Patent Description:
Cryogenic physical therapy, also known as cryogenic sauna, means that a human body enters an extremely low temperature environment and maintains for <NUM>-<NUM> minutes, after cryogenic freezing stimulates skins, the body releases endorphins, thereby enabling the body to accelerate blood circulation, continuously burn fat, increase skin elasticity, restore from muscle fatigue and achieve other functions and effects. A cryogenic physical therapy device such as a cryogenic physical therapy cabin refers to a refrigeration device with an extremely low temperature for providing physical therapy for the human body. In related technologies, the cryogenic physical therapy cabin cannot adjust the operation state thereof according to a user adjustment instruction, and the intelligence level thereof is relatively low.

<CIT> discloses an ultracold sauna room device. The ultracold sauna room device comprises a sauna room unit and a refrigerating unit for refrigerating the sauna room unit; the sauna room unit comprises a sauna room; the sauna room comprises a top plate, a bottom plate and wall plates; a room door is arranged on one wall plate; the refrigerating unit is a unit automatically laminating refrigerating machine, and an evaporator of the unit automatically laminating refrigerating machine is located at the upper part of the sauna room; a fan is arranged at the top part of the sauna room, and an air return wall is arranged in the sauna room; a louver is arranged at the lower part of the air return wall, a gap is formed between the top part of the air return wall and the front of the top plate, and an air return passage is formed between the air return wall and the respective wall plate; the refrigerating unit is used for refrigerating the sauna room unit, the fan in the sauna room is used for enabling cold air of the evaporator to blow down, and the air with a high temperature in the sauna room enters the air return wall through the louver of the air return wall, then goes upwards, and is blown down by the fan, so as to form a circulating system, so that a more comprehensive, faster and more uniform refrigerating in the sauna room is realized.

<CIT> discloses a cryosauna for recreational procedures. The cryosauna for recreational procedures comprises a source of liquid nitrogen, a unit to prepare an operating mixture, and a patient box. The unit has thermo insulated evaporator and mixer in fluid communication with each other. The evaporator is connected via a valve to the source of liquid nitrogen, the mixer through a fan is open to ambient air and connected with the patient box. The patient box is made roofless and comprises a floor, walls, and an adjustable stage to accommodate the patient. The cryosauna also comprises a recycle stream bypass channel connecting the patient box and evaporator and is provided with a three-way discharge valve, a first and a second discharge ducts connecting the patient box with inputs of the discharge valve and a duct fan installed at an output of the discharge valve.

Embodiments of the present application provide a cryogenic physical therapy cabin and a cryogenic physical therapy cabin system, which can adjust operation states thereof according to a user adjustment instruction and improve the intelligence level thereof. The specific technical solution is as follows:
The invention is set out in the appended set of claims.

In order to more clearly describe the technical solution of the embodiments of the application or of the prior art, drawings needed in the embodiments and the prior art will be briefly described below.

For ease of description, spatial relative relationship terms may be used in the description to describe the relationship of an element or a feature to another element or another feature as shown in the figures, such as "interior," "exterior," "rear", "top", "bottom", "below", "under", "above", "over", etc. These spatial relative relationship terms mean to include different orientations of devices in use or operation, except for those depicted in the drawings.

The technical solution of the embodiments of the application will be clearly and fully described in detail with reference to the drawings of the embodiments of the present application. Obviously, the embodiments described herein are only some instead of all of the embodiments of the present application. Based on the embodiments the application, all other embodiments obtained by those of ordinary skills in the art based on the application are within the scope of the present application.

In embodiments in the first aspect of the application, a cryogenic physical therapy cabin <NUM> is provided, as shown in <FIG> and <FIG>. The cryogenic physical therapy cabin <NUM> includes: a cabin body <NUM>; a cabin door <NUM>, which is hinged with the cabin body <NUM> to form at least one sauna room; a refrigeration module, which includes an evaporator <NUM> arranged on an inner wall of the cabin body <NUM>; an air outlet module, which is arranged on the cabin body <NUM> and includes fan blades <NUM> and a fan <NUM> electrically connected to the fan blades <NUM>, wherein the fan <NUM> is configured to drive a rotation of the fan blades <NUM> to generate a circulating airflow inside the sauna room; and a main control module, which includes a controller electrically connected to the fan <NUM> and the refrigeration module, wherein the controller is configured to receive a user adjustment instruction and adjust operation states of the air outlet module and the refrigeration module according to the user adjustment instruction.

After connecting the cabin body <NUM> and the cabin door <NUM>, the cabin has a substantially rectangular overall shape. Preferably, surface layers of the cabin body <NUM> and the cabin door <NUM> are made of a metal plate. Optionally, a plurality of thermal insulation layers can be arranged between inner layers and outer layers of the cabin body <NUM> and the cabin door <NUM>. The thermal insulation layers are made of a material with a lower thermal conductivity, such as a polyurethane foam material or a vacuum insulation plate, and thus the sealing and insulation of the sauna room can be increased. Optionally, as shown in <FIG>, the bottom of the cabin body <NUM> is arranged with casters to facilitate movement. The shape of the cryogenic physical therapy cabin is not limited in the application. For example, the cabin body <NUM> and the cabin door <NUM> can be enclosed in a cube, a cylinder, an irregular polyhedron, or an egg shape.

The refrigeration module is configured to cool the air in the sauna room. Specifically, the refrigeration module can maintain the sauna room at a low temperature through the evaporation and the compression of a circulating refrigerant. The evaporator <NUM> is arranged on the inner wall of the cabin body <NUM>. the refrigerant absorbs a large amount of heat during the evaporation of the evaporator <NUM> to achieve cooling of the air in the sauna room. When the cryogenic physical therapy cabin includes one sauna room, the temperature range of the sauna room can be -<NUM> to - <NUM>.

Optionally, the refrigeration module can also include a compressor, a condenser and an expansion valve, etc., so that the evaporation and compression of the refrigerant are carried out circularly. The compressor, the condenser, and the expansion valve are arranged on an outer wall of the cabin body <NUM>. The airflow generated by the air outlet module can produce a forced convection of the air in the sauna room, and generate a heat exchange with the cold air close to the evaporator <NUM>, so that the temperature in the sauna room is distributed more evenly. Preferably, as shown in <FIG>, the fan blades <NUM> are arranged inside the cabin body <NUM>, and the fan <NUM> is arranged outside the cabin body <NUM>, which can reduce the probability that the fan <NUM> can not be activated again due to an extremely low temperature inside the cabin body <NUM>, and is convenient for extending the continuous operation time of the fan <NUM>.

The main control module can be an assembly in which hardware such as a processor, a memory, etc. is integrated. The main control module can independently perform functions such as a data storage, a signaling interaction and a processing function on the operation parameters of the refrigeration module and the air outlet module, so as to control the refrigeration module and the air outlet module.

