Installation instructions and notes on implementation of an intermeshed equipotential bonding system with EMClots Project: Project key: Project management: Responsible for the lot: Revision number Created on Edited by Description Draft 0.1 24.05.2017 Steinmetzger Creating the document Version 1.0 10.08.2017 Wagner Adjusting details Version 1.6 11.04.2018 Wagner Adjusting basic rules
Contents 1. Standards and guidelines... 3 2. Fastening elements EMClots... 4 3. Basic rules for the system... 5 3.1 Choice of the right cross section... 5 3.2 Structure of the system... 6 3.3 Examples of installation... 9 4. Installation sequence...11 5. Labelling of the connection points...12 6. Documentation of the system...13 7. Instrumental examination...16 8. Ordering specifications...18 Page 2
The goal of this document is to present the optimal implementation of an intermeshed equipotential bonding system for functional-equipotential bonding and protective-equipotential bonding. The advantage of such a system is the low-impedance dissipation of interference currents and the related high quality for reliability and function of the electric system. 1. Standards and guidelines VDE 0100-540 / DIN EN 61140 Leakage currents PE conductors should not be used as a conductive path for operating currents in normal operation. If the PE current is equal to or greater than 10 ma under normal operating conditions when the device is turned on, one of the following constructive measures has to be implemented: - PE conductor has to have at least 10 mm² along the entire length - Second protective conductor of equal cross-section has to be provided at a separate terminal on the device Machinery Directive DIN EN 60204-1 Excerpt for implementing a CBN "Functional equipotential bonding is usually achieved by means of a connection with the PE conductor system (CBN). However, if the level of electrical disturbances in the PE conductor system is not sufficiently low so as to ensure the proper function of the electrical equipment, it may be necessary to connect the functional-equipotential bonding system to a separate connector for functional grounding..." Since CBN is being installed in most cases, a low level of disturbances is required. DIN VDE 0100-444 and DIN EN 50310 Structure of equipotential bonding systems Star-shaped equipotential bonding structures are not suitable in particular when using signal cables and information technology equipment (e.g. PROFINET). The equipotential bonding should be set up intermeshed as small as possible and thus with low impedance (<0.3 ohm). Draft of the PI Directive "Recommendations for the functional earth and shielding of PROFIBUS and PROFINET" The recommendation of good practices of the PI which currently is being drafted, specifically describes the measures that need to be ensured when employing PROFIBUS and PROFINET. Under requirement H3 it says: "Design the equipotential bonding system as finely intermeshed as possible (MESH-BN)" Page 3
2. Fastening elements EMClots The use of EMClots significantly facilitates the implementation of a distributed intermeshed equipotential bonding system. The components can be used for connecting, fastening and branching of conductor cables of extra-fine wire and stranded type. Undefined interference currents are thus prevented and uniform equipotential bonding is implemented even in long production lines. They are ideal for the implementation according to the finely meshed and low-impedance execution of the equipotential bonding system in machines and systems as required by EN 50310. EMClots Junction V2 EMClots Junction V2 3-fold The EMClots Junction serves to fixate conductor cable (trunk) and to create two branches (spurs) for connection to the BN. The EMClots Junction serves to fixate conductor cable (trunk) and to create three branches (spurs) for connection to the BN. EMClots Fastening V2 EMClots Connector V2 The EMClots Fastening serves to fixate conductor cables (trunk). The EMClots Connector serves to fixate and connect to conductor cables (trunk). Page 4
3. Basic rules for the system 3.1 Choice of the right cross section The choice of the right cross section should be based on the load of the equipotential bonding system. A combined bonding network (CBN) is required for functional and protective reasons. Its main task is not to conduct short-circuit currents which lead to release the fuse of the system. The CBN is mainly installed to reduce potential differences and to conduct potential current. These currents are for example a result of an inductive coupling between protective earth (PE) and the phase of motor cables. The standard DIN VDE 0298-4 describes the maximum current load of conductors with different cross sections. In the following table, the maximum permitted values of