RU2410171C1 - Procedure for calibration of duplicating skewed gauges - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: procedure consists in preliminary shift of open and closed grooves by means of open flange of foot thinning at value increasing in course of rolling with change of gauges. Reduction of time for profile set-up and upgraded accuracy of gauge set-up with consideration of intensity of operation in preceding gauges are achieved like follows: a value of groove shifting in each following finish doubled gauge during rolling is determined with consideration of rolling process in gauges preceding the finish one in accordance with expression considering relation of values of grooves shifting at rollers boring in k- finish doubling gauge and in preceding k-gauge; number of doubling gauges in rollers, summary value of collar wear, value of the most intense shift of grooves during cones running-in at the beginning of the first gauge operation, and also coefficient considering influence of rolling process in gauges preceding the finish gauge.

EFFECT: improved treatment of surface of rail profile head rolling, improved symmetry of rail, increased efficiency at rail rolling implementing support cones.

3 dwg

Description

The invention relates to metallurgy and can be used in the calibration and subsequent rolling of railway rails or other similar profiles using support cones.

Duplicate gauges are known [1], for example, in the finishing stand of the duo, in which high quality rails are obtained in all respects by preliminary shifting the streams when boring gauges in the rolls to compensate for the wear of the cones when switching from one caliber to another, thereby improving the design of the profile when rolling. The magnitude of the shift of the streams in the direction of sinking of the open flange of the sole, depending on the sequence of the caliber, is determined by the dependence

where k is the serial number of the caliber;

a is the total amount of wear of the shoulders;

n is the number of duplicate calibers in the rolls.

The disadvantages of duplicate calibers with a defined value of the shift of streams towards the sunken open flange of the sole, depending on the order of work of the caliber according to the above dependence, include the following:

1. The total wear of the working cones is determined without taking into account the magnitude of the most intensive shear of the streams during running-in of the cones at the beginning of the first caliber, which subsequently affects the symmetrical configuration of the profile not only in the first caliber, but also in the subsequent ones. This reduces roll resistance and productivity.

Duplicate rail gauges are also known [2], in which, in order to improve the design of the head and reduce the total asymmetry range of the rail profile, the shift values of the gauge streams depending on the order of their operation are determined when the rolls are bored according to the dependence taking into account the running-in of the support cones of the first caliber:

where X _k is the magnitude of the shear of the streams when bore rolls;

k is the serial number of the caliber;

a is the total amount of wear of the shoulders;

n is the number of duplicate calibers in the rolls;

m is the value of the most intense shear of streams during running-in of cones at the beginning of the first caliber.

The disadvantages of the duplicate calibers of the finishing stand, made with the shift of the streams, calculated according to this dependence, include the lack of consideration of the influence of the production of elements of the finishing gauge. The closest in their technical essence and the achieved results to the proposed invention are duplicate calibers, taking into account the running-in of support cones when working on the first caliber [2].

The problem to which this invention is directed is to improve the quality of rails in the design of the head rolling surface and its symmetry, as well as to increase the productivity of the mill by reducing the time to set up the profile.

The technical result is achieved by the fact that the shift of the duplicate rail gauges of the finishing stand for rolling rails of type P65, made in the form of a series of calibers placed along the length of the barrel rolls with preliminary displacement (shift) of open and closed streams due to thinning of the open sole flange increasing along the shift gauges the value of open and closed streams, is determined taking into account the rolling technology in calibers preceding the finishing, in accordance with the expression:

where X _k is the value of the shear of the streams when boring the rolls in the k-th finishing gauge;

X _k-1 - the magnitude of the shear of the streams when boring the rolls in the previous k-th finishing duplicate caliber;

k is the serial number of the caliber in the finishing stand;

n is the number of duplicate finishing calibers in the rolls of the finishing stand;

a is the total amount of wear of the shoulders;

m is the magnitude of the most intense shear of streams during running-in of cones at the beginning of the first finishing gauge;

, при этом t₁=0,8, t₂=1,3, t₃=0,9, где k=1, 2, 3 соответственно.t _k - coefficient taking into account the influence of rolling technology in calibers preceding the final k-th caliber, subject to the conditions

while t ₁ = 0.8, t ₂ = 1.3, t ₃ = 0.9, where k = 1, 2, 3, respectively.

A comparative analysis of the proposed technical solution with the prototype shows that the proposed duplicate gauges more rationally distribute the wear of the working cones in the rolls with these calibers and take into account the rolling technology in calibers preceding the finish (the actual wear of the calibers and working cones in the pre-finishing and previous calibers). This indicates the conformity of the proposed technical solution to the criteria of the invention of "novelty."

