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Ronan X90 Series User Manual

Page 4

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Time Delay Range: Integral: 0.5 to 20 seconds (10 or
20 seconds normal); jumper-selectable Remote: .05 to
20 seconds (10 or 20 seconds normal); jumper-
selectable

Display: Integral: LED status indicator Remote: LED
status indicator

Accuracy: Integral ± 1/8” Remote: ± 1/8”

All equipment approved by CSA.

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3.0 THEORY OF OPERATION


The Ronan Series X90 gamma switches provide an
alarm signal whenever the radiation field intensity at the
detector (G-M tube) changes by more than its
predetermined value. The variation in the field intensity
may be due to either a change in the level (at the limit),
or a change in the density of the process material in the
radiation beam path. In a typical arrangement, the X90
detects the level of liquid in a vessel when it has
exceeded a predetermined limit. The level limit is
defined by an imaginary straight line drawn from the
source to the detector.


















Figure 1:
Source and Detector

When the feed valve is open, liquid is fed into the vessel
and the liquid level rises. The liquid level will rise until it
interrupts the gamma ray beam. There is then a change
in the field intensity at the detector due to absorption by
the process of some of the energy present in the beam,
and the instrument puts out an alarm signal in the form
of a relay contact changeover. This signal may be used
to close the feed valve and/or activate an annunciator.
As the liquid is used from the vessel, the level will fall,
thus again exposing the detector to the gamma radiation
and the feed valve will be opened when the contacts
revert to normal.

This is an example of a high limit switch, i.e., the process
level is not allowed to rise above a certain limit.

Conversely, the source and the detector may be lowered
to below the liquid level and the system functions as a
low limit switch, in which case the system will produce an
alarm when the liquid level falls below this low limit. The
liquid itself may be under pressure at high temperature
or even corrosive, but its characteristics will not affect
the switch, since the system components are outside of
the vessel.

A time delay based on the measurement controls the
interval between radiation level change and alarm. A
hysteresis band about the required level prevents
fluttering and spurious alarm situations.

3.1 Optional Gaging Configurations

3.1.1 Model X90-1004 Remote Probe: The Ronan
Model X90-1004 Remote Probe (located on vessel)
with the X90-301(V) switch electronics may be
located in a general purpose or Division II location.
This is the most widely used configuration. The
X90-1004X is a high-sensitivity tube, which may be
specified for very weak fields (0.1 mR/hr. or less).

3.1.2 Model X90-1005 Integral Switch: The
Ronan Model X90-1005 Integral Switch in a Model
X90-1001XP housing is usually specified when the
X90-301(V) switch electronics cannot be located in
a general purpose or Division II area. It may be
used when the vessel is easily accessible for
calibration and maintenance.

The Model X90-1005 contains the G-M tube sensor
and switch electronics on a single chassis and is
mounted on or just off the vessel wall.

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4.0 FUNCTIONAL OPTIONS

4.1 High-Limit Process Alarm

The Process alarm relay will change over when the
level of process material rises above the set limit.


4.2 Low-Limit Process Alarm

The process alarm relay will change over when the
process level falls below the set limit.


4.3 Failure Alarm

In the case of the high-limit switch, under normal
conditions the G-M tube receives full radiation and
produces an output. This output will fall, producing
an alarm when either the radiation is interrupted by
the process level rising to above the set limit or the
G-M tube or its power supply fails. However, if the
tube or power supply fails, a failure alarm will be
actuated, indicating the problem is in the unit. If