ degree 230 270 540 900 0.048 0.043 0.055 0.066 420 130 800 290 740 550 760 810 3.8 11.5 12 mm < 0.02 < 0.03 mm < 0.02 mm < 0.03 < 0.05 G 2.5 Normal operation (continuous operation) 9000 s (p*p) + Ǹn m Start and stop operation, resonance ranges (temp.) s (p*p) + 13200 Ǹn (n in rpm) Mass moment of inertia of the rotor IV (around rotary axis) IV with optical rotational speed measuring system Proportional mass moment of inertia for the transmitter side without rotational speed measuring system with optical rotational speed measuring system Max. permissible static eccentricity of the rotor (radially) to the center point of the stator without rotational speed measuring system with rotational speed measuring system Max. permissible axial displacement of the rotor to the stator Weight, approx. Rotor Stator 9) kgm2 0.0023 0.0033 0.0059 kgm2 0.0025 0.0035 0.0062 58 56 56 54 mm mm mm kg kg "2 "1 "2 1.1 1.8 2.4 2.3 The influence of radial deviations, impact, defects of form, notches, marks, local residual magnetism, structural variations or material anomalies on the vibrational measurements needs to be taken into account and isolated from the actual undulation. HBM A1979−10.0 en 63 T12 15.2 Nominal (rated) torque 2 kNVm to 10 kNVm Type Accuracy class Torque measuring system Nominal (rated) torque Mnom Nominal (rated) rotational speed nnom Option 3, code L 1) Option 3, code H 1) Non-linearity including hysteresis, related to nominal (rated) sensitivity Fieldbuses, frequency output 10 kHz/60 kHz For a max. torque in the range: between 0% of Mnom and 20% of Mnom > 20% of Mnom and 60% of Mnom > 60% of Mnom and 100% of Mnom Voltage output For a max. torque in the range: between 0% of Mnom and 20% of Mnom > 20% of Mnom and 60% of Mnom > 60% of Mnom and 100% of Mnom Relative standard deviation of repeatability per DIN 1319, related to the variation of the output signal Fieldbuses/frequency output Voltage output Temperature effect per 10 K in the nominal (rated) temperature range on the output signal, related to the actual value of the signal span Fieldbuses/frequency output Voltage output on the zero signal, related to the nominal (rated) sensitivity Fieldbuses/frequency output Voltage output Nominal (rated) sensitivity (span between torque = zero and nominal (rated) torque) Frequency output 10 kHz/60 kHz Voltage output Sensitivity tolerance (deviation of the actual output quantity at Mnom from the nominal (rated) sensitivity) Frequency output Voltage output 1) T12 0.03 kNm rpm rpm 12 000 16 000 10 10 000 14 000 12 000 <"0.006 (optional <"0.004) <"0.013 (optional <"0.007) <"0.02 (optional <"0.01) <"0.015 <"0.035 <"0.05 "0.01 "0.03 "0.03 "0.1 "0.02 (optional "0.01) "0.1 kHz 5/30 10 "0.05 "0.1 See page 87. A1979−10.0 en HBM 64 Nominal (rated) torque Mnom Output signal at torque = zero Frequency output 10 kHz/60 kHz Voltage output Nominal (rated) output signal Frequency output with positive nominal (rated) torque 10 kHz/60 kHz with negative nominal (rated) torque 10 kHz/60 kHz Voltage output with positive nominal (rated) torque with negative nominal (rated) torque Scaling range Frequency output/voltage output Resolution Frequency output 10 kHz/60 kHz Voltage output Residual ripple Voltage output Maximum modulation range 3) Frequency output 10 kHz/60 kHz Voltage output Load resistance Frequency output Voltage output Long-term drift over 48 h Voltage output Measurement frequency range Frequency output/voltage output −1 dB Frequency output/voltage output −3 dB 2) 3) T12 kNm 10 kHz 10/60 kHz 15/90 (5 V symmetrical 2)) kHz 5/30 (5 V symmetrical 2)) +10 −10 10 to 1000 (of Mnom) Hz mV 0.03/0.25 0.33 mV kHz 4 to 16/24 0 96 −10.2 to +10.2 k k 2 10 mV "3 Hz Hz 0 to 