An actuation mechanism for a valve comprises a first member having a generally spherical surface on a first side of a bisecting line and a generally ellipsoidal surface on a second side of the bisecting line. The first member is rotatable around a central point of the bisecting line. The valve has a second member with a truncated ellipsoidal surface on both sides of a bisecting line. The second member matingly engages the first member at the first member ellipsoidal surface. The valve also includes a longitudinal member coupled to the second member and a biasing member coupled to the longitudinal member. The first member is rotated around the central point from a first position to a second position to move the second member and the longitudinal member linearly. The biasing member returns the first member and second member to the first position upon release of the first member.

Disclosed is a self-aligning mirror device for transmission line offset correction. The disclosed self-aligning mechanism automatically adjusts deflectors to couple radiation between two or more offset waveguides or optical fibers.

Disclosed is a self-aligning mirror device for transmission line offset correction. The disclosed self-aligning mechanism automatically adjusts deflectors to couple radiation between two or more offset waveguides or optical fibers.

A turning device includes: a driving source; a main drive gear rotationally driven by the driving source; a driven gear that engages with the main drive gear and is rotated integrally with a rotated body, wherein the turning device rotationally drives the driving source to rotate the rotated body; a movement mechanism that causes the main drive gear to reciprocate in an axial direction between a separated position at which engagement of the main drive gear and the driven gear is released and an engaged position at which the main drive gear engages with the driven gear; a forward rotation mechanism that intermittently rotates the main drive gear; and a reverse rotation mechanism that intermittently rotates the main drive gear in a direction opposite to a direction by the forward rotation mechanism.

A turning device includes: a driving source; a main drive gear rotationally driven by the driving source; a driven gear that engages with the main drive gear and is rotated integrally with a rotated body, wherein the turning device rotationally drives the driving source to rotate the rotated body; a movement mechanism that causes the main drive gear to reciprocate in an axial direction between a separated position at which engagement of the main drive gear and the driven gear is released and an engaged position at which the main drive gear engages with the driven gear; a forward rotation mechanism that intermittently rotates the main drive gear; and a reverse rotation mechanism that intermittently rotates the main drive gear in a direction opposite to a direction by the forward rotation mechanism.

A remote controller includes a main body of control device, a dial wheel mechanism arranged at the main body of control device, and a controller configured to obtain rotation angle information of the dial wheel mechanism and control movement of an external device according to the rotation angle information. The dial wheel mechanism includes a support, a positioning member disposed at the support, and a rotating member rotatably disposed at the support. The positioning member includes a positioning element and at least one elastic arm disposed at the positioning element. The rotating member is configured to rotate relative to the support, causing the at least one elastic arm to abut against the support and to be elastically deformed. The rotating member includes multiple positioning slots to engage with the positioning element, which is configured to selectively engage with one of the positioning slots.

A remote controller includes a main body of control device, a dial wheel mechanism arranged at the main body of control device, and a controller configured to obtain rotation angle information of the dial wheel mechanism and control movement of an external device according to the rotation angle information. The dial wheel mechanism includes a support, a positioning member disposed at the support, and a rotating member rotatably disposed at the support. The positioning member includes a positioning element and at least one elastic arm disposed at the positioning element. The rotating member is configured to rotate relative to the support, causing the at least one elastic arm to abut against the support and to be elastically deformed. The rotating member includes multiple positioning slots to engage with the positioning element, which is configured to selectively engage with one of the positioning slots.

The present invention provides a stirrer set, comprising: a fitting tube having an opening portion and a hollow rotating shaft fitted into the opening portion, the hollow rotating shaft having an external wall which is annularly recessed to form at least one annular groove. The present invention also provides a stirring device, wherein a drive element comprising a power transmission element, such as a belt, may be rotatably driven to cause, via the power transmission element, the stirrer set to rotate for performing a stirring function. As such, the stirring device provides higher design flexibility when dealing with high-flux samples, and the element replacement rates can be significantly reduced. Thus, the costs related to manufacturing, repair, maintenance and other processes can be reduced in an effective manner.

Construction is achieved of a cam device that is able to effectively prevent a drive-side cam from rotating relative to a driven-side cam in a locked state. Tip-end butt sections 63 are provided on the outer-diameter side portions of tip-end surfaces 41a (40a) of convex sections of one of drive-side convex sections 34a of the drive-side cam surface 31a and driven-side convex sections 36a of the driven-side cam surface 32a, and tip-end concave sections 64 that are further recessed in the axial direction than the tip-end butt sections 63 are provided on the inner-diameter side portions of the one convex sections. In the locked state, only the tip-end butt sections 63 come in contact with the tip-end surfaces 40a (41a) of the other convex sections of the drive-side convex sections 34a and the driven-side convex section 36a.

A clutching adjuster having a housing with a ball stud bore and a nose, and a ball stud journaled by the ball stud bore for axial movement therethrough, the ball stud having a threaded portion, a ball, an unthreaded portion, an outbound annular travel barrier, and an inbound annular travel barrier, where in adjusting operation, rotation of the ball stud causes axial movement of the ball stud through the ball stud bore via engagement of the threaded portion of the ball stud with the nose, and where in length of travel clutching operation and end of travel clutching operation where the ball stud is axially rotated through the ball stud bore, the receipt of an undue axial force of resistance on the ball stud results in a deflection of at least a portion of the nose, allowing the engagement between the ball stud and the nose to clutch.