Virtual reference

Electromagnetic flowmeters featuring virtual reference offer an innovative grounding method that allows the flow sensor to be installed in any pipe, without grounding rings or grounding electrodes.

Like all electrical equipment, electromagnetic flowmeters (EMF) must be grounded in accordance with safety regulations, e.g. protective grounding or potential equalization. Firstly, EMF grounding ensures protection against contact and prevents electric shock. Hence in the event of an error there is no hazardous voltage to the conductive parts of the device. Secondly, grounding provides a fixed reference potential to the EMF signal voltage.

This EMF signal voltage is typically about a millivolt or less. The converter can only process such small signals without interference and with maximum resolution provided there is not a great difference between the potential (the voltage) of the medium and the reference potential of the signal processing in the converter. There are several methods to ensure this. In addition to the three classical methods of grounding – grounding via a blank metal pipe, grounding via grounding rings in electrically non conducting pipelines and grounding via grounding electrodes – there is the method of virtual reference, which is done without separate grounding of the medium.

The alternative to classical grounding

Diagram of classical and virtual grounding

In certain applications, the conventional grounding methods of EMFs pose problems, e.g. in lines with cathodic corrosion protection or in galvanisation plants voltage is also present between the electrodes and the earth. When using aggressive media in the application, the grounding rings for conventional grounding must usually be manufactured from expensive special material (Tantalum, Titanium, Nickel, etc.) which amounts to extremely high costs when dealing with large pipe sizes.

With the virtual reference, the EMF sensor can be installed in any type of pipeline without grounding rings or electrodes. The converter's input amplifier records the potentials of the measuring electrodes and a sophisticated method is used to create a voltage which corresponds to the potential of the ungrounded liquid. This voltage is used as the reference potential for signal processing. Thus, there are no interfering potential differences between the reference potential and the voltage on the measurement electrodes.

Cost and safety benefits

OPTIFLUX 4300 with virtual reference in a chemical plant

The elimination of grounding rings and the simpler installation of the EMFs results in lower costs and help operators reduce systematic failures as faulty grounding is the most common cause of error when commissioning an EMF. There is no risk of electrolytic destruction when there are potential differences in the system. No stray currents flow over the product or grounding lines.

The virtual reference is basically possible from a diameter (nominal width) of DN10 (3/8”) and from a conductivity of ≥ 200 µS/cm. KROHNE invented this method for the virtual referencing of EMFs back in 1998.

Benefits of KROHNE virtual reference

化学用途および最高精度要求向け高性能電磁流量計 — Virtual grounding is very cost-effective when using EMFs with larger diameters

Significantly lower investment costs
- No grounding rings or grounding electrodes required

Increased safety by reducing the number of potential leakage points
- No grounding rings with additional sealing points or grounding electrodes as potential leakage points
- No risk of electrolytic destruction when there are potential differences in the system
No equalising currents
- Reference potential is generated in signal converter and is insulated against earth: No current runs through the pipeline, the process liquid or the earth
- No equalising current in electrolysis or galvanic systems and no stress on the cathodic protection
Simplified installation, engineering & maintenance
- Reduces the risk of wrong installation of grounding rings and gaskets as one of the most common reasons for faulty installations, especially in case of large diameters
- Reduced installation time
- Right selection of grounding ring material no longer necessary
- No chemical compatibility issues
Compatible with Custody Transfer applications: OIML-R49 and MID MI-001 certified

関連製品

機械 & 装置用途、定量供給システム、コンパクトスキッド向け電磁流量計

導電率5 μS/cm以上、固形分含有率70% 以下の液体の流量測定に対応した高コストパフォーマンスモデル
-25…+120°c / -13…+248°f
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3 x 4…20 mA, HART^®, Modbus, FF, Profibus-PA/DP, PROFINET

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3 x 4…20 mA, HART^®,Modbus, FF, Profibus-PA/DP, PROFINET

OPTIFLUX 4400 C - PFAライ二ング、KROHNE電磁流量計コンパクト仕様

安全計装システム（SIS）、高度なプロセス用途および現場での無線検証向け電磁流量計

部分プルーフテスト（自動化）に対応し、SIL アプリケーションでのプルーフテスト間隔を延長
MPO（Multi Phase Operation）：巻込みガスや固形物を伴うような大きなプロセス擾乱下でも、測定を継続し、安定した再現性のある測定値を実現
Bluetooth^® によるパラメータ設定、モニタリング、現場検証
フランジ口径: DN2.5...3000 / ⅒...120"、最大PN40 / ASME Cl 600 (要望に応じて上限設定可能)
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認証：OIML R117、MI-005等
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3 x 4...20 mA、HART^®、Modbus、FF、Profibus-PA/DP、PROFINET

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高精度(±0.2%)、食品分野での高精度な計量配合添加プロセスに最適
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各種衛生規格プロセス接続
3 x 4…20 mA、HART^®、Modbus、FF、Profibus-PA/DP、PROFINET