4000 0 to 6000 0.05 to 4000 (fourth-order Bessel, −1 dB); factory setting 1000 Hz 0.05 to 100 (fourth-order Bessel, −1 dB); factory setting 1 Hz Low-pass filter LP1 Hz Low-pass filter LP2 Hz Group delay (low-pass LP1: 4 kHz) Frequency output 10 kHz/60 kHz Voltage output Energy supply Nominal (rated) supply voltage (DC) (separated extra-low voltage) Current consumption in measuring mode Current consumption in startup mode Nominal (rated) power consumption Maximum cable length Shunt signal Tolerance of the shunt signal, related to Mnom s s 320/250 500 18 to 30 < 1 (typ. 0.5) <4 < 18 50 50% of Mnom or 10% of Mnom "0.05 RS−422 complementary signals, note termination resistance. Output signal range in which there is a repeatable correlation between torque and output signal. HBM A1979−10.0 en 65 T12 Nominal (rated) torque Mnom kNm Rotational speed/angle of rotation measuring system Optical, using infrared light and a metallic slotted disc numbe Mechanical increments Positional tolerance of the increments mm Tolerance of the slot width mm Pulses per revolution (adjustable) numbe Pulse frequency at nominal (rated) rotational speed nnom Option 3, code L 4) kHz 4) Option 3, code H kHz Minimum rotational speed for sufficient pulse rpm quality Group delay s Hysteresis of direction of rotation reversal in the case of relative vibrations between rotor and stator degree Torsional vibration of the rotor Radial vibrations of the stator mm Permitted degree of contamination, in the optical path of the sensor pickup (lenses, slotted disc) 360 10 720 "0.05 "0.05 360; 180; 90; 720; 360; 180; 60; 45; 30 120; 90; 60 72 96 120 168 < 5 (typ. 2.2) < approx. 2 < approx. 2 < 50 Effect of turbulence on the zero point, related to the nominal (rated) torque Option 3, code L 4) Option 3, code H 4) 4) 5) Output signal for frequency/pulse output Load resistance Rotational speed Fieldbuses Resolution System accuracy (with torsional vibrations of max. 3% of the current rotational speed at 2x rotational frequency) Max. rotational speed variation at nominal (rated) rotational speed (100 Hz filter) Voltage output Measuring range Resolution Scaling range Overload limits Load resistance Linearity error Nominal (rated) power consumption Maximum cable length k < 0.02 < 0.01 < 0.02 < 0.01 5) 5 symmetrical; two square-wave signals, approx. 90_ out-of-phase 2 rpm 0.1 ppm 150 rpm 1.5 mV k "10 0.33 10 to 1000 "10.2 > 10 < 0.03 < 18 50 See page 87. RS−422 complementary signals, note termination resistances. A1979−10.0 en HBM 66 Nominal (rated) torque Mnom Temperature effect per 10 K in the nominal (rated) temperature range on the output signal, related to the actual value of the signal span on the zero signal Residual ripple Angle of rotation Accuracy Resolution Correction of runtime deviation between torque LP1 and the angle of rotation for filter frequencies T12 kNm mV degree degree 10 < 0.03 < 0.03 <3 1 (typ. 0.1) 0.01 Hz degree 4000; 2000; 1000; 500; 200; 100 Performance Measurement frequency range Resolution Hz 80 (−1 dB) Full scale value Measuring range Temperature effect per 10 K in the nominal (rated) temperature range on the power signal, related to the full scale value Non-linearity including hysteresis, related to the full scale value Sensitivity tolerance (deviation of the actual measurement signal span of the power signal related to the full scale value) Temperature signal of the rotor Accuracy Measurement frequency range Resolution Physical unit Data rate HBM 0 to 360 (single-turn) to "1440 (multi-turn) [Mnom] in Nm [nnom] in rpm P max + M nom @ n nom @ p 30 "0.05@n/nnom "0.02@n/nnom "0.05 Hz − Meas. values/ 5 (−1 dB) 0.1 C 40 A1979−10.0 en 67 T12 Fieldbuses CAN Bus Protocol