Patent application number | Description | Published |
20100071885 | Cover structure for core of heat exchanger - A cover structure for the core of a heat exchanger is provided. The core of a heat exchanger includes a partition plate and a cover. The cover includes a plurality of frames, an upper cover body, and a lower cover body. The upper cover body and the lower cover body join and together define a receiving space for receiving the frames. The frames are disposed on two sides of one of the upper cover body and the lower cover body, allowing the receiving space to be formed between the frames. Each of the frames has a plurality of crosswise extending posts provided therein. Each of the crosswise extending posts extends from an edge thereof, wherein the edge of each of the crosswise extending posts adjoins the receiving space. The crosswise extending posts and the frames together define a plurality of slits. The crosswise extending posts of the frames are coupled to the partition plate directly. The frames and the partition plate are fixed in position within the cover, thereby saving raw materials and reducing the required amount of adhesive material used. | 03-25-2010 |
20110024100 | HEAT RADIATING UNIT STRUCTURE AND HEAT SINK THEREOF - A heat radiating unit is provided on a front face with at least one raised strip having a curved head portion and a neck portion, the neck portion being located at a joint of the raised strip and the heat radiating unit and having a width smaller than that of the curved head portion; and on a reverse face with at least one receiving groove opposite to the raised strip, the receiving groove having a curved recess portion and an engaging shoulder portion, and the engaging shoulder portion being located at a joint of the receiving groove and the heat radiating unit. A plurality of the heat radiating units can be assembled to provide a heat sink by engaging the curved head portion and the neck portion of one heat radiating unit with the curved recess portion and the engaging shoulder portion, respectively, of another heat radiating unit. | 02-03-2011 |
20110088872 | HEAT PIPE STRUCTURE - A heat pipe structure includes a pipe body and a convection device. The pipe body defines a chamber enclosed in an inner wall of the pipe body. The convection device includes a rotary unit and a driving unit for creating a fluid pressure gradient in the chamber of the pipe body. The rotary unit and the driving unit are respectively located at an interior and an exterior of the pipe body. When the driving unit is excited, the rotary unit is driven to rotate under magnetic induction. With the fluid pressure gradient created in the chamber of the pipe body, the circulation of the working fluid in the chamber can be improved, and a forced convection flow of the working fluid in the pipe body is enabled to largely increase the heat transfer efficiency and heat transfer effect of the heat pipe. | 04-21-2011 |
20110168360 | HEAT EXCHANGER - A heat exchanger includes a body having a center and a spiral guiding trough extending spirally and outwardly from the center toward an outside of the center. The radius of the spiral guiding trough increases gradually from the center toward the outside of the center. A first port and a second port are in communication with the spiral guiding trough respectively. With the combination of the spiral guiding trough and the body, the fluid can be sufficiently mixed in the spiral guiding trough, thereby achieving an excellent thermal-conducting effect. | 07-14-2011 |
20110174470 | SPIRAL HEAT EXCHANGER - A spiral heat exchanger includes two assembled covers defining a chamber therebetween for receiving a spiral unit therein. The spiral unit includes a first and a second spiral member separately spirally extending from a central outlet to a peripheral outlet on the two covers to respectively form a first and a second flow passage. A driving unit is assembled to and drives the assembled covers to rotate at the same time, so that cold and hot airflows respectively enter and flow through the first and second spiral members from the central outlet to the peripheral outlet under a centrifugal force to exchange heat at the spiral unit. The spiral unit provides extended flow passages and increased heat exchange area, giving the spiral heat exchanger increased heat transfer capacity and heat exchange efficiency and allowing omission of fans and radiating fin assembly to eliminate operating noise and accumulated dust. | 07-21-2011 |
20120018128 | SLIM TYPE PRESSURE-GRADIENT-DRIVEN LOW-PRESSURE THERMOSIPHON PLATE - A slim type pressure-gradient-driven low-pressure thermosiphon plate includes a main body closed by a cover. The main body includes a central heat receiving zone, a pressure accumulating zone and a first flow passage unit separately located at two opposite sides of the heat receiving zone, a free zone communicating with the pressure accumulating zone, a first and a second condensing zone communicating with the free zone, a third and a fourth condensing zone communicating with the first flow passage unit, a second flow passage unit located between and communicating with the first and the third condensing zone, and a third flow passage unit located between and communicating with the second and the fourth condensing zone. In the thermosiphon plate, a low-pressure end is created through proper pressure-reduction design to form a pressure gradient for driving steam-water circulation, and the working fluid can transfer heat without any wick structure. | 01-26-2012 |
20120018130 | THERMAL SIPHON STRUCTURE - A thermal siphon structure includes a main body, a chamber disposed therein, an evaporation section, a condensation section and a connection section positioned between the evaporation section and condensation section. The evaporation section and condensation section are respectively arranged in the chamber on two sides thereof. The connection section has a set of first communication holes and a set of second communication holes in communication with the evaporation section and condensation section. The evaporation section and condensation section respectively have multiple first and second flow guide bodies, which are arranged at intervals to define therebetween first and second flow ways. Each of the first and second flow ways has a narrower end and a wider end. The first flow ways communicate with a free area. The condensation section is designed with a low-pressure end to create a pressure gradient for driving a working fluid to circulate without any capillary structure. | 01-26-2012 |
20120018131 | PRESSURE DIFFERENCE DRIVEN HEAT SPREADER - A pressure difference driven heat spreader includes a chamber defined in a main body; a vaporizing section arranged in the chamber and including a plurality of first flow-guiding members spaced from one another to define first flow passages therebetween, the first flow passages each having at least one free end communicating with a free zone; a condensing section arranged in the chamber opposite to the vaporizing section and including a plurality of second flow-guiding members spaced from one another to define second flow passages therebetween; and an interconnecting section arranged between the vaporizing and condensing sections and having first and second communicating holes for communicating the vaporizing section with the condensing section. The condensing section functions as a low-pressure end, so that a pressure gradient is produced in the pressure difference driven heat spreader to drive steam-water circulation therein, and no wick structure is needed for driving the working fluid. | 01-26-2012 |
20120024499 | LOOP TYPE PRESSURE-GRADIENT-DRIEN LOW-PRESSURE THERMOSIPHON DEVICE - A loop type pressure-gradient-driven low-pressure thermosiphon device includes a case sealed by a cover to define a chamber with a vaporizing section. The vaporizing section includes a plurality of spaced flow-guiding members and first flow passages formed between adjacent flow-guiding members. The flow passages respectively have at least one free end communicating with a free zone in the chamber. A pipeline is connected at two ends to two opposite sides of the case, and has a second flow passage communicable with the vaporizing section. The pipeline extends through at least one heat-dissipating element, so that the pipeline and the heat-dissipating element together define a condensing section. In the thermosiphon device, a low-pressure end is created through proper pressure-reduction design to form a pressure gradient for driving steam-water circulation, and the working fluid can be driven to circulate and transfer heat in the pipeline and the case without any wick structure. | 02-02-2012 |