Owner manual

ManualsBrandsYokogawa ManualsSensorsEJX115A

<7. Operation>

7-3

IM 01C25K01-01E

IMPORTANT

• Remove the BT200 from the terminal box,

and conrm that none of the terminal screws

are loose.

• Close the terminal box cover and the

amplier cover. Screw each cover in tightly

until it will not turn further.

• There are two covers that must be locked

on the ATEX Flameproof type transmitters.

An Allen head bolts (shrouding bolts) are

provided under edge of the each cover for

locking. When a shrouding bolts are driven

counterclockwise by an Allen wrench, it

is coming out and locks up a cover. (See

section 8.4) After locking, the covers should

be conrmed not to be opened.

• Tighten the zero-adjustment cover mounting

screw to x the cover in position.

7.4 Shutting Down Operation

Shut down the transmitter operation as follows.

1) Turn off the power.

2) Close the stop valves on the up and

downstream sides.

NOTE

Whenever shutting down the transmitter for a

long period, remove any process fluid from the

transmitter pressure-detector section.

7.5 Transmitter Measurement

Range (Determining

Differential Pressure Range)

The following describes the procedure for

calculating the differential pressure range and the

calculation example in low ow measurement.

Conversion factor in pressure unit:

1 Pa = 1.01972×10

-1

mmH

2

O

1 mmH

2

O = 9.80665 Pa

1 atm = 1.01325×10

2

kPa

7.5.1 Determining the Differential

Pressure Range

Use the following procedures to determine a

differential pressure range according to the uid

conditions being measured.

(a) Calculate a water or air equivalent ow from the

ow of the uid being measured (100% ow).

 Equivalent Water Flow Calculation

Q

w

= 0.03162

.

Qf

.

ρf (1)

Where, Qw: Water equivalent volumetric ow

(m

3

/h) at 4°C, 1 atm

Qf: Volumetric liquid ow (m

3

/h)

at operating conditions (t°C, p kPa)

ρf: Specic liquid density (kg/m

3

)

at operating conditions (t°C, p kPa)

 Equivalent Air Flow Calculation

Q

o

= 0.5356

.

Qn ρn

.

.

(2)

273.15 + t

101.325+ p

Zf

Zn

Where, Qo: Air equivalent volumetric ow at 0°C,

1 atm (Nm

3

/h)

Qn: Volumetric gas ow at 0°C,

1 atm (Nm

3

/h)

ρn: Specic gas density at 0°C,

1 atm (kg/Nm

3

)

Zn: Compression factor of gas at 0°C,

1 atm

Zf: Compression factor of gas at

operations conditions (t°C, p kPa)

(b) Obtain a differential pressure from the

above equivalent water or air ow using the

nomograph shown in Figure 7.5.1 or 7.5.2. In

this procedure, multiply Qw or Qo by 1000/60 to

convert the ow unit into liter/min.

(c) Select an orice bore, taking into considerations

pressure loss, etc.

(d) As necessary, calculate Reynolds number at

normal ow rate and correct the differential

pressure obtained from the procedure (b).