DOI: 10.5937/jaes18-25211
This is an open access article distributed under the CC BY-NC-ND 4.0 terms and conditions.
Volume 18 article 691 pages: 292 - 300
Calculation of the forming tool for rib cold rolling by the enveloping method is usually complex and very time-consuming.
The cold rolling process is not always optimized, resulting in a poor quality of the rolled rib profile and premature
failure of the forming tool. Improvement in techniques of rib rolling on metal heat-exchange tubes is a challenging
technological task, which has defined the purpose of the present work – the study of the effect of the forming tool for
cold rolling of ribs by enveloping method on the accuracy of geometrical dimensions of ribbed surfaces. Absence of
a well-developed calculation methodology for this type of tool now adversely affects the rate of manufacturing application
of rib cold rolling processes. Since the main task when introducing the rib rolling process is to achieve the
required accuracy of the work-piece, it seems expedient to improve calculation methodologies allowing designing
a forming tool for rib cold rolling taking into account the required accuracy of geometrical dimensions of the ribbed
surfaces. The present work proposes a methodology that allows performing calculations of parameters required for
manufacturing and supervision over various rolling tools. Experimental approbation data of the outlined methodology
results are presented. Because of deformation processing without additional technological operations, the effect of
surface hardening has been achieved, and the roughness of rolled ribbed surfaces Ra was 0.8 μm, which is comparable
in quality only with finishing machining. It was demonstrated that when calculating the coordinates of profile
points, the geometry of the lead-in, as well as rolls with a screw rib, it is particularly important to determine the angle
of crush forming rolls and the y-coordinate of rolling bars as the main characteristics of the profile.
Some results of this manuscript were obtained as a part
of the work under the Agreement on the provision of subsidies
under date of 13 December 2019 No. 75-15-2019-
1941 (the agreement internal number 05.607.21.0321)
on the topic: “Development of design and technological
solutions for modular pre-fabricated transmission line
towers with integrated systems for continuous digital
monitoring of the condition and thermal stabilization of
the soil to meet the needs of the Arctic regions and the
Far North” with the Ministry of Science and Higher Education
of the Russian Federation. The unique identifier
of the applied research (project) is RFMEFI60719X0321.
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