The user adjustment instruction can be input through an input component integrated into the main control module. The user adjustment instruction can also be input through terminals such as mobile phones and remote controllers that establish communication connections with the main control module, wherein, the input component can be a physical switch, a button, a touchpad, etc. The input component can be set according to the application scenario of the cryogenic physical therapy cabin, and is not limited in this application. The user adjustment instruction include setting the physical therapy temperature, physical therapy wind speed, and physical therapy time according to the user's personal needs.

In the cryogenic physical therapy cabin <NUM> provided in the embodiment of this application, the cabin body <NUM> is integrated with a refrigeration module, an air outlet module, and a main control module. The refrigeration module can cool the sauna room in the cryogenic physical therapy cabin <NUM> to form an extremely low temperature environment that can be used for single or multiple people for physical therapy. During the use of cryogenic physical therapy cabin <NUM>, the main control module can adjust the operation states of the refrigeration module and the air outlet module connected to it according to the user adjustment instruction. The user adjustment instruction includes a physical therapy temperature, a physical therapy wind speed, physical therapy time, etc. set according to the user's personal preferences and tolerance, to make the temperature and air volume inside the sauna room more suitable for the user's needs. In addition, after users enter the sauna room for physical therapy, the main control module can further adjust the corresponding operation state according to different user adjustment instructions, further adapting to user needs. According to a specific user adjustment instruction, the main control module can adjust the temperature in the cryogenic physical therapy cabin <NUM> to a state corresponding to this user adjustment instruction. The internal state of the cryogenic physical therapy cabin <NUM> can be adjusted according to different user needs, which can increase the intelligence level of the cryogenic physical therapy cabin <NUM>. In addition, the air outlet module is arranged in the cryogenic physical therapy cabin <NUM>, so that cooling in the sauna room is more comprehensive, faster, and more uniform, which is conducive to rapid cooling of the sauna room and shortening the waiting time of the user.

In some embodiments of the present application, as shown in <FIG>, the cryogenic physical therapy cabin <NUM> further includes a first heater <NUM>, which is arranged on the evaporator <NUM> and electrically connected to the controller, and the controller is further configured to adjust the operation state of the first heater <NUM>.

The first heater <NUM> generates heat after being powered on, causing the frost on the surface of the evaporator <NUM> to melt. In the embodiment of this application, defrosting treatment is performed on the evaporator <NUM> by fixing the first heater <NUM> on the evaporator <NUM>, thereby reducing the probability that the cooling effect of the evaporator <NUM> is reduced due to frost formed on the surface.

The power on and off of the first heater <NUM> are controlled by the controller. Specifically, the controller can start or stop the first heater <NUM> at a fixed time. Optionally, within a heating cycle, the heating duration of the first heater can be <NUM> to <NUM> minutes to improve the defrosting effect of the first heater.

Optionally, while the first heater <NUM> is activated, the controller can issue an instruction to shut down the fan <NUM>, stopping the rotation of the fan blades <NUM> and reducing the energy consumption of the cryogenic physical therapy cabin <NUM>.

The first heater <NUM> can be located below the evaporator <NUM> or inside the evaporator <NUM>. For example, the evaporator <NUM> can include multiple fins and evaporation tubes arranged in the fins. The first heater <NUM> can include a straight tube heater and a bent tube heater. The first heater <NUM> in a straight tube shape is inserted into the fin through hole <NUM> of the evaporator <NUM>, and the first heater <NUM> in a bent tube shape is wound around the fin through hole <NUM> of the evaporator <NUM>. The shape of the first heater <NUM> or its fixed position on the evaporator <NUM> are not limited in this application.

In other embodiments, the heating and defrosting treatment of the evaporator <NUM> can also be achieved by transporting the high-temperature refrigerant in the compressor to the evaporator <NUM>. The specific process will not be repeated here.

In some embodiments of the present application, as shown in <FIG>, the cryogenic physical therapy cabin <NUM> further includes a first temperature sensor <NUM>, which is arranged on the inner wall of the cabin body <NUM>, and is electrically connected to the controller and configured to send the detected first temperature value to the controller. The controller is further configured to adjust the rotation speed of the fan <NUM> according to the first temperature value and the user adjustment instruction. The user adjustment instruction includes a target apparent temperature, a physical therapy temperature, a physical therapy wind speed, etc. required by the user.

Further, the user adjustment instruction includes a preset target apparent temperature, and the controller being further configured to adjust the rotation speed of the fan according to the first temperature value and the user adjustment instruction, includes: the controller being further configured to obtain the current first rotation speed of the fan, and calculate a current actual apparent temperature according to the first rotation speed and the first temperature value, the controller being further configured to calculate a difference value between the actual apparent temperature and the target apparent temperature, and adjust the rotation speed of the fan to the second rotation speed according to the difference value.

In the embodiment of the application, after receiving the user adjustment instruction, the controller determines the physical therapy wind speed corresponding to the target apparent temperature according to the target apparent temperature required by the user, and adjusts the rotation speed of the fan <NUM> to the first rotation speed according to the physical therapy wind speed. The controller can also adjust the cooling capacity of the refrigeration module according to the user's desired physical therapy temperature and maintain it for the first preset duration. The first temperature sensor <NUM> obtains the first temperature value in real-time in the sauna room and sends the first temperature value to the controller. The controller calculates the current actual apparent temperature according to the first temperature value and the first rotation speed, determines the preset target apparent temperature according to the physical therapy temperature and physical therapy wind speed, and obtains the difference value between the actual apparent temperature and the preset target apparent temperature, and then adjusts the rotation speed of the fan <NUM> to the second rotation speed according to the above difference value. The actual apparent temperature is the apparent temperature actually felt by the user in the sauna room, and the preset target apparent temperature is the apparent temperature calculated by the controller according to the user adjustment instruction. The first preset duration, first rotation speed, and second rotation speed can be set according to actual needs, such as the powers of the refrigeration module and the fan, and the temperature of the interior of the cryogenic physical therapy cabin, which is not limited in this application.

The apparent temperature refers to the degree of cold and warm that the human body feels, which is converted into a corresponding temperature. The apparent temperature will be comprehensively affected by the air temperature, wind speed and relative humidity. The relative humidity in the cryogenic physical therapy cabin <NUM> is kept in a relatively stable range, and the influence of the relative humidity on the apparent temperature is negligible. The contrast relationship among the wind speed, air temperature and apparent temperature in the cryogenic physical therapy cabin <NUM> is shown in Table <NUM>, wherein, the wind speed can be the rotation speed of the fan. According to Table <NUM>, the higher the wind speed, the lower the apparent temperature. For example, the air temperature in the cryogenic physical therapy cabin <NUM> is -<NUM>, and the apparent temperature of - <NUM> can be reached when the wind speed is controlled at <NUM>/s.

