Abstract
The lids of glass containers which have a ‘twist-off’ mechanism are manufactured from tinplate through a process of cutting and drawing. Previously, the tinplate was protected with a double layer of a certain epoxy-phenolic varnish. During cutting, the detachment of threads of varnish is produced, and these may reach more than 150 microns in diameter. These threads stick to the equipment, thus hindering the shaping process. After manufacturing thousands of lids, stops must inevitably be made in production in order to clean machinery. Through the application of a fractioned design of experiment (DoE) application, carried out on an industrial scale, the effect of a number of factors on the detachment of threads of varnish was studied. Some to these factors refer to coating, others to the substratum and others to the process of cutting and drawing. It is concluded that the detachment is greater in the disk areas which are parallel to the forward direction of the production line. This problem could be substantially reduced, and even eliminated, if the direction of the rolling of the sheet metal were perpendicular to that of the forward direction of the production line, if the blank-holder is situated at 4 bar, if the time between the curing process and cutting is no more than 3threedays, if the clearance in the cutting is situated at 0.06 mm, and if the grammage of the varnish and the grammage of the layer of tin are increased.
Highlights
Glass container lids for use in the food industry are made of tin sheets with a thickness of between 0.14 and 0.18 mm [1]
The production is done with a cutting process and through punching and drawing
Tinplate has shown some processing problems because the tin tends to adhere to the cutting and drawing tools, significantly increasing friction between the main components of the tool and the tinplate being formed [3]
Summary
Glass container lids for use in the food industry are made of tin sheets with a thickness of between 0.14 and 0.18 mm [1]. The steel presents a wholly ferritic microstructure, with an elastic limit of between 580 and 620 MPa [2]. These are cold rolled, recrystalised, ferritic steels. Before coating with Sn, they undergo a second cold rolling in order to increase the elastic limit. Tinplate has shown some processing problems because the tin tends to adhere to the cutting and drawing tools, significantly increasing friction between the main components of the tool (punch and die) and the tinplate being formed [3]. Metals are not inert to foodstuffs, so tinplate is coated with protective varnishes to prevent metal-food interaction and migration of metal components [4]. The tinplate is protected with two layers of a certain coating [5,6]
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