In the study of other well-known technical solutions in this technical field, signs that distinguish the claimed solution from the prototype were not identified, therefore, they provide the technical solution with the criterion of "inventive step".

Figure 1 shows the installation drawing of the mill "850" and the duplicate gauges of the finishing mill "800-II", the arrows "P" indicate the direction of axial forces that occur during rolling in the finishing gauge. The sequence of transitions from one backup gauge to another during rolling of P65 type rail rails is shown.

Figure 2 shows the construction of the final caliber. The position of the caliber streams without displacement is shown by a solid thick line. The dotted line shows the shift of streams by the value of "X _k ", determined by the above dependence.

Thin solid lines show the oscillation of the symmetry of the rolling surface of the rail head relative to the straight line MM during gauge operation. The deviation from the symmetrical position ranges from the value (-e) to the value (+ e) for the total range of oscillation (L).

Figure 3 graphically presents the results of the calculation to determine the shift of the streams when working on each finishing gauge according to the prototype and the proposed option.

A specific example of the proposed duplicate finishing stand calibers was implemented in the NKMK rail and beam shop during rolling of railway gauges of the wide gauge type P65.

For clarity, the advantages of the proposed duplicate calibers compared to the prototype, we consider them together when used in the conditions of the rail and beam shop of OJSC "NKMK". P65 rails are rolled using three backup gauges located on the finishing stand of 850 duo and two backup calibers on the finishing stand of the 800-II trio. In this case, the rolling of rails of type P65 is carried out in the following sequence of operation of duplicate calibers.

1. The 1st and 2nd duplicate calibers of the finishing stand of 850 duo work with the 1st pre-finishing duplicate caliber of the stand of the 800-II trio. When switching to the 2nd duplicate caliber of the stand of 850 duo, the transition to the 2nd duplicate caliber of the finishing stand of the 800-II trio is not carried out.

2. A simultaneous transition is performed on both stands in duplicate calibers: duo 850 and trio 800-II (transition to the 3rd backup caliber of the stand "850" and the 2nd backup caliber of the stand "800-II").

From the above rolling technology, it follows that the working conditions in the finishing duplicate calibers of the 850 duo stand are different. This scheme of operation of duplicate calibers in the finishing and finishing stands is determined by the arrangement of the mill equipment, the length of the roll barrels, the calibration features, as well as a number of technological features of the existing rolling technology in order to ensure the optimum ratio of mill use by reducing the time for transshipment of the rolling rolls and the maximum possible productivity at achievement of the required quality to rails like P65. Usually, 1200 tons of metal are currently rolled on one finishing rail gauge, so the total volume of metal rolled in the rolls of the finishing and finishing stands is ≈3600 tons. In order to achieve improved design of the rolling surface of the head and rail as a whole in all finishing duplicates gauges when working on a specific duplicate gauge of the finishing stand, take into account the wear of the caliber and working cones in the previous pre-finishing gauge. This is done by entering into the calculation formula the magnitude of the shear of the streams when boring the finishing calibers of the coefficient t _k , which has its own empirically determined value for each finishing caliber.

The absence of the influence of taking into account the rolling technology in calibers preceding the finish leads to uneven wear of the working cones and accordingly increases the deviation from the symmetry of the rail, the geometric design of the profile head worsens, which also negatively affects the straightening of the rails on the roller straightening machine.

In order to show the advantages of the proposed duplicate calibers over the prototype, we will carry out their joint calculation with the same initial data.

1. The number of calibers is three, i.e. n = 3 and, accordingly, for the first caliber k = 1, for the second k = 2 and for the third k = 3.

2. The total value of the wear of the cones according to the average research data for the total volume of metal rolling on a set of rolls equal to ≈3600 tons, we take equal to 2.4 mm.

3. The value of the most intense shear of the streams during rolling during running-in of the support cones at the beginning of the first caliber m is taken to be 0.3 mm (m = 0.3 mm).

The calculation of the magnitude of the shift of streams in calibers according to the prototype is carried out according to the formula (2):

The value of the position of one stream relative to another in the head area after the shift of the streams during running-in of the cones at the beginning of the first caliber e is defined as X ₁ -m = 0.65-0.3 = 0.35 mm

(the fluctuation range e varies X ₁ -m = 0.65-0.3, from -0.35 to 0.35 mm),

(the oscillation range e varies (X ₂ -X ₁ ) / 2 = (1.35-0.65) / 2, from -0.35 to 0.35 mm),

(the oscillation range e varies (X ₃ -X ₂ ) / 2 = (2.05-1.35) / 2, from -0.35 to 0.35 mm).

