A heating chamber (11) for an aerosol generation device (1), the heating chamber (11) comprising: a compression element (111) comprising a thermally active material; and a reaction surface (112), wherein the heating chamber (11) is adapted to receive an aerosol substrate (2) between the compression element (111) and the reaction surface (112), and the compression element (111) is configured to compress the aerosol substrate (2) against the reaction surface (112), wherein the compression element (111) is configured to undergo displacement according to a temperature of the heating chamber (11) and a thermal response characteristic of a magnetic property of the thermally active material.

A heat dissipation assembly includes a case and a partition structure. The case has a chamber. The partition structure includes a partition wall vertically disposed in the chamber to separate a first flow path and a second flow path in the chamber, and the partition wall has a breach and a valve structure disposed at the breach, wherein the valve structure covers the breach when the valve structure is not pushed open. When a fluid pressure existed in a section of one of the first flow path and the second flow path which is adjacent to the valve structure is greater than a fluid pressure existed in a section of the other one of the first flow path and the second flow path which is adjacent to the valve structure, the valve structure is pushed away to expose at least a part of the breach.

A cooling system for a light emitting diode assembly includes a heat exchanger configured to exchange heat from a fluid to ambient air, an enclosure configured to house the LED assembly, and a pump configured to circulate the fluid through the enclosure, through the LED assembly, or both, and through the heat exchanger. The fluid is configured to absorb heat at the LED assembly and generated by the LED assembly, and the heat exchanger is configured to cool the fluid and remove the heat absorbed by the fluid at the LED assembly.

An apparatus with two anchors including a housing, a movable element, and a rotary element is provided. The housing includes a first expansion unit, a second expansion unit, and a linkage. First alignment structures are disposed in the movable element and anti-rotation structures are disposed in the linkage. When the movable element and the rotary element enter the housing from two ends and are coupled along an axis, the movable element and the rotary element can approach each other to expand the first expansion unit and the second expansion unit to form two anchors. The apparatus with two anchors secures a sensor in a variety of environments such as walls or machines. When the apparatus with two anchors fixes a sensor in a hole of a stamping machine, the impact force does not cause stress concentration on the sensor so as to improve the reliability of the sensor.

An apparatus with two anchors including a housing, a movable element, and a rotary element is provided. The housing includes a first expansion unit, a second expansion unit, and a linkage. First alignment structures are disposed in the movable element and anti-rotation structures are disposed in the linkage. When the movable element and the rotary element enter the housing from two ends and are coupled along an axis, the movable element and the rotary element can approach each other to expand the first expansion unit and the second expansion unit to form two anchors. The apparatus with two anchors secures a sensor in a variety of environments such as walls or machines. When the apparatus with two anchors fixes a sensor in a hole of a stamping machine, the impact force does not cause stress concentration on the sensor so as to improve the reliability of the sensor.

A two-phase immersion cooling apparatus may include an immersion tank with a primary condenser in thermal communication with an interior volume of the immersion tank and a vapor management system fluidically connected to the immersion tank. The vapor management system may enable the apparatus to effectively manage periods of high vapor production by removing vapor and other gases from a headspace of the immersion tank, condensing the vapor to liquid, and returning the liquid to the immersion tank.

A stability controlled system includes a computing platform having a hardware processor, a memory storing a software code, a moveable component, and a tilt sensor. The hardware processor executes the software code to monitor the tilt sensor to determine whether the system is at a tilt with respect to a support surface for the system. When the tilt sensor is sensing the tilt with respect to the support surface: when the moveable component is off, the software code prevents the moveable component from turning on, and when the moveable component is on, the software code performs one of (a) turning off the moveable component, and (b) slowing down a regular rate of motion of the moveable component. When the tilt sensor is not sensing the tilt with respect to the support surface, the software code permits the moveable component to be turned on and have the regular rate of motion.

A stability controlled system includes a computing platform having a hardware processor, a memory storing a software code, a moveable component, and a tilt sensor. The hardware processor executes the software code to monitor the tilt sensor to determine whether the system is at a tilt with respect to a support surface for the system. When the tilt sensor is sensing the tilt with respect to the support surface: when the moveable component is off, the software code prevents the moveable component from turning on, and when the moveable component is on, the software code performs one of (a) turning off the moveable component, and (b) slowing down a regular rate of motion of the moveable component. When the tilt sensor is not sensing the tilt with respect to the support surface, the software code permits the moveable component to be turned on and have the regular rate of motion.

A stability controlled system includes a computing platform having a hardware processor, a memory storing a software code, a moveable component, and a tilt sensor. The hardware processor executes the software code to monitor the tilt sensor to determine whether the system is at a tilt with respect to a support surface for the system. When the tilt sensor is sensing the tilt with respect to the support surface: when the moveable component is off, the software code prevents the moveable component from turning on, and when the moveable component is on, the software code performs one of (a) turning off the moveable component, and (b) slowing down a regular rate of motion of the moveable component. When the tilt sensor is not sensing the tilt with respect to the support surface, the software code permits the moveable component to be turned on and have the regular rate of motion.

A stability controlled system includes a computing platform having a hardware processor, a memory storing a software code, a moveable component, and a tilt sensor. The hardware processor executes the software code to monitor the tilt sensor to determine whether the system is at a tilt with respect to a support surface for the system. When the tilt sensor is sensing the tilt with respect to the support surface: when the moveable component is off, the software code prevents the moveable component from turning on, and when the moveable component is on, the software code performs one of (a) turning off the moveable component, and (b) slowing down a regular rate of motion of the moveable component. When the tilt sensor is not sensing the tilt with respect to the support surface, the software code permits the moveable component to be turned on and have the regular rate of motion.