During the process of using the cryogenic physical therapy cabin <NUM> for physical therapy, users will bring in a large amount of hot air when opening the door, and the human body will dissipate a lot of heat in the cryogenic physical therapy cabin <NUM>, causing certain fluctuations in the temperature inside the sauna room. By adjusting the wind speed, the user's actual apparent temperature can be quickly changed, so that the actual apparent temperature can quickly reach the preset target apparent temperature, achieving the same effect of cryotherapy. Compared with the method of adjusting the refrigerating capacity of the refrigeration module, the method of adjusting the apparent temperature by changing the wind speed can greatly reduce the energy consumption, which is conducive to improving the effect of physical therapy.

When the controller determines that the temperature in the sauna room is high according to the first temperature value, the controller sends an instruction for increasing the rotation speed to the fan <NUM>, which increases the rotation speed of the fan <NUM> and the wind speed in the sauna room, which is conducive to reducing the user's actual apparent temperature. On the contrary, when the controller determines that the temperature in the sauna room is low according to the first temperature value, the controller sends an instruction for reducing the rotation speed to the fan <NUM>, which reduces the rotation speed of the fan <NUM> and the wind speed in the sauna room, which is conducive to increasing the user's actual apparent temperature.

During the physical therapy in the cryogenic physical therapy cabin <NUM>, when the user's tolerance to the low temperature in the sauna room is low, the user can input a smaller physical therapy wind speed through the main control module, thereby reducing the wind speed in the sauna room and improving the user's actual apparent temperature. When the user's tolerance to the low temperature in the sauna room is high, the user can input a larger physical therapy wind speed through the main control module, thereby increasing the wind speed in the sauna room and reducing the user's actual apparent temperature.

The embodiment of this application achieves real-time adjustment of the temperature and air volume in the sauna room through the joint action of the first temperature sensor <NUM> and the controller, further improving the intelligence level of the cryogenic physical therapy cabin <NUM> and bringing users a more comfortable user experience.

In other embodiments, the controller is further configured to adjust the first heater <NUM> based on the first temperature value. The controller obtains the change rate of the first temperature value based on its variation over a certain period of time. When the change rate of the first temperature value is detected to be lower than a threshold, the controller controls the first heater <NUM> to power on, thereby causing the evaporator <NUM> to frost or melt ice.

In some embodiments of the application, as shown in <FIG>, the cryogenic physical therapy cabin <NUM> further includes a door closer <NUM> and a sealing strip <NUM>. One side of the door closer <NUM> is fixedly connected with the cabin door <NUM>, the other side of the door closer <NUM> is fixedly connected with the cabin door <NUM>, and the door closer <NUM> is configured to drive the cabin door <NUM> to move in a direction close to the cabin door <NUM>; the sealing strip <NUM> is arranged around the surface edge at one side of the cabin door <NUM> towards the cabin body <NUM>.

In the embodiment of the application, the door closer <NUM> can drive the door <NUM> to rotate in a direction towards the cabin body <NUM>, and the force exerted by the door closer <NUM> on the cabin door <NUM> can make the cryogenic physical therapy cabin <NUM> drive the cabin door <NUM> to close without manual operations, thus greatly reducing the entry of air and water vapor, reducing frost in the cryogenic physical therapy cabin <NUM> and saving energy. The sealing strip <NUM> is disposed between the cabin door <NUM> and the cabin body <NUM>, playing a role of sealing and isolating the air flow between the interior and exterior of the cryogenic physical therapy cabin <NUM>.

Optionally, the door closer <NUM> can be a hydraulic device installed on the upper portion of the cabin door <NUM>, which acts like a spring. When the cabin door <NUM> is opened, the door closer <NUM> can automatically close the cabin door <NUM> by releasing the elastic energy after compression, which can ensure that the cabin door <NUM> is closed to the initial position accurately in time after opened.

Optionally, the sealing strip <NUM> has multiple sealing lips arranged in parallel, all of which are closely abutted against the inner wall of the cabin body <NUM>, thereby increasing the contact area between the sealing strip <NUM> and the sealing structure between the cabin door <NUM> and the cabin body <NUM>, allowing the sealing strip <NUM> to fully contact the sealing structure, which is conducive to improving the sealing performance between the cabin door <NUM> and the cabin body <NUM>.

In some embodiments of the present application, as shown in <FIG>, the cryogenic physical therapy cabin <NUM> further includes a door lock structure <NUM>, which includes a lock body portion <NUM> and a lock shaft portion <NUM>. The lock body portion <NUM> is arranged on the cabin body <NUM>, and the lock shaft portion <NUM> is arranged on the cabin door <NUM>. Alternatively, the lock shaft portion <NUM> is arranged on the cabin body <NUM>, and the lock body portion <NUM> is arranged on the cabin door <NUM>. The door lock structure <NUM> is electrically connected to the controller, which regulates the connection or disconnection of the lock body portion <NUM> and the lock shaft portion <NUM>.

Furthermore, as shown in <FIG> and <FIG>, the door lock structure <NUM> includes a lock body portion <NUM> and a lock shaft portion <NUM>. The lock body portion <NUM> includes a fixed part <NUM> and a slider <NUM> that is slidably connected to the fixed part <NUM>. The slider <NUM> includes a first support <NUM> and an electromagnet <NUM> fixed on the first support <NUM>. The slider <NUM> further includes a connecting plate <NUM>, which includes a bent hook portion <NUM> and a suction plate portion <NUM>. The connecting plate <NUM> can be relatively rotatably connected to the first support <NUM>, to enable the suction plate portion <NUM> to move in a direction close to or away from the electromagnet <NUM>. The bent hook portion <NUM> has a first receiving slot for receiving the lock shaft portion <NUM> when the door lock structure <NUM> is locked. The lock body portion <NUM> is arranged on the cabin body <NUM>, and the lock shaft portion <NUM> is arranged on the cabin door <NUM>. Alternatively, the lock shaft portion <NUM> is arranged on the cabin body <NUM>, and the lock body portion <NUM> is arranged on the cabin door <NUM>. The controller is electrically connected to the electromagnet <NUM>, and is configured to control the power on or off of the electromagnet <NUM>.