installation type B1 (installation in an electrical installation system) are shown: Table 1 permitted maximum load of conductors Permitted maximum load (B1) mended current Maximum recom- Cross section Safety factor 4 mm 2 34 A 15 A 2,3 6 mm 2 43 A 20 A 2,2 10 mm 2 60 A 30 A 2,0 16 mm 2 81 A 40 A 2,0 25 mm 2 107 A 50 A 2,1 35 mm 2 133 A 65 A 2,0 50 mm 2 160 A 80 A 2,0 Based on the maximum permitted load a recommended value is prescribed. This recommended value is calculated by a safety factor. Based on those information and past experience from practical plants, the following cross sections should be used: Table 2 recommended cross sections Load of the system Typical application Recommended cross section Trunk Spur 0 10 A 10 40 A Ab 40 A Small plants without big electrical consumers. e.g.: pick-and-place systems or transport systems Plants with big drives or welding applications. Especially systems with stud or spot welding. Such a high current indicates an incorrect dimensioning of the equipotential bonding system. 10 mm 2 6-10 mm 2 16 mm 2 10 mm 2 A system with such high loads should be planned and dimensioned. Page 5
3.2 Structure of the system The system is built up by trunks (ring-shaped backbone) and spurs (connections). In the following illustration, this is shown based on a classic cell structure. = Trunk of the MESH-BN 12 m 10 m = Spurs of the MESH-BN 20 m Creating a trunk (backbone): Using the cable trays as part of the equipotential bonding system Creating a ring structure with up to 20 metre long loops to ensure reliably maintaining the required loop impedance of 0.3 ohm. As many and small meshes as possible to reduce the impedance and to provide the current with as many and short distances as possible. Install fastening elements EMClots at intervals of 1 metre. A 16 mm² conductor cable is usually used for the trunk. Conductor cables should be tin-plated and non-insulated so that all necessary system parts can be flexibly integrated. For example: conductor cable class 2, tin-plated, non-insulated Alternatively: conductor cable class 7, tin-plated, non-insulated Alternatively: multi-frequency combination conductor cable Connection of the components by spur: Connection of electronic devices, robots, protective bonding etc. Connection by short and flexible conductor cables: max. 2 m Connection to the robot's foot within 2 m A device or system component which requires protective-equipotential bonding (BN) is connected by a 10 mm² spur conductor cable (DIN EN 61140). A device or system component which requires functional-equipotential bonding (FE) is connected by a 6 mm² spur conductor cable. Conductor cable in tin-plated and flexible design, insulated in drag chains. E.g. conductor cable class 7, tin-plated, insulated (green/yellow) or non-insulated Alternatively: multi-frequency combination conductor cable For robots: conductor cable class 8, tin-plated, insulated, torsion capable Page 6
Using the cable trays as part of the equipotential bonding: The fastening of the EMClots can be done within or outside of cable trays. Mounting should be carried out here using a type M6x9 screw. In special application cases, the fastening is possible with a second screw from above. Principally it is recommendable to connect conductive system components, in particular cable trays, to the equipotential bonding (BN) in order to achieve a greatest possible intermeshing. Likewise, conductive system components provide a good discharge capacity for low and high frequency currents due to their large cross-section and the large surface. Separate conductor cables for the equipotential bonding where possible from the lines with electric power (e.g. by spacers). Routing the equipotential bonding together with the 24-volt or the information technology does not pose a problem. The individual currents are minimal due to the intermeshed system. The following variants are possible: Installation inside the cable tray at the bottom. Requires space and installation access from below. Installation laterally inside the cable tray. Protection by the duct and space saving. Page 7
Installation outside of the cable tray. Requires no space within the duct and offers flexible installation possibilities by accessibility and visibility. Installation on profile. Flexible installation possibilities by accessibility and visibility. Attention: coating of profiles prevents connection to bonding network. Installation on other parts. Flexible installation possibilities by accessibility and visibility. Attention: coating of parts prevents connection to bonding network. Page 8
