Numerical set point adjustment – Fluid Components International FLT Series Rack Mount User Manual

Doc. No. 06EN003250 Rev. N/C

3 - 3

FLT



Series FlexSwitch



Rack Mount

CHAPTER 3 - OPERATION

FLUID COMPONENTS INTL

Numerical Adjustment versus Adjustment by Observation

A set point is established using either numerical or empirical adjustment. The empirical adjustment requires the
customer to establish normal process operation and adjust the set point relative to this condition. The numerical
approach requires measuring normal and alarm process conditions with a voltmeter and setting up the instrument in
the calibrate mode based on these values. The empirical adjustment requires little time and one tool to establish the
set point. The numerical adjustment requires control of the process as well as additional time and tools to establish
the set point. Refer to Table 3-7 to determine which method is more appropriate for the application requirements.

Table 3-7. Numerical versus Observation Factors

Numerical Set Point Adjustment

The control circuit has two mutually exclusive alarms for each channel; they are identified as Alarm 1 and Alarm 2.
Each has a set point adjustment potentiometer and a LED indicator. Both alarms can be setup for one of three
applications: flow, level/interface, or temperature. The following application specific adjustment procedures are
generic and can be used for setting either or both alarms on each channel. Channel A will be used to explain the
setup procedures. The procedures to setup Channel B are the same steps except for the component designations.
Refer to Tables 3-1 through 3-6 and Figures 3-1 and 3-2.

Table 3-2A. Selectable Heater Wattage Control

Jumper CH A

J7

J6

J5*

J3*

J4

Jumper CH B

J33

J32

J31*

J29*

J30

FLT93-F Element
(560 Ohm Heater)

0.57

Watts

0.52

Watts

0.49

Watts

0.20

Watts

OFF

FLT93-S Element
(110 Ohm Heater)

3

Watts

1.75

Watts

0.75

Watts

0.27

Watts

OFF

Conditions

Channel A
Alarm 1
Red LED

Channel A
Alarm 2
Green LED

Flow/Level

Switch

Temp. Switch

De-energized At
No Flow Or Dry

De-energized When
Above Temperature

J22

J20

De-energized At
Flow Or Wet

De-energized When
Below Temperature

J21

J19

Table 3-4. CH A Alarm Condition

*J5 and J31are standard for FLT93-S and
J3 and J29 are standard for FLT93-F.

Table 3-2B. Fixed Heater Wattage Control

Jumper CH A

J5

J3

J4

Jumper CH B

J31

J29

J30

FLT93-F Element
(560 Ohm Heater)

Not

Applicable

0.20

Watts

OFF

FLT93-S Element
(110 Ohm Heater)

0.75

Watts

Not

Applicable

OFF

Table 3-3. Application

Flow/Level

Temp.

Channel A, Alarm 1

J14

J16

Channel A, Alarm 2

J13

J15

Channel B, Alarm 1

J40

J42

Channel B, Alarm 2

J39

J41

Table 3-5. CH B Alarm Condition

Table 3-6. Relay Contact Configuration

Channel

A

1 Alarm

J17

Alarm 2 Disabled

2 Alarms

J18

Channel

B

1 Alarm

J43

Alarm 2 Disabled

2 Alarms

J44

Numerical Adjustment

Observation Adjustment

Tools Needed

One small flat blade screwdriver. One DC
voltmeter (digital preferred) capable of
resolving to 0.001 volts on a 20 volt range.

One small flat blade screwdriver.

Estimated

Time

Required

The time required to establish the normal and
alarm process conditions, plus ten to twenty
minutes to make instrument adjustments.

The time required to establish the normal
process condition, plus five to ten
minutes to make instrument adjustments.

Conditions

Channel B
Alarm 1
Red LED

Channel B
Alarm 2
Green LED

Flow/Level

Switch

Temp. Switch

De-energized At
No Flow Or Dry

De-energized When
Above Temperature

J48

J46

De-energized At
Flow Or Wet

De-energized When
Below Temperature

J47

J45