An eccentric bushing assembly comprises an outer eccentric bushing configured to be disposed in an opening of a panel comprising a central axis. The outer eccentric bushing is operable to float axially, rotate circumferentially, and to move radially with respect to the central axis. The eccentric bushing assembly further comprises an inner eccentric bushing disposed radially inward from the outer eccentric bushing and interfacing with the outer eccentric bushing, the inner eccentric bushing is operable to rotate relative to the outer eccentric bushing. The eccentric bushing assembly further comprises a spherical bushing comprising a through hole operable to receive a connecting pin therein and to rotate in at least one degree of freedom. The rotation of the spherical bushing can facilitate alignment of an axis of the pin with the through hole.

A wing nut may include a body having a first part extending from a first end surface to a parting line and a second part extending from the parting line to a second end surface. A passage may axially extend through the body, the passage defining an interior surface of the body. An internal threaded section may be formed on an interior surface of the first part. An internal shoulder may be formed on the interior surface of the second part. A stress relief may be formed on the interior surface of the second part between the internal shoulder and the parting line. A rib may extend inward from the interior surface of the second part, the rib being intermediate the stress relief and the internal threaded section. At least one lug may extend radially from the exterior surface of the body.

A device is for fixing equipment to an end of the inner surface of a tube. The device has an elongated body, a ring adapted to surround and slide along a segment of the elongated body, and at least two flaps rotatable on the ring. Each hole in the elongated body is adapted for bearing a bolt aligned with the longitude of the elongated body. The ring has at least two threaded bores designed to mate with the threads of the bolts so that the position of the ring on the elongated body is controllable by applying torque to the bolts; and the flaps are positioned homogenously around the ring. The elongated body has at least one portion adapted to guide the flaps so that the flaps radially open against the inner surface of the tube.

A screw connection system connecting a plastic component with a metal component has a bushing and a screw with a screw shank and an external thread arranged on the screw shank. The screw is captively guided in the bushing. The bushing, in a screw-connected state of the screw connection system, extends with a first section in a bore of the plastic component and with a second section in an aligned bore of the metal component aligned with the bore of the plastic component. The bore of the plastic component and the aligned bore of the metal component are positioned at an angle relative to a vertical line on joining surfaces of the plastic component and of the metal component adjoining each other in the screw-connected state. The bushing is movable out of the plastic component when screwing the screw into the metal component.

A wing nut may include a body having a first part extending from a first end surface to a parting line and a second part extending from the parting line to a second end surface. A passage may axially extend through the body, the passage defining an interior surface of the body. An internal threaded section may be formed on an interior surface of the first part. An internal shoulder may be formed on the interior surface of the second part. A stress relief may be formed on the interior surface of the second part between the internal shoulder and the parting line. A rib may extend inward from the interior surface of the second part, the rib being intermediate the stress relief and the internal threaded section. At least one lug may extend radially from the exterior surface of the body.

A screw connection system connecting a plastic component with a metal component has a bushing and a screw with a screw shank and an external thread arranged on the screw shank. The screw is captively guided in the bushing. The bushing, in a screw-connected state of the screw connection system, extends with a first section in a bore of the plastic component and with a second section in an aligned bore of the metal component aligned with the bore of the plastic component. The bore of the plastic component and the aligned bore of the metal component are positioned at an angle relative to a vertical line on joining surfaces of the plastic component and of the metal component adjoining each other in the screw-connected state. The bushing is movable out of the plastic component when screwing the screw into the metal component.

In some examples, a vessel mounting system may include a first collar and a second collar. The second collar may include a clip engageable with an edge of the first collar to engage the second collar with the first collar.

In some examples, a vessel mounting system may include a first collar including at least one protrusion engageable with a groove of a vessel to align the first collar relative to the vessel. A second collar may include at least one stud disposable in a corresponding aperture of the first collar to align the second collar relative to the first collar.

A bearing arrangement for connecting two components including a bearing bushing having an inner sleeve and an elastic element surrounding the inner sleeve. Two connection portions are arranged axially on both sides of the inner sleeve wherein a connector having a shaft portion extending through the inner sleeve applies a clamp force compressing the connection portions axially against the inner sleeve. The inner sleeve is deformed by the clamp force of the connector in such a manner that at least one contact portion of the inner sleeve presses radially to the inside and against the shaft portion.

A clamping device (100) includes a first movable member (210) that is movable along an extending direction of a first body interior space (120), a disc spring (260), an annular spring (270), a spring (280) and a collet (300). A driving mechanism (400) has a second movable member (430) that moves along an extending direction of a second body interior space (130) with rotation of a rotary member (410). When the rotary member is rotated in one direction, the first movable member moves toward an oil-filled closed space (121) and the clamping device is set to a clamping mode that will hold a tool holder (510). On the other hand, when the rotary member is rotated in the opposite direction, the first movable member moves towards the side opposite of the oil-filled closed space and the clamping device is set to an unclamping mode that will release the tool holder.