3.3 Examples of installation Examples of the installation of the EMClots EMClots Connector V2 to close loops, installation on construction parts Used in the figure: conductor class 2, tin-plated, 16 mm 2 (Trunk) EMClots Connector V2 to close loops, installation below on cable tray Used in the figure: conductor class 2, tin-plated, 16 mm 2 (Trunk) EMClots Connector V2 to close loops, installation lateral on cable tray Used in the figure: conductor class 2, tin-plated, 16 mm 2 (Trunk) EMClots Junction V2 to connect spurs, installation on a safety fence Used in the figure: conductor class 2, tin-plated, 16 mm 2 (Trunk) and conductor class 5, tin-plated 10mm 2 (Spur) EMClots Junction V2 to connect spurs, installation lateral on cable tray Used in the figure: conductor class 2, tin-plated, 16 mm 2 (Trunk), conductor class 7, tin-plated 6mm 2 (Spur, above) and conductor class 7, tin-plated 10mm 2 (Spur, below) Page 9
Examples of the installation of Spurs Connection on the main earth terminal Used in the figure: conductor class 2, tin-plated, 16 mm 2 (4 th connection) and conductor class 7, tin-plated 10mm 2 (6 th connection) Connection of functional earth on a PROFINET-device Used in the figure: conductor class 7, tin-plated 6mm 2 (Spur) Connection of functional earth on a PROFINET-device Used in the figure: conductor class 7, tin-plated 6mm 2 (Spur) Connection of protective earth on a frame Used in the figure: conductor class 7, tin-plated 10mm 2 (Spur) Connection of protective earth on the cabinet of a robot control Used in the figure: conductor class 7, tin-plated 10mm 2 (Spur) Connection of protective earth on conductive plant components Used in the figure: conductor class 5, tin-plated 10mm 2 (Spur) Page 10
4. Installation sequence Step 1: Installation of all cable trays Step 2: Planning the connection points (functional- and protective-equipotential bonding) Installation of the EMClots Junction in the cable duct near the connection points Step 3: Installation of the trunk Attaching the conductor cable to the already installed EMClots Junction Optional: Installation of further EMClots for affixing the conductor and for maintaining the basic rules of the overall system (mesh size, maximum distance of the fastening elements etc.) Step 4: Connecting the flexible spur conductor cables to the EMClots Junction. Use corresponding wire end ferrules for this. Advice: highly flexible conductor cables have a super-fine structure and need appropriate ferrules and cable lugs. Especially the ratio of outer diameter of the conductor and the inner diameter of the component is important. Route the conductor cables to the connection points - taking the maximum pass length of 2 m into account. Fastening the conductor at the connection point, including labelling of the conductor. Page 11
5. Labelling of the connection points Labels should be applied directly at the fastening element The labelling should be clear The connection point should be labelled with the abbreviation "BN" for Bonding Network. A clear association to the system, the machine and a unique number of the fastening element. The following nomenclature is feasible: Position 1 Position 2 Position 3 Bonding Network XXX. XX. X Abbreviation for the system Abbreviation for the mesh Unique number of the fastening element BN H95. 01. 041 Identification of the system: In Section 6.3.2 of the DIN EN 60445 (VDE 0197): 2011-10, the following is regulated: "In case bare conductors that are used as PE conductors are marked by colours, they must be green-yellow, either along the entire length of the conductor or in every part or every unit or every accessible point. If adhesive tape is used, then bicoloured tape must be used." Furthermore it states: "NOTE 3: In case the PE conductor is easily identifiable by is shape, its construction or its location, e.g. the concentric conductor, the colour marking over the entire length is not necessary, however, the ends or accessible points ought to be clearly marked by the graphic symbol or the bicolour combination green-yellow or the alpha-numeric identification PE." Based on these statements, the following recommendation can be derived: A marking of the conductors should be made at the connection points as well as at accessible points. The marking can consist of: The graphic symbol: The bicolour combination green-yellow in the form of a cable lug or shrink sleeve The alpha-numeric mark "PE" Page 12
6. Documentation of the system The following part describes a possible documentation of the meshed equipotential bonding system. It is only a recommendation and not mandatory for the system. The documentation can be done individually but should contain the following points: A comprehensive documentation is to be created. In addition to the fastening elements, the installation site must be recorded. The documentation must include a description of the type of the conductor cable used, including the cross-section used. The following symbols can be used: line symbol description function EMClots Grounding point (terminal, bolt, ) Grounding loop 16 mm 2 Symbol Connection below Connection right Connection above Function Grounding loop 16 mm 2 To differ functional and protective grounding it is recommended to use different colors. This could be implemented like described in the following part: Page 13