Data rate Hardware bus link Baud rate Maximum line length Connector PROFIBUS DP Protocol Baud rate PROFIBUS Ident Number Input data , max. Output data, max. Diagnostic data Connector − Meas. values/ kBit/s − − MBaud − bytes bytes bytes − Update rate 6) Configuration entries v2 v4 Meas. v8 values/ v 12 v 16 u 16 Limit value switches (on fieldbuses only) Number − Reference level − Hysteresis Adjustment accuracy Response time (LP1 = 4000 Hz) TEDS (Transducer Electronic Data Sheet) Number 6) digits ms − TEDS 1 (torque) − TEDS 2 (rotational speed/angle of rotation) − CAN 2.0B, CAL/CANopen−compatible max. 4800 (PDO) as per ISO 11898 1000 500 250 125 100 25 100 250 500 600 5-pin, M12x1, A-coding per CANopen DR−303−1 V1.3, electrically isolated from power supply and measurement ground PROFIBUS DP Slave, per DIN 19245-3 max. 12 096C (hex) 152 40 18 (2@4−byte module diagnosis) 5-pin, M12x1, B-coding, electrically isolated from power supply and measurement ground 4800 2400 1200 600 300 150 4 for torque, 4 for rotational speed Torque low pass 1 or low pass 2 Rotational speed low pass1 or low pass 2 0 to 100 typ. 3 A choice of voltage sensor or frequency sensor Frequency/pulse sensor When CAN PDOs are activated simultaneously, the update rate on the PROFIBUS is reduced. A1979−10.0 en HBM 68 Nominal (rated) torque Mnom General information EMC Emission (per EN61326−1, Table 3) RFI voltage RFI power RFI field strength Immunity from interference (EN61326−1, Table A.1) Electromagnetic field (AM) Magnetic field Electrostatic discharge (ESD) Contact discharge Air discharge Fast transients (burst) Impulse voltages (surge) Conducted interference (AM) Degree of protection per EN 60529 Reference temperature Nominal (rated) temperature range Operating temperature range Storage temperature range Impact resistance, test severity level according to DIN IEC 68; Part 227; IEC 682271987 Number Duration Acceleration (half sine) Vibration in 3 directions according to EN 60068−2−6: IEC 68-2-6-1982 Frequency range Duration Acceleration (amplitude) Load limits7) Limit torque, (static) " Breaking torque, (static) " Longitudinal limit force (static) " Longitudinal limit force (dynamic) amplitude Lateral limit force (static) " Lateral limit force (dynamic) amplitude Limit bending moment (static) " Limit bending moment (dynamic) amplitude Oscillation width per DIN 50100 (peak-to-peak) 8) 7) 8) T12 kNm − − − Class A Class A Class A V/m A/m 10 30 kV kV kV kV C C C C IP 54 23 +10 to +60 −10 to +60 −20 to +70 ms m/s2 1000 650 Hz m/s2 % of Mnom % of Mnom kN kN kN kN Nm Nm Nm 5 to 65 1.5 50 10 50 200 160 > 400 > 320 39 19.5 4.5 560 280 42 21 10 600 300 80 40 12 800 400 120 60 18 1200 600 4000 4800 8000 16000 Each type of irregular stress (bending moment, lateral or longitudinal force, exceeding nominal (rated) torque) can only be permitted up to its specified limit provided none of the others can occur at the same time. If this condition is not met, the limit values must be reduced. If 30% of the limit bending moment and lateral limit force occur at the same time, only 40% of the longitudinal limit force is permissible and the nominal (rated) torque must not be exceeded. The effects of permissible bending moments, longitudinal and lateral forces on the measurement result are v"0.3% of the nominal (rated) torque. The nominal (rated) torque must not be exceeded. HBM A1979−10.0 en 69 T12 Nominal (rated) torque Mnom Mechanical values Torsional stiffness cT Torsion angle at Mnom Stiffness in the axial direction ca Stiffness in the radial direction cr Stiffness during the bending moment round a radial axis cb Maximum deflection at longitudinal limit force Additional max. radial