A heat pipe comprises a first pipe and at least a second pipe. The first pipe includes an evaporator, a heat insulator and a condenser communicating with each other to define a hollow chamber. The second pipe disposed in the hollow chamber includes an accommodating space and a first capillary structure disposed in one end of the accommodating space closer to the evaporator. Two opposite sides of an outer pipe wall of the second pipe directly abut an inner pipe wall of the first pipe. The first pipe further includes a second capillary structure which is disposed in the hollow chamber closer to the evaporator and extended to an outside of the second pipe and occupies at least ⅔ volume of the evaporator. A first part of the first capillary structure and the second capillary structure are connected to each other by winding so as to enhance transportation therebetween.

A heat pipe comprises a first pipe and at least a second pipe. The first pipe includes an evaporator, a heat insulator and a condenser communicating with each other to define a hollow chamber. The second pipe disposed in the hollow chamber includes an accommodating space and a first capillary structure disposed in one end of the accommodating space closer to the evaporator. Two opposite sides of an outer pipe wall of the second pipe directly abut an inner pipe wall of the first pipe. The first pipe further includes a second capillary structure which is disposed in the hollow chamber closer to the evaporator and extended to an outside of the second pipe and occupies at least ⅔ volume of the evaporator. A first part of the first capillary structure and the second capillary structure are connected to each other by winding so as to enhance transportation therebetween.

The present invention provides an apparatus and method for supporting a mechanically stable and thermally isolated platform for operating sample devices which require extensive thermal isolation. The apparatus comprises a mounting base, a substrate, and microstructured tubes interconnecting the mounting base and substrate and having a thermally resistive inner portion and a thin coated layer that exhibits high electrical conductivity and low thermal emissivity. Radiation reflectors may be incorporated into the apparatus to protect components and reflect infrared radiation, and a getter equipped vacuum cover may be sealed to a vacuum header to maintain a low pressure environment within the apparatus.

The present invention provides an apparatus and method for supporting a mechanically stable and thermally isolated platform for operating sample devices which require extensive thermal isolation. The apparatus comprises a mounting base, a substrate, and microstructured tubes interconnecting the mounting base and substrate and having a thermally resistive inner portion and a thin coated layer that exhibits high electrical conductivity and low thermal emissivity. Radiation reflectors may be incorporated into the apparatus to protect components and reflect infrared radiation, and a getter equipped vacuum cover may be sealed to a vacuum header to maintain a low pressure environment within the apparatus.

A thermal management system and methods for use are disclosed. The thermal management system comprises a shield portion and a dissipation portion. The shield portion may comprise a hot side skin, a conduction layer, an insulation layer, and a cool side skin. The dissipation portion may comprise a fin array. Heat absorbed by the shield portion is partially or fully conducted to the dissipation portion for transfer to the ambient environment. The thermal management system may be employed as an aircraft wheel heat shield, an automotive brake heat shield, a gas turbine heat shield, an electronic heat sink, and in various other applications where heat shielding and/or heat transfer are desirable.

A heat exchanger cooling system includes: a passage extending from a water tank and branching off into a first passage and a second passage at a branch portion provided in the middle of extension of the passage, the passage including a water discharge portion provided on a distal end side of the first passage so as to face a radiator; a pump configured to send water into the passage from the water tank; a first opening-closing valve provided in the first passage and configured to open and close the first passage; a second opening-closing valve provided in the second passage and configured to open and close the second passage; and a controlling portion configured to control an operation of the pump and to control opening and closing of the first opening-closing valve and the second opening-closing valve.

Method and apparatus for thermally protecting a product, when storing and/or shipping a product, to control temperatures products are exposed to. Embodiments increase the amount of time portions of the product experience a desired temperature range and/or reduce the amount of time portions of the product experience temperatures outside a desired temperature range and/or experience an undesirable temperature range. Embodiments incorporate thermally conductive materials, referred to as conductive equalizers, positioned around and/or near the product positioned inside a packaging container, where the conductive materials conduct heat from locations in the package interior to other locations in the package interior. The conductive equalizers conductively transfer heat from hotter portions of the interior of the container to cooler portions of the interior of the container and/or from portions of the interior desired to be cooled to the cold bank, resulting in a more uniform temperature distribution around the product.

Method and apparatus for thermally protecting a product, when storing and/or shipping a product, to control temperatures products are exposed to. Embodiments increase the amount of time portions of the product experience a desired temperature range and/or reduce the amount of time portions of the product experience temperatures outside a desired temperature range and/or experience an undesirable temperature range. Embodiments incorporate thermally conductive materials, referred to as conductive equalizers, positioned around and/or near the product positioned inside a packaging container, where the conductive materials conduct heat from locations in the package interior to other locations in the package interior. The conductive equalizers conductively transfer heat from hotter portions of the interior of the container to cooler portions of the interior of the container and/or from portions of the interior desired to be cooled to the cold bank, resulting in a more uniform temperature distribution around the product.

A heat rejection system that employs temperature sensitive shape memory materials to control the heat rejection capacity of a vehicle to maintain a safe vehicle temperature. The technology provides for a wide range of heat rejection rates by actuation of the orientation or position of a heat rejection panel which impacts effective properties of the heat rejection system in response to temperature. When employed as a radiator for crewed spacecraft thermal control this permits the use of higher freezing point, non-toxic thermal working fluids in single-loop thermal control systems for crewed vehicles in space and other extraterrestrial environments.

Methods for improving heat transfer at the interface between the internal reactor wall and mesh media containing microfibrous entrapped catalysts (MFECs) and/or microfibrous entrapped sorbents (MFESs) are described herein. Improved (e.g., more rapid) heat transfer can be achieved using a variety of approaches including increasing the contacting area of the interface between the mesh media and the reactor wall so that more contacting points are formed, enhancing the contacting efficiency at the contacting points between the mesh media and the reactor wall, increasing the number of contact points between the mesh media and the reactor wall using fine fibers, and combinations thereof.