Belts having a cover layer and opposing continuous tooth section defining an outer surface, a cross-linked elastomeric body, and a tensile reinforcement section disposed between the cover layer and the cross-linked elastomeric body. The continuous tooth section includes a plurality of tooth structures, each having tooth flank, a land, and an easement area between the tooth flank and the land, and the easement area has a progressively decreasing radial thickness from the tooth flank to the land. In some aspects, the easement area has a low pressure-angle of contact with a sprocket, when engaging a sprocket. In some aspects, the belt is an endless belt, while in some other aspects, the belt is a spliced belt having a splice.

Belts having a cover layer and opposing continuous tooth section defining an outer surface, a cross-linked elastomeric body, and a tensile reinforcement section disposed between the cover layer and the cross-linked elastomeric body. The continuous tooth section includes a plurality of tooth structures, each having tooth flank, a land, and an easement area between the tooth flank and the land, and the easement area has a progressively decreasing radial thickness from the tooth flank to the land. In some aspects, the easement area has a low pressure-angle of contact with a sprocket, when engaging a sprocket. In some aspects, the belt is an endless belt, while in some other aspects, the belt is a spliced belt having a splice.

Belts having a cover layer and opposing continuous tooth section defining an outer surface, a cross-linked elastomeric body, and a tensile reinforcement section disposed between the cover layer and the cross-linked elastomeric body. The continuous tooth section includes a plurality of tooth structures, each having tooth flank, a land, and an easement area between the tooth flank and the land, and the easement area has a progressively decreasing radial thickness from the tooth flank to the land. In some aspects, the easement area has a low pressure-angle of contact with a sprocket, when engaging a sprocket. In some aspects, the belt is an endless belt, while in some other aspects, the belt is a spliced belt having a splice.

Belts having a cover layer and opposing continuous tooth section defining an outer surface, a cross-linked elastomeric body, and a tensile reinforcement section disposed between the cover layer and the cross-linked elastomeric body. The continuous tooth section includes a plurality of tooth structures, each having tooth flank, a land, and an easement area between the tooth flank and the land, and the easement area has a progressively decreasing radial thickness from the tooth flank to the land. In some aspects, the easement area has a low pressure-angle of contact with a sprocket, when engaging a sprocket. In some aspects, the belt is an endless belt, while in some other aspects, the belt is a spliced belt having a splice.

The invention relates to a method for filling in a tension member in particular for conveyor belts, in particular a tension member which is configured as a steel cable. The method is intended to allow the full penetration of the tension member structure. Here, the method contains at least the following method steps: introducing the individual wires (2, 2, 2, 2, 2) of the strand (5) into the stranding head (1) of a stranding machine (10) andpartially or fully applying at least one coating agent to at least 50% of the individual wires (2, 2, 2, 2, 2) of the strand (5) prior to the twisting of the individual wires (2, 2, 2, 2, 2) to form a strand (5) or simultaneously with the twisting of the individual wires (2, 2, 2, 2, 2) to form a strand (5) andtwisting the individual wires (2, 2, 2, 2, 2) to form a strand (5), wherein at least 50% of the individual wires (2, 2, 2, 2, 2) have been provided with at least one coating agent, andmaking a cable from at least one strand (5).

The invention relates to a method for filling in a tension member in particular for conveyor belts, in particular a tension member which is configured as a steel cable. The method is intended to allow the full penetration of the tension member structure. Here, the method contains at least the following method steps: introducing the individual wires (2, 2, 2, 2, 2) of the strand (5) into the stranding head (1) of a stranding machine (10) andpartially or fully applying at least one coating agent to at least 50% of the individual wires (2, 2, 2, 2, 2) of the strand (5) prior to the twisting of the individual wires (2, 2, 2, 2, 2) to form a strand (5) or simultaneously with the twisting of the individual wires (2, 2, 2, 2, 2) to form a strand (5) andtwisting the individual wires (2, 2, 2, 2, 2) to form a strand (5), wherein at least 50% of the individual wires (2, 2, 2, 2, 2) have been provided with at least one coating agent, andmaking a cable from at least one strand (5).

Rubber article-reinforcing steel cord in which corrosion resistance is improved without an increase in weight. In a rubber article-reinforcing steel cord (1), plural sheath strands (3) each formed by twisting together plural steel filaments are twisted together around at least one core strand (2) formed by twisting together plural steel filaments. Core strand (2) and sheath strands (3) are each formed by twisting together one or two core filaments (2c) and (3c) and plural sheath filaments (2s) and (3s), respectively, and a relationship represented by the following Formula (1) is satisfied when a wire diameter of core filament(s) (2c) of core strand (2), a wire diameter of sheath filaments (2s), a wire diameter of core filaments (3c) of sheath strands (3), and a wire diameter of sheath filaments (3s) are defined as dcc, dcs, dsc and dss, respectively: dcc>dcsdsc>dss (1).

Provided are a method for setting the embedding depth of loop coils in a conveyor belt which can enhance the durability of a loop coil without testing a large number of samples, and a method for manufacturing a conveyor belt in which the loop coil is embedded. A two-dimensional or three-dimensional FEM analysis model of an actual conveyor belt is prepared, and the appropriate embedding depth of the loop coils in the actual conveyor belt, i.e., the rubber thickness between the core layer and the loop coils is set on the basis of at least one of a principal stress or a deformation amount occurring in the loop coil in the analysis model when a falling object having predetermined specifications is dropped from above an upper cover rubber in the analysis model onto the upper cover rubber.

Provided are a method for setting the embedding depth of loop coils in a conveyor belt which can enhance the durability of a loop coil without testing a large number of samples, and a method for manufacturing a conveyor belt in which the loop coil is embedded. A two-dimensional or three-dimensional FEM analysis model of an actual conveyor belt is prepared, and the appropriate embedding depth of the loop coils in the actual conveyor belt, i.e., the rubber thickness between the core layer and the loop coils is set on the basis of at least one of a principal stress or a deformation amount occurring in the loop coil in the analysis model when a falling object having predetermined specifications is dropped from above an upper cover rubber in the analysis model onto the upper cover rubber.

A linear module includes: a base, a slide stage, two support frames, two retaining units and a steel belt. With the pivoting freedom given by the guide portions of the retaining units, when the slide stage moves, the rolling elements can be abutted more closely against the contact surface of the steel belt via the pivoting of the guide portions, so as to reduce the occurrence of deformation and clearance produced by the steel belt, which not only improves the sealing performance of the steel belt and operation smoothness of the linear module, but also produces a dust proof effect, thus achieving the purposes of automatically adjusting contact angle, preventing deformation while extending the life of the steel belt.