Disclosed is an endless metal belt (101, 102) which has a length/circumference (l1) and a width (b1) and which is produced by welding a number of individual metal belt parts (2). A rolling direction (3) of the individual metal belt parts (2) and the weld seams (4) extend transversely to the length/circumference (l1) of the metal belt (101, 102). Also disclosed is a method for producing an endless metal belt (101, 102) of said type.

Disclosed is an endless metal belt (101, 102) which has a length/circumference (l1) and a width (b1) and which is produced by welding a number of individual metal belt parts (2). A rolling direction (3) of the individual metal belt parts (2) and the weld seams (4) extend transversely to the length/circumference (l1) of the metal belt (101, 102). Also disclosed is a method for producing an endless metal belt (101, 102) of said type.

Disclosed is a method for manufacturing an endless belt, of the flat type made of metal material, designed to be wound around at least one indexed pulley provided with teeth. The endless belt includes, for the one part, locations which are each designed to receive a product to be conveyed and, for the other part, indexing perforations. The manufacturing method includes the following successive steps: a) a step of supplying a flat band made of the metal material, b) a step of closing the band by welding of the transverse edges thereof via a weld seam, and c) a step of perforating the weld seam, at the at least one longitudinal indexing line, in order to form at least one additional indexing perforation that is also designed to engage with the teeth of the at least one indexed pulley.

Disclosed is a method for manufacturing an endless belt, of the flat type made of metal material, designed to be wound around at least one indexed pulley provided with teeth. The endless belt includes, for the one part, locations which are each designed to receive a product to be conveyed and, for the other part, indexing perforations. The manufacturing method includes the following successive steps: a) a step of supplying a flat band made of the metal material, b) a step of closing the band by welding of the transverse edges thereof via a weld seam, and c) a step of perforating the weld seam, at the at least one longitudinal indexing line, in order to form at least one additional indexing perforation that is also designed to engage with the teeth of the at least one indexed pulley.

A drive force transmission mechanism includes a drive pulley, a driven pulley and an endless belt. The endless belt is wound around the drive pulley and the driven pulley and transmits a rotation of the drive pulley to the driven pulley. At least one of the drive pulley and the driven pulley has a protruding part protruding outwardly in a radial direction around an outer circumferential face of the drive pulley or the driven pulley. The belt is a nonmagnetic metal belt having an outer circumferential face and an inner circumferential face. The outer circumferential face has a surface roughness smaller than a surface roughness of the inner circumferential face.

The invention relates to a method of production for attachment by cohesive bonding of a profile having at least one profile element onto a toothed belt previously produced as a semi-finished product. The toothed belt has a tooth side with a toothing and a toothed belt back located on the back of the tooth side of the toothed belt. In the method of production the at least one profile element is built up layer by layer from at least one first profile element layer and a second profile element layer on the toothed belt back, by the application of an application compound to the toothed belt back at a profile element position by melt layer printing.

The invention relates to a method of production for attachment by cohesive bonding of a profile having at least one profile element onto a toothed belt previously produced as a semi-finished product. The toothed belt has a tooth side with a toothing and a toothed belt back located on the back of the tooth side of the toothed belt. In the method of production the at least one profile element is built up layer by layer from at least one first profile element layer and a second profile element layer on the toothed belt back, by the application of an application compound to the toothed belt back at a profile element position by melt layer printing.

Disclosed is a method for manufacturing an endless belt, of the flat type made of metal material, designed to be wound around at least one indexed pulley provided with teeth. The endless belt includes, for the one part, locations which are each designed to receive a product to be conveyed and, for the other part, indexing perforations. The manufacturing method includes the following successive steps: a) a step of supplying a flat band made of the metal material, b) a step of closing the band by welding of the transverse edges thereof via a weld seam, and c) a step of perforating the weld seam, at the at least one longitudinal indexing line, in order to form at least one additional indexing perforation that is also designed to engage with the teeth of the at least one indexed pulley.

This disclosure relates to methods and apparatuses of employing belts for an angular drive. A twisted geometry is applied to a first free span of the belt. A sheave supports the first free span of the belt at a first extremity of the first free span and sheave is at least one of positioning and orienting the rotating sheave or the driven sheave so as to misalign a geometric centerline of the first free span of belt at a given fleet angle with respect to a second extremity of the first free span.

Manufacturing a steel sheet for a steel belt includes hot rolling a steel slab containing, in mass %, 0.60 to 0.80% of C, 1.0% or less of Si, 0.10 to 1.0% of Mn, 0.020% or less P, 0.010% or less S, 0.1 to 1.0% of Cr, 0 to 0.5% of V, 0 to 0.1% of Ti, 0 to 0.1% of Nb, and 0 to 0.01% of B, the balance Fe and unavoidable impurities, under a finish hot rolling temperature of 800 to 900 C. An average cooling rate from finish rolling to coiling is 20 C. per second or more. A coiling temperature is 450 to 650 C. The hot-rolled slab is cold rolled with a total rolling reduction ratio of 40% or more and a reduction ratio per one pass of less than 12%, without performing a heat treatment. The cold-rolled slab is aged at 200 to 500 C. for 0.5 to 30 hours.