Basic topics of mechanical seals.
Argesanu, Veronica ; Jula, Mihaela ; Laza, Ioan 等
1. INTRODUCTION
The constructive diversification of mechanical seals to a couple of
materials according to their destination, depends directly on the
allowed speed range, on the pressure inside the sealed space and on the
way in which the hydrostatic trimming of the two rings was made, and
finally, depends on the operating economic course of activity.
(Cristea;s.a. 1973, Mayer, 1977)
The complete adjustment of all the types of mechanical seals
implies additional anticorrosive and calorific protection of the elastic
pre-tensioned component, the cooling of the surfaces which are in
contact, and re-circularization and/or the evacuation of the discharge
flow.
All the functional and constructive conditions mentioned above have
lead to the generation of facility thermical seals, which, starting from
basic elements like rings, arches, that vary from a wide range that
covers various particular requirements.
2. CONSTRUCTION AND OPERATION
2.1 Construction
A mechanical seal is made, mainly, from the following components
(fig.1):
--A stationary ring (1) and a sliding one with a relative rotation
movement (2), one of these rings allowing the axial movement on the
shaft compensation of the wear.
--A system of reciprocal pressing system of the two
rings--represented in the figure by the cylindrical spring (3) and by
the seals represented by the two "o" rings immobile towards
the sheaf and the housing.
--The average dimension of the realized clearance h and the axial
force verso pressing force Fa, determine a certain pressure behavior
inside the clearance that has an influence on lubrication of the contact
surfaces, their durability and tightness.
--The compression of the sliding ring by the pressure depends on
the h rates between the pressurized surface, Ah, and the sliding surface
A, and finally on their mutual position.
[P.sub.a]/p = [A.sub.h]/A = k (1)
Taking in consideration the above proportion we can have the
following situations (fig 2):
[FIGURE 1 OMITTED]
[FIGURE 2 OMITTED]
2.2 Operation
--K>1, which means "unsteadily" or " fussy"
seals;
--K<=1, which means "uncharged" or "
balanced" seals;
--K=0; we have this situation when the contact compression is not
influenced by the environment pressure, being obtained only through the
force of the spring.
The unbalanced seals, having k>1, that is [p.sub.a] > p, have
a more pronounced wear of the sliding rings, but in the same time they
have a more stable operation, an experimental lower pressure in the
clearance.
According to the data, the losses through the no seals Q, are in
inverse proportion with the square of contact pressure p:
Q[p.sup.2] = const. (2)
2.3 Energy Consuption
The energy consumption process is taking place because of the
following dissipative sources:
a) Detention (discharge) of the fluid quantity contained inside of
the seal--this loose will be generally speaking, neglected.
b) The sliding friction between the mechanical sealed surfaces; it
is accepted that these loses can be formulated according to moment
[M.sub.fr] [mNm] and the relative angular speed [omega][rad/s], with the
help of the following ratio:
[P.sub.fr] = ([DELTA] [P.sub.fr]/[d.sub.[alpha]]) x d x w/100 =
[10.sup.-3] x [M.sub.fr] x w [w] (3)
The friction moment which appears at the mechanical seal represents
the amount between the moment of friction of the contact surface
[M.sub.a] and the moment due to the movement of the seal into the fluid
M[.sub.h].
[M.sub.a] = [pi] x [D.sup.2.sub.m] / 2 x b x [p.sub.a] x [mu] (4)
The moment [M.sub.a] is important; it has a bad influence on the
thermic charging of sealing and wear of the rings. The component
[M.sub.h] has a great importance at high speeds having a positive
influence, generally having a cooling effect.