deviation at lateral limit force Additional plumb/parallel deviation at limit bending moment (at j dB) Balance quality level per DIN ISO 1940 Max. limits for relative shaft vibration (peak-to-peak) 9) Undulations in the connection flange area, based on ISO 7919−3 kNm kNm/ rad degrees kN/mm kN/mm kNm/ degrees mm 10 2300 2600 4600 7900 0.049 950 1300 0.066 1000 1500 0.06 950 1650 0.07 1600 2450 21.7 22.4 43 74 < 0.05 < 0.1 mm < 0.02 mm < 0.07 G 2.5 Normal operation (continuous operation) 9000 s (p*p) + Ǹn m Start and stop operation, resonance ranges (temp.) s (p*p) + 13200 Ǹn (n in rpm) Mass moment of inertia of the rotor IV (around rotary axis) IV with optical rotational speed measuring system Proportional mass moment of inertia for the transmitter side without rotational speed measuring system with optical rotational speed measuring system Max. permissible static eccentricity of the rotor (radially) to the center point of the stator without rotational speed measuring system with rotational speed measuring system Max. permissible axial displacement of the rotor to the stator Weight, approx. Rotor Stator 9) kgm2 0.0192 0.037 0.097 kgm2 0.0196 0.038 0.0995 54 53 53 52 mm "2 mm "1 mm "2 kg 4.9 8.3 14.6 kg 2.4 2.5 2.6 The influence of radial deviations, impact, defects of form, notches, marks, local residual magnetism, structural variations or material anomalies on the vibrational measurements needs to be taken into account and isolated from the actual undulation. A1979−10.0 en HBM 70 T12 16 Dimensions 16.1 Rotor 100 NVm to 200 NVm b2 b5 b3 b3 b1 b7 30 b4 dA dG dza dF 6x60 dzi dc dz b6 d B xS View A 30 Plane of temperature measurement xS = measuring plane (center of the installation point) 6xY 60 6x60 d B Dimensions without tolerances, per DIN ISO 2768−mK Dimensions in mm (1 mm = 0.03937 inches) b4 b5 b6 b7 47.15 14 12.5 Measuring range 100 Nm/200 Nm b1 22 b2 60 b3 18 Measuring range 100 Nm/200 Nm HBM 60 6x60 dA dB dC 115.5 84 99 Dimensions in mm (1 mm = 0.03937 inches) dF dG dK d SC12 101 110 14 8.2 xS 30 M8 d Z dza g5 dzi H6 131 57 57 A1979−10.0 en 71 T12 16.2 Rotor 500 NVm to 10 kNVm b2 b3 b1 5 b7 b4 dza dF dzi dc dz b5 dG dA b3 b6 d B xs View A 8xY Plane of temperature measurement xs = measuring plane (center of the installation point) d B Dimensions without tolerances, per DIN ISO 2768−mK Dimensions in mm (1 mm = 0.03937 inches) b4 b5 b6 b7 45.7 14 47.7 14 2.5 3.3 62.7 17.5 2.8 3.3 66.7 17.5 3.5 10 Measuring range 500 Nm/1 kNm 2 kNm/3 kNm 5 kNm 10 kNm b1 22 23 24.8 24.8 b2 60 64 84 92 b3 18 20 26 30 Measuring range Dimensions in mm (1 mm = 0.03937 inches) dF dG dK d SC12 xS 30 32 42 46 M10 M12 M14 M16 dA dB dC d Z dza g5 dzi H6 500 Nm/1 kNm 136.5 101.5 120 124 133 17 10 151 75 75 2 kNm/3 kNm 172.5 130 155 160 169 19 12 187 90 90 5 kNm 10 kNm 200.5 242.5 155.5 196 179 221 188 230 197 239 22 26 14.2 17 221 269 110 140 110 140 A1979−10.0 en HBM 72 T12 16.3 Stator 100 Nm to 200 Nm with rot.speed meas. system View Z Dimensions in mm (1 mm = 0.03937 inches) min. 43 Reserved additional space for connected state min. 10 150 Reserved additional space for mounting and dismounting M6 max. thread reach 10+1 approx. 54 Cable socket adjustable in 4 angular positions approx. 100 Reserved additional space for connection cable with plug 180 UNF 1/4max. thread reach 0.4+0.02 approx. V20 114.3 = 4 1/2 ACCESSORIES ! Cable socket 7-pin and 8-pin 90 cable routing Side view Y 60 32 24 (18) 89.5 Side view X 24 28 45 62 66 194.5 260 115.5 110 101 57 g5 84 (28) 18 22 4 14 57 H6 99 131 28 10 8 (28) 6.5 56 Top view HBM A1979−10.0 en 73 T12 16.4 Stator 100 Nm to 200 Nm with rot. speed meas. system Dimensions in mm (1 mm = 0.03937 inches) View A 84 For rotational speed measuring system and rotational speed measuring system with reference marker only A1979−10.0 en HBM 74 T12 16.5 Stator 100 Nm to 10 kNm with rot. speed meas. system View Z Dimensions in mm (1 mm = 0.03937 inches) approx. 