A modular reel drive assembly comprises two reel drive tower modules (12, 14), a reel hub adapter (54) and a reel hub adapter support module (22, 24). The hub adapter support module (22, 24) comprises at least one support pin which is configured to be movable between a storage position in which the at least one support pin is not aligned with at least one aperture (38, 39, 40, 41) on the hub adapter support module (22, 24) and an operational position in which the support pin is aligned with at least one aperture (38, 39, 40, 41) on the hub adapter support module (22, 24).

A coiler bar assembly includes a coupler housing and a bearing housing used to suspend a reel shaft above a surface. The reel shaft is configured to include bearings to permit its rotation relative to the housings. The coupler housing includes a receiving plate coupled to an end of the reel shaft and a coupler that is engaged with a motor shaft. The motor shaft extends up to the receiving plate. A handle is included and is pivotally coupled to the coupler housing and the coupler about two separate axes. Pivoting the handle permits translation of the coupler along the motor shaft to selectively engage the receiving plate. When engaged, rotation of the motor shaft induces rotation of the reel shaft. The handle is operated externally from the coupler housing.

A coiler bar assembly includes a coupler housing and a bearing housing used to suspend a reel shaft above a surface. The reel shaft is configured to include bearings to permit its rotation relative to the housings. The coupler housing includes a receiving plate coupled to an end of the reel shaft and a coupler that is engaged with a motor shaft. The motor shaft extends up to the receiving plate. A handle is included and is pivotally coupled to the coupler housing and the coupler about two separate axes. Pivoting the handle permits translation of the coupler along the motor shaft to selectively engage the receiving plate. When engaged, rotation of the motor shaft induces rotation of the reel shaft. The handle is operated externally from the coupler housing.

A capstan includes a lift motor, a flexible lifting member, and a tether assembly. The lift motor is operatively connected to a shaft. The flexible lifting member includes a first end and a second end. The first end is connected to the shaft. The flexible lifting member connects a lift assembly to the lift motor via the shaft. The tether assembly includes a switch arranged between a portion of the flexible lifting member and a portion of the capstan. The second end is connected to the tether assembly. The switch acts as a safety in case of a broken flexible lifting member and allows for an automated unloading cycle.

A capstan includes a lift motor, a flexible lifting member, and a tether assembly. The lift motor is operatively connected to a shaft. The flexible lifting member includes a first end and a second end. The first end is connected to the shaft. The flexible lifting member connects a lift assembly to the lift motor via the shaft. The tether assembly includes a switch arranged between a portion of the flexible lifting member and a portion of the capstan. The second end is connected to the tether assembly. The switch acts as a safety in case of a broken flexible lifting member and allows for an automated unloading cycle.

The invention relates to a sleeve plate designed to support and center a bobbin sleeve, comprising: a centering projection; and a main body, in particular circular in design, further designed in particular in a plate-like manner, with a surface side.

The centering projection can be designed in particular to be received by an opening in an end face of the bobbin sleeve. The centering projection is arranged in a rotationally centered manner on the surface side of the main body and projects from this surface side and is designed in such a way as to center the bobbin sleeve when the bobbin sleeve is in the received state. The centering projection has a lateral surface. In order to improve the receiving of a bobbin sleeve on a sleeve plate during a transition from a run-up rotational state to a winding state, thereby increasing the process reliability and thereby saving resources, it is provided that a functional device can be assigned or is assigned to the centering projection, in particular the lateral surface of the centering projection.

The invention relates to a sleeve plate designed to support and center a bobbin sleeve, comprising: a centering projection; and a main body, in particular circular in design, further designed in particular in a plate-like manner, with a surface side.

The centering projection can be designed in particular to be received by an opening in an end face of the bobbin sleeve. The centering projection is arranged in a rotationally centered manner on the surface side of the main body and projects from this surface side and is designed in such a way as to center the bobbin sleeve when the bobbin sleeve is in the received state. The centering projection has a lateral surface. In order to improve the receiving of a bobbin sleeve on a sleeve plate during a transition from a run-up rotational state to a winding state, thereby increasing the process reliability and thereby saving resources, it is provided that a functional device can be assigned or is assigned to the centering projection, in particular the lateral surface of the centering projection.

A capstan includes a lift motor, a flexible lifting member, and a tether assembly. The lift motor is operatively connected to a shaft. The flexible lifting member includes a first end and a second end. The first end is connected to the shaft. The flexible lifting member connects a lift assembly to the lift motor via the shaft. The tether assembly includes a switch arranged between a portion of the flexible lifting member and a portion of the capstan. The second end is connected to the tether assembly. The switch acts as a safety in case of a broken flexible lifting member and allows for an automated unloading cycle.

It is possible to suppress damage to a yarn path guide mechanism and a textile machine. There is a first supporter which makes contact with a supporting shaft supporting a roller, a second supporter which is capable of making contact with the supporting shaft, and a biasing member which biases the second supporter in a direction in which the supporting shaft is sandwiched between the second supporter and the first supporter. When a virtual straight line which passes through a winding center and a rotation center is a first virtual straight line whereas a virtual straight line which extends in a direction orthogonal to the first virtual straight line and passes through the rotation center is a second virtual straight line, the second supporter makes contact with a part of the supporting shaft, which is positionally opposite to the winding center over the second virtual straight line.

It is possible to suppress damage to a yarn path guide mechanism and a textile machine. There is a first supporter which makes contact with a supporting shaft supporting a roller, a second supporter which is capable of making contact with the supporting shaft, and a biasing member which biases the second supporter in a direction in which the supporting shaft is sandwiched between the second supporter and the first supporter. When a virtual straight line which passes through a winding center and a rotation center is a first virtual straight line whereas a virtual straight line which extends in a direction orthogonal to the first virtual straight line and passes through the rotation center is a second virtual straight line, the second supporter makes contact with a part of the supporting shaft, which is positionally opposite to the winding center over the second virtual straight line.