The counting results are graphically presented in figure 3, a. Here, with respect to the MM line, conditionally reflecting the symmetrical rolling surface of the rail head, the rolling position oscillation of one stream relative to another in the head region from -e to + e is shown during rolling, where the -e value is defined as the shift of the stream in the first gauge (X ₁ ) minus the magnitude of the most intense shear of streams during running-in of cones at the beginning of the first caliber (m).

The magnitude of the shift of the streams in the proposed duplicate calibers is made taking into account the coefficient t _k , taking into account the influence of the rolling technology in the finishing caliber, which precedes the kth finishing.

The choice of a certain value of the coefficient t _k is due to the features of the rolling technology, the higher the coefficient, the more intense the work of the finishing duplicate caliber, due to the development in calibers preceding the finishing caliber, and accordingly the greater the range of fluctuations of deviations from the rail symmetry.

1 backup gauge

In the 1st gauge, the coefficient t _k , taking into account the influence of rolling technology in the gauge preceding the finish gauge, is 0.8, since rolling starts with new or repaired gauges and the effect of rolling technology in the finishing gauge on the finishing gauge is practically not manifested.

2 backup gauge

In the 2nd gauge, the coefficient t _k , taking into account the influence of the rolling technology in the gauge preceding the finishing gauge, is 1.3, since rolling is performed on the previously working pre-duplicating gauge and previous rough gauges, respectively, in this finishing gauge the most intensive wear of the support cones is carried out at the work of the finishing stand kit "850".

3 backup gauge

In the 3rd gauge, the coefficient t _k , taking into account the influence of the rolling technology in calibers preceding the finishing, is 0.9, since rolling is carried out on a new finishing and finishing duplicate calibers, but with draft calibers worked, therefore the coefficient is slightly higher than when working on 1st duplicate caliber finishing stand "850".

Calculation of the shift of streams in calibers is carried out according to the formula (3):

(the oscillation range e varies X ₁ -m = 0.54-0.3, from -0.24 to 0.24 mm),

(the oscillation range of e varies (X ₂ -X ₁ ) / 2 = (1.48-0.54) / 2, from -0.47 to 0.47 mm),

(the oscillation range e varies (X ₃ -X ₂ ) / 2 = (2.1-1.48) / 2, from -0.31 to 0.31 mm),

, t₁+t₂=t₃=0,8+1,3+0,9=3.Where

, t ₁ + t ₂ = t ₃ = 0.8 + 1.3 + 0.9 = 3.

Figure 3, b graphically shows the results of the calculation of the shift of the streams of fine calibers, taking into account the coefficient t _k , taking into account the influence of rolling technology in the finishing gauge, which precedes the k-th finishing.

Analyzing and comparing the results shown in figure 3, a and 3, b, the results of the prototype and the proposed technical solution, we can draw the following conclusions:

1. The shift of the streams and the ranges of variation of the parameter e for the same ordinal calibers according to the prototype and the proposed technical solution will be different.

According to the prototype, e relative to the MM line is a constant value, e = 0.35 mm, both in (-) and in (+), since it does not take into account the rolling technology in calibers preceding the finishing. The proposed duplicate gauges have a different range of fluctuations of the value of e, depending on the features of the rolling technology in calibers prior to finishing.

This deviation range of the parameter e is symmetric, and its oscillation is: from e = -0.24 mm to e = + 0.24 mm in the first; from e = -0.47 mm to e = + 0.47 mm in the second and from e = -0.31 mm to e = + 0.31 mm in the third backup gauge.

To understand the role of the coefficient t _k in calculating the shear of streams in finishing calibers, taking into account the influence of rolling technology in calibers preceding the finishing, we will carry out a comparative analysis of the work of finishing duplicate calibers for rolling rails bored with shear of streams determined by the dependence for the prototype [2], but with the actual production of cones, which corresponds to the values of the shift of streams in calibers calculated according to the proposed dependence, i.e. taking into account the development of calibers preceding the finish, figure 3, c.

1. When working on the first backup gauge, the actual range of production of support cones when removing 1200 tons of metal from the caliber (excluding the value of the intensive shear of streams during running-in cones at the beginning of the first caliber) is 0.48 mm Thus, the deviation e of the rolling surface of the profile head from the MM line (conditionally reflecting the symmetrical rolling surface of the rail head) will be in the following ranges: from -0.35 to +0.13 mm, i.e. the failure of the support cones from the planned calculation is 0.22 mm.

