PLANT FOR THE PRODUCTION AND THE PACKAGING OF STEEL BARS OR RODS

Abstract

A plant for the production and packaging of bars and steel profiles includes a rolling station of rods and profiles of indefinite length, a cooling station, a scrap separation station, a diverter device, cutting shears, intended to cut said bars and profiles in bar portions having a fixed length, and a speed changing device, able to move the bar portions at a speed rate such that they can be placed within respective grooves or housing provided on the outer surface of at least one cylinder or rotating drum. Each cylinder or rotating drum is associated with a speed changing device, so that the housing receives bar portions at different speeds, depending on the fact that the housing belong to one first or to at least second rotating cylinder, in order to avoid overlap of the bar portions when the same are discharged onto the cooling plate.

Claims

1. A method for the production and packaging of steel bars, rods or profiles, comprising: rolling bars, rods or profiles of indefinite length; diverting the bars, rods or profiles into at least a first flow and a second flow; cutting the at least first and second flows of bars, rods or profiles in portions having at least a first fixed length; transporting the portions of bars, rods or profiles with changing a speed of the portions with a speed changing device; rotating at least two cylinders, each of the cylinders having an outer surface with grooves or housings which, during the rotation, pass from an upper position where the grooves or housings receive the portions, to a lower position, where the grooves or housings offload the portions, wherein the grooves or housings have a second fixed length greater than the first fixed length and greater that a commercial length of the bars, rods or profiles; adjusting a speed of the speed changing device to handle the portions at a set speed rate such that the portions can be placed within respective grooves or housings on condition that the grooves or housings in the upper position receive relative portions while the grooves or housings in the lower position offload the portions, which have been previously received in the upper position, on at least one cooling plate; wherein each rotating cylinder is associated with a different speed changing device so that the grooves or housings of different rotating cylinders receive the portions at different speeds, depending on the fact that the grooves or housings belong to one first or to at least one second rotating cylinder and so that the portions have stop positions in the relative grooves or housings; and wherein the portions have the same positions within the grooves or housings, both for the first rotating cylinder and for the second rotating cylinder, so that the portions are arranged within the grooves or housings of each respective rotating cylinder always in the same positions, and wherein a first speed changing device is installed in front of a respective first rotating cylinder and maintains at first a respective first portion at a speed such that the first portion is arranged in a first housing or groove of the first rotating cylinder, while a second speed changing device is installed in front of a respective second rotating cylinder and maintains a respective second portion at a speed such that said second portion is arranged in a second housing or groove of the second rotating cylinder which is close to or next to, but spaced from, compared to the corresponding first housing or groove of the first rotating cylinder, so as to prevent overlap between the first portion with the second portion onto the cooling plate.

2. The method of claim 1, further comprising separating scrap from the bars, rods or profiles.

3. The method of claim 1, further comprising directing, respectively and alternately, the portions into the first rotating cylinder and into the second rotating cylinder.

4. The method of claim 1, further comprising transporting the portions from a first seat to a second seat, adjacent the first seat, of the at least one cooling plate.

5. The method of claim 4, wherein the transporting step is performed only after the offload of at least one of the portions from each of the first and second rotating cylinders.

6. The method of claim 1, further comprising transporting the portions from the at least one cooling plate, via alignment rollers, to a wrapping station and into a binding station and into a packaging station.

7. The method of claim 6, further comprising position at least a first portion of the portions at an inlet side of the alignment rollers at least a second portion of the portions at an output side of the alignment rollers so that at least two bundles of bars are simultaneously formed in the wrapping station.

8. The method of claim 1, further comprising maintaining a relative portion at a rate such that the relative portions are housed in the grooves or housings of at least one first rotating cylinder that is near or close to, but spaced from, the grooves or housings of at least one second rotating cylinder, so that the portions offloaded onto the cooling plate do not overlap.

9. The method of claim 1, further comprising loading, cyclically and alternately, a first groove or housing of the first rotating cylinder and, later, a second groove or housing of a second rotating cylinder.

10. A method for the production and packaging of steel bars, rods or profiles, comprising: diverting a flow of bars, rods or profiles into at least a first flow and a second flow; cutting the at least first and second flows of bars, rods or profiles in portions having at least a first fixed length; adjusting a speed of the first and second flows of portions with at least first and second speed changing devices; rotating at least two cylinders, each of the cylinders having an outer surface with grooves or housings which, during the rotation, pass from an upper position where the grooves or housings receive the portions, to a lower position, where the grooves or housings offload the portions, wherein the grooves or housings have a second fixed length greater than the first fixed length; adjusting a speed of the speed changing devices to handle the portions at a set speed rate such that the portions are placed within respective grooves or housings so that the grooves or housings in the upper position of the first and second cylinders receive portions from the first and second flows, while the grooves or housings in the lower position offload the portions, which have been previously received in the upper position, on at least one cooling plate without overlap of the portions; wherein each rotating cylinder is associated with a different speed changing device so that the grooves or housings of different rotating cylinders receive the portions at different speeds so that the portions have stop positions in the relative grooves or housings.

