Protection systems of the titlting mechanisms at the rolling trains.
Miklos, Imre Zsolt ; Alic, Carmen Inge ; Miklos, Cristina Carmen 等
1. INTRODUCTION
This paper presents the study of the hook tilting mechanism from
the Blooming 1000's rolling train. To this mechanism, due to a
wrong operation, it could happen that, on one side, when the hooks are
going down, they jab into the bloom, and on the other side, when the
hooks are going up, they can hang in the roller table. This can damage
the component elements by producing additional loads. In case of the
tilting mechanism from Blooming 1000, the main connecting rod is fitted
with a minimum resistance section, by two safety bolts, which break-up
when additional loads appear. The connecting rod's cross-section is
presented in fig.1 (***, 2003). The tilting mechanism's protection
by safety bolts is convenient at first sight, only that it presents some
disadvantages. Thus, in the moment of bolt's break, due to
accidental additional loads, the rolling process should be interrupted,
whilst the broken bolt is removed and replaced with a new one. This
operation is difficult, due to the difficult access to the section with
bolts.
The above presented issues have been previously studied, and to
solve them, there were proposed several technical solutions. To design
this, is necessary to know the force value from the tilting
mechanism's connecting rod. The blooms' tilting mechanism
works with shocks and, therefore, the efforts condition from its
elements can be only determined when the dynamic coefficient is known
very well. To have a real situation, the experimental method is accepted
(with tensometer stamps).
[FIGURE 1 OMITTED]
After measurements, is obtained the maximum force values from the
mechanism's connecting rod in the following conditions: idle run,
loaded run, and bolts' break (Zamfir & Elczner, 1982).
Unfortunately, these studies were not completed.
The authors have continued these studies by research, design and
execution of an automatic power limit bolt with tapered blocking bodies;
also they have made experimental tests in operating conditions. The
results are satisfactory, following further to be implemented on the
tilting mechanism.
2. DESCRIPTION AND WORKING OF THE AUTOMATIC POWER LIMIT BOLT
The schematic of the automatic power limit bolt, with tapered
blocking bodies, is presented in fig. 2. The pressing force Q from the
compression spring (4) is calibrated depending on the maximum regime
force from the connecting rod. When force F from the connecting rod
exceeds a certain pre-value, the blocking bodies (3) will be pushed
outside the transversal seats, compressing the springs until their
release from the two tapered bores. After additional load is ended, the
compression springs will push back the blocking bodies into the
connecting rod's tapered bores. Thus, the connecting rod's
mid-section of the is displaced by the exterior one, allowing the
effort's end, making the automatic power limit bolt to enter the
next kinematical cycle.
Taking into account that the connecting rod's critical force
(the spring's pressing force) is very big and because the
spring's space is limited (for a little deformation), is
recommended to use compression ring springs, which satisfy the
conditions below.
3. CALCULATION AND DESIGN OF THE AUTOMATIC POWER LIMIT BOLT
For the automatic power limit bolt, is noted by F the force from
the connecting rod when the bolt is breaking up, and the bolt's
load diagram is presented in fig. 3. On each blocking body will act half
of the critical force, F/2. The blocking body's load diagram is
presented in fig. 4.
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
[FIGURE 4 OMITTED]
By notations from fig. 3 between the distributed force F/2 and
force P which pushes the blocking body into the tapered bore, the
following relation can be written (Miklos, 2005):
P = F/4 x (sin[alpha] + [mu] x cos[alpha]) (1)
Forces which act on the blocking bodies (fig. 4) will be: P,
respectively [mu]P, spring's pressing force Q and [N.sub.1],
[N.sub.2] (the slide-way reactions) respectively [F.sub.1] and [F.sub.2]
the friction forces in the slide-way. From the forces' balance
condition, results the relation of the force P depending on Q and the
geometrical measures of the tapered blocking body.
P = Q/[cos[alpha]] - [mu] x sin[alpha](1 + 2xb/1 - [mu]xa/1)] (2)
From the relations (1) and (2) is determined the spring's
pressing force value, Q:
Q = F x [cos[alpha] - [mu] x (1+2xb/1 - [mu]xa/1) x sin
[alpha]]/4(sin[alpha]+[mu]xcos[alpha]) (3)
Next, the problem is to choose the optimal value of a angle of the
bolt's tapered body, respectively to determinate the limit value to
avoid the stuck phenomenon in the connecting rod's tapered bore, in
working conditions. The sticking of the blocking body into the
connecting rod's tapered bore is produced when the denominator from
relation (2) is null, respectively force P tends to infinite. Taking
into account these specifications and the fact that [alpha] angle
can't have negative values, the range where a angle can take values
is:
0 < [alpha] < arctg 1/[mu]x(1+2xb/1 - [mu]xa/1) (4)
The relations (1)-(4) were solved by a computing program, which
allows to know the maximum values of [alpha] angle, [[alpha].sub.max],
where appear the stuck of the blocking body into the connecting rod and
spring's pressing force Q, for different values of friction
coefficient [mu] (different pairs of materials), respectively the
geometrical measures of the tapered blocking body.
Keeping constant the geometric measures, for different values of
the friction coefficient between the tapered blocking body's
material and the connecting rod's material are obtained different
limit values for the blocking body's angle.
[FIGURE 5 OMITTED]
For the analyzed tilting mechanism's real case, admitting
[mu]=0.15, will result the maximum angle where appears the sticking
danger: [[alpha].sub.max] = 78.68 [degree] (Miklos, 2001).
4. EXPERIMENTAL TRIALS
Because the main connecting rod of the tilting mechanism has a big
length (2480 mm), for the experimental trials it was considered just a
portion from connecting rod, respectively the portion on which is
assembled the automatic power limit bolt.
The experimental trial on the automatic power limit bolt with
tapered blocking bodies was performed on the universal machine of
tensile and pressure tests, (Miklos, 2001) the trial diagram being
presented in fig.5.
From the experimental trials results that the bolt is broken at
values between 50200 and 50750daN of the connecting rod's force, to
the calculated (53010daN) (Zamfir & Miklos, 1999).
5. CONCLUSION
Further the above research can be concluded that the presented
protection system runs properly in real operation conditions and is
proposed to be located on the tilting real mechanism from the Blooming
1000 rolling train. As future research, is foreseen to adapt this
protection system also to other similar mechanisms from steel industry.
6. REFERENCES
Miklos, I. ZS. (2001). Contributions to improve the technological
performances of the bloom tilting mechanisms at the rolling trains,
Doctorate Thesis, University from Petrosani, 2001
Miklos, I. ZS. (2005). Mechanisms. Mechanisms analysis,
"Mirton" Publishing House, ISBN 973-661-743-2, Timisoara
Zamfir, V.; Elczner, G. (1982). Kinematic and dynamic analysis of
the blooming 1000's hook tilting mechanism, Research contract no.
270/1982, Hunedoara, 1982
Zamfir, V.; Miklos, I. Zs. (1999). The kinetostatic analysis of the
tilting mechanism at the 1000 mm rolling train. UPT's Scientific
Bulletin, Vol. 44(58), Fascicle 2, Page 275 - 282, ISSN--1224-6077
*** (2003) Technological instructions for the Blooming 1300 and
1000 mm rolling trains, Vol. II, Arcelor Mittal Hunedoara, Plant
no.4--Rolling Mills, Hunedoara, 2003