Specifically, when the cabin door <NUM> moves close to the cabin body <NUM>, the connecting plate <NUM> is subjected to an external force and rotates relative to the first support <NUM>, causing the lock shaft portion <NUM> to be placed in the first receiving slot. The controller controls the electromagnet <NUM> to be energized, causing the electromagnet <NUM> to be connected to the suction plate portion <NUM> through attraction, and the connecting plate <NUM> to be fixed relative to the first support <NUM>, and the lock body portion <NUM> to be fixedly connected to the lock shaft portion <NUM>. At the same time, the controller controls the slider <NUM> to slide relative to the fixed part <NUM>, thereby driving the cabin door <NUM> to move further closer to the cabin body <NUM> until the cabin door <NUM> is tightly connected to the cabin body <NUM>. When it is necessary to reopen the cabin door <NUM>, the controller controls the electromagnet <NUM> to power off, and the connecting plate <NUM> can rotate relative to the first support <NUM>, causing the lock shaft portion <NUM> to detach from the first receiving slot, achieving the opening of the cabin door <NUM>. The cryogenic physical therapy cabin <NUM> adopts a door lock structure <NUM> to connect the cabin door <NUM> and the cabin body <NUM>. The opening or closing of the door lock structure <NUM> can be controlled by the controller. Therefore, in the case of a unmanned cryogenic physical therapy cabin <NUM>, the controller can control the connection or disconnection of the lock body portion <NUM> and the lock shaft portion <NUM> based on the internal situation of the cryogenic physical therapy cabin <NUM>, thereby controlling the opening or closing of the cabin door <NUM>, reducing the probability that users inside the cryogenic physical therapy cabin <NUM> are unable to leave for a long time due to the failure of the cabin door <NUM> to open in time, which can improve the safety of the cryogenic physical therapy cabin <NUM> during use.

Furthermore, as shown in <FIG> and <FIG>, the fixed part <NUM> includes a first mounting plate <NUM> and a first side plate <NUM> fixedly connected to the first mounting plate <NUM>. The first mounting plate <NUM> is configured for fixedly connecting to the cabin body <NUM> or the cabin door <NUM>. The first side plate <NUM> is provided with a first guide rail <NUM>, and the extension direction of the first guide rail <NUM> is perpendicular to that of the first mounting plate <NUM>. The slider <NUM> further includes at least one first pulley <NUM>, which is arranged on the first support <NUM> and is slidably connected to the first guide rail <NUM>.

Specifically, as shown in <FIG> and <FIG>, the fixed part <NUM> can be fixed on the cabin door <NUM> or the cabin body <NUM> through the first mounting plate <NUM>. The first guide rail <NUM> cooperates with the first pulley <NUM> to slide the slider <NUM> along the extension direction of the first guide rail <NUM>, providing guidance for the sliding of the slider <NUM>. Driven by the first pulley <NUM>, the slider <NUM> slides on the fixed part <NUM>, further locking the cabin body <NUM> and the cabin door <NUM>.

Furthermore, as shown in <FIG> and <FIG>, the fixed part <NUM> further includes a second side plate <NUM>, which is connected to the first mounting plate <NUM> and is arranged parallel to the first side plate <NUM>, and on which a second guide rail <NUM> is provided. The slider <NUM> further includes at least one second pulley <NUM>, which is arranged on the first support <NUM> and is slidably connected to the second guide rail <NUM>.

Furthermore, as shown in <FIG> and <FIG>, the first guide rail <NUM> and the second guide rail <NUM> form a dual guide rail structure, reducing the probability of derailment of the slider <NUM> during the sliding process on the fixed part <NUM>, increasing the sliding stability of the slider <NUM>, and thereby enhancing the stability of the door lock structure <NUM>. The first mounting plate <NUM>, the first side plate <NUM>, and the second side plate <NUM> can jointly form a receiving space, within which some structures of the slider <NUM> can slide back and forth along the extension direction of the guide rail.

Furthermore, as shown in <FIG> and <FIG>, the cryogenic physical therapy cabin further includes a driving mechanism <NUM>, which includes a gear <NUM> and a gear rack <NUM>. The gear <NUM> is arranged on the fixed part <NUM>, the gear rack <NUM> is arranged on the first support <NUM>, and the gear <NUM> is meshed with the gear rack <NUM>. Alternatively, the gear <NUM> is arranged on the first support <NUM>, and the gear rack <NUM> is arranged on the fixed part <NUM>. The driving mechanism <NUM> further includes an electric motor <NUM> connected to the gear <NUM>.

Specifically, the electric motor <NUM> provides power to drive the gear <NUM> to rotate. The meshing transmission between the gear <NUM> and the gear rack <NUM> can enable the gear rack <NUM> to drive the slider <NUM> to move in a straight line, making the door lock structure <NUM> more compact in structure and enhancing the reliability of the operation process of the door lock structure <NUM>. A second mounting plate <NUM> is installed between the first side plate <NUM> and the second side plate <NUM>, and the gear <NUM> is installed on the second mounting plate <NUM>. The electric motor <NUM> can be a stepper electric motor <NUM>, which is installed on a side of the second mounting plate <NUM> away from the gear <NUM>.

Furthermore, as shown in <FIG> and <FIG>, the slider <NUM> further includes a first elastic element <NUM>, one end of which is fixedly connected to the first support <NUM> and the other end of which is fixedly connected to the suction plate portion <NUM>.

In the embodiment of the present application, the first elastic element <NUM> is connected to the first support <NUM> and the suction plate portion <NUM>, which can limit the rotation angle of the connecting plate <NUM>, and also can reset the connecting plate <NUM> through its own rebound force after the lock shaft portion <NUM> drives the connecting plate <NUM> to rotate, thereby smoothly connecting or disconnecting the lock shaft portion <NUM> and the locking body portion <NUM>. The first elastic element <NUM> can include a spring, an elastic strip, etc..

Furthermore, as shown in <FIG>, the cabin body <NUM> further includes a limit switch <NUM>, which is configured to detect the distance between the cabin door <NUM> and the cabin body <NUM>.

When the user or the door closer <NUM> drives the cabin door <NUM> close to the cabin body <NUM> to within the sensing range of the limit switch <NUM>, the limit switch <NUM> closes to energize the electromagnet <NUM>, thus connecting the lock body portion <NUM> and the lock shaft portion <NUM>, and the lock structure <NUM> is in a locked state. Limit switch <NUM> can timely detect the closed state of the cabin door <NUM>, improving the intelligence of the door lock structure <NUM> and the cryogenic physical therapy cabin <NUM>.

In some embodiments of the present application, as shown in <FIG>, the cryogenic physical therapy cabin <NUM> further includes a human body sensor <NUM> and a timer, which are electrically connected to the controller. The human body sensor <NUM> is arranged in the sauna room, and the controller is further configured to control the timer on or off according to the sensing result of the human body sensor <NUM>. The human body sensor <NUM> can timely detect the situation of the user inside cabin body <NUM>, improving the intelligence of the cryogenic physical therapy cabin <NUM>.

In this embodiment, the human body sensor <NUM> is configured to detect whether there is anyone in the sauna room. When the controller determines that a user has entered the sauna room based on the detection results of the human body sensor <NUM>, the controller starts the timer to start timing. On the contrary, when the controller determines that the user has left the sauna room based on the detection results of the human body sensor <NUM>, the controller controls the timer to stop timing.

In some embodiments of the present application, the controller is further configured to control the operation states of the air outlet module and the refrigeration module based on the timing duration of the timer. When the timing duration of the timer exceeds a second preset time or a user's preset physical therapy time, the controller can control the air outlet module and refrigeration module to turn off, further improving the intelligence and safety performance of the cryogenic physical therapy cabin <NUM>, wherein, the second preset duration can be the maximum duration for which the user will not be in danger while in the sauna room.

