A split sprocket for use in a modular conveyor belt is disclosed. The split sprocket includes first and second portions that may be selectively arranged in a first configuration in which the sprocket maintains a fixed axial position on the shaft and a second configuration in which the sprocket can axially float along the shaft.

A swing gear set for a large scale or heavy machine can be produced from components of a swing gear set including an internal gear ring assembled from plurality of internal toothed segments and/or an external gear ring assembled from a plurality of external toothed segments. The internal toothed segments and/or the external toothed segments are produced by bisecting a metal block in the shape of a rectangular prism into first and second intermediate blanks. The metal block can be produced by a forging process and the intermediate blanks can be machined by various machining process to produce the finished internal and external toothed segments.

A receiving disk for a segmented pulley transmission is provided. The receiving disk comprises: a generally circular body having a pulley facing side and a rear side, opposite the pulley facing side; at least one mating feature located at the pulley facing side of the body, the mating feature being configured to engage a complimentary mating feature, which is secured to a pulley segment of the segmented pulley transmission, when the pulley segment is in an engaged region; and at least one securing feature located in proximity to the mating feature and configured to secure the complimentary mating feature, when the complimentary mating feature is engaged with the mating feature. A segmented pulley transmission comprising the receiving disk is further provided.

A receiving disk for a segmented pulley transmission is provided. The receiving disk comprises: a generally circular body having a pulley facing side and a rear side, opposite the pulley facing side; at least one mating feature located at the pulley facing side of the body, the mating feature being configured to engage a complimentary mating feature, which is secured to a pulley segment of the segmented pulley transmission, when the pulley segment is in an engaged region; and at least one securing feature located in proximity to the mating feature and configured to secure the complimentary mating feature, when the complimentary mating feature is engaged with the mating feature. A segmented pulley transmission comprising the receiving disk is further provided.

The present disclosure provides a method for forging a gear capable of preventing burrs from being formed at an edge of the surface opposite to a direction in which a material in external teeth of the material is pushed. A first exemplary aspect is a method for moving the second punch along a tooth profile groove of the guide die to stack the material and the second punch in this order; and pushing the material and the second punch into a tooth profile groove of the tooth profile die in a stacked state to pass them therethrough, in which a tooth pressing part of the second punch covers at least an edge of a region where external teeth are formed on a surface of the material on the first punch side.

A bicycle sprocket comprises a sprocket body, a plurality of sprocket teeth, a mounting member, at least one fastening member, and a cover member. The sprocket body has at least one first threaded portion. The mounting member has at least one fastening hole configured to be aligned with the at least one first threaded portion in the assembled state. The at least one fastening member has a fastening shaft portion, a fastening head portion, and a second threaded portion. The second threaded portion is configured to threadedly engage with the at least one first threaded portion of the sprocket body in the assembled state. The cover member is configured to at least cover the fastening shaft portion of the at least one fastening member when viewed from an axial direction with respect to the rotational center axis in the assembled state.

A multipart sprocket wheel engages modular belt modules in a conveyor belt. Each multipart sprocket wheel has two or more periphery elements. Each element has an outer edge and an inner edge. Sprocket teeth are provided on the outer edge. The inner edge has an engagement surface. Each element has fasteners for being fastened to an adjacent periphery element. Two or more periphery elements' outer edges form a full circle. One or more adapter members are used. Each adapter member has an outer face and an inner face. The outer face firmly engages the inner edge of one or more periphery elements. The inner face engages a conveyor drive axle.

A multipart sprocket wheel engages modular belt modules in a conveyor belt. Each multipart sprocket wheel has two or more periphery elements. Each element has an outer edge and an inner edge. Sprocket teeth are provided on the outer edge. The inner edge has an engagement surface. Each element has fasteners for being fastened to an adjacent periphery element. Two or more periphery elements' outer edges form a full circle. One or more adapter members are used. Each adapter member has an outer face and an inner face. The outer face firmly engages the inner edge of one or more periphery elements. The inner face engages a conveyor drive axle.

Provided is a gear mechanism in which power transmission efficiency is good and strength of gear does not reduce. The gear mechanism 10 is provided with a gear body 12 in which a plurality of gears is stacked in a rotation axis direction, each gear being equipped with a disk portion 16 and a plurality of teeth 18 arrange at equal intervals on the outer periphery of the disk portion 16. The plurality of stacked gears 14 is shifted in the rotation direction such that the contact ratio is 1 or more. When the reference module of the gear 14 is m′, the diameter of the pitch circle is d, the number of teeth of the gear 14 is zA, and the number of gears 14 is a, m′=d/(zA×a) is satisfied.

Provided is a gear mechanism in which power transmission efficiency is good and strength of gear does not reduce. The gear mechanism 10 is provided with a gear body 12 in which a plurality of gears is stacked in a rotation axis direction, each gear being equipped with a disk portion 16 and a plurality of teeth 18 arrange at equal intervals on the outer periphery of the disk portion 16. The plurality of stacked gears 14 is shifted in the rotation direction such that the contact ratio is 1 or more. When the reference module of the gear 14 is m′, the diameter of the pitch circle is d, the number of teeth of the gear 14 is zA, and the number of gears 14 is a, m′=d/(zA×a) is satisfied.