Abstract: Various systems are provided for damping vibration in a mobile radiographic imaging system. In one embodiment, a vibration damping assembly for a C-arm imaging system comprises a pivot element rotatably coupled to a toe portion of the C-arm imaging system and configured to form an interface between the toe portion, a damping element, and a ground surface on which the C-arm imaging system sits.

Abstract: An X-ray imaging system is provided. The X-ray imaging system includes an X-ray radiation source, an X-ray detector, and a C-arm. The C-arm has the X-ray radiation source disposed on a first end and the X-ray detector disposed on a second end opposite the first end. The X-ray imaging system also includes a motorized system configured to rotate the C-arm about three different rotational axes.

Abstract: Various systems are provided for damping vibration in a mobile radiographic imaging system. In one embodiment, a vibration damping assembly for a C-arm imaging system comprises a pivot element rotatably coupled to a toe portion of the C-arm imaging system and configured to form an interface between the toe portion, a damping element, and a ground surface on which the C-arm imaging system sits.

Abstract: An X-ray imaging system is provided. The X-ray imaging system includes an X-ray radiation source, an X-ray detector, and a C-arm. The C-arm has the X-ray radiation source disposed on a first end and the X-ray detector disposed on a second end opposite the first end. The X-ray imaging system also includes a motorized system configured to rotate the C-arm about three different rotational axes.

Abstract: An X-ray imaging system is provided. The X-ray imaging system includes an X-ray radiation source, an X-ray detector, and a C-arm having the X-ray radiation source disposed on a first end and the X-ray detector disposed on a second end opposite the first end. The C-arm includes a track. The X-ray imaging system also includes a C-arm rotation device configured to enable the C-arm to rotate along the track in an orbital direction relative to the C-arm rotation device, wherein a portion of the C-arm rotation device is disposed within the track. The X-ray imaging system also includes an orbital rotation positioning device configured to be disposed within the track, wherein the orbital rotation positioning device blocks rotation of the C-arm beyond a position of the orbital rotation positioning device.

Abstract: An X-ray imaging system is provided. The X-ray imaging system includes an X-ray radiation source, an X-ray detector, and a C-arm. The C-arm has the X-ray radiation source disposed on a first end and the X-ray detector disposed on a second end opposite the first end. The X-ray imaging system also includes a motorized system configured to rotate the C-arm about three different rotational axes.

Abstract: A device is provided. The device includes an orbital clutch and brake assembly configured to couple to a C-arm rotation device that enables the C-arm to rotate in an orbital direction relative to the C-arm rotation device. The orbital clutch and brake assembly includes a housing, a roller, and a brake pad. The roller and brake pad are disposed within the housing. The brake pad is configured to directly contact the roller and to not contact the C-arm when the orbital clutch and brake assembly applies a braking force to the C-arm.

Abstract: A device is provided. The device includes an orbital clutch and brake assembly configured to couple to a C-arm rotation device that enables the C-arm to rotate in an orbital direction relative to the C-arm rotation device. The orbital clutch and brake assembly includes a housing, a roller, and a brake pad. The roller and brake pad are disposed within the housing. The brake pad is configured to directly contact the roller and to not contact the C-arm when the orbital clutch and brake assembly applies a braking force to the C-arm.

Abstract: An X-ray imaging system is provided. The X-ray imaging system includes an X-ray radiation source, an X-ray detector, and a C-arm. The C-arm has the X-ray radiation source disposed on a first end and the X-ray detector disposed on a second end opposite the first end. The X-ray imaging system also includes a motorized system configured to rotate the C-arm about three different rotational axes.

Abstract: An X-ray imaging system is provided. The X-ray imaging system includes an X-ray radiation source, an X-ray detector, and a C-arm having the X-ray radiation source disposed on a first end and the X-ray detector disposed on a second end opposite the first end. The C-arm includes a track. The X-ray imaging system also includes a C-arm rotation device configured to enable the C-arm to rotate along the track in an orbital direction relative to the C-arm rotation device, wherein a portion of the C-arm rotation device is disposed within the track. The X-ray imaging system also includes an orbital rotation positioning device configured to be disposed within the track, wherein the orbital rotation positioning device blocks rotation of the C-arm beyond a position of the orbital rotation positioning device.

Abstract: Systems and methods for controlling an X-ray imaging system are described. The systems and methods typically include a support arm with a first end and a second end. The first end of the support arm connects to an articulating arm assembly and the second end of the support arm pivotally attaches to an X-ray imaging arm at a pivot joint so that the pivot joint functions as an axis of orbital rotation for the X-ray imaging arm. One or more controls for the X-ray imaging system are disposed on the support arm for the X-ray imaging arm. The controls can therefore remain stationary while the X-ray imaging arm rotates orbitally. The support arm can include a single member or a double member and one or more controls can be disposed on each member of the support arm. Other embodiments are also described.