Connection line Connection symbol Description Function Grounding point (terminal, robot, ) Protective earth Grounding point (bolt, PROFINET-device ) Functional earth The following symbols should be used: Cross section Description and application symbol 6 mm 2 Functional grounding (FE) Additional functional grounding (robot) 10 mm 2 Protective grounding, robot axis 1 To connect switch or welding-control cabinets, to close a mesh 16 mm 2 To create a mesh or a grounding loop (CBN) Page 14
Example: Page 15
7. Instrumental examination An examination of the system needs to be carried out to certify the functionality. This test should be conducted at important points while the system is in operation. Basically two points are observed during the examination: Quality of the system Measurement during standstill (even before commissioning) is possible Load of the system Measurement must be made under conditions that closely simulate production At selected points, the peak values need to be monitored over a longer period Size of the mesh (impedance of the loop) Functionality of the shielding of the data and motor lines (impedance of the loop) Height of the currents on the PE and CBN conductors Height of the shield currents of the data and motor lines Quality values: To certify a sufficiently intermeshed equipotential bonding system, the following values need to be maintained for the loop impedance: Protective or functional equipotential bonding (CBN): max. 0.3 ohm (at 2.083 khz) To ensure a sufficiently active effect of the shields, the following values need to be maintained for shields: Motor cable shielding: Signal cable shielding: max. 0.3 ohm (at 2.083 khz) max. 0.6 ohm (at 2.083 khz) The load of the system can be determined by the current. Thus the following limits should be maintained: Protective conductor (PE): max. 5% of the phase current Protective- or functional-equipotential bonding (CBN): max. 300 ma (DGUV V3) To protect the devices against too much current, the following limits are recommended for the load of the shields: Motor cable shielding: Signal cable shielding: max. 300 ma max. 40 ma Page 16
Example evaluation of the readings: Type of cable impedance current Valuation Bonding network (Trunk) 0,43 Ω 550 ma Not OK Bonding network (Spur) 0,03 Ω 250 ma OK PROFIBUS-shield CPU 0,35 Ω 160 ma Not OK PROFIBUS-shield ET200 0,50 Ω 25 ma OK Measuring instruments: Application purpose Designation To determine the quality of the system (impedance at 2.083 khz) Loop impedance measuring clamp MWMZ II Indu-Sol GmbH To determine the load Simple current measurement Leakage current measuring clamp LSMZ I Indu-Sol GmbH To determine the load Intelligent current measurement To determine the load Intelligent current measurement on up to 4 channels Intelligent current measuring clamp ISMZ I Indu-Sol GmbH Permanent current analysis EMV-INspektor V2 Indu-Sol GmbH Page 17
8. Ordering specifications EMClots : Ordering specifications Trunk connection Spur connection Item no. EMClots Junction V2 10-16 mm 2 4-10 mm 2 122180100 EMClots Junction V2 25-35 mm 2 6-16 mm 2 122180101 EMClots Junction V2 3-fach 10-16 mm 2 4-10 mm 2 122180110 EMClots Junction V2 3-fach 25-35 mm 2 6-16 mm 2 122180111 EMClots Connector V2 10-16 mm 2-122180200 EMClots Connector V2 25-35 mm 2-122180201 EMClots Fastening V2 10-16 mm 2-122180300 EMClots Fastening V2 25-35 mm 2-122180301 Conductor cables: Ordering specifications Cross-section Diameter Insulation Item no. Multifrequency conductor 6 mm 2 4,5 mm bare 122040901 Multifrequency conductor 10 mm 2 5,5 mm bare 122040903 Multifrequency conductor 16 mm 2 7,0 mm bare 122040904 Conductor cable class 2 16 mm 2 5.1 mm bare 122040501 Conductor cable class 7 6 mm 2 3.9 mm bare 122040601 Conductor cable class 7 10 mm 2 5.1 mm bare 122040603 Conductor cable class 7 16 mm 2 6.3 mm bare 122040604 Conductor cable class 7 gn/ye 6 mm 2 6.0 mm PVC (gn/ye) 122040721 Conductor cable class 7 gn/ye 10 mm 2 7.3 mm PVC (gn/ye) 122040723 Conductor cable class 7 gn/ye 16 mm 2 8.8 mm PVC (gn/ye) 122040724 Conductor cable class 8 10 mm 2 8.0 mm PUR (gn/ye) 122041103 Attachments: Ordering specifications Cross-section Length Item no. Wire end splices Cu-tin-plated 10 mm 2 18 mm 122080177 Measurement instruments: Ordering specifications Item no. EMCheck LSMZ I 122010005 EMCheck MWMZ II 122010010 EMCheck ISMZ I 122010020 EMC-INspektor V2 122010001 EMCheck measuring clamp case 122010006 EMCheck measuring clamp case XL 122010007 Page 18