A medical care system having one or more clinician rooms, and one or more patient areas. The clinician rooms and patient areas are separate from one another to prevent an infectious virus (such as COVID-19) from spreading from one room or area to another room or area. A dividing wall is provided between each clinician room and the respective patient area. A glass partition is located in the dividing wall and one or more gloves are provided in the glass partition. Thus, a clinician located in a clinician room can interact with a patient located in the patient area to conduct a physical medical examination, such as for example to take the temperature of the patient or test for a virus.

A smart system and methods for coupling a medical transporter apparatus with an imaging apparatus, involving: a smart docking module comprising at least one coupler responsive to a controller operable by a set of executable instructions, the smart docking module comprising a non-magnetic material; and the smart docking module configured by the controller to automatically perform at least one of: position, dock, engage, latch, lock, interlock, release, emergency-release, quick-release, disengage, emergency-disengage, and quick-disengage the medical transporter apparatus in relation to the imaging apparatus.

A surface mount assembly may comprise at least one connector set, including a mount anchor and mount fitting that are configured to lockingly engage, and a remote release assembly for unlocking the two. The surface mount assembly may include a catch to catch the mount fitting as it drops from engagement with the mount anchor. The surface mount assembly may further include a guide member for guiding the mount fitting into engagement with the mount anchor. The surface mount assembly may further include a case mount assembly that is crashworthy, in that it is configured to transfer the loads from cargo contained in the case to the mount fitting, while largely bypassing the case. The surface mount assembly may also include two connector sets, where the remote release assembly is disposed between the two and is configured to simultaneous release each of the two from engagement.

The invention provides aeromedical ambulance equipment. In some embodiments, the equipment includes a module base comprising a mount assembly having an unlocked configuration and a locked configuration. The mount assembly preferably can be adjusted between the unlocked and locked configurations by a tool-free operation. In addition, certain embodiments provide a module base having an advantageous system for releasably locking a stretcher onto the module base.

The invention provides aeromedical ambulance equipment. In some embodiments, the equipment includes a module base comprising a mount assembly having an unlocked configuration and a locked configuration. The mount assembly preferably can be adjusted between the unlocked and locked configurations by a tool-free operation. In addition, certain embodiments provide a module base having an advantageous system for releasably locking a stretcher onto the module base.

A mobile diagnosis system according to an embodiment includes a plurality of containers and a mobile body. The plurality of containers store medical equipment and can be combined with each other. The mobile body is configured such that a combination of the containers suitable for a person or a region requiring a medical service among the plurality of containers is loaded thereon, and transports the containers to the person or the region.

An expandable roof system (100) for an expandable vehicle, trailer (200) or transportable unit, comprises a fixed roof component (10), a first moveable roof component (20) and a second moveable roof component (30). The first moveable roof component (20) is mounted above the fixed roof component (10), and the second moveable roof component (30) is mounted above both the fixed roof component (10) and the first moveable roof component (20). The first moveable roof component (20) is arranged for lateral movement between a stored position in which it overlies the fixed roof component (10) and a deployed position in which it is laterally offset from a first side (16) of the fixed roof component (10). The second moveable roof component (30) is arranged for lateral movement between a stored position in which it overlies both the fixed roof component (10) and the first moveable roof component (20), and a deployed position in which it is laterally offset from a second side (11) of the fixed roof component (10).

A shock absorbing apparatus for mitigating agitations while riding within a vehicle. The apparatus is configured to allow a gurney to be connected thereto and further be connected to the floor of an emergency vehicle. The apparatus includes an airbag system that is deflated/inflated by closing/opening the gurney entrance door of the vehicle.

An embodiment is directed to an ambulance vehicle, especially mobile stroke unit. The embodiment of the ambulance vehicle includes a support structure within an interior space of the ambulance vehicle for supporting a cot or stretcher used for transporting the patient. The embodiment of the ambulance vehicle further includes an actuator for tilting the support structure and/or the support structure being at least partially housed in a recess formed in a floor of the interior space.

Mobile medical clinic vehicles are disclosed. An enclosure is connected to a chassis and accommodates medical equipment items for patients and healthcare providers to utilize. One or more electrical components receive electrical power output from a generator, when operated, and provide a first output at a first voltage to a first subset of the medical equipment items and a second output at a second voltage to a second subset of the medical equipment items.