2. The work of the second backup gauge does not begin with the deviation [-e ₂ ] = - 0.35 mm (as provided in the prototype, if the plus deviation in the first caliber due to the development of the cones was [+ e] = 0.35 mm ), and with the magnitude [-e ₂ ] = 0.35 + 0.22 = 0.57 mm. Taking into account the development of the pre-finishing caliber, the actual range of fluctuations of deviations in the second finishing caliber due to the more intensive production of cones is 0.94 mm. Thus, the positive deviation in the second gauge will be [+ e ₂ ] = 0.37 mm, which is 0.02 mm more than planned for the prototype.

в третьем калибре при прокатке 1200 т металла значительно меньше, чем во втором, но больше, чем в первом, и составляет 0,62 мм. Таким образом, положительная величина отклонения в третьем калибре составит [+е₃]=0,62-0,33=0,29 мм.3. The work of the third backup gauge begins with the deviation [-e ₂ ] = 0.35-0.02 = 0.33 mm. Taking into account the development of calibers of stand II of line 800, but with a new finishing gauge, the range of deviation fluctuations

in the third gauge, when rolling 1200 tons of metal, it is much less than in the second, but more than in the first, and amounts to 0.62 mm. Thus, the positive deviation in the third gauge will be [+ e ₃ ] = 0.62-0.33 = 0.29 mm.

Analysis of the work of the final duplicate calibers for rolling rails without taking into account the development of pre-final calibers according to the prototype showed that in the second caliber work begins with a greater deviation of streams than by the proposed method for calibrating duplicate calibers, which leads to a maximum deviation of 0.57 in the symmetry of the rail head mm, relative to MM.

The vibration reduction is achieved due to the introduced coefficients t _k for each backup gauge, which distribute the wear of the cones during rolling in each particular gauge symmetrically, which allows to achieve the most positive results of the quality of the design of the rolling surface of the rail head, taking into account the influence of the rolling technology in calibers preceding the finish. Whereas on the prototype we see a more significant range of oscillations due to the lack of consideration for this factor, which affects the symmetry of the rail profile head during the rolling process.

The use of the proposed backup gauges when rolling railway rails provides the following advantages compared to the prototype:

1. Improving the design of the rolling surface of the rail head and the profile as a whole. This is achieved due to the fact that the maximum deviation in symmetry of the head and profile as a whole is reduced when rolling in the second backup gauge. The asymmetry range decreases when working on the first and third calibers.

2. Increase productivity. Reducing the total asymmetry range in the first and third calibers and the maximum symmetry deviation in the second gauge facilitates profile adjustment.

Thus, the proposed duplicate gauges make it possible to obtain a high quality of symmetry along the rolling surface of the rail profile head, increase mill productivity, and also generally improve technical and economic performance in the manufacture of rails.

Information sources

1. Copyright certificate No. 286935 “Duplicating calibers, for example, calibers of finishing stands of a beam and beam mill”, B21B 1/08 (1970).

2. Kuznetsov S.A., Sharapov I.A., Trynkin A.R. and Kravchenko E.L. "Duplicate rail gauges, for example, finishing stands duo beam and beam mill" // Patent No. 2197338, decl. 02.22.1999, publ. January 27, 2003

Claims (1)

A method of calibrating duplicate oblique gauges for rolling a rail of type P65 placed along the length of the roll barrel, comprising preliminary shifting the open and closed streams by thinning the open sole flange by an amount increasing in the course of the gauge change during rolling, characterized in that the open and closed streams are fixed relative to each other using support cones, while the magnitude of the shear of the streams for each subsequent in the course of rolling the finishing duplicate caliber is determined taking into account the technology of rolling and calibres, preceding the finishing, according to the expression:

where X _k is the magnitude of the shear of the streams when boring the rolls in the k-th finishing gauge, mm;
X _k-1 - the magnitude of the shear of the streams when boring rolls in caliber, preceding the k-th finishing duplicate caliber, mm;
k is the serial number of the caliber;
n is the number of duplicate finishing calibers in the rolls;
a is the total amount of wear of the shoulders, mm;
m is the value of the most intense shear of streams during running-in of cones at the beginning of the first finishing caliber, mm;
t _k - coefficient taking into account the influence of rolling technology in calibers preceding the finishing k-th caliber, subject to the conditions

,
wherein t ₁ = 0.8, t ₂ = 1.3, t ₃ = 0.9, where k = 1, 2, 3, respectively.

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