Abstract: A three-dimensional pulsating heat pipe includes a pipe member and a connecting member. The pipe member is coiled around an axis to form a plurality of loop portions, and the loop portions are arranged in order along the axis so as to form a three-dimensional coiled structure. The three-dimensional coiled structure has a heat receiving section, and the pipe member has different effective pipe cross-sectional areas on two opposite sides adjacent to the heat receiving section. The connecting member is connected to two ends of the pipe member, such that the connecting member and the pipe member together form a closed loop.

Abstract: A three-dimensional pulsating heat pipe includes a pipe member and a connecting member. The pipe member is coiled around an axis to form a plurality of circular pipe portions, and the circular pipe portions are arranged in order along the axis so as to form a three-dimensional coiled structure. The three-dimensional coiled structure has a heat receiving section, and the pipe member has different effective pipe cross-sectional areas on two opposite sides adjacent to the heat receiving section. The connecting member is connected to two ends of the pipe member, such that the connecting member and the pipe member together form a closed loop.

Abstract: A multi-pipe three-dimensional pulsating heat pipe includes at least two pipes and at least two chambers. The at least two pipes form into respective three-dimensional annular loops. A cooling zone is formed to one side of the annular loops. Two opposing ends of the at least two pipes are connected spatially to the at least two chambers, respectively, so as to form the multi-pipe three dimensions pulsating heat pipe.

Abstract: A composite fiber capillary structure includes a first interlacing layer and a second interlacing layer. The first interlacing layer is formed as a hollow cylindrical net structure by metal wires with a first diameter. The second interlacing layer is also formed as a hollow cylindrical net structure by metal wires with a second diameter. The first diameter is larger than the second diameter, and the second interlacing layer covers the first interlacing layer in a sleeving manner. In addition, a fabricating method of the composite fiber capillary structure and a heat pipe with the composite fiber capillary structure are also provided.

Abstract: A heat distribution structure, a method for manufacturing the same and a heat-dissipation module incorporating the same are disclosed. The heat distribution structure includes a first cap with a first grove and a second cap with a second groove and a support body interposed between the first cap and the second cap, wherein microstructures are formed at the bottoms of the first groove and the second groove and through holes are formed in the support body. The support body is interposed between the first and second caps, such that a cavity is formed by the first cap, the support body and the second cap. A working fluid is contained in the cavity that flows therein through capillary action provided by the microstructures of the first and second grooves and the through holes in the support body, thus evenly distributing heat in the heat distribution structure.

Abstract: A heat-dissipating device and a heat-dissipating system are provided. The heat-dissipating system includes a driver, a heat-exchanger and a heat-dissipating device. The heat-exchanger is communicated to the driver and includes a body, a hydrophobic membrane and a cover. The body has an inlet, an outlet and a channel. Both ends of the channel exposed on a body's surface are respectively communicated to the inlet and the outlet, the inlet and outlet are communicated respectively to the driver and heat-exchanger. The membrane is disposed on the body's surface and covers the channel. The cover combines with the body and has a chamber and an exhaust port. The membrane separates the channel from the chamber communicated to the exhaust port communicated to the heat-exchanger. The driver drives a working fluid to the heat-dissipating device, and the fluid further goes to the heat-exchanger from the heat-dissipating device and then back to the driver.

Abstract: A cold plate including a cold wall, a first cavity, a first pipe, a second cavity, an expansion unit and a second pipe is provided. The first cavity covers on the cold wall to form a first fluid space, and the first pipe is connected with the first cavity. The second cavity is disposed inside the first cavity and covers on the cold wall to form a second fluid space. The expansion unit is disposed between the second cavity and the cold wall to interconnect the first fluid space and the second fluid space. The second pipe is disposed inside the first pipe and connected with the second cavity. Besides, a refrigeration system including the cold plate mentioned above is also provided.

Abstract: An evaporator, applicable to a two-stage expansion cooling system, is used for receiving a high-pressure liquid working fluid. The evaporator includes a thermal-conductive block having a channel system. The channel system includes a high-pressure channel, a low-pressure channel, and a second stage expansion channel. The second stage expansion channel has an input end and an output end. The input end is communicated with the high-pressure channel. The output end is communicated with the low-pressure channel, and has a cross-sectional area smaller than that of the low-pressure channel. The high-pressure liquid working fluid flows into the thermal-conductive block from the high-pressure channel, and then enters the second stage expansion channel through the input end. A part of the high-pressure liquid working fluid flowing out of the output end expands into a saturated low-pressure liquid working fluid and enters the low-pressure channel.

Abstract: A cold plate including a cold wall, a first cavity, a first pipe, a second cavity, an expansion unit and a second pipe is provided. The first cavity covers on the cold wall to form a first fluid space, and the first pipe is connected with the first cavity. The second cavity is disposed inside the first cavity and covers on the cold wall to form a second fluid space. The expansion unit is disposed between the second cavity and the cold wall to interconnect the first fluid space and the second fluid space. The second pipe is disposed inside the first pipe and connected with the second cavity. Besides, a refrigeration system including the cold plate mentioned above is also provided.

Abstract: An evaporator, applicable to a two-stage expansion cooling system, is used for receiving a high-pressure liquid working fluid. The evaporator includes a thermal-conductive block having a channel system. The channel system includes a high-pressure channel, a low-pressure channel, and a second stage expansion channel. The second stage expansion channel has an input end and an output end. The input end is communicated with the high-pressure channel. The output end is communicated with the low-pressure channel, and has a cross-sectional area smaller than that of the low-pressure channel. The high-pressure liquid working fluid flows into the thermal-conductive block from the high-pressure channel, and then enters the second stage expansion channel through the input end. A part of the high-pressure liquid working fluid flowing out of the output end expands into a saturated low-pressure liquid working fluid and enters the low-pressure channel.