New and improved CT imaging systems are presented which improve the ability to deploy CT imaging in a mobile setting, such as in an ambulatory setting or as part of a mobile hospital unit. Improvements disclosed include implementation of an internal drive system for moving a scanner component relative to a fixed or static platform/base, improved modularity of components for quick maintenance/repair and the inclusion of an integrated patient alignment mechanism connected directly to the CT system.

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.

A method for providing medical services to a patient, including: receiving a medical service request associated with a patient location; selecting an aircraft, located at an initial location, from a plurality of aircraft based on the patient location and the initial location; determining a flight plan for flying the aircraft to a region containing the patient location; at a sensor of the aircraft, sampling a first set of flight data; at a processor of the aircraft, autonomously controlling the aircraft to fly based on the flight plan and the set of flight data; selecting a landing location within the region; and landing the aircraft at the landing location, including: sampling a set of landing location data; determining a safety status of the landing location based on the set of landing location data; outputting a landing warning observable at the landing location; at the sensor, sampling a second set of flight data; and in response to determining the safety status and outputting the landing warning, autonomously controlling the aircraft to land at the landing location based on the second set of flight data.

The invention relates to a bench with a scales function, which comprises sensors disposed in parallel along lower lateral bars of the bench and connected to a digital transmitter that transmits to a screen by means of a cable or Bluetooth. In addition to the current functions of the platforms to which the beds are anchored in the vehicles, the bench with an electronic scales function provides the exact value of the weight of the patient, in real time, facilitating the calculation of the precise doses of drugs, fluids, etc.

The present disclosure provides an unmanned vehicle and an unmanned rescue system. The unmanned vehicle includes: a communication unit for receiving a rescue request signal carrying personal information and location information of a rescue object; a main control unit for, after the communication unit receives the rescue request signal, controlling the unmanned vehicle to drive to the location of the rescue object; a broadcasting unit controlled by the main control unit for broadcasting the personal information and location information of the rescue object during the drive of the unmanned vehicle. The unmanned vehicle rescue system includes a triggering device, a control center and the unmanned vehicle; the triggering device is used for sending out a “help” signal; the control center is used for sending out a rescue request signal to the unmanned vehicle.

Systems and methods for powering a medical imaging machine and a workstation are provided. A vehicle houses the medical imaging machine and workstation. A combustion engine for the vehicle is connected to a generator and a drivetrain for moving said vehicle. One or more electrical panels receive electrical power from said generator and provide a first output at a first voltage to the medical imaging machine and a second output at a second voltage to the workstation controls of the medical imaging machine.

A patient litter basket spin control assembly for use on a patient litter basket is provided. The assembly comprises thruster unit for discharging an air stream and is mounted on the patient litter basket. At least one sensor is associated with the thruster unit for sensing rotational movement or spin of the patient litter basket, and a power source is provided for powering the thruster unit and the sensor. A clamp member mounts on the patient litter basket and releasably receives the thruster unit. The sensors modulate the force of the air stream from the thruster unit so that the air stream counters the rotational movement of the patient litter basket to stabilize the patient litter basket by preventing the spin.

An intelligent autonomous electrical vehicle platform assembly provides a mobile platform that comprises a self-motorized, electrical power drive to carry at least one platform container or passenger vehicle while being controlled remotely by an operator, or autonomously driven through artificial intelligence, or operated in a shared transportation system. The mobile platform has a platform chassis having wheels with a hub motor assembly contained therein. The hub motor is powered electrically from a battery charged by an external power source and/or a solar panel. The mobile platform carries a platform container that forms an enclosed area with various themes, including: a cargo transport area, a food and beverage area, a medical assistance area, or a home area having an inhabitant-assigned parking area and utility. The inhabitant of the mobile home receives creature comforts of a home environment, and controls movement, parking, energy, temperature, and payment options for the mobile home.

Systems for providing oncological services to animals are provided. The system includes a transportation vehicle configured to be driven under its own power. The transportation vehicle includes an outer frame housing a plurality of rooms. The plurality of rooms includes an examination room configured to enable a medical professional to medically examine and perform medical diagnostic testing one or more animals, a chemotherapy treatment room configured to enable the medical professional to perform one or more oncological treatments on the one or more animals, and a changing room configured to enable the medical professional to don or doff personal protective equipment.

A method of treating an inside volume of a mobile vehicle including the steps of: a) obtaining a treatment system placed in an operative position with respect to the mobile vehicle and having: i) at least one UV light source; and ii) an air mover; b) operating the air treatment system in one state wherein surfaces within the inside volume are directly exposed to UV light rays; c) changing the air treatment system from the one state into another state so that at least part of the surfaces directly exposed to UV light rays from the at least one UV light source with the treatment system in the one state are not directly exposed to UV light rays; and d) operating the treatment system in the another state wherein air advanced by the air mover is disinfected by UV light rays from the at least one UV light source and distributed within the inside volume.