100 Reserved additional space for connection cable with plug 180 150 min. 43 M6 Maximum thread reach 10 +1 approx. 54 Reserved additional space for connected state min. 10*) Reserved additional space for mounting and dismounting approx. 20 Cable socket adjustable in 4 angular positions UNF 1/4” Maximum thread reach 0.4” +0.02” 114.3 = 4 1/2” Accessories Cable socket 7-pin and 8-pin 90 cable routing *) At 5 kNm and 10 kNm: min. 14 mm Side view Y Air gap area: Side view X Radially = 10 mm Axially = b2 (see page 70) 24 28 45 62 66 H2 H1 10 8 6.5 (28) 56 Stator mid−point 28 Top view For rotational speed measuring system and rotational speed measuring system with reference marker only Dimensions without tolerances, per DIN ISO 2768−mK Measuring range (NVm) 100 200 500 1k 2k 3k 5k 10 k HBM Dimensions in mm (1 mm = 0.03937 inches) D H1 H2 81 122 260 194.5 91.5 143 280 204.5 109.5 179 310 222.5 123.5 144.5 207 249 333 369 239.5 263.5 A1979−10.0 en 75 T12 16.6 Stator 100 Nm to 200 Nm with prot. against contact Dimensions in mm (1 mm = 0.03937 inches) [Covering agent] 56 [Housing] [Covering agent] 56 [Housing] 12 32 118 93.5 23 81 88 0.55 194.5 89.3 [Locking screw] Rotational speed sensor [projection] 307 102.5 [Protection against contact cpl.] 58 [Protection against contact cpl.] 58 View without housing half Cutaway dimension (in rotational speed measuring system only) and without cutaway in the standard version (without rotational speed measuring system) Part of the standard version! The components on both sides must be removed to mount the protective housing. View A A1979−10.0 en HBM 76 T12 16.7 Stator 100 Nm to 200 Nm with prot. against contact Dimensions in mm (1 mm = 0.03937 inches) View B 225+2 205 196 185−2 11 88 40 6.6 Connection holes Z (6.6) 56 [Housing] (11) View without covering agent 43 Connecting hole with countersinking HBM A1979−10.0 en 77 T12 16.8 Stator 500 Nm to 1 kNm with prot. against contact (58) (56) 139 12 32 against contact) 204.5 98 103.5 317 99.3 (Locking screw) 102.5 (Cover plate) 58 (Protection against contact, cpl.) 56 (Protection (Cover plate) 223+2 205 View without protection against contact half 196 187−2 View A 11 Connection holes Z 98 6.6 90 40 (56) Protection against contact 11 6.6 43 Connecting hole with countersinking View without cover plate A1979−10.0 en Dimensions in mm (1 mm = 0.03937 inches) HBM 78 T12 16.9 Stator 2 kNm to 10 kNm with prot. against contact b4 b1 (Housing) b2 b3 (Cover plate) d1 b6 b5 View without protection against contact half d2 d3 d4 d5 View A Connection holes Z b2 Protection against contact (6.6) H6 b9 (11) 11 6.6 H4 H1 H2 H7 (Locking screw) H3 H5 b3 (Cover plate) b1 b2 b7 b8 Connecting hole with countersinking View without cover plate Measuring range 2 kNm/3 kNm 5 kNm 10 kNm b1 58 80 88 b2 56 78 86 b3 Measuring range 2 kNm/3 kNm 5 kNm 10 kNm HBM d1 175 203 245 b4 b5 b6 12 12 12 Dimensions in mm (1 mm = 0.03937 inches) b7 b8 b9 H1 H2 H3 H4 32 43 97.5 116 222.5 353 121.5 32 65 99 133 239.5 384 138.5 32 73 99 157 263.5 429 162.5 Dimensions in mm (1 mm = 0.03937 inches) d2 d3 d4 259+2 241 232 289+2 269 260 331+2 311 302 H6 107 120 145 H5 120.5 134.5 155.5 H7 117.3 134.3 158.3 d5 223−2 249−2 291−2 A1979−10.0 en 79 T12 16.9.1 Protection against contact plates 100 Nm to 200 Nm Dimensions in mm (1 mm = 0.03937 inches) M3 screw head 1:4 M4 screw head [Locking screw] External = 7 Height = 2 External = 9 Height = 2.5 16.9.2 Protection against contact plates 500 Nm to 10 kNm Dimensions in mm (1 mm = 0.03937 inches) Spacing bolts for 5 kN@m and 10 kN@m only Screw head External = 7 Height = 2 Screw head (locking screw) External = 9 Height = 2.5 A1979−10.0 en HBM 80 T12 16.10 Mounting dimensions Mounting dimensions Stator mid-point Rotor mid-point Measuring range Mounting dimension (mm) 5 kNm 25 11 10 kNm 33 15 100 Nm 200 Nm 500 Nm 1 kNm 2 kNm 3 kNm (Tolerance "1 mm) HBM Reserved add. space for fieldbus connection cables: approx. 