Furthermore, the controller is further configured to control the connection or disconnection of the lock body portion <NUM> and the lock shaft portion <NUM> based on the timing duration of the controller. By combining the timer, the door lock structure <NUM>, and the controller, the intelligence and safety performance of the cryogenic physical therapy cabin <NUM> have been further improved.

In this embodiment, the timing duration of the timer is determined according to the user adjustment instruction or the second preset duration stored in the controller. After the timing duration of the timer exceeds the second preset duration or the user's preset physical therapy time, the controller controls to disconnect the electrical supply to the electromagnet <NUM>, disconnects the lock body portion <NUM> and the lock shaft portion <NUM>, and the door lock structure <NUM> is in an unlocked state. The user can push and open the cabin door <NUM> to leave the cryogenic physical therapy cabin <NUM>, which can reduce the probability of danger due to that the user forgets the usage time and can further improve the safety of the cryogenic physical therapy cabin during use.

Furthermore, the controller can restart the timer after a new user enters the cryogenic physical therapy cabin, and repeat the action of controlling to disconnect the electrical supply to the electromagnet <NUM> when the user's usage time reaches the second preset time or the user's preset physical therapy time.

In some embodiments of the present application, the cryogenic physical therapy cabin <NUM> further includes an alarm, which is electrically connected to the controller. The controller is further configured to control the alarm to provide an alarm when the timing duration exceeds the preset alarm duration. The controller adjusts the alarm to send an alarm signal to remind the duty personnel, wherein the alarm signal can be sound, light, etc. Through the joint action of the alarm and the controller, the alarm can send an alarm signal to prompt the duty personnel to handle it in a timely manner, reducing the probability of frostbite of users and improving the safety performance of the cryogenic physical therapy cabin <NUM>.

In this embodiment, when the timing duration of the timer reaches a preset alarm duration and the human body sensor <NUM> detects that the user in the sauna room has not left the sauna room, the controller can also determine whether the timing duration exceeds the preset alarm duration based on the detection results of the human body sensor <NUM>. After the timing duration exceeds the preset alarm duration, the controller is further configured to adjust the operation states of the air outlet module, the refrigeration module, and the first heater <NUM>. The controller adjusts the refrigeration module to stop cooling, the controller adjusts the air outlet module to stop the rotation of the fan <NUM>, and the controller activates the first heater <NUM> to start heating, so that the sauna room is recovered to a room temperature, which reduces the probability of danger due to that the user is in a low temperature environment for a long time, and improves safety.

In other implementations, alarm signals can also be output through terminals such as mobile phones and computers that establish communication connections with the main control module. The specific process will not be repeated here.

In some embodiments of the present application, as shown in <FIG> and <FIG>, the cryogenic physical therapy cabin <NUM> further includes an emergency switch <NUM>, which is configured to convert the lock body portion <NUM> and lock shaft portion <NUM> from a connected state to a disconnected state. By providing the emergency switch <NUM>, it is beneficial to improve the safety performance of the cryogenic physical therapy cabin <NUM>.

In this embodiment, as shown in <FIG> and <FIG>, the emergency switch <NUM> further includes a connector <NUM>, an eccentric wheel <NUM>, and a microswitch <NUM>. The emergency switch <NUM> is connected to one end of the connector <NUM>, the other end of the connector <NUM> is connected to the eccentric wheel <NUM>, the eccentric wheel <NUM> is rotatably connected to the electromagnet <NUM>, the microswitch <NUM> is fixed on the eccentric wheel <NUM>, and the microswitch <NUM> is electrically connected to the electromagnet <NUM>. Under the action of an external force, the emergency switch <NUM> drives the connector <NUM> to move, which in turn drives the eccentric wheel <NUM> to rotate. The eccentric wheel <NUM> triggers the microswitch <NUM>, which in turn causes the electromagnet <NUM> to power off and unlocks the door lock structure <NUM>. The connector <NUM> can be a steel wire or a steel rod.

Furthermore, the emergency switch <NUM> includes an internal emergency switch. The internal emergency switch is arranged inside the cabin body <NUM>, and is connected to connector <NUM>. During use, if the user feels unwell in the cryogenic physical therapy cabin <NUM>, he/she can unlock the door lock structure <NUM> by pressing the internal emergency switch, and then push and open the cabin door <NUM> to leave the sauna room, ending the physical therapy.

Furthermore, the emergency switch <NUM> further includes an external emergency switch. The external emergency switch is installed outside the cabin body <NUM>, and is connected to the connector <NUM>. In other implementations, the external emergency switch is electrically connected to the controller. After the controller detects the activation of the external emergency switch, the controller controls the door lock structure <NUM> to unlock. After the user's physical therapy time in the cryogenic physical therapy cabin <NUM> exceeds the preset alarm time, the alarm will send an alarm signal. After receiving the alarm signal, the duty personnel can press the external emergency switch to open cabin door <NUM> to rescue the user.

As shown in <FIG> and <FIG>, the cabin door <NUM> further includes a glass window structure <NUM>, which is arranged on the cabin door <NUM>. The glass window structure <NUM> includes at least two pieces of glass fixedly connected and arranged in parallel with each other, and there is an air gap between the adjacent two pieces of glass. An electric heater is arranged on the first glass <NUM> in the at least two pieces of glass close to the sauna room. The controller is electrically connected to the electric heater, and is configured to control the operation state of the electric heater.

During the use of the cryogenic physical therapy cabin <NUM>, the electric heater is energized to heat the glass window structure <NUM>. The temperature of the first glass <NUM> connected to the sauna room is higher than that of the sauna room, and preferably, the temperature of the first glass <NUM> is <NUM> to <NUM> higher than that of the sauna room. Moreover, maintaining the temperature of the first glass <NUM> within a certain range can effectively improve the frosting or fogging of the glass window structure <NUM>, reduce the obstruction of frost layers and other factors to the glass window structure <NUM>, and enable duty personnel to observe the internal situation of the cryogenic physical therapy cabin <NUM> in real-time through the glass window structure <NUM>, thereby improving the safety performance of the cryogenic physical therapy cabin <NUM>.

Furthermore, a piece of second glass <NUM> further from the sauna room in the at least two pieces of glass is equipped with an electric heater. Providing an electric heater on the second glass <NUM> is beneficial for reducing the probability of mist or dew appearing on the surface of the second glass <NUM>. In addition, the electric heater can also generate heat when dew is already formed on the second glass <NUM>, thereby quickly evaporating the dew on the glass window structure <NUM> and reducing the obstruction of dew and other objects to the glass window structure <NUM>, so as to enable duty personnel to observe the internal situation of the cryogenic physical therapy cabin <NUM> in real-time through the glass window structure <NUM>, further improving the safety performance of the cryogenic physical therapy cabin <NUM>.