11. The method of claim 10, further comprising separating scrap from the bars, rods or profiles.

12. The method of claim 10, further comprising directing, respectively and alternately, the first flow and the second flow into the first rotating cylinder and into the second rotating cylinder.

13. The method of claim 10, further comprising transporting the portions from a first seat to a second seat, adjacent the first seat, of the at least one cooling plate.

14. The method of claim 13, wherein the transporting step is performed only after the offload of at least one of the portions from each of the first and second rotating cylinders.

15. The method of claim 10, further comprising transporting the portions from the at least one cooling plate, via alignment rollers, to a wrapping station and into a binding station and into a packaging station.

16. The method of claim 15, further comprising position at least a first portion of the portions at an inlet side of the alignment rollers at least a second portion of the portions at an output side of the alignment rollers so that at least two bundles of bars are simultaneously formed in the wrapping station.

17. The method of claim 10, further comprising maintaining the first flow at a rate such that the portions from the first flow are housed in the grooves or housings of at least one first rotating cylinder that is near or close to, but spaced from, the grooves or housings of at least one second rotating cylinder, so that the portions offloaded onto the cooling plate do not overlap.

18. The method of claim 10, further comprising loading, cyclically and alternately, a first groove or housing of the first rotating cylinder and, later, a second groove or housing of a second rotating cylinder.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0019] The objects and advantages mentioned above, as well as others which will emerge hereinafter, become more evident from the following description, relating to preferred embodiments of the invention, given as an example and preferred, but not limitative, and the attached drawings, in which:

[0020] FIG. 1 shows a block diagram of a plant for the production and packaging of bars and steel profiles, realized according to the prior art;

[0021] FIG. 2 is a schematic sectional view taken along the line II-II of FIG. 1;

[0022] FIG. 3 shows a block diagram of a first embodiment of a plant for the production and packaging of bars and steel profiles according to the present invention;

[0023] FIG. 4 is a schematic sectional view taken along the line IV-IV of FIG. 3;

[0024] FIG. 5 is a schematic view of the deposition process of the bars on the plate or cooling bed implemented in the system of FIG. 3, according to the present invention;

[0025] FIG. 6 shows a block diagram of a further embodiment of plant for the production and packaging of bars and steel profiles according to the present invention;

[0026] FIG. 7 is a schematic sectional view taken along the line VII-VII of FIG. 6; and

[0027] FIG. 8 is a schematic view of the deposition process of the bars on the plate or cooling bed implemented in the plant according to FIG. 6, according to the present invention.

DETAILED DESCRIPTION OF THE INVENTION

[0028] With particular reference to FIGS. 3-5 mentioned, where the same elements of FIGS. 1 and 2 are indicated using the same reference numbers, with 1 is shown a bar or profile of indefinite length, which is placed at the beginning of the line, with 2 is indicated one rolling station, with 3 is shown a cooling station, with 4 is shown a scrap separation station, with 5 is indicated a diverter device, while with 6 is shown a cutting shear for cutting bars 1 to a fixed length Lh (equal to the maximum commercial length) or lengths equal to one or more multiples of the fixed length Lh, and with 7 is indicated a speed changing device (braking device), able to move the fixed length bar portions 1a, 1b at a speed rate able to brake and arrange the bars themselves 1a, 1b within each housing 18 (of length L, with L greater than the fixed length Lh), provided on the outer surface, respectively, of each rotating drum or cylinder 8a, 8b.

[0029] The housings 18 are constituted by as many grooves provided in the lateral surface of the rotating cylinders 8a, 8b, arranged horizontally and rotating about the axis of the cylinder.

[0030] The grooves of the rotating cylinders 8a, 8b placed higher receive the respective bar portions 1a, 1b from the rolling station 2, while the lower grooves unload the bar portions 1a, 1b, which had been previously received in the high position, on the cooling plate 13.

[0031] Furthermore, the speed changing device 7, installed in front of each rotating cylinder 8a, 8b, keeps the bar portions 1a, 1b at a suitable speed to stop and comfortably house said bar portions 1a, 1b into housings 18 of the rotating cylinders or drums 8a, 8b, while the diverter device 5 directs the bar portions 1a, 1b towards the grooves of the rotating cylinders 8a, 8b.