[M.sub.a] = [pi] x [D.sup.2.sub.m] / 2 x b x [p.sub.a] x [mu] (5)
This last loss will be determinated in all the cases. The designer
has the opportunity that through the discharge effect to influence the
value of pa and therefore this loss. The contracted ring determines a
smaller loss, but is a disadvantage, by representing a greater danger of
braking. Estimating the losses through the non sealing we can have the
following situations:
a) the conditions of mixed friction in the annular tumble
[Q.sub.2] = [pi] x d x ([p.sub.1] [p.sub.2]) x [h.sub.2] x S/
[p.sup.2] (6)
S=interface factor
b) mixed friction conditions in the annular thimble
Q = [c.sub.2] x [pi] d x ([p.sub.1] - [p.sub.2]) x [eta] x [square
root of vb]/[p.sup.2] (7)
c) fluid friction conditions in the annular thimble
Q = [c.sub.3] x [pi] x d x ([p.sub.1] - [p.sub.2]) x [square root
of [eta]] b[v.sup.3]/[p.sup.3] (8)
The abstraction of the heat is made more often by the sealed
medium, excluding the vaporization process in the interstice. The
temperature arising inside the interstice is a consequence of the
heating produced through the friction, and may produce pronounced
detritions, the aerate of the lubricant film that will result in to a
that fast growing of friction coefficient and of detritions, in some
cases the exceeding of the integration temperature of materials, which
can lead as well to a thermic breaking of the rings, reciprocal slider
of thermal palling.
Taking in consideration all the condition mentioned above, we can
say that rings made of materials with a high thermal conductivity, may
have a better behavior in connection with the thermic aspects. The seals
used for high temperature have to be reared as much as possible, the
temperature from interface is being kept under the critical temperature
of vaporization, in order to prevent the appearance of dry friction,
anticipating, for example (fig.3) the construction with double
mechanical seals. In case the maximum temperature passes the sensitive
point of the elastomeric components of the seal, then we have to use
metallic water skins (fig.4), having the advantage of a small axial
gauge, higher capacities of loading and better flexibility
characteristics. (Aithani et al., 2006, Basu & Butler, 2008,
Kharitonov, 1973) Regarding the seals for a higher speed of the shafts
of the pumps compressors or turbines, the springs are fixed on the
armature or we use seals with an intermediate floating ring (fig 5).
Secondly, it becomes necessary to mix as less as possible the obdurate
liquid (a fluid oil with a pressure greater than that of the
exploitation medium) with the exploitation medium, a small energy
consumption at obturation (by a small consumption of obturator liquid)
as well as by the transference cross section of the obturator liquid in
the exploitation liquid. There have been found different solutions like
double seals, in whose intermediate space is coursing the obturator
liquid (fig 6).
[FIGURE 3 OMITTED]
[FIGURE 4 OMITTED]
[FIGURE 5 OMITTED]
[FIGURE 6 OMITTED]
This answer gives a higher safety against the attrition of inside
the fitting. The liquid obturator can be used (2), in the same time (1),
for cooling the seal. For a better washing result, the washing section
has to be as small as possible, in order that a sufficient speed to draw
the solid particles. A small opening of the inside can be obtained in
various ways : with carbon, bronze or PTFE rings. In the case of working
in environments with stringy suspension, the compression springs have to
be protected against blockage (fig.7). (Nagaralli et al., 1997; Mayer,
1961)
[FIGURE 7 OMITTED]
3. CONCLUSION
In conclusion, the particulars that appear in seal problems, the
constructive solutions, the right choosing of materials, as well as the
usage of special made accessories lead to the diversification of seals
types, taking in consideration the functional aspects as well as those
of safety in exploitation
4. REFERENCES
Aithani D.; Lockhart H.; Auras R. & Tanprasert K. (2006).
"Predicting the Strongest Peelable Seal for 'Easy-Open'
Packaging Applications", Journal of Plastic Film and Sheeting
Basu P. & Butler J. (2008). "Studies on the operation of
loop-seal in circulating fluidized bed boilers", Mechanical
Engineering Department, Dalhousie University, P.O. Box 1000, Halifax,
Nova Scotia, Canada
Cristea, V.; s.a. (1973). EtansariET, Bucuresti
Kharitonov V. (1977). "Mechanical seals for vessels with
agitators", Chemical and Petroleum Engineering
Mayer, E. (1961). Leakage and Friction of Mechanical Seals Paper
E3, England
Mayer, E. (1977). Mechanical Seals Newnes, Butterworths London,
Boston
Nagaralli R.; Ramakrishna A. & Varada Rajulu A. (1997).
"Physico-Mechanical Properties of Filled Polyethylene Films",
Journal of Plastic Film and Sheeting
