SU1726079A1 - Method of transverse transfer of ingots with wavy surface - Google Patents

Abstract

The invention relates to pipe production and can be used in the discharge-unloading sections of production lines of a pilger mill. The aim of the invention is to improve the reliability of transportation. In the method of transverse transfer of ingots with a wavy outer surface, the ingots are placed on an inclined lattice and the angle of inclination thereof is calculated using a mathematical expression that takes into account the number of waves on the ingot. The optimum value of the angle of inclination of the lattice ensures reliable movement of the ingots, reduces shock loads on the equipment. 1 hp ff.

Description

The invention relates to pipe production and can be used on the discharge-unloading sections of the production lines of a pilger machine (Pilgerstan) and units receiving ingots with a wavy surface (TL).

There is a known method of transporting ingots, which is used on the ingot preparation section of Pilgerstan and contains horizontal displacement of ingots in the direction perpendicular to their axis, plate-roller chain conveyor to the ejector retractor (3B), then to the transport roller table to itself and then - heating furnace. Ingots using an electric bridge crane with an overhead electromagnetic washer are overloaded from a warehouse to successively working tables (usually 3 pieces) equipped with the above conveyors, while putting the ingots on each table in one row, up to six pieces in it.

This method has the following disadvantages: the increased harmful effects of dynamic shocks on its transport equipment, its considerable abrasive wear and, consequently, its unreliability, its low durability, frequent and fast failures, short maintenance-free life. When using a loading table in the form of a shlepperny device with a lamellar-roller chain conveyor for heavy ingots with a wavy contour (in cross section), this table has considerable operational unreliability. The gravity (large mass) of the ingots in combination with a significant abrasive coating of sand, slag, and the remains of the sprue on them leads to a rapid and significant abrasive wear of the elements and assemblies of the plate conveyor, jamming and breaking it during operation, and hence to its fuzzy work , and serious and prolonged outages him.

In this case, the loading is carried out by a bridge crane with an electromagnetic washer,

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with

osh

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u o o o

XJ Yu

unloading of which is possible only at a certain (albeit at a low) height, in the raised (and not in the laid) position of the ingots above the conveyor. In addition, the electromagnetic washer takes at least two (heavy) ingots, and when at least two heavy ingots do not fit easily at the same time, but fall (even from a low height) on the conveyor with its plates on hinges and on roller carts, these and other elements of the conveyor are quite quickly mechanically broken, destroyed, broken, taken out of order by these numerous numerous heavy ingots for each work shift.

Thus, intensive abrasive and mechanical (shock-dynamic) wear - destruction - makes the shlepper loading table not only operationally unreliable, but even inoperative, bottleneck in the production line of Pilgerstan, especially when used to work with ingots of VP.

In addition, the disadvantages of this method are the unreliability and even the practical inoperability of the transfer conveyor when working with ingots with VP, low productivity, especially when working with ingots with VP and turning the method into a factor in the bottleneck in production, which limits the rate of work and reduces the performance of pilger lines, complexity of equipment, aggravated by multicontourity (dictated by the length of the ingots) of the plate-roller chain conveyors in the loading table, which are expensive to of t, and remontiruyuts and shifts are often a year; inefficiency due to the cost of periodic purchases of complex and numerous pieces of equipment, frequent repairs of complex and multiple pieces of equipment, including significant energy consumption for re-manufacturing and installation of new, and then rapidly emerging multi-circuit conveyors, and in addition, the impossibility of real automation (i.e. provision of work in automatic mode) of the production line of pilgerstans as a whole.

There is also known a method of transporting pipes in a direction, perpendicular to their axis, along the inclined surface of the transfer grid, which includes overcoming the maximum friction force of the rest of the dry metal surfaces of the grid and the pile of pipes.

This method is peculiar to the functional and operational unreliable movement of ingots from the VP along an inclined grid. Moreover, it is practically unsuitable (inoperable) for products such as heavy ingots of any kind (including round ones) and especially as heavy ingots with VP.

Light and round products (pipes) roll along easily and simply (albeit noisy) along an inclined clonal plane — it is enough to create a slight inclination angle of the plane, which is almost easily caught by eye, i.e. no computation, set 5, is set by the operator. In addition, when working with pipes, it is not dangerous to significantly exceed the optimal angle of inclination: light pipes slide down faster and louder (with more noise), but the equipment in their path, for example, 3B, will not be broken.

Products such as heavy ingots with VP to

lonely cat ts with difficulty, and a pile in general

not cat ts because such ingots are in a pile

always coupled (like toothed gearing in a gearbox) as opposed to round pipes, which are only slightly (at a point or along a straight line) touch each other. If the angle of inclination of the grate is small (although sufficient for self-rolling of round pipes),

0 then the ingot with the VP on it does not roll. If the angle with a slight excess is large for self-rolling of the ingot with the VP, then the latter breaks the equipment into its way (for example, 3B). Repeatedly, the dynamics of the self-moving of the pile of ingots turn out to be more crushing, with the only difference that the pile slides (and does not roll like a single ingot).

Thus, at a small (insufficient) angle of inclination of the lattice, ingots with VP do not budge, i.e. there is a functional unreliability of the joint venture, and with a large (redundant) angle they self-displace, but too much, and therefore they break and demolish everything in

5 its way, i.e. obvious operational insecurity of the joint venture.

