The embodiments of the invention provide an intelligent shared cryogenic physical therapy system, including cryogenic physical therapy devices, human-machine interaction devices and a server. The server is configured to acquire target location information and recommend a cryogenic physical therapy device based on a relationship between the target location information and pre-recorded location information of each of the cryogenic physical therapy devices; and send a use request to a human-machine interaction device when a target cryogenic physical therapy device is selected and it is determined that the account balance meets a fee deduction condition. The human-machine interaction device can acquire the use request and generate the control instruction. A programmable controller of the cryogenic physical therapy device is configured to control the physical therapy module to perform an operation indicated by the control instruction when receiving the control instruction. After finishing the cryogenic physical therapy, the human-machine interaction device is configured to send a fee deduction request to the server, so that the server can update the account balance when receiving the fee deduction request. The user does not need to go to a specific service merchant, and can select a suitable cryogenic physical therapy device according to actual conditions.

The embodiments of the present invention provides a cryogenic physical therapy cabin for home use, which includes a thermal insulation cabin body, an electronically controlled cabin door, a sensing module, a refrigeration module, a heating module and a programmable controller, wherein the sensing module, the refrigeration module and the heating module are arranged inside the thermal insulation cabin body, and the programmable controller is electrically connected with the sensing module, the refrigeration module, the heating module and the electronically controlled cabin door respectively; the sensing module is configured to acquire sensing data and send the sensing data to the programmable controller; the programmable controller is configured to control opening and closing of the electronically controlled cabin door based on an operation instruction issued by a first user and/or the sensing data; the programmable controller is further configured to control the refrigeration module to perform refrigeration operation and control the heating module to perform a heating operation based on the sensing data. The programmable controller controls the cryogenic physical therapy cabin based on the operation instruction and/or the sensing data, which supports to be operated by a single user and meets home cryogenic physical therapy needs of the user.

The embodiments of the present invention provide a method, an apparatus for controlling a cryogenic physical therapy cabin, an electronic device and a storage medium. The method comprises: acquiring physical therapy information input by a user; acquiring target feature information of a target user, and controlling a cabin door of the physical therapy cabin to be opened when it is determined that the target feature information matches pre-stored feature information; controlling the cabin door of the physical therapy cabin to be closed after determining that the user enters the physical therapy cabin; adjusting a temperature of the physical therapy cabin to reach the physical therapy temperature, and recording the physical therapy duration of the user; and after determining that the physical therapy duration of the user reaches the physical therapy duration, adjusting the temperature of the physical therapy cabin to a preset temperature, and controlling the cabin door of the physical therapy cabin to be opened. The cryogenic physical therapy cabin can be controlled based on the physical therapy information input by the user and the target feature information of the target user, so as to complete the cryogenic physical therapy process to the user. There is no need for the assistance of staff and the cryogenic physical therapy cabin can be operated by a single user, thereby better meeting the cryogenic physical therapy needs of the user.

The misting system has, in one embodiment, two seats with misting heads above each seat. A platform supports the seats, a tank, a pump and a power source. A supply line couples the tank-supplied pump and the misters. Removable canopy is mounted above seats by vertical and curvaceous struts and the misters are mounted on the struts. A user actuated UA control on the seat(s) activates pump ON to release mist. Wheels make the module mobile. Battery, solar power, and chiller are options. A countdown timer turns OFF the pump or controllable, inline valves after initial activation of the UA control. A level sensor in the tank alerts the user via a user display. A pressurized system can be used. Multiple modules coupled together are controlled by a master module with master controls.

A method of treating nail infections that uses nail protein removing compositions to reduce cell to cell cohesion; antimicrobial composition to reduce surface tension, inhibit spores, and attack infection cell membranes; an enclosure capable of heating the antimicrobial composition above nail temperature and capable of dispensing antimicrobial composition to infected nails.

A vertical motion adjuster for a thermotherapy device includes a conveyance unit provided with a movable member configured to move along a mat, a support unit having a first side and a second side, the first side rotatably coupled to one side of the conveyance unit, and an elevation unit installed between the conveyance unit and the support unit and configured to adjust an angle of inclination of the support unit by raising or lowering the second side of the support unit such that the second side of the support unit is moved in the shape of an arc.

A device includes light sources, electromagnetic field generators, and vibration components to apply a variety of treatment regimens to a living animal organism, including a human person or a body part of a person. The light and electromagnetic therapy are applied at frequencies which have physiological effects, and which can be combined to induce lipolysis, stimulate muscle, and achieve other effects. Feedback is used to dynamically adjust the intensity, duration, and other parameters of the light, electromagnetic, and vibration treatment modalities.

The cryogenic chamber has a treatment cabin (12) cooled by a cooling factor in the form of liquid air or liquid nitrogen distributed through the nozzle system (17). The treatment cabin (12), which can be open at the top or equipped with a roof, is available in a stationary or mobile version, namely it can be placed on a trailer and is transitional, namely it has a rear door (2) and a front door (1) and its side walls have outlet openings (8, 11) and a grid (7) intended for introducing the cooling factor from the cooling chamber (16), whereas in the treatment cabin (12) at the front and at the back there are elements (18) blocking the animal taking the treatment. The shape of the treatment cabin (12) is based on a rectangle. The chamber is equipped with roller blinds (4, 5) and its operation is controlled by a panel with a monitor as well as a power supply and control system (3).

The Transformation Chamber is unique in that it combines three additional elements to a regular cryotherapy session and is the last portion of the session. The Transformation Chamber has infrared and near infrared lighting that works in-conjunction with a guided meditation, and vibration. With all elements combined in one device allows client's to achieve more in less time in one place.

A heat exchange module having a heat transfer fluid channel and a heat transfer plate in heat transfer relation with fluid in the channel. The reference side of a thermoelectric cooler (TEC) is in thermal contact with the plate. A heat transfer tile is in thermal contact with a user side of the TEC. The module is configured to be operatively positionable with the tile in heat transfer relation with skin of a patient.