[0032] Then, each bar 1 of indefinite length at the entrance of the line system is divided, by the cutting shear 6, in bar portions 1a, 1b of fixed length Lh, which are housed inside the housings 18 of length L (with L>Lh and L greater than the length of the commercial bars), while the diverter device 5 directs the bars 1a, 1b, alternately and respectively, in the rotating cylinder 8a in the rotating cylinder and 8b and the speed changing device 7 enables to restrain the bars 1a, 1b, so that the same reach a speed able to allow them to be inserted (in the direction of flow F) inside the respective housings 18 on the lateral surface of each rotating cylinder 8a, 8b.

[0033] The positions of the bar portions 1a, 1b inside the seats 18 are the same, both for the rotating cylinder 8a that for the rotating cylinder 8b.

[0034] In particular, it is expected that the bars 1a, 1b are arranged in the housings 18 of each rolling cylinder, respectively, 8a, 8b, always in the same positions, in such a way that, during handling the discharge of said bars 1a, 1b on the plate or cooling bed 13, the same do not overlap each other.

[0035] In detail, both the cylinder 8a that the cylinder 8b downloading each a first bar portion 1a, 1b on a first receptacle 19 of the cooling plate 13, which has means for transporting the bar portions 1a, 1b, such as moving knives or blades.

[0036] Subsequently, the moving knives move the bar portions 1a, 1b of to a second seat 20 of the cooling plate 13 only after both the bars 1a, 1b are discharged from the respective cylinders 8a, 8b.

[0037] The process continues in this way until the bar portions 1a, 1b arrive on suitable alignment rollers 9, where they are kept in place in order to be downloaded into the wrapping station 10 and into a binding station 11 and into a packaging station 12.

[0038] In order to make better use of the capacity (limited) for housing the cooling plate 13, it is possible to use a system of production and packaging of bars and/or profiles such as that illustrated in the attached FIGS. 6-8, according to which the cutting shears 6 subdivide rods 1 of indefinite length in bar portions 1a, 1b of fixed length Lh (the length Lh is such that it is possible to accommodate 2 or more bar portions 1a, 1b within the length L, with L equal to the length of the housing 18 of each rotating cylinder 8a, 8b, and, in particular, Lh< L) and the diverter device 5 directs the bar portions 1a, 1b, alternately and respectively, towards the cylinder 8a and towards the cylinder 8b.

[0039] Furthermore, the speed changing device 7 installed in front of a relative rotating cylinder 8a, 8b maintains the respective bars first at a speed such that the above-mentioned first bars can be arranged in the housings 18 of the rotating cylinder 8a, while the speed changing device 7 installed in front of the rotating cylinder 8b maintains the respective bar portions 1b at a speed such that said bar portions 1b can be arranged in the housings 18 of the rotating cylinder 8b which are close to or close, but different, compared to the corresponding housings 18 of the rotating cylinder 8a, so as not to overlap the bar portions 1a, 1b onto the cooling plate 13.

[0040] Then, the positions of the bar portions 1a, 1b are always the same both inside the rotating cylinder 8a and inside the cylinder 8b (as shown in detail in the attached FIG. 8), and the rotating cylinders 8a and 8b download the bar portions 1a, 1b firstly on a first seat 19 of the cooling plate 13.

[0041] In particular, the positions of the bars 1a, 1b inside the respective cylinders 8a, 8b are such that, when said bars 1a, 1b are discharged onto the cooling plate 13, the same does not overlap each other and, specifically, it is expected that the first bars are always placed in a housing 18 of the rotating cylinders 8a, 8b, in successive positions, one row to another and not interfering with each other within said housing 18 (as shown in detail in the attached FIG. 8).

[0042] In this way, it is loaded, cyclically and alternately, firstly the entire housing 18 of a first rotating cylinder 8a and secondly another housing 18 of a second rotating cylinder 8b.

[0043] At this point and, therefore, only after that both the bar portions 1a, coming from the rotating cylinder 8a, and the bar portions 1b, coming from the rotating cylinder 8b, are placed in the seat 19 of the cooling plate 13, the moving blades of the cooling plate 13 to ensure transfer the bar portions 1a, 1b inside the seat 20, next and adjacent to the seat 19, of the cooling plate 13.

[0044] When the bar portions 1a, 1b arrive on alignment rollers 9, the same are kept in place in order to allow packaging and, in particular, the bars are first positioned on the inlet of the alignment rollers 9, while the bar portions 1b are placed at the output side of the alignment rollers 9.

[0045] In the wrapping station 10, placed in front of the binding stations 11 and packaging station 12, two bundles of bars are simultaneously formed.

[0046] From the above description, the technical characteristics of the plant for the production and packaging of bars and steel profiles, object of the present invention, are clear, as well as the advantages are also clear.

[0047] It's, finally, clear that different variations may be made to the plant in question, without departing from the principles of novelty inherent in the inventive idea according to the appended claims, just as it is clear that, in the practical embodiment of the invention, the materials, shapes and dimensions of the technical details may be any according to requirements and the same may be replaced with other elements that are technically equivalent.