| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 165104320 | With pressurizing means or degassifying means | 6 |
| 20090272513 | METHODS AND SYSTEMS FOR CONTROLLING TEMPERATURE IN A VESSEL - A method and system for preheating a vessel that includes an area of excess heat and a flow of purge fluid that is channeled to an area to be purged wherein the purge fluid is deficient of heat are provided. The system includes a cooling tube assembly positioned between the area of excess heat and the area to be purged and a first heat exchanger coupled in flow communication to the cooling tube assembly, the first heat exchanger configured to transfer heat between a flow of cooling fluid through the cooling tube assembly and the flow of purge fluid wherein the flow of cooling fluid through the cooling tube assembly is maintained sub-cooled and the flow of purge fluid is heated to facilitate reducing a thermal stress in the area purged. | 11-05-2009 |
| 20100078155 | Thin Cavity Fluidic Heat Exchanger - A heat exchanger comprising a first surface, a second surface, and a spacer configured to maintain a cavity between the first surface and the second surface, wherein the cavity has a thickness less than or equal to about 20 thousands of an inch (mils) and has a width-to-thickness ratio greater than or equal to about 8:1, and wherein the cavity allows any fluid in the cavity to exchange heat with the first surface, the second surface, or both is disclosed. Also disclosed is an apparatus comprising a thermal load and a heat exchanger substantially adjacent to or integrated with the thermal load, wherein any fluid flowing through the heat exchanger has a velocity greater than or equal to about 20 feet per second (fps). | 04-01-2010 |
| 20120180997 | Coolant De-Aeration Reservoir - A coolant de-aeration system is provided that includes a coolant reservoir, a plurality of de-aeration chambers within the reservoir, a plurality of de-aeration chamber apertures that direct coolant flow through the de-aeration chambers, a reservoir inlet and a reservoir outlet that share a common coolant flow pathway that allows the majority of coolant to flow directly between the reservoir inlet and the reservoir outlet, and a reservoir inlet aperture that directs a portion of coolant passing along the common coolant flow pathway through the reservoir's de-aeration chambers for de-aeration prior to being returned to the common coolant flow pathway. | 07-19-2012 |
| 20140311713 | HEAT DISSIPATION COMPONENT - A heat dissipation component includes a first film, a second film, and a working fluid. The second film is connected with a part of the first film to form a plurality of vein channels. The vein channels include a main vein channel and a plurality of branch vein channels, and the main vein channel is connected with the branch vein channels. The working fluid is disposed in the vein channels. The heat dissipation component is bendable to be easily assembled with an electronic device. The working fluid may flow in the vein channels via a pressure difference generated by a phase transition, gravity, and a capillary effect, or via a pressure difference generated, by a pulse generator to transfer the heat to the whole heat dissipation component. The first film and the second film may have heat conduction material to improve the heat transfer rate. | 10-23-2014 |
| 20160137032 | VEHICLE AIR CONDITIONER - This vehicle air conditioner includes a first water-refrigerant heat exchanger, a second water-refrigerant heat exchanger, a heater core, a distributing unit which distributes the coolant, fed from a heat generating component of a vehicle, to a plurality of cooling path, and a junction unit which causes the coolant guided from a plurality of cooling paths to join, and feeds the coolant to the heat generating component. The first water-refrigerant heat exchanger inputs the coolant distributed by the distributing unit, through a first cooling path, and feeds the coolant to be guided to the junction unit, to a second cooling path. The second water-refrigerant heat exchanger inputs the coolant distributed by the distributing unit, through a third cooling path, and feeds the coolant to the heater core. The heater core inputs the coolant fed by the second water-refrigerant heat exchanger, and feeds the coolant to be guided to the junction unit, to a fourth cooling path. | 05-19-2016 |
| 20160146093 | RADIATOR RESERVOIR TANK AND RADIATOR STRUCTURE - There is provided a radiator reservoir tank including: a tank body that is connected to a radiator and that includes an inlet section and an accumulation section for cooling water; a first rib that is disposed inside the tank body, and that extends out from a side wall at one side of facing side walls of the tank body toward another side, and that partitions between the inlet section and the accumulation section, and that is provided with a gap to the side wall at the other side; and a second rib that is provided further toward the inlet section side or the accumulation section side than the first rib, that extends out from the side wall at the other side toward the one side, and that is provided with a gap to the side wall at the one side. | 05-26-2016 |
