Yokogawa ADMAG AXF User Manual

IM 01E20C01-01E

6-31

6. PARAMETER DESCRIPTION

Example: Situation where high limit is set to 90%

F0656.EPS

4mA

Output

Input

18.4mA(90%)

NOTE

If “21.6mA or more” has been set for G21:4-20
mA Alarm Out, 21.6mA or more will be output
upon an alarm occurrence, regardless of the
high limit setting.

[J20: Flow Direction] Setting of the flow direction
Upon shipment from the manufacturing plant, the
system is setup such that flow in the same direction, as
shown by the direction of the arrow mark on the
flowtube, will be measured as forward flow; however,
this parameter can be used to set “Reverse” so that
flow in the opposite direction to the arrow mark will be
treated as forward.
Note: This function does not apply to measurement in

both the forward and reverse directions, al-
though this can be setup using by selecting
“Fwd/Rev Ranges” from either F10: SO1
Function or

.

Setting

Function

Forward direction corresponds with arrow mark

Forward direction is opposite to arrow mark

Forward

Reverse

T0638.EPS

[J21: Rate Limit] Setting of the rate limit value
᭹ This parameter is used in situations where sudden

noise cannot be eliminated by increasing the
damping time constant.

᭹ In situations where step signals or sudden noise

signals caused by slurries or the like are entered, this
parameter is used to set the standard for determining
whether an input corresponds to a flow measurement
or noise. Specifically, this determination is made
using upper and lower rate limits and using the dead
time.

᭹ Rate limit values are set using a percentage of the

smallest range. The range of deviation per one
calculation cycle should be input.

[J22: Dead Time] Setting of dead time
This parameter sets the time for application of the rate
limit, and if a value of 0 is set, the rate limit function
will be terminated.

NOTE

Determining rate limit value and dead time

F0616.EPS

T

0

T

0

2%
2%

Rate limit value:
Determines the level for output
fluctuation cutoff. For example,
if this is set to 2%, noise above
2% will be eliminated as shown
in the diagram.

Dead time (T

0

):

This is to be determined using the
output fluctuation width. If noise
exceeds the dead time as shown in
the diagram below, the dead time
should be made longer.

᭹ Signal processing method:

A fixed upper and lower limit value is setup with

respect to the primary delay response value for the
flow rate value obtained during the previous sam-
pling, and if the currently sampled flow rate is
outside these limits, then the corresponding limit is
adopted as the current flow rate value. In addition, if
signals which breach the limits in the same direction
occur over multiple samples (i.e., within the dead
time), it is concluded that the corresponding signal is
a flow rate signal.

Example 1: Step input

F0617.EPS

10

%

1

%

Step signal

Flow rate value
after rate limit
processing

63.2

%

100

225

Dead time: 3 s

Input: 0 to 10%
Damping time constant: 3 s
Dead time: 3 s
Rate limit value: 1%

Number of signal samples

Flow rate value after
damping

(a)

(b)

(c)

(d)

(1) In comparison with the previous value at (a), it is

determined that the signal is in excess of the rate
limit value and the response becomes 1%. How-
ever, the actual output applies damping, and
therefore the output turns out to be as indicated by
the solid line.

(2) Subsequent flow values within the dead time zone

correspond to signals of post-damping flow value
+ rate limit value (1%).

(3) Since input signals do not return to within the rate

limit value during the dead time, it is determined at
(c) that this signal is a flow rate signal.