140 mm, from plug connection tag A1979−10.0 en 81 T12 17 Supplementary technical information Axial and radial run-out tolerances Axial run-out AB Radial run-out AB Internal centering Hardness 46 to 54 HRC 0.8 Surface quality of the axial and radial run-out tolerances (A, B and AB) Measuring range (NVm) Axial run-out tolerance (mm) 100 200 500 1k 2k 3k 5k 10 k 0.01 0.01 0.01 0.01 0.02 0.02 0.025 0.025 A1979−10.0 en Radial run-out tolerance (mm) 0.01 0.01 0.01 0.01 0.02 0.02 0.025 0.025 HBM 82 18 T12 Condition at the time of delivery Parameter factory settings are marked with an asterisk (*). Underlined parameters are not overwritten by returning to the factory settings. SYSTEM Default settings Project name Language Define pass code (1 – 9999) Pass code active? Reactivate pass code LED display mode Fieldbus interfaces CANopen CAN address CAN baud rate LSS manufacturer number LSS product number LSS revision number LSS serial number PDO measuring rate divider Signal PDO 1 (transmit, max. 4.8 kHz) Signal PDO 2 (transmit, max. 1.2 kHz) Signal PDO 3 (transmit, max. 0.6 kHz) Signal PDO 4 (transmit, max. 0.6 kHz) Write calibration information Torque calibration date (dd.mm.yyyy) Torque calibration initials Torque calibration cycle Measuring point number Calibration date for rotational speed/angle of rotation output (dd.mm.yyyy) HBM My Project Deutsch; English Yes*; No Reactivate pass code Standard (measuring mode) Rotor clearance setting mode Opt. rotational speed measuring system setting mode 110 100 kB; 125 kB; 250 kB; 500 kB; 1000 kB* 285 1025 4294967040 4294967040 1; 2*; 4; 8; 16; 32; 64 Off Torque low pass 1* Torque + rotational speed low pass 1 Torque low pass 1 + angle of rotation Off Torque low pass 2* Torque + rotational speed low pass 2 Off* Power + rotor temperature Off* Status for torque, rotational speed/angle of rotation 30.11.06 RH 30.11.06 A1979−10.0 en T12 83 Calibration initials for rotational KM speed/angle of rotation output Calibration cycle for rotational speed/angle of rotation output Measuring point number Voltage calibration date 30.11.06 (dd.mm.yyyy) Voltage calibration initials HM Voltage calibration cycle Measuring point number Pass code input Enter pass code (1 – 9999) TRANSDUCER PARAMETERIZATION Torque Measuring point designation MyTorqueMeasPnt Measuring point number Unit Nm*; kNm; ozfin; ozfft; lbfin; lbfft Decimal point .; .0; .00; .000*; .0000; .00000 Sign Positive*; negative Low pass filter 1 0.05 Hz; 0.1 Hz; 0.2 Hz; 0.5 Hz; 1 Hz; 2 Hz; 5 Hz; (nominal (rated) value) 10 Hz; 20 Hz; 50 Hz; 100 Hz; 200 Hz; 500 Hz; 1 kHz*; 2 kHz; 4 kHz Low pass filter 2 0.05 Hz; 0.1 Hz; 0.2 Hz; 0.5 Hz; 1 Hz*; 2 Hz; 5 Hz; (nominal (rated) value) 10 Hz; 20 Hz; 50 Hz; 100 Hz Measure point 1 Measure point 1 Actual value of physical point 1 0.000* Setpoint (value) of physical point 1 0.000* Measure point 2 Measure point 2 Actual value of physical point 2 100.000* Setpoint (value) of physical point 2 100.000* 2-point scaling Active; deactivated* Rotational speed Unit 1/min*; rpm; 1/s; rad/s Decimal point .; .0; .00; .000* Sign Positive*; negative Low-pass filter 1 0.05 Hz; 0.1 Hz; 0.2 Hz; 0.5 Hz; 1 Hz; 2 Hz; 5 Hz; (nominal (rated) value) 10 Hz; 20 Hz; 50 Hz; 100 Hz; 200 Hz; 500 Hz; 1 