The present invention refers to a device and method for aligning the input apparatuses and the channels in the rolling stands.
Rolling plants for long products, for example round bars for different uses, comprise a series of rolling stands, arranged in sequence. In
Each stand 1 is equipped with two rolling cylinders or rollers 2, 3, one top one bottom, on which the channels 4 are formed.
The rolled material passing through the aforementioned channels 4 is deformed according to the profile of the channel itself.
The channel is formed in two half-grooves 4′ and 4″, the first of which is formed in the top roller 2 and the second in the bottom roller 3.
With reference to
The system comprising the rolling stand complete with grooved rollers and the relative input apparatuses is foreseen to make, at the output of the stand itself, a rolled material of desired shape and size, and with narrow tolerances.
For such a purpose it is necessary that:
The top cylinder is axially adjustable with respect to the bottom cylinder, and the distance between the two cylinders is symmetrically adjustable with respect to the centre of the channel.
The aforementioned distance must be precalibrated at a precise measurement to take into account the elastic yielding of the machine under the deformation load in order to obtain the required size.
Currently, the aforementioned alignments are carried out by the eye of the operator, according to his experience or with the use of optical instruments or video cameras.
These systems do not allow a relative alignment of the two grooves and of the input guide apparatuses to be obtained with the required precision to obtain products with narrow tolerances.
The input guide apparatus is mounted on a slide held in position by guides at 45° and by a central key. The assembly is mounted on a guide support fixed to the structure of the stand.
Through a screw and lead nut system, the slide can be translated in the longitudinal direction to centre the apparatus in the centre of the channel.
The general purpose of the present invention is, therefore, that of providing a device that allows an alignment of the grooves forming the passage channel of the rolled material to be obtained.
Another purpose of the present invention is that of making a device that allows the measurement of the position of the input apparatus-carrying slide with respect to the centre of the rolling channel.
The last but not least purpose of the present invention is that of providing a method for aligning the input apparatuses and the channels in a rolling stand.
In view of the aforementioned purposes, according to the present invention, it has been thought of to make a device for aligning the input apparatuses and the channels in a rolling stand having the characteristics outlined in the attached claims.
The structural and functional characteristics of the present invention as well as its advantages compared to the prior art shall become even clearer from an examination of the following description, referring to the attached drawings, which show an alignment device made according to the innovative principles of the invention itself.
In the drawings:
a and 4b illustrate, in a schematic and partially sectioned side view, the device according to the present invention in two different operating positions;
With reference to
It should be noted that the rolling stand, to which the device according to the invention is applied, has identical reference numerals for the elements common to the stand according to the prior art according to
The instrument also comprises four shafts 22, each pivoted through a pin F so as to be able to oscillate about said pin. Such shafts in operating measurement state are inclined, by an angle α with respect to the horizontal.
An end 22′ of each shaft 22 carries a push rod 23 suitable for making contact with the surface of one of the grooves 4′ or 4″ that constitute the rolling channel 4.
In such a way, the push rod 23 detects the position of the surface of the groove.
The opposite end 22″ of each shaft, actuates an electronic sensor 24 that, through a suitable calculation algorithm, provides the value of the position of each surface with respect to the centre of the instrument.
The four shafts 22 can each oscillate independently about its pivot F, so as to carry out independent measurements of the position of the groove surface 4′, 4″ to be controlled with respect to the centre of the instrument.
The shafts 22 in practice behave like levers, which can be of the first, second or third type.
To make the slide 13 translate along a slide-carrying base 16, one acts on a ball crank handle 15.
Through the device according to the invention the following measurements are carried out:
The centering method therefore foresees the steps of:
a) Arranging and mounting the device 10 in place of the input apparatus to the rolling stand;
b) opening wide the shafts until the contact of the push rods 23 with the surfaces of the grooves 4′ and 4″;
c) detecting the four rays R1-R4 between the surfaces of the grooves 4′ and 4″ and the central detection axis X of the instrument;
d) controlling the equality between the rays R3 and R4;
e) displacing the slide 13 acting on the ball crank handle 15 until R3=R4 is obtained, in the case in which R3 is different to R4, in such a way obtaining the centering key of the stands input apparatus, perfectly centred with the groove 4″ of the bottom roller 3;
f) controlling the equality between R1 and R2;
g) displacing the top roller 2 through suitable mechanisms of the rolling stand, to centre the top groove with the bottom one should R2 be different to R1;
h) checking that the opening H is at the value foreseen by the rolling conditions, said opening being calculated through geometric relationships by reading of the rays R1-R4 in relation to the ray of the known channel;
i) proceeding to the adjustment open or closed of the two rollers 2, 3 if there is a difference of reading;
l) adjusting the height of the slide-carrying slides 16, should the values of the rays R1 and R4 or else R2 and R3 not be equal to each other;
m) dismounting the device 10;
n) remounting the input apparatus in the stand.
The precalibration of the system is thus obtained, with the required precision, which fall within tolerance values of 0.01 mm more or less.
An inspection table 30 allows the necessary calibrations for zeroing the measurement instruments to be carried out, being equipped with an upright 31 with a calibration channel 32.
Number | Date | Country | Kind |
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MI2004A2060 | Oct 2004 | IT | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2005/011633 | 10/28/2005 | WO | 00 | 3/23/2007 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2006/045629 | 5/4/2006 | WO | A |
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2022286 | Dec 1979 | GB |
Number | Date | Country | |
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20080053176 A1 | Mar 2008 | US |