An aerodynamic rail cover for an operating room with laminar airflow is provided. The rail cover comprises a rail cover component configured to be movably attached to a support rail of a ceiling mounted support arrangement of a medical imaging system. The rail cover component comprises a base element and an air guiding surface element connected to the base element. The base element is configured to be attached to a portion of the support rail of the ceiling mounted support arrangement. The air guiding surface element forms an air guide to be mounted at least temporarily to cover a portion of the support rail of the ceiling mounted support arrangement. The air guiding surface element comprises two surface parts that extend from starting edges on opposite sides of the base element to a common trailing edge.

A modular patient lift system includes a ceiling grid, a plurality of rails, a gantry configured to traverse the ceiling grid via the plurality of rails, and a patient lift coupled to the gantry and configured to traverse the ceiling grid with the gantry. The modular patient lift system further includes one or more sensors provided on at least one of the plurality of rails, the gantry, and the patient lift, the one or more sensors configured to collect at least one of environmental data and position data.

The present invention relates to an aerodynamic rail cover for an operating room with laminar airflow. In order to provide measures to improve the provision of a laminar airflow in an operating zone, an aerodynamic rail cover (10) for an operating room with laminar airflow is provided. The rail cover comprises at least one cover component (12), wherein the cover component comprises a base element (14); and an air guiding surface element (16) connected to the base element. The base element is configured to be attached to a portion of a support rail of a ceiling mounted support arrangement of a medical imaging system. The air guiding surface element forms an air guide to be mounted at least temporarily to cover a portion of the support rail and comprises two surface parts (18) that are extending from starting edges (20) on opposite sides of the base element to a common trailing edge (22). Further, the rail cover component is configured to be movably attached to the support rail of the ceiling mounted support arrangement of a medical imaging system.

Method and system allowing more accurate detection and identification of unwanted arcing include novel processing of signal voltage representing recovered power-line current. In one implementation, arc-faults are detected based on numerical analysis where individual cycles of line voltage and current are observed and data collected during each cycle is processed to estimate likelihood of presence of arc-event within each individual cycle based on pre-defined number of arc-events occurring within pre-defined number of contiguous cycles. In another implementation, fast transient current spikes detection can be done by: computing difference values between consecutive line-current samples collected over a cycle, average of differences, and peak-to-peak value of line-current; comparing each difference value to average of difference; comparing each difference value to peak-to-peak value; and, based on calculation of composite of two comparisons, using thresholds to determine if arcing is present within processed cycle.

An apparatus comprising an arm with a depending hollow attachment housing, into which is inserted a corresponding attachment portion of a depending device. The housing and attachment portion both have corresponding openings which come into alignment when the attachment portion is inserted into the housing. The apparatus comprises a securing segment which passes through the aligned openings in the housing and attachment portion to prevent the vertical separation of the housing and attachment portion, and a sleeve which surrounds the housing and is vertically moveable between a first position wherein it exposes the openings and securing segment and a second position wherein it covers the securing segment thereby preventing the securing segment from becoming dislodged. The housing comprises a removable delimiter which reduces the allowable vertical movement of the sleeve so that its vertical movement is restricted so as to prevent the sleeve adopting its first position.

The invention relates to a stand device (1) for arranging in an operating room and for locally moving a medical device (20), comprising a braking device (50) having at least one brake (51) that is configured to adjust a degree of freedom of movement of the medical device (20) or a support system (10) holding the device, wherein the stand device (1) further comprises a control device (30) connected to the braking device (50) that is configured to evaluate an external force acting on the stand device (1) or a movement caused by the external force and configured to control the braking device (50) and to adjust the degree of freedom of movement. As a result, the medical device can be moved without operating a switch/pushbutton. Furthermore, the invention relates to a corresponding control device and a method for positioning the medical device.

Various embodiments concern locking release mechanisms that allow an articulated support arm to be moved between various vertical orientations. A locking release mechanism may include a handle release mechanism positioned within the handle of the articulated support arm, and a gas spring release mechanism positioned within the body of the articulated support arm. The articulated support arm can include a gas spring that remains locked until the handle release mechanism is activated, e.g. by applying pressure to a grip actuator. Other embodiments concern cable management techniques for articulated support arms. Oftentimes, an articulated support arm will include cables routed through the arm that are configured to support an attachment. For example, the cable(s) may be adapted for audio signals, video signals, power, etc. The cable(s) can be readily cleaned and/or serviced when routed through an articulated support arm composed of one or more removable pieces.

A mounting device for a stand device for arrangement in the operating room and to position or displace a medical apparatus in the operating room, in particular by means of a rotational movement, incorporates a mounting apparatus, which extends along an axis of rotation in a longitudinal direction and has a cavity, which in particular is cylindrical and which is oriented in the longitudinal direction, for accommodating a rotatably supportable connection component of the stand device, in particular a spindle; and an adjustment apparatus for arranging the connection component in a position, which can be predefined, in relation to the mounting apparatus; wherein the mounting device forms a rotational coupling for supporting the connection component on the mounting apparatus, which rotational coupling can be adjusted about the axis of rotation. The invention further relates to a mounting system including such a mounting device.

A rotation-adjustable hanging device includes a pivot seat, a hanging arm body and a limiting unit. The hanging arm body includes a pivot end connected pivotally to the pivot seat about a first pivot axis. The limiting unit includes a main body, two limiting arms and two limit ends. The main body is disposed on the pivot seat and defines a second axis. The limiting arms are directed toward the pivot end to extend the limit ends to the arm body such that the limit ends are disposed at two opposite sides of a first line that passes through the first and second pivot axes and such that the limit ends is able to stop rotation of the arm body.

A magnetic suspension system for a medical device is provided. The magnetic suspension system comprises a support structure having an area provided with a ferromagnetic characteristic, and a carriage comprising a magnet exerting a magnetic attraction force between the carriage and the support structure. The carriage comprises a friction reducing device and a drive device configured to drive a motion of the carriage upon the support structure in an arbitrary predetermined direction, the drive device being separate from the friction reducing device.