kHz*; 2 kHz; 4 kHz Low-pass filter 2 0.05 Hz; 0.1 Hz; 0.2 Hz; 0.5 Hz; 1 Hz*; 2 Hz; 5 Hz; (nominal (rated) value) 10 Hz; 20 Hz; 50 Hz; 100 Hz Angle of rotation Unit Degree*; rad Decimal point .; .0*; .00 Signal for zero balance Rotational speed sensor* (with reference signal); Command* (without reference signal) A1979−10.0 en HBM 84 T12 Rotational speed/angle of rotation output Measuring point designation MySpeedMeasPnt Measuring point number Mechanical increments 360*/720* Signals F1/ F2 Frequency* Pulse (pos. edge)/direction of rotation Pulse (pos./neg. edge)/direction of rotation Pulse (4 edges)/direction of rotation Output pulse division 1*; 2; 4; 6; 8; 12 Increments per revolution 360*/720* Hysteresis for reversing the On*; Off direction of rotation Frequency output Signal Torque low pass 1* Torque low pass 2 Mode 10 +/− 5 kHz* 60 +/− 30 kHz* Setpoint (value) of physical point 1 0.000* (dep. on nominal (rated) measuring range) Setpoint (value) of physical point 2 1000.000* (dep. on nominal (rated) measuring range) Frequency of point 1 10.000000* (dep. on electrical configuration) Frequency of point 2 15.000000* (dep. on electrical configuration) Analog output Signal Torque low pass 1* Torque low pass 2 Rotational speed low pass 1 Rotational speed low pass 2 Measuring point number Mode 10 V* Setpoint (value) of physical point 1 0.000* Setpoint (value) of physical point 2 1000.000* Voltage of point 1 0.0000* Voltage of point 2 10.0000* Power Unit W; kW*; MW; hp Decimal point .; .0; .00; .000* Low pass filter (−1 dB) 0.1 Hz; 1 Hz*; 10 Hz; 100 Hz SIGNAL CONDITIONING Torque Shunt On; Off* Shunt signal (of nominal (rated) 10%; 50%* value) Zero signal compensation Zero signal compensation Zero value 0.000* HBM A1979−10.0 en 85 T12 Angle of rotation Measuring range Number of revolutions n ADDITIONAL FUNCTIONS Limit values Limit value 1 Monitoring Signal Switching direction Level Hysteresis Limit value 2 Monitoring Signal Switching direction Level Hysteresis Limit value 3 Monitoring Signal Switching direction Level Hysteresis Limit value 4 Monitoring Signal A1979−10.0 en 0 to n x 360 degrees, pos. direction of rotation* 0 to n x 360 degrees, neg. direction of rotation 0 to −n x 360 degrees, pos. direction of rotation 0 to −n x 360 degrees, neg. direction of rotation −n x 360 to n x 360 degrees, pos. direction of rotation −n x 360 to n x 360 degrees, neg. direction of rotation 1*; 2; 3; 4 On; Off* Torque low pass 1* Torque low pass 2 Overshoot* Undershoot 10.000* 0.500* On; Off* Torque low pass 1* Torque low pass 2 Overshoot* Undershoot 10.000* 0.500* On; Off* Torque low pass 1* Torque low pass 2 Overshoot Undershoot* −10.000* 0.500* On; Off* Torque low pass 1* Torque low pass 2 On; Off* Rotational speed low pass 1* Rotational speed low pass 2 Overshoot* Undershoot 10.0* 0.5* On; Off* Rotational speed low pass 1* Rotational speed low pass 2 Overshoot* Undershoot 10.0* 0.5* On; Off* Rotational speed low pass 1* Rotational speed low pass 2 Overshoot Undershoot* −10.0* 0.5* On; Off* Rotational speed low pass 1* Rotational speed low pass 2 HBM 86 Switching direction Level Hysteresis SAVE/LOAD PARAMETERS Load from transducer Choose parameter set Save to transducer Choose parameter set TEDS template for torque Rotational speed/angle of rotation output HBM T12 Overshoot Undershoot* −10.000* 0.500* Overshoot Undershoot* −10.0* 0.5* 1*; 2; 3; 4; factory settings 1; 2; 3; 4 HBM Frequency Sensor* High Level Voltage Output HBM Frequency Sensor* HBM Pulse Sensor A1979−10.0 en 87 T12 19 Ordering numbers Code S100Q Option 1: measuring range 100 Nm S200Q 200 Nm S500Q 500 Nm S001R 1 kNm S002R 2 kNm S003R 3 kNm S005R 5 kNm S010R 10 kNm Code Code Option 5: bus