A mobile oxygen point of use apparatus includes a standalone and portable mounting panel having a first side and a second side and is configured to be portably relocated within a facility by at least one human operator. A first set of oxygen flow regulators are mounted on the first side of the mounting panel and have multiple first oxygen inputs and multiple first oxygen outputs. A second set of oxygen flow regulators are mounted on the second side of the mounting panel and have multiple second oxygen inputs and multiple second oxygen outputs. A low pressure oxygen input is mounted on the mounting panel and a single pipeline or hose is configured to be connected from the low pressure oxygen input to a source of oxygen. Distribution plumbing connects the low pressure oxygen input to the multiple first oxygen inputs and the multiple second oxygen inputs.

An equipment mounting system may include a quick mount track having a backing plate with a center slot, a first outer slot, and a second outer slot, the first outer slot and the second outer slot comprise a plurality of diamond contour target regions, and a plurality of locking pin apertures along the center slot in the backing plate, the locking pin apertures are in horizontal alignment with the plurality of diamond contoured target regions. The equipment mounting system also may include a mount removably coupled to the quick mount track wherein the plurality of diamond contour target regions allow for a round head of a t-shaped stud of the mount to engage the first outer slot and the second outer slot at an angle to the backing plate.

A surgical room power system including at least one source of power wired to a power source for a surgical room, the at least one source of power being wired to the surgical room; at least one power receiver; and a surgical power consumer wired to the at least one power receiver, the surgical power consumer being configured to assist a surgeon during a surgical procedure on a patient. The at least one source of power wirelessly transfers power to the at least one power receiver for powering the surgical power consumer.

A power transfer system comprises a patient transport apparatus and a power transfer device. The power transfer system provides convenience and ease of connection between a power source and the patient transport apparatus to provide power to one or more electrically powered devices on the patient transport apparatus or to provide energy for an energy storage device on the patient transport apparatus.

An equipment adaptor assembly and equipment stand is disclosed which generally comprises an adaptor body having a width and a depth, a connector extending from the adaptor body and configured for securement to the equipment, a first brace extending from a first portion of the adaptor body for stabilizing the equipment relative to the adaptor when secured to the connector, and a second brace extending from a second portion of the adaptor body for stabilizing the equipment relative to the adaptor when secured to the connector. The adaptor may be configured to be interchangeably securable to a floor stand and a horizontal support structure while maintaining a level orientation of the equipment relative to horizontal when secured to the adaptor and without rearranging the adaptor.

A power transfer system comprises a patient transport apparatus and a power transfer device. The power transfer system provides convenience and ease of connection between a power source and the patient transport apparatus to provide power to one or more electrically powered devices on the patient transport apparatus or to provide energy for an energy storage device on the patient transport apparatus.

A stand device for arranging in an operating room and for locally moving a medical device can incorporate a braking device having at least one brake to adjust a degree of freedom of movement of the medical device or a support system holding the device, wherein the stand device can further comprise a control device connected to the braking device to evaluate an external force acting on the stand device or a movement caused by the external force and configured to control the braking device and to adjust the degree of freedom of movement. The medical device can be moved without operating a switch/pushbutton. Furthermore, the disclosure relates to control devices and a methods for positioning the medical device.

A method and system for providing a specific temperature to a specific bed in a common room having a plurality of beds is disclosed that include: an air filtering module for cleaning the air in the common room, a primary air conditioning module for setting a common temperature, a plurality of secondary air conditioning modules for setting a specific temperature at each bed, a plurality of air circulating modules for creating a convection current of the specific temperature from underneath each bed, and a central processing unit (CPU) for setting specific temperatures of each bed in accordance with a mode selected from an auto mode, a manual mode, and a timing control mode.

A mobile oxygen point of use apparatus includes a standalone and portable mounting panel having a first side and a second side and is configured to be portably relocated within a facility by at least one human operator. A first set of oxygen flow regulators are mounted on the first side of the mounting panel and have multiple first oxygen inputs and multiple first oxygen outputs. A second set of oxygen flow regulators are mounted on the second side of the mounting panel and have multiple second oxygen inputs and multiple second oxygen outputs. A low pressure oxygen input is mounted on the mounting panel and a single pipeline or hose is configured to be connected from the low pressure oxygen input to a source of oxygen. Distribution plumbing connects the low pressure oxygen input to the multiple first oxygen inputs and the multiple second oxygen inputs.