Heavy 4” 300# flanged rotameter not only gives wrong readings but also caused pipe weld cracks in the process plant.
Article Type: | Root Cause Analysis (RCA) |
Category: | Instrumentation |
Equipment Type: | Sensors |
Author: | S. Raghava Chari |
Note: This root cause analysis (RCA) is from real-time scenarios that happened in industries during the tenure of two or three decades ago. These articles will help you to improve your troubleshooting skills and knowledge.
Rotameter Information: Fig 1 shows a 4” flanged rotameter. The rotameter inlet bore tapers to a larger dia at the exit. Table 1 lists its data:
Table 1; Typical 4” Rotameter Data
h (mm) | MBR (mm) | Q (m3/H) | C – Q/h (ratio) |
500.00 | 100 | 2827 | 5.65 |
475.00 | 99.00 | 2671 | 5.62 |
356.25 | 94.26 | 1952 | 5.48 |
237.50 | 89.6 | 1279 | 5.38 |
118.75 | 84.75 | 615 | 5.18 |
0.00 | 80 | 0.00 | 0.00 |
Table 1 shows that the rotameter scale is nearly linear. The plunger pump delivered flow stream velocity varies instant to instant and hence the float assumes a position representing the instantaneous flow rates average depending upon the float’s mass and the flow stream viscosity.
Hence, rotameters read pulsating flows a lot more accurately than square root scale receivers connected to Differential Pressure Transmitters (DPTs) across orifice plates, because, the DPT measured
hav = (h1+h2+h3+ … hn)/n
where
h1, h2, and h3, are the instantaneous differential pressures across the orifice plate. The receiver’s square root scale square root scale reads the above shown √aaverage.
But the receiver must actually read √hc = (√h1+√h2+√h3+ … √hn)/n. These two averages may differ as much as 50% depending upon the type of machine delivering the pulsating flows and the orifice upstream pipelines’ and vessels’ volumes sum.
Electronic DPTs calibrated to output √h signals are also free from this error.
Problem: The carbomate pump suction pipe bolted body clamped pneumatic transmitter 4” 300# flanged SS rotameter though capable of reading the pump delivered flow roughly accurately, always read very wrong. The reasons are:
The Plunger pump delivered flow pulsations generally shake the connected piping way high; the rotameter upstream, downstream and the bypass 4”x300# heavy plug valves aggravated the pipeline’s vibrations much more.
Hence, the pipelines’ added welds for the rotameter and its bypass installation cracked and shutdown the plant often at enormous production loss
The author highlighted the worthless rotameter system posed plant shutdowns. Operations too tired of the plant shutdowns, which loaded them heavily besides lost production, reluctantly agreed the rotameter and bypass valves temporary removal, on the author agreeing to find better flow metering methods, Eventually, they forgot the flow measurement that served no purpose!
RCA solution benefits are:
Thanks to far higher on stream hours, far higher production and far reduced workload, the operation crew eventually did not ask for the no-use rotameter
Long after the rotameter removal, the author thought of an alternative for the rotameter: each of the carbomate pumps has Fig 2 RPM indicator: the Pulse to I converter powered a speed probe views the pump shaft key and sends electrical pulses/sec signal proportional to the pump RPM to the pulse to I convertor.
An I-P converter renders the pulse to the I convertor’s 4-20 mA output into 3-15 psi signals for the panel mounted ‘Speed Recording Controllers (SRC)’ which pull/push the hydraulic torque convertors’ internal vanes angle adjusting rod to vary the pump RPM.
The author could have easily added pump delivered m3/H graduations to the SRCs’ pump RPM scales in a different color as the plunger pumps’ delivered flow
Q = 3*N*S*0.25πd^2*l where
Symbol | Description |
Q | Pump delivered flow m3/min |
3 | Each pump’s Number of plungers |
N | Pump RPM |
d | Plunger dia m |
l | Stroke Length m |
The operation engineers forgot the flow measurement and the more pressing other work pressured the author too!
Author: S. Raghava Chari
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