A method of producing an endless metal ring includes welding ends of a maraging steel plate such that the maraging steel plate has a ring shape, annealing the maraging steel plate with the ring shape in a furnace at 845 C. or higher, and nitriding the annealed maraging steel plate, wherein, during the annealing, a dew point temperature indicating an amount of water in the furnace is adjusted such that a value of the dew point temperature [ C.] is equal to or higher than a value obtained by subtracting 35 from time [min] at an annealing temperature of 845 C. or higher.

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.

A metal element, which is pressed and punched by a mold, includes: a neck section positioned between a pair of right and left ring slots; an ear section continuous to a radially outer side of the neck section; and a body section continuous to a radially inner side of the neck section. A locking edge extending in a right-left direction is formed at a radially outer end of the front surface of the body section, and the metal element includes a projection section extending in the right-left direction on a back surface of the body section at a position backward of the locking edge.

A metal element, which is pressed and punched by a mold, includes: a neck section positioned between a pair of right and left ring slots; an ear section continuous to a radially outer side of the neck section; and a body section continuous to a radially inner side of the neck section. A locking edge extending in a right-left direction is formed at a radially outer end of the front surface of the body section, and the metal element includes a projection section extending in the right-left direction on a back surface of the body section at a position backward of the locking edge.

A machining surface of a die are provided with a pair of inclined surfaces facing each other across a gap and a flat surface interposed therebetween. Each inclined surface includes an inner end portion on a side near the flat surface and an outer end portion on a side farther away from the flat surface. The molding method includes a mounting step of mounting the metal sheet on the die to span both inclined surfaces, and a pressing step of forming a reduced-thickness portion by pressing the metal sheet between the punch and the inclined surfaces of the die. The pressing step includes setting a bottom dead center of the punch to maintain a gap formed between the inner end portion and a surface of the metal sheet facing the inner end portion.

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.

The present invention discloses a method for synchronously processing dual belt materials. The method comprises steps of feeding, processing, detecting, assembling and outputting finished products. The step of feeding materials comprises cleaning, dividing materials, positioning and feeding. The step of assembling comprises pushing and assembling. A dual-belt-material feeder is used for feeding, and a dual-belt-material mold is used for punching. The dual-belt-material feeder (1) comprises a moving feeding device (11), a fixed feeding device (13) and two guide frames (14). The dual-belt-material mold comprises two punching molds. The beneficial effects of the method for synchronously processing dual belt materials are that: the method can be used for producing thin wall miniature assembly parts in a single line and assembling the thin wall miniature assembly parts on line, so that problems caused by that the thin wall miniature assembly parts are produced in two production lines can be avoided.

The present invention discloses a method for synchronously processing dual belt materials. The method comprises steps of feeding, processing, detecting, assembling and outputting finished products. The step of feeding materials comprises cleaning, dividing materials, positioning and feeding. The step of assembling comprises pushing and assembling. A dual-belt-material feeder is used for feeding, and a dual-belt-material mold is used for punching. The dual-belt-material feeder (1) comprises a moving feeding device (11), a fixed feeding device (13) and two guide frames (14). The dual-belt-material mold comprises two punching molds. The beneficial effects of the method for synchronously processing dual belt materials are that: the method can be used for producing thin wall miniature assembly parts in a single line and assembling the thin wall miniature assembly parts on line, so that problems caused by that the thin wall miniature assembly parts are produced in two production lines can be avoided.