Operating manual for centrifugal pumps AT - TB… - MC… - TC… - TMA
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All flushing systems MUST use tubing with diameters equal or larger than the connections provided on the pump, buffer
liquid must be compatible with the pumped product. Pressure on the buffer liquid should always be constant and/or high
enough to cover the entire pump performance.
In the case of ‘once through’ seal flushing (buffer liquid not recycled), it is very important the regulation and control of
pressure in the seal housing. In the double seal case it is recommended to adjust the buffer liquid pressure with a flow
regulating valve installed after the seal housing while reading pressure on a gauge installed between the seal housing
and the valve. Avoid controlling buffer liquid pressure before the seal housing, reading the pressure before the seal
housing is NOT recommended as it could lead to wrong conclusions which could be cause for serious damages. With an
adequate seal tank in the system (see fig. 33) a closed loop seal flushing, containing possible leakages is provided.
Adequate controls and/or instrumentation will provide pressure and liquid level controls in the tank to indicate the
conditions of the sealing system. Increase of liquid level (or pressure) is indication of product leaking through the pump
seal. Decrease of liquid level (or pressure) is indication of buffer liquid leaking inside the pump or to the atmosphere
through the outside seal, in which case the leakage is also visible.
The liquid to be used in the seal tank must offer full compatibility with the pumped liquid in the event the seal at pump
side will leak, (for example when the two liquids will mix there must not be any dangerous chemical reactions) as well the
liquid must offer good lubricating characteristics and good heat dissipation. Some good examples of suitable buffer liquids
are water, vaseline oils or vegetable oils.
Pressure in the seal tank is often kept with pressurised Ozone or Nitrogen bottle. Cooling of the buffer liquid in the loop
(picks up friction heat from the seal faces) is achieved with fresh liquid through the cooling coil fitted inside the seal tank.
Seal tank is provided with Inlet & Outlet connections for sealing liquid. DO NOT reverse these two connections; the liquid
circulates by natural heat convection (warm liquid moves upward and cold liquid downward), reversing the connections
would prevent the start of such natural phenomenon. The buffer liquid outlet connection going to pump seal housing is at
bottom of tank while the return connection is approximately at the middle of the tank.
Checking of proper liquid circulation is done while pump is in service; the piping at seal housing connection should be
colder by 3 to 5°C than the outlet tubing exiting the seal housing going to the tank. If this is not the case simply change
the tubing on the seal housing (connect tubing from inlet to the outlet and vice versa) do not change the connections on
the tank. Sometimes this adjustment is required because the rotation of the mechanical seal (and at times peculiar seal
design) generates an hydraulic pressure that could be opposite and higher than the natural. 0nly in ‘field’ check one can
be assured of the correct liquid circulation. Monitoring the pressure in the seal tank with pressure switches or pressure
gauges and/or controlling the liquid level in the tank allow the verification of possible seal leakages and prompt corrective
actions can be taken when required.
Use good quality gauges to monitor the pressure, with good dial and scale graduation adequate for good reading in the
anticipated pressure range. As a minimum use liquid filled gauges with dial size of minimum 60 mm and 2.5 accuracy.
Additional data and information may be requested from Pompetravaini or its local representative if required.
Incorrect pressure of seal housing could cause severe damage to the rotating parts. To minimise seal system
malfunctions avoid pressure fluctuations in the seal loop as well as in the pump operating pressure.
Seal housing with double mechanical seals back-to-back type,
must always have a pressure such that the inside seal (closer
to pump impeller) will not be pushed out of its seat by the total
pump pressure (suction plus pump operating pressures) even
when pump is in stand-by mode. Flushing liquid therefore must
be at least 0.5 bar over the maximum pump discharge pressure
throughout its performance.
A lower pressure, even if for a moment, will cause the
stationary part of internal seal to come out of its seat and the
pumped liquid will mix with the flushing liquid due to the higher
pressure inside the pump, see fig. 27.
In the case of double seals in series (Tandem) the pressure of
the flushing liquid should be as low as possible but high enough
to provide good flow in the circuit. High pressures (over 0.3 bar
over the atmospheric pressure) may push the stationary seat
of mechanical seal at product side (closer to pump impeller), out of its seat (especially when pump is at rest without
pressure), therefore flushing liquid would mix with the product inside the pump following seal system damage.
Incorrect pressure in sealing system is the most common cause for seal system failure, therefore a continued
monitoring with prompt corrective actions are necessary.
See fig. 20-21-22-23 for locations of liquid flushing connections. Required flow and pressure for buffer liquid are listed in
tab. 3 and/or contact Pompetravaini and/or seal supplier. See tab. 4 for liquid flow required to cool or heat the seal
housings. For a longer seal life cooling is recommended when pumping liquids over 90°C. Tab. 4 also lists cooling or
heating liquid flow for pumps of “U2” design that include jacketed pump casing.
Standard mechanical seals supplied with our pumps meet ISO 3069/UNI EN 12756 standards, see pump “Disassembly
and Assembly Instructions” for overall dimensions. Special or non-standard seals can be installed after proper evaluation
by our technical department. Mechanical seals do not require maintenance until losses of liquid are visible (for seal
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Fig. 27