Furthermore, the electric heater includes a heating coating arranged on at least one side surface of the first glass <NUM>, and the electric heater further includes an electric conductor <NUM>, which is electrically connected to the heating coating and is electrically connected to the controller. The heating coating can include a semiconductor coating, etc. The controller controls the energizing and the heating of the heating coating by energizing the electric conductor <NUM>. The electric conductor <NUM> is located between two pieces of glass, so that the overall visible area of the first glass <NUM> will not be reduced due to the obstruction of the electric conductor <NUM>, resulting in a relatively better light transmission performance of the first glass <NUM>.

Furthermore, the electric heater includes a heating wire arranged on the first glass <NUM>, which is electrically connected to the controller. The heating wire has less obstruction to the glass window structure <NUM>, which can reduce the impact on the transparency of the glass window structure <NUM>. In addition, the heating wires are evenly distributed on the first glass <NUM>, which has the advantage of uniform heating.

Furthermore, the glass window structure <NUM> includes four pieces of glass fixedly connected and arranged parallel to each other. Four pieces of glass are installed in the glass window structure <NUM>, and multi-layer glass can improve the airtightness and thermal insulation performance of the glass window structure <NUM>.

Furthermore, the adjacent two pieces of glass are connected by bonding. In the glass window structure <NUM>, a bonding layer can be provided between adjacent two pieces of glass. The adjacent two pieces of glass are connected by bonding, which has high stability and low complexity, and low production cost. In addition, the adhesive layer has good thermal insulation performance, which can further improve the thermal insulation effect of the glass window structure <NUM>, and thus further improve the thermal insulation performance of the cryogenic physical therapy cabin <NUM>.

In some embodiments of the present application, as shown in <FIG>, the cryogenic physical therapy cabin <NUM> further includes an intercom system <NUM>, a display screen <NUM>, and a camera <NUM>. The intercom system <NUM> includes a first intercom terminal located inside the cabin body <NUM> and a second intercom terminal located outside the cabin body <NUM>. The display side of the display screen <NUM> is located inside the cabin body <NUM>, and the camera <NUM> is located inside the cabin body <NUM>.

The camera <NUM> is used for real-time monitoring of the situation inside the sauna room, the intercom system <NUM> is used for users entering the sauna room to communicate with duty personnel, and the display screen <NUM> is configured to play safety prompts to users. Users who enter the cryogenic physical therapy cabin <NUM> for physical therapy can provide feedback to the duty personnel through the intercom system <NUM> at any time during use when encountering emergency situations. The duty personnel can also handle sudden situations inside the sauna room in a timely manner through the surveillance video of the camera <NUM>, which is beneficial for improving the safety performance of the cryogenic physical therapy cabin <NUM>.

In other implementation, as shown in <FIG>, emergency components, such as emergency cotton clothes, emergency glass hammers <NUM>, are further equipped inside the cabin body <NUM>. When the door lock structure <NUM> cannot be opened, the emergency cotton clothes are used for user warmth, and the emergency glass hammer <NUM> is used for users to break and escape from a window.

In some embodiments of the present application, as shown in <FIG>, the cryogenic physical therapy cabin <NUM> further includes a main control operation panel <NUM>, which is arranged on the outer wall of the cabin body <NUM>. The main control operation panel <NUM> is electrically connected to the controller, and is configured to receive the user adjustment instruction and send it to the controller. By providing the main control operation panel <NUM> in the cryogenic physical therapy cabin <NUM>, it is convenient for users to input the user adjustment instruction, which is conducive to improving the intelligence level of the cryogenic physical therapy cabin <NUM>.

In this embodiment, the main control operation panel <NUM> is integrated with a physical switch, a button, a touchpad, etc., as an input component for the user adjustment instruction. Optionally, the main control operation panel <NUM> is also equipped with display components that can be configured to display operating parameters such as the temperature inside the cabin body <NUM>, the wind speed of the air outlet module, and the cooling capacity of the refrigeration module, facilitating real-time monitoring of the operation state of the cryogenic physical therapy cabin <NUM> by the duty personnel.

In some embodiments of the present application, the main control operation panel <NUM> includes a central control module, a data acquisition module, a communication module, and a storage module, and the main control operation panel is electrically connected to the controller. When users first use the cryogenic physical therapy cabin <NUM>, they can store user information in the cryogenic physical therapy cabin <NUM> by operating the main control operation panel <NUM>. Afterwards, the cryogenic physical therapy cabin <NUM> can call the stored user information and adjust the cryogenic physical therapy cabin <NUM> into a user-desired operation state according to the user information, avoiding the need for users to repeatedly input user information before each therapy, improving the intelligence level of the cryogenic physical therapy cabin <NUM>.

In this embodiment, the central control module, the data acquisition module, the communication module, and the storage module are electrically connected and integrated with the main control operation panel <NUM>. The central control module, the data acquisition module, the communication module, and the storage module communicate with each other. The storage module is configured to store computer programs, and the central control module is configured to execute programs stored on the storage module. Specifically, the data acquisition module obtains user information and sends it to the central control module. The central control module receives user information, converts to-be-processed data into the user adjustment instruction based on the user information, and sends the user adjustment instruction to the controller. The controller controls and adjusts the operation states of the air outlet module and the refrigeration module based on the received the user adjustment instruction.

The user information includes user physical therapy needs, user accounts, user fingerprints, user face images, etc. User information can be obtained through the data acquisition module, which includes a fingerprint collector, a face recognition camera, and an input component integrated in the main control operation panel <NUM>. The main control operation panel <NUM> is communicated with the display screen <NUM> through signals. The main control operation panel <NUM> and the display screen <NUM> can also be configured to display information including user accounts, physical therapy temperatures, physical therapy wind speeds, physical therapy time, etc..

Optionally, the main control operation panel <NUM> can be configured to receive the user adjustment instruction input through mobile phones, remote controllers, and the like that establish communication connections with the main control operation panel <NUM>, thereby enabling the interaction between the cryogenic physical therapy cabin <NUM> and external terminals. Users can use external terminals to control the temperature and wind speed inside the sauna room, improving the convenience of operation.

In some embodiments of the present application, as shown in <FIG> and <FIG>, at least one air pressure balance hole <NUM> is provided in the cabin body <NUM>, and connects the interior and exterior of the cabin body <NUM>. At least one air pressure balance valve <NUM> is arranged in each air pressure balance hole <NUM>, and includes a second support <NUM> and an elastic sheet <NUM>. The second support <NUM> is abutted against the hole wall of the air pressure balance hole <NUM>, and at least one through hole <NUM> is provided in the second support <NUM>. The elastic sheet <NUM> is connected to the second support <NUM>, and along the axis direction of the air pressure balance hole <NUM>, the elastic sheet <NUM> covers at least one through hole <NUM>, and elastic sheet <NUM> is movable in a direction close to or away from the second support <NUM>. By providing the air pressure balance valve <NUM>, the air pressure inside the cryogenic physical therapy cabin <NUM> can be adjusted to maintain the air pressure the cryogenic physical therapy cabin <NUM> within a safe range.