The noted disadvantage when working with ingots with EPs complicates the problem of using the inertia of ingots for their

0 harmless self-movement along the plane, if we consider that the inclined grate is always loaded (it is expedient production-economically) not with one ingot, but with a pile of ingots (at least two

5 pieces), which (the pile) can only be shifted by itself. And at what angle optimally (i.e. harmlessly) this pile will begin to move (slide), it is not known, because the known slip friction coefficients do not extend, to the special conditions of the method under consideration for ingots with HV, and therefore do not allow to calculate for him this angle. Special conditions are the necessity of overcoming simultaneously occurring processes of multiple abrasive bonding of ingots with each other and multiple abrasive friction of their edges (waves) against the grid. Catching the hands of the operator on the angle-to-eye control console when performing the production task already at the very first attempts most likely leads to equipment breakdown.

The aim of the invention is a functionally and operationally reliable self-slipping movement of ingots with VP.

In addition, the goal is to reduce the intensity of abrasive wear of the transport equipment of the method and the harmful destructive effect on it of the dynamic impact of falling and dropping ingots and increasing its durability; improving the operational and functional reliability of transport equipment by ensuring its operability with ingots with IP; increase in productivity by 8%, especially when working with ingots with VP; significant simplification of equipment in combination with a sharp decrease in the number of its units and assemblies in each unit, as well as their repairs and shifts; a significant increase in efficiency due to the elimination of the costs of periodic purchases of complex and numerous pieces of equipment, the cost of frequent repairs of the same pieces of equipment, significant energy consumption spent on re-manufacturing and installation of first new and then quickly coming out of multi-loop conveyors; as well as providing the possibility of automating the whole Pilgerstan production line.

The goal is achieved by the fact that the proposed method of transporting ingots in the direction perpendicular to their axis along the inclined surface of the transfer lattice contains overcoming with the minimum sliding speed (within the physical Coulomb law) maximum friction force of the dry metal surfaces of the lattice and pile of ingots.

The grating is inclined at an angle a, determined by taking into account the number of n waves on the surface of the ingot from the expression

a - (1.05 ... 1.6)

l p

In addition, in a position inclined by the calculated angle of the lattice with ingots, it is vibrated with them. 5 The selection (for ingots with VP) of the value of a numerical coefficient (from its limits 1.05 ... 1.6} is made depending on the number m - 1-6 ingots on the inclined plane and on the contact state

0 (coupled ™) or ingot splitting.

The minimum value of the coefficient

equal to 1.05, accepted for fragmented

ingots in any quantity within t,

what allows ingots (everyone in separately) to overcome the moving component of its gravity force, the friction of rest and the adhesion force of the surfaces of the ingot and the grid, i.e. budge and roll down it.

0 Reduction of the coefficient below 1.05 leads to the fact that ingots, even fragmented, as a rule, are not able to overcome their mobile component, the force of friction, rest and engagement of their surface with the surface of the lattice, and therefore cannot move themselves from place.

An upper limit of 1.6 is taken for interlocked ingots in

0 their number is more than 3, but in the total number of rri 3-6, which allows ingots (together in the clutch) to overcome the rolling component of the total gravity (the whole group of ingots) rest friction

The 5 groups and the general force of adhesion of the ingot and lattice surfaces and move - slide from the place downwards along it. When choosing the marginal value of the coefficient (i.e., greater than 1.6), the force of movement of the self-moving jointly along the ingot lattice becomes excessively large and dangerous, fraught with deformation and destruction 3B and, moreover, further disengagement of each

5 of the next ingot dropped from the lattice from the ingot adjacent to it.

The average value of the coefficient, equal to 1.3, is accepted for coupled ingots, not exceeding 3 pieces, all this at

0 total number of ingots t 6. The given conditions and restrictions correspond and contribute to a prosperous (without delays, but also without destruction and difficulties of disengagement when ejecting an ingot from the grid to

5 bed) self-relocation of such groups of ingots down the lattice up to 3V.

The regulation of the angles of inclination of the transfer lattice when working with ingots with a VP (according to a mathematical expression allows, much more precisely than catching by eye, select and set

operation, the optimally required value of a (i.e., without the harmful destructive effects of self-transfer of ingots) and thus naturally provides functionally and operationally reliable self-transfer of ingots from the EP along an inclined transfer grid, i.e. ingots with VP due to their inertia and self-shifting (overcome the friction of rest), and self-slip, and do not destroy anything on their way (for example, 3B).

Thus, the operability of the method and its inclined transfer grille with ingots from VP was acquired by transferring their operation from light round pipes to heavy ingots from VP, from rolling along the lattice of the first to sliding of the pile, the latter being finely adjustable.

0

five

the use of the useful part of the force of inertia of its colossal weight is combined with the exception of the destructive effect of this force.

Claims (2)

1. A method of transverse transfer of ingots with a wavy outer surface, including the placement of ingots on an inclined lattice, characterized in that, in order to increase the reliability of transportation, the angle of inclination of the lattice is chosen according to a mathematical expression  (1.05 ... 1.6) -, where n - the number of waves on surface ingot. 2. A method according to claim 1, characterized in that the inclined grating imparts vibration.