connection CANopen (2 device plugs) CANopen and Profibus DPV1 Code Option 6: rotational speed measuring system Without rotational speed measuring system With optical rotational speed measuring system; 360 or 720 pulses/revolution With optical rotational speed measuring system; 360 or 720 pulses/revolution and reference signal Option 2: accuracy Standard Greater accuracy1) Lin. t"0.01% and TK0 t"0.01%/10 K Code Code Option 3: nominal (rated) rotational speed Dependent on meas. range up to 15 000 rpm Dependent on meas.range up to 18 000 rpm Option 7: protection against contact Without protection against contact With protection against contact Option 8: MODULFLEX) coupling2) Code Code Option 4: electrical configuration Without coupling DF1 Output signal 60 kHz " 30 kHz With fitted coupling DU2 Output signal 60 kHz " 30 kHz and "10 V SF1 Output signal 10 kHz " 5 kHz SU2 Output signal 10 kHz " 5 kHz and "10 V Code Order no.: A1979−10.0 en No customized modification 11) K-T12 − Ordering example: K-T12 − Option 9: Customized modification 2) S 5 0 0 Q S F 1 For voltage output: lin. t"0.05% ; TK0 t"0.1%/10 K For Option 3, code L only; see data sheet B1957-xx de for specifications. HBM 88 20 T12 Accessories Article Connection cable, set Torque Torque connection cable, Binder 423 7pin-D-Sub 15-pin, 6 m Torque connection cable, Binder 423 free ends, 6 m Rotational speed Torque connection cable, Binder 423 8-pin-D-Sub 15-pin, 6 m Rotational speed connection cable, Binder 423 8-pin free ends, 6 m Rotational speed connection cable, reference signal, Binder 423 8-pin-D-Sub 15-pin, 6 m Rotational speed connection cable, reference signal, Binder 423 8-pin free ends, 6 m CAN Bus CAN Bus M12 connection cable, A-coded, D-Sub 9-pin, switchable termination resistor, 6 m Plugs/sockets Torque 423G−7S, 7-pin cable socket, straight cable entry, for torque output (plug 1, plug 3) 423W−7S, 7-pin cable socket, 90 cable entry, for torque output (plug 1, plug 3) Rotational speed 423G−8S, 8-pin cable socket, straight cable entry, for rotational speed output (plug 2) 423W−8S, 8-pin cable socket, 90 cable entry, for rotational speed output (plug 2) CAN Bus TERMINATOR M12/termination resistor, M12, A-coded, 5-pin, plug Termination resistor, CAN Bus M12, A-coded, 5-pin, socket T-SPLITTER M12/T-piece M12, A-coded, 5-pin Cable plug/socket/CAN Bus M12, cable socket 5-pin M12, A-coded, cable plug 5-pin M12, A-coded PROFIBUS Connection cable, Y-splitter, M12 socket, B-coded; M12 plug, B-coded; M12 socket, B-coded, 2 m Cable plug/socket/PROFIBUS M12, cable socket 5-pin M12, B-coded, cable plug 5-pin M12, B-coded Termination resistor PROFIBUS M12, B-coded, 5-pin T-piece PROFIBUS M12,B-coded, 5-pin Connection cable, by the meter Kab8/00−2/2/2 Kab8/00−2/2/2/1/1 DeviceNet cable Other Setup toolkit for T12 (System CD T12, PCAN-USB adapter, CAN Bus connection cable, 6 m) HBM Order no. 1−KAB149−6 1−KAB153−6 1−KAB150−6 1−KAB154−6 1−KAB163−6 1−KAB164−6 1−KAB161−6 3−3101.0247 3−3312.0281 3−3312.0120 3−3312.0282 1−CANHEAD−TERM 1−CAN−AB−M12 1−CANHEAD−M12−T 1−CANHEAD−M12 1−KAB167-2 1−PROFI−M12 1−PROFI−AB−M12 1−PROFI−VT−M12 4−3301.0071 4−3301.0183 4−3301.0180 1−T12−SETUP−USB A1979−10.0 en T12 A1979−10.0 en 89 HBM 90 HBM T12 A1979−10.0 en Hottinger Baldwin Messtechnik GmbH Im Tiefen See 45 S 64293 Darmstadt S Germany Tel. +49 6151 803−0 S Fax: +49 6151 803−9100 Email: info@hbm.com S www.hbm.com measure and predict with confidence 7−2002.1979 Subject to modifications. All details describe our products in general form only. They are not to be understood as a guarantee of quality or durability. A1979−10.0 en E Hottinger Baldwin Messtechnik GmbH.
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