In this embodiment, as preferred, the elastic sheet <NUM> is made of metal material. During the process of a user entering the sauna room of the cryogenic physical therapy cabin <NUM>, a large amount of warm air will be brought in when the cabin door <NUM> is opened. After the cabin door <NUM> is closed, the warm air is rapidly cooled by the cold air inside the sauna room, causing a decrease in the air pressure inside the sauna room. The pressures inside and outside cabin body <NUM> creates a pressure difference, and the external air pushes the elastic sheet <NUM> to deform and enters the cabin. When the air pressures inside and outside the cabin body <NUM> are balanced, the elastic sheet <NUM> utilizes its own elasticity to return to its original state, forming a hollow space to provide an insulation function.

Furthermore, as shown in <FIG> and <FIG>, the elastic sheet <NUM> includes a first portion and a second portion. The first portion is fixedly connected to the second support <NUM> and covers at least one through hole <NUM> along the axis direction of the air pressure balance hole <NUM>. The second portion can move in a direction close to or away from the second support <NUM>. Preferably, there are four elastic sheets <NUM>, and there are correspondingly four through holes <NUM>. During the process of external air entering the sauna room, the first portion remains fixed to the second support <NUM>, and the second portion moves towards the side away from the second support <NUM> under the action of air pressure, preventing the elastic sheet <NUM> from rotating along the axis direction of the air pressure balance hole <NUM>, which otherwise causes the second portion to leak out of the opening position of the through hole <NUM>, causes cold air inside the cabin body <NUM> to leak into the external space, reduces the refrigeration performance of the cryogenic physical therapy cabin <NUM>.

Furthermore, as shown in <FIG> and <FIG>, the air pressure balance valve <NUM> further includes a pressing sheet <NUM>, which is fixedly arranged on the side of the elastic sheet <NUM> away from the second support <NUM>, and the pressing sheet <NUM> is in contact with the first portion. Providing the pressing sheet <NUM> is beneficial for increasing the contact area between the first portion and the second support <NUM>, and improving the fixation effect between the first portion and the second support <NUM>.

Furthermore, as shown in <FIG>, the air pressure balance valve <NUM> further includes a bracket <NUM>, which is abutted against the elastic sheet <NUM>. The bracket <NUM> is located on the side of the elastic sheet <NUM> away from the second support <NUM>. Along the axis direction of the air pressure balance hole <NUM>, the orthographic projection of the bracket <NUM> covers the orthographic projection of the first portion, and the orthographic projection of the bracket <NUM> at least partially covers the orthographic projection of the second portion. The bracket <NUM> has a limiting effect on the displacement of the second portion towards the side away from the second support <NUM>, preventing the second portion from failing to be restored to its original state due to significant elastic deformation caused by the movement of the second portion, further improving the service life of the pneumatic balance valve <NUM>.

Furthermore, the air pressure balance valve <NUM> further includes a second elastic element, which is arranged between the second support <NUM> and the elastic sheet <NUM>, and through which the elastic sheet <NUM> moves in a direction close to or away from the second support <NUM>. The second elastic element can be a spring. Providing the second elastic element is beneficial for buffering the movement of the elastic sheet <NUM> under the action of air pressure, thereby reducing the deformation of the elastic sheet <NUM> and further improving the service life of the air pressure balance valve <NUM>.

In some embodiments of the present application, the refrigeration module includes a compressor refrigeration structure or a liquid nitrogen refrigeration structure. By installing a compressor refrigeration structure or a liquid nitrogen refrigeration structure as well as an evaporator <NUM> in the cryogenic physical therapy cabin <NUM>, it is possible to continuously provide extremely low physical therapy temperatures for the sauna room with good insulation performance, which is conducive to improving the refrigeration effect and further improving the user's physical therapy effect.

In this embodiment, when the refrigeration module adopts a compressor refrigeration structure, the compressor refrigeration structure specifically includes a two-stage cascade refrigeration machine, a three- stage cascade refrigeration machine, a single machine automatic cascade refrigeration machine, or a single machine precooling and automatic cascade refrigeration machine. The selection of compressor refrigeration structure is related to the number of sauna rooms. The specific structure can refer to the refrigeration structure of compressors in existing technologies, and will not be repeated here.

When the refrigeration module adopts a liquid nitrogen refrigeration structure, the refrigeration module is equipped with an evaporator <NUM>, a liquid nitrogen tank, a liquid nitrogen pipeline, and a flow valve. The evaporator <NUM> is connected to the liquid nitrogen tank through the liquid nitrogen pipeline, and the evaporator <NUM> is provided on the inner wall of the cabin body <NUM>. The liquid nitrogen tank is provided on the outer wall of the cabin body <NUM>, and the air in the sauna room is cooled by the vaporization and heat absorption of liquid nitrogen in the evaporator <NUM>. The flow valve is electrically connected to the controller, which controls the flow rate of the flow valve and thus controls the internal temperature of the sauna room. The liquid nitrogen refrigeration structure can reduce the internal temperature of the sauna room to -<NUM> to -<NUM>.

In some embodiments of the present application, the cryogenic physical therapy cabin <NUM> further includes a second heater and a water receiving tray, which is located below the evaporator <NUM> to receive defrosted water generated by the evaporator <NUM>. The second heater is located on the water receiving tray, and is electrically connected to the controller. In this embodiment, the second heater is controlled by the controller to start or stop heating, and the second heater is configured to prevent the defrosted water stored in the water receiving tray from condensing, facilitating the export of the defrosted water to the outside of the cryogenic physical therapy cabin <NUM>.

By providing a second heater and a water receiving tray in the cryogenic physical therapy cabin <NUM>, it is possible to prevent defrosted water from falling onto the ground in the sauna room and forming ice, preventing users from slipping and falling during use, and improving the safety performance of the cryogenic physical therapy cabin <NUM>.

In some embodiments of the present application, as shown in <FIG>, the cabin body <NUM> further includes a cover plate <NUM> connected to the inner wall of the cabin body <NUM>, and an air duct is formed between the cover plate <NUM> and the inner wall. The evaporator <NUM> is arranged at a first end of the air duct, and the fan blades <NUM> are arranged at a second end of the air duct. The cover plate <NUM> includes an air outlet <NUM> connected to the second end, and a return air inlet <NUM> connected to the first end.