Abstract: Systems and methods for rotating X-ray devices are disclosed. The systems and methods use X-ray devices with an X-ray imaging arm orbitally rotating about pivot joints that are physically attached to the X-ray imaging arm. The pivot joint coincides with the center of gravity for the X-ray imaging arm. The X-ray device has an X-ray imaging arm with an X-ray source and detector respectively disposed at nearly opposing locations of the imaging arm. The pivot joint can serve as an axis of orbital rotation around which the imaging arm pivots. The pivot joint can be pivotally attached to a first end of an X-ray imaging arm fork, which has a second end attached to an X-ray imaging arm support structure. The imaging arm fork can include a lateral pivot joint that provides a lateral axis of rotation for the imaging arm. The fork can contain one or two arms.

Abstract: Systems and methods for braking and releasing one or more pivot joints used in an X-ray positioning device are described. The systems and methods use a support arm that extends between a main assembly of the x-ray positioning device and an X-ray imaging assembly with an X-ray source and an X-ray detector that are disposed nearly opposite to each other. The support arm includes one or more pivot joints (such as horizontal, lateral, and/or orbital pivot joints) that allow the imaging assembly to move with respect to the main assembly. The pivot joints can each be connected to an automated braking system that is capable of selectively locking and unlocking a corresponding pivot joint, as indicated by a user-controlled switching mechanism. The braking systems containing multiple pivot joints can be individually controlled by separate switching mechanisms or simultaneously controlled by a single switching mechanism. Other embodiments are described.

Abstract: C-arm retention locks allowing users to secure and unsecure C-arm positioning devices of an X-ray machine, systems containing such locks, and methods of using such locks are described. The C-arm retention lock comprises a latch bail and a latching assembly. The latching assembly comprises a latch base having an ear and a generally flat engagement surface at an end of the latch base proximate the ear, a latch having an arm, the latch being pivotally connected to the latch base so the latch is rotatable between closed and open positions, and a tensioning device engaging the latch and latch base such that the tensioning device pulls the latch toward either of the closed or open positions. The latching assembly or latch bail is configured to be connected to a C-arm and the latching assembly retains the latch bail between the ear and the arm when the latch is closed.

Abstract: Systems and methods for braking and releasing one or more pivot joints used in an X-ray positioning device are described. The systems and methods use a support arm that extends between a main assembly of the x-ray positioning device and an X-ray imaging assembly with an X-ray source and an X-ray detector that are disposed nearly opposite to each other. The support arm includes one or more pivot joints (such as horizontal, lateral, and/or orbital pivot joints) that allow the imaging assembly to move with respect to the main assembly. The pivot joints can each be connected to an automated braking system that is capable of selectively locking and unlocking a corresponding pivot joint, as indicated by a user-controlled switching mechanism. The braking systems containing multiple pivot joints can be individually controlled by separate switching mechanisms or simultaneously controlled by a single switching mechanism. Other embodiments are described.

Abstract: Systems and methods for braking and releasing one or more pivot joints used in an X-ray positioning device are described. The systems and methods use a support arm that extends between a main assembly of the x-ray positioning device and an X-ray imaging assembly with an X-ray source and an X-ray detector that are disposed nearly opposite to each other. The support arm includes one or more pivot joints (such as horizontal, lateral, and/or orbital pivot joints) that allow the imaging assembly to move with respect to the main assembly. The pivot joints can each be connected to an automated braking system that is capable of selectively locking and unlocking a corresponding pivot joint, as indicated by a user-controlled switching mechanism. The braking systems containing multiple pivot joints can be individually controlled by separate switching mechanisms or simultaneously controlled by a single switching mechanism. Other embodiments are described.

Abstract: Systems and methods for making and using sliding counterbalanced C-arm positioning devices are described. In such systems and methods, each C-arm positioning device includes a C-arm X-ray device, a linear bearing rail, a linear bearing block, and a counterbalance mechanism. Generally, the C-arm is connected to the linear bearing block, which, in turn, is slidably coupled to the bearing rail to allow the bearing block and C-arm to slide up and down on the rail. The counterbalance mechanism can apply a force to the bearing block to counterbalance the weight of the C-arm and the bearing block. Thus, the described C-arm positioning device can allow a user to easily raise or lower the C-arm with relatively little effort. While some implementations of the C-arm positioning device are connected to mobile support structure, other implementations of the C-arm positioning device are mounted to a fixed support structure. Other implementations are also described.