Kenco Engineering SmartSonic Transmitter (Remote) User Manual

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GENERAL DESCRIPTION
The SmartSonic Acoustic Wave Transmitter is designed for high accuracy level measurement of a variety of liquids. The
SmartSonic Integral can also be used for Open Channel Flow Measurement.

PRINCIPLE OF OPERATION

MODEL DESCRIPTION

P50-L35V-6N8AE - Remote Transmitter

KAWT-xx – Remote Cable (xx = Length in Feet)

PN5-XGB-1-C – 1” NPT Polypropylene Transducer

ACC-I – Remote Cable Connector

PN5-XGD-1-C – 1” NPT PVDF (Kynar) Transducer

SPECIFICATIONS

INSTALLATION
Unpack the transmitter carefully. Inspect all units for damage. Report any damage to carrier immediately. Check the
contents against the packing slip and purchase order. Kenco’s SmartSonic Acoustic Wave Transmitters are
manufactured to the highest quality standards. These instruments use electronic components that can be damaged by
static electricity. Make sure that you are properly grounded before starting installation. Insure that all electrical
connections are properly made, and that there are no “floating” connections.

Description

Specification

Power Supply

100-230 Vac

Maximum Range

39.4 feet

Minimum Dead Zone

1.3 feet

Maximum Span

38.1 feet

Frequency

50 kHz

Analog

4-20mA

Digital

RS-422

Output
Signal

Discrete

(5) SPDT Relays

AC

2A @ 220Vac

Relay
Ratings

DC

2A @ 30Vdc

Display

Graphical LCD

User
Interface

Keypad

4 Button

Wave Angle

5º @ 3db

Mounting Connection

1” NPT

Ambient

-40ºF to 140ºF

Temperature
Range

Process

-40ºF to 212ºF

Accuracy

±0.2% of max. range

Resolution

0.04” (1 mm)

Enclosure Material

ABS + UV

Transducer Housing Material

Polypropylene or PVDF

Transducer Material

Glass Reinforced Epoxy

Cable Length

328ft. (std.); 656ft. (opt.)

Electronics

2.4 lbs

Weight

Sensor

1.1 lbs.

The SmartSonic Transmitters consist of two main components:

•

The Electronics

•

The Sensor (Transducer)

The transducer contains a piezoelectric crystal that converts an electrical signal
from the electronics, into acoustic (sound) waves. These acoustic waves are
directed through the air toward the process media surface. They are then
reflected off of this surface and returned to the transducer. The piezoelectric
crystal then converts the received waves into an electrical signal which is
analyzed by the electronics.

The time difference between the transmitted wave and the received wave is
proportional to the distance from the face of the transducer to the process media
surface. This distance is used by the electronics to calculate level or open
channel flow in the units selected by the operator.

Process

Media

Air

Acoustic

Waves