In this embodiment, the air duct and the evaporator <NUM> are located in the same vertical plane. The fan <NUM> drives the fan blades <NUM> to rotate, forming a low air pressure at the second end of the air duct. A pressure difference is formed between the first end of the air duct and the second end of the air duct, and the air inside the air duct flows from the first end of the air duct to the second end of the air duct due to the pressure difference. Then, the air inside the sauna room continuously enters from the return air inlet <NUM>, and undergoes heat exchange with the surface of the evaporator <NUM> and cools down, The cooled air flows through the second end of the air duct and is exported from the air outlet <NUM> to the sauna room.

The combined action of the air duct and the rotating fan blades <NUM> causes forced convection between the cold air in the evaporator area and the cold air in the cabin body <NUM>, increasing the heat exchange rate and thus improving the refrigeration performance of the cryogenic physical therapy cabin <NUM>.

In some embodiments of the present application, the cryogenic physical therapy cabin <NUM> further includes a second temperature sensor, which is configured to collect a second temperature value at the cabin door <NUM>. The air outlet module further includes an air outlet adjustment mechanism for adjusting the opening degree of the air outlet <NUM>, which is located at the air outlet <NUM>. The second temperature sensor, the air outlet adjustment mechanism are electrically connected to the controller, and the second temperature sensor is configured to send the detected second temperature value to the controller. The controller is further configured to adjust the operation state of the air outlet adjustment mechanism based on the second temperature value and the user adjustment instruction. In this embodiment, the second temperature sensor can be installed on the cabin door <NUM> or close to the cabin door <NUM>.

By providing a second temperature sensor close to cabin door <NUM>, it is advantageous to accurately collect the air temperature close to cabin door <NUM>, which in turn facilitates the controller to adjust the air outlet adjustment mechanisms at different positions according to the actual temperature, providing different air volumes for different air outlets, improving the accuracy of adjustment and further energy-saving for the cryogenic physical therapy cabin <NUM>.

Optionally, the air outlet adjustment mechanism can be composed of a driving device and a baffle, and the output end of the driving device is connected to one end of the baffle to drive the baffle to rotate relative to the air outlet <NUM>, thereby controlling the area covered by the baffle relative to the air outlet <NUM>, and achieving the adjustment of the opening degree of the air outlet <NUM>.

Furthermore, the cover plate <NUM> further includes a cover plate extension located along the upper portion of the cabin body <NUM> and close to the cabin door <NUM>. The cover plate extension and the inner wall of the cabin body <NUM> form an extension air duct, and multiple air outlets are provided along the extension direction of the extension air duct. The cryogenic physical therapy cabin <NUM> can also include multiple second temperature sensors and multiple air outlet adjustment mechanisms. The multiple air outlet adjustment mechanisms are respectively provided at the multiple air outlets, and the multiple second temperature sensors are provided in one-to-one correspondences with the multiple air outlets. The controller can adjust the opening degree of the multiple air outlets.

The controller is further configured to: after determining the first opening degree of each air outlet according to the preset apparent temperature and adjusting the air outlet adjustment mechanism according to the first opening degree, determine the actual apparent temperature according to the second temperature value corresponding to each air outlet and the first opening degree of each air outlet; if the actual apparent temperature is greater than the preset apparent temperature, determine the second opening degree of each air outlet according to the difference value between the actual apparent temperature and the preset apparent temperature, and adjust the air outlet adjustment mechanism according to the second opening degree to reduce the actual apparent temperature to the preset apparent temperature.

In some embodiments of the present application, as shown in <FIG>, the air outlet adjustment mechanism includes a wind guide plate <NUM>, and the controller is further configured to adjust the angle between the plane where the wind guide plate <NUM> is located and the vertical direction according to the user adjustment instruction.

In this embodiment, the user adjustment instruction can include the user's height, and the angle between the plane where the wind guide plate <NUM> is located and the vertical direction can be adjusted according to the user's height, thereby ensuring that the wind direction of the air outlet <NUM> faces the main trunk of the user's body, in order to achieve better physical therapy effects.

The embodiment in the second aspect of this application provides a cryogenic physical therapy cabin system, which includes a mobile terminal and the cryogenic physical therapy cabin <NUM> in any embodiment in the first aspect mentioned above. The mobile terminal is communicated with the main control module of the cryogenic physical therapy cabin <NUM> through signals.

The mobile terminal includes but is not limited to a mobile phone, a tablet computer, an intelligent cabin, etc. People who use the mobile terminal is the user, who can send a user adjustment instruction through the mobile terminal to control the operation state of the cryogenic physical therapy cabin <NUM>. According to the cryogenic physical therapy cabin system in the embodiment of the present application, it shares the same inventive concept as the cryogenic physical therapy cabin <NUM> in the embodiment in the first aspect mentioned above. Therefore, the cryogenic physical therapy cabin system in the embodiment of the present application can achieve all the beneficial effects of the cryogenic physical therapy cabin <NUM> in the embodiment of the first aspect mentioned above.

It should be noted that the relationship terms herein such as "first", "second", and the like are only used for distinguishing one entity or operation from another entity or operation, but do not necessarily require or imply that there is any actual relationship or order between these entities or operations. Moreover, the terms "include", "comprise" or any other variants thereof are intended to cover non-exclusive inclusions, so that processes, methods, articles or devices including a series of elements include not only those elements listed but also those not specifically listed or the elements intrinsic to these processes, methods, articles, or devices. Without further limitations, elements defined by the sentences "comprise(s) a. " or "include(s) a. " do not exclude that there are other identical elements in the processes, methods, articles, or devices which include these elements.

All the embodiments of the present application are described in corresponding ways, same or similar parts in each of the embodiments can be referred to one another, and the parts emphasized are differences to other embodiments.

Claim 1:
A cryogenic physical therapy cabin (<NUM>), comprising:
a cabin body (<NUM>);
a cabin door (<NUM>), which is hinged with the cabin body (<NUM>) to form at least one sauna room;
a refrigeration module, which comprises an evaporator (<NUM>) arranged on an inner wall of the cabin body (<NUM>);
an air outlet module, which is arranged on the cabin body (<NUM>) and comprises fan blades (<NUM>) and a fan (<NUM>) electrically connected to the fan blades (<NUM>), wherein the fan (<NUM>) is configured to drive the fan blades (<NUM>) to rotate to generate a circulating airflow inside the sauna room; and
a main control module, which comprises a controller electrically connected to the fan (<NUM>) and the refrigeration module, wherein the controller is configured to receive a user adjustment instruction and adjust operation states of the air outlet module and the refrigeration module according to the user adjustment instruction,
characterized in that the cabin door (<NUM>) further comprises a glass window structure (<NUM>), which comprises at least two pieces of glass (<NUM>, <NUM>) fixedly connected and arranged in parallel with each other, wherein there is an air gap between adjacent two pieces of glass (<NUM>, <NUM>), and an electric heater is arranged on a first glass (<NUM>) in the at least two pieces of glass (<NUM>, <NUM>) close to the sauna room; and
the controller is electrically connected to the electric heater, and is configured to control an operation state of the electric heater.