Emerson IP221 appendix Interface detection Attenuation method Figure, Reflection Method Figure

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1.2Interface detection Attenuation method – Figure 1.3

Attenuation is the reduction in strength of the ultrasonic signal caused by its transmission through a liquid. Viscous liquids, emulsions and liquids containing solid particles have a greater attenuation than clear thin liquids. Usually the difference in attenuation between the two liquids is sufficient and the attenuation method can be used to determine which liquid is in the sensor gap. In this case the gain of the control unit is set so that the relay is energised only when the liquid with the lower attenuation is in the gap. For this application Sensor Type 402S is used horizontally. The heavy-duty sensor type 433S may also be used, perhaps from above on an extension tube. For use in pipes, the sensor pair 442S should be mounted in line, facing one another, generally horizontally across the diameter, to detect the interface or presence of liquid. As an example, the interface between oil and water can be detected using this method.

OIL

 

Receiver Crystal

Transmitter Crystal

Sensor in Oil. The ultrasonic beam is

attenuated and will not reach the

receiver crystal.

Figure 1.3 - Attenuation Method

 

WATER

 

Receiver Crystal

Transmitter Crystal

Sensor in Water. The ultrasonic beam reaches the receiver crystal.

Reflection Method – Figure 1.4

If the attenuation’s are similar and the attenuation method does not work, then the reflection method must be used.

If an ultrasonic beam is transmitted from one liquid to another at a suitable angle, it does not go straight through the interface, but is bent, so that it does not reach the receiver crystal. If there is no interface in the gap, but only one liquid, then the beam travels in a straight line, is received and the relay energised.

For this application the sensor must be mounted at about 10º from the horizontal, as shown in Figure

1.4.Note that this method gives an alarm only when the reflective surface of the interface itself is at the sensor.

Oil

Water

Sensor in lower liquid. The ultrasonic beam reaches the receiver crystal.

Figure 1.4

Oil

Water

Receiver

Crystal

Transmitter

Sensor at interface level. The ultrasonic

Crystal

beam is reflected/refracted and will not

 

reach the receiver crystal.

In order to differentiate between two liquids, interface sensors have a large gap (usually 150mm) and oscillate at 3.75MHz.

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Contents Contents Safety Information IntroductionInstallation Fault Finding Specification and descriptionProtection of permanently installed equipment Explanation of symbolsGap sensors SensorsHi-Sens cylindrical sensors Interface detection Attenuation method Figure Reflection Method FigureHead Amplifier Units Solids Density DetectionNormal acting head amplifiers Ii Inverse acting head amplifiers Type Industrial Case MarineSensor State Output Control UnitsInstallation 2.1 Calibration Head amplifier internalsIi Gap Sensors Calibration procedure by sensor type Hi-Sens SensorsIii Interface Sensors Attenuation Method Iv Interface Sensors Reflection Method Sludge SensorSensor and head amplifier installation Adjacent head amplifier mounting detailsPage Control unit installation Wiring CableIii Control unit Ii Head Amplifier UnitRelay Ratings Control Unit Connections Certificates of Conformity Intrinsically safe installationII 1 G EExia IIC EN 50014 & EN Fault Finding Fault indicatedUnit not switching Relay contacts not changingSensor specification Head AmplifiersPower consumption Intrinsic safetyTemperature Range HousingStandard Control Unit Recommended Spare Parts 5.1 Sensor and head amplifierRack Mounted Unit Intrinsic Safety Mounting Sensor Type Test Switch Appendix I Part NumbersOptions Sensor ConnectionIntrinsic Safety Mounting Mains Voltage Output Relay RacksAppendix II List of illustrations Section Title Appendix III List of tables Section TitleMaintenance / Inspection Abcdef International Americas
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