In a wrinkling prevention device, a work roll having a diameter smaller than that of a press-roll is pressed against the press-roll, and the work roll is supported by a bearing frame through a backup. With this configuration, an uncoated part can be elongated with a uniform pressing force. Further, an edge roller is disposed at an end part of the bearing frame which supports the work roll, and the edge roller is brought into contact with the other press-rolls not in contact with the work roll so that the axis parallelism of the work roll with the press-roll can be ensured.

Provided is a shaping device for a roller electrode for seam welding that prepares shapes for a first roller electrode and a second roller electrode attached to an arm of a robot. This shaping device is provided independently from the robot and disposed within rotational range of the arm, and is provided with a first roller and a second roller that are disposed on a line orthogonal to a line joining the rotational centers of the first and second roller electrodes and are in contact with the outer circumferences of the first and second roller electrodes.

In a wrinkling prevention device, a work roll having a diameter smaller than that of a press-roll is pressed against the press-roll, and the work roll is supported by a bearing frame through a backup. With this configuration, an uncoated part can be elongated with a uniform pressing force. Further, an edge roller is disposed at an end part of the bearing frame which supports the work roll, and the edge roller is brought into contact with the other press-rolls not in contact with the work roll so that the axis parallelism of the work roll with the press-roll can be ensured.

In a method for automated determination of the relative position (x/y/z) between a first hole (27) on a first microsystem component (11), which is preferably provided with a first channel (44) opening in the first hole (27), and at least one second hole (29) on a second microsystem component (12), which is preferably provided with a second channel (45) opening in the second hole (29), the two microsystem components (11, 12) lie in a liquid medium (41) at least in the region (25, 26) of the holes (27, 29). Under the supervision of a control device (15) controlled by a computer (22), the first and second microsystem components (11, 12) are displaced relative to one another into different relative positions (x/y/z). Electrical signals (37) are delivered to one of the two microsystem components (12, 12) and are recorded on the other of the two microsystem components (11, 12) as measurement values (38) which depend on the relative position of the two microsystem components (11, 12) with respect to one another. For different relative positions (x/y/z) between the two microsystem components (11, 12), measurement values (38) are determined, from which the relative position (xn/yn/zn) in which the two microsystem components (11, 12) are to be positioned with respect to one another in such a way that their holes (27, 29) are mutually aligned is ascertained in the control device (15) (FIG. 1).

In a method for automated determination of the relative position (x/y/z) between a first hole (27) on a first microsystem component (11), which is preferably provided with a first channel (44) opening in the first hole (27), and at least one second hole (29) on a second microsystem component (12), which is preferably provided with a second channel (45) opening in the second hole (29), the two microsystem components (11, 12) lie in a liquid medium (41) at least in the region (25, 26) of the holes (27, 29). Under the supervision of a control device (15) controlled by a computer (22), the first and second microsystem components (11, 12) are displaced relative to one another into different relative positions (x/y/z). Electrical signals (37) are delivered to one of the two microsystem components (12, 12) and are recorded on the other of the two microsystem components (11, 12) as measurement values (38) which depend on the relative position of the two microsystem components (11, 12) with respect to one another. For different relative positions (x/y/z) between the two microsystem components (11, 12), measurement values (38) are determined, from which the relative position (xn/yn/zn) in which the two microsystem components (11, 12) are to be positioned with respect to one another in such a way that their holes (27, 29) are mutually aligned is ascertained in the control device (15).

A connector and assembly of a cabling category and comprising two mating zones connected by an intermediate zone. Each of the zones is manufactured such that Near End Cross Talk (NEXT) resulting from transmission of the high frequency signal across each zone is below a specified amount chosen such that NEXT introduced by a high frequency signal transmission between via all the zones is below a level as specified for the cabling category.

A variable-clocking terminal assembly includes a crimp barrel, a terminal lug, and a locking collar. The crimp barrel includes a crimp portion having a crimp portion cavity sized and configured to receive a cable end of an electrical cable. The crimp barrel includes a conical portion extending axially from the crimp portion. The terminal lug has a cylindrical portion and a terminal tongue extending outwardly from the cylindrical portion. The cylindrical portion has a conical cavity configured complementary to the conical portion. The locking collar has collar threads configured to engage threads formed on one of the crimp barrel and the terminal lug for drawing the conical portion into direct physical engagement with the conical cavity in a manner locking an orientation of the terminal lug relative to the crimp barrel and establishing electrical continuity between the conical portion and the conical cavity.

A method of manufacturing a connector and assembly of a cabling category and comprising two mating zones connected by an intermediate zone. Each of the zones is manufactured such that Near End Cross Talk (NEXT) resulting from transmission of the high frequency signal across each zone is below a specified amount chosen such that NEXT introduced by a high frequency signal transmission between via all the zones is below a level as specified for the cabling category.

A variable-clocking terminal assembly includes a crimp barrel, a terminal lug, and a locking collar. The crimp barrel includes a crimp portion having a crimp portion cavity sized and configured to receive a cable end of an electrical cable. The crimp barrel includes a conical portion extending axially from the crimp portion. The terminal lug has a cylindrical portion and a terminal tongue extending outwardly from the cylindrical portion. The cylindrical portion has a conical cavity configured complementary to the conical portion. The locking collar has collar threads configured to engage threads formed on one of the crimp barrel and the terminal lug for drawing the conical portion into direct physical engagement with the conical cavity in a manner locking an orientation of the terminal lug relative to the crimp barrel and establishing electrical continuity between the conical portion and the conical cavity.

Provided is a shaping device for a roller electrode for seam welding that prepares shapes for a first roller electrode and a second roller electrode attached to an arm of a robot. This shaping device is provided independently from the robot and disposed within rotational range of the arm, and is provided with a first roller and a second roller that are disposed on a line orthogonal to a line joining the rotational centers of the first and second roller electrodes and are in contact with the outer circumferences of the first and second roller electrodes.