The present disclosure relates to a booth-type mobile infectious disease clinic, and more particularly, to a mobile infectious disease clinic, which is a booth-type mobile infectious disease clinic which makes it possible to assemble and disassemble a large number of mobile infectious disease clinics, that allows a test subject to be tested by a healthcare provider using an infectious disease test kit while exposure of the body parts is minimized and the healthcare provider and the test subject are isolated in the booth-type mobile infectious disease clinic, that performs sterilization of an infectious disease using an ultraviolet C (UV-C) lamp to reduce the time taken for disinfecting the clinic, and that allows the light radiation intensity of the UV-C lamp to be adaptively adjusted according to the body temperature of the test subject.

The present disclosure relates to a tent-type mobile infectious disease clinic, and more particularly, to a mobile infectious disease clinic, which is a tent-type mobile infectious disease clinic that makes it possible to promptly install a large number of mobile infectious disease clinics due to having mobility and being easy to install and remove, that allows a test subject to be tested by a healthcare provider using an infectious disease test kit while the test subject is isolated in the tent-type mobile infectious disease clinic, the healthcare provider is outside the tent-type mobile infectious disease clinic, and exposure of the body parts is minimized, that performs sterilization of an infectious disease using an ultraviolet C (UV-C) lamp to reduce the time taken for disinfecting the clinic, and that allows the light radiation intensity of the UV-C lamp to be adaptively adjusted according to the body temperature of the test subject.

The present disclosure relates to a vehicle-type mobile infectious disease clinic, and more particularly, to a mobile infectious disease clinic, which is a vehicle-type mobile infectious disease clinic, that allows a test subject to be tested by a healthcare provider using an infectious disease test kit while exposure of the body parts is minimized and the healthcare provider and the test subject are isolated in the vehicle-type mobile infectious disease clinic, that performs sterilization of an infectious disease using an ultraviolet C (UV-C) lamp to reduce the time taken for disinfecting the clinic, and that allows the light radiation intensity of the UV-C lamp to be adaptively adjusted according to the body temperature of the test subject.

A collapsible air isolation apparatus is disclosed. The apparatus may include a collapsible frame including a base and a set of rigid panel elements at least partially enclosing a volume of space, where the set of rigid panel elements is foldably hinged to at least one of the base or another of the rigid panel elements, and where at least one panel of the set of rigid panel elements comprises an open space for mounting a motor for moving air. The apparatus may include the motor for moving air configured to create a negative pressure within the volume of space of the collapsible frame.

A normobaric hypoxia trainer including a training chamber, an intake fan for allowing ground level air to be introduced into the training chamber; an exhaust fan for removing air from the training chamber; a plurality of circulation fans for mixing interior air of the training chamber to create a uniform oxygen concentration within the training chamber; a nitrogen generation system, the nitrogen generating system including a plurality of polysulphone membrane cartridges for separating out nitrogen from air; a compressor for supplying compressed air to the nitrogen generation system; a pressure regulator for regulating the pressure of the compressed air; a heater for controlling temperature of the compressed air, the heated pressure regulated compressed air passing through the polysulphone membrane cartridges such that nitrogen can be separated out from the air; and, a flow controller for controlling flow rate of the separated nitrogen into the training chamber.

A normobaric hypoxia trainer including a training chamber, an intake fan for allowing ground level air to be introduced into the training chamber; an exhaust fan for removing air from the training chamber; a plurality of circulation fans for mixing interior air of the training chamber to create a uniform oxygen concentration within the training chamber; a nitrogen generation system, the nitrogen generating system including a plurality of polysulphone membrane cartridges for separating out nitrogen from air; a compressor for supplying compressed air to the nitrogen generation system; a pressure regulator for regulating the pressure of the compressed air; a heater for controlling temperature of the compressed air, the heated pressure regulated compressed air passing through the polysulphone membrane cartridges such that nitrogen can be separated out from the air; and, a flow controller for controlling flow rate of the separated nitrogen into the training chamber.

The present invention belongs to the field of hyperbaric chambers for performing hyperbaric and hyperbaric-oxygen therapies for medical or non-medical purposes, more precisely to the field of constructional execution of flexible-inflatable hyperbaric chambers. The essence of the inflatable hyperbaric chamber with a multilayer structure according to the invention is in the three-layer structure and in separable connection of individual layers of the said structure as well as functional elements, which allows the chamber to operate at a pressures between 130 kPa (1.3 bar) and 300 kPa (3.0 bar). The three-layer structure consists of an inner bag for sealing, an outer bag for protection and relief of the inner bag and which maintains the shape of the chamber, as well as a grid for maintaining the structure and even distribution of forces.

A negative pressure room with a safety management system according to an embodiment of the present disclosure includes an interior space being under negative pressure and is provided in a movable form, so that the negative pressure room can be constructed promptly and economically in the event of a spreading infection, thereby enabling rapid and efficient quarantine treatment and observation of patients with confirmed and suspected infections, the negative pressure room is isolated from a general ward, thereby preventing the possibility of further infection to other patients or medical staff, and real-time monitoring whether negative pressure is appropriately generated in the interior space, air quality in the interior space, and the state of an isolated patient is enabled.

The present disclosure provides an isolation unit to protect uninfected persons from a patient infected with a respiratory disease during a use case. The isolation unit generally includes a frame and cover configured to form an enclosed space surrounding the head, neck and shoulders of the patient, the enclosed space containing air and a fan/filter system in fluid communication with the enclosed space and which includes a vacuum to create a negative pressure within the enclosed space to withdraw air in the enclosed space to the fan/filter system and a filter to remove any contaminants in the air.

A chamber for placement over a patient while allowing medical personnel to perform a medical procedure on the patient releasing virus, bacteria, or other contaminants, including a frame forming, supporting, and operatively integrated within a transparent body including a supported arch, an unsupported arch, and a top shield extending between the supported arch and the unsupported arch, wherein the body includes at least one access hole, and wherein the chamber surrounds the patient's head and the unsupported arch deforms around the patient's body in order to capture and exhaust any virus, bacteria, or other contaminants released by the patient during the medical procedure through negative pressure. A method of using the chamber of to perform a medical procedure on a patient. Methods of preventing exposure to waste anesthetic gas released from a patient after surgery, and preventing exposure to ultrafine particles and volatile organic compounds during 3D printer use.