Abstract: A condenser has a main condensing module, an auxiliary condensing module, and a connecting tube. The main condensing module has an input base tube, a first connecting base tube, and a main heat dissipating mechanism, which are series connected. The auxiliary condensing module has a second connecting base tube, an output base tube, and an auxiliary heat dissipating mechanism, which are series connected. The connecting tube is mounted between the main condensing module and the auxiliary condensing module. An interior room of the first connecting base tube communicates with an interior room of the second connecting base tube.

Abstract: A heat sink is applied to a display unit and has a heat conductor, at least one first cooling fan, and at least one second cooling fan. The heat conductor has a heat-conducting member, multiple first cooling fins, and multiple second cooling fins. The heat-conducting member has a base portion, an extending portion formed on the base portion, and multiple channels formed in the heat-conducting member and filled with a working fluid. The first cooling fins are formed on the base portion. The second cooling fins are formed on the extending portion. The at least one first cooling fan is disposed on the base portion. The at least one second cooling fan is disposed on the extending portion. The heat conductor can be sectioned and the working fluid can change phases for heat dissipation, providing a good heat dissipation effect to the heat sink is good.

Abstract: A heat dissipating apparatus has a phase change material evaporator, a condenser, a refrigerant output tube, and a refrigerant input tube. The evaporator has a base having an evaporation chamber, a refrigerant inlet and a refrigerant outlet, a reinforcement panel mounted in the evaporation chamber and dividing the evaporation chamber into two spaces, and multiple heat conduction fins separately arranged in the two spaces. An opening area of the refrigerant outlet is larger than an opening area of the refrigerant inlet. The evaporator, the refrigerant output tube, the condenser and the refrigerant input tube form a closed refrigerant circulation loop with a refrigerant filled therein. Gas pressure of a gas-phased refrigerant in the two spaces can be increased. With pressure difference between the refrigerant outlet and the refrigerant inlet, the gas-phased refrigerant can be accelerated to flow toward the refrigerant outlet and flowability of the refrigerant can be increased.

Abstract: A liquid heat-dissipating assembly has a heat-guiding tube assembly, multiple heat-dissipating units, and at least one heat-dissipating tube. The heat-guiding tube assembly has a first tube, a second tube, and a separating segment. The first tube has at least one first channel. The second tube has at least one second channel. The separating segment is mounted between the first tube and the second tube. The heat-dissipating units are connected with the heat-guiding tube assembly, and each heat-dissipating unit has a heat-dissipating body, a first pipe, and a second pipe. The heat-dissipating body has a passage. The first pipe is connected with the passage and the at least one first channel. The second pipe is connected with the passage and the at least one second channel. The at least one heat-dissipating tube is connected with the at least one second channel of the second tube.

Abstract: A phase change evaporator includes multiple heat-dissipating fins formed on an evaporator body of the evaporator. A cooling device includes the evaporator, a condenser, a coolant output pipe and a coolant return pipe connected between the evaporator and the condenser, and coolant filled inside a closed coolant circulation loop formed by the evaporator, the condenser, the coolant output pipe and the coolant return pipe. When the evaporator body absorbs heat, the coolant inside the evaporator body is converted into a gaseous state by the heat and then quickly dissipates the heat absorbed thereby through the heat-dissipating fins for a part of the gaseous coolant to be condensed to resume heat absorption and for the remaining part to flow to the condenser through the coolant output pipe to be condensed to a liquid state and return to the evaporator body along the coolant return pipe for heat absorption.

Abstract: A cooling device includes a parallel-connected condenser and an evaporator assembly. The parallel-connected condenser has a primary condenser assembly and at least one auxiliary condenser assembly. The evaporator assembly includes an evaporator, a coolant input pipe and a coolant output pipe. Two ends of the coolant input pipe are respectively connected to the evaporator and a first primary condenser tube. Two ends of the coolant output pipe are respectively connected to the evaporator and a second primary condenser tube for the parallel-connected condenser and the evaporator assembly to form a closed coolant circulation loop with coolant filled therein. By virtue of the primary condenser assembly and the auxiliary condenser assembly parallelly connected, gaseous coolant can be circulated through different paths and liquefied to effectively enhance cooling and liquefaction efficiency of coolant when the coolant is circulated through the cooling device.

Abstract: A phase change evaporator includes multiple heat-dissipating fins formed on an evaporator body of the evaporator. A cooling device includes the evaporator, a condenser, a coolant output pipe and a coolant return pipe connected between the evaporator and the condenser, and coolant filled inside a closed coolant circulation loop formed by the evaporator, the condenser, the coolant output pipe and the coolant return pipe. When the evaporator body absorbs heat, the coolant inside the evaporator body is converted into a gaseous state by the heat and then quickly dissipates the heat absorbed thereby through the heat-dissipating fins for a part of the gaseous coolant to be condensed to resume heat absorption and for the remaining part to flow to the condenser through the coolant output pipe to be condensed to a liquid state and return to the evaporator body along the coolant return pipe for heat absorption.

Abstract: A heat dissipating apparatus has a phase change material evaporator, a condenser, a refrigerant output tube, and a refrigerant input tube. The evaporator has a base having an evaporation chamber, a refrigerant inlet and a refrigerant outlet, a reinforcement panel mounted in the evaporation chamber and dividing the evaporation chamber into two spaces, and multiple heat conduction fins separately arranged in the two spaces. An opening area of the refrigerant outlet is larger than an opening area of the refrigerant inlet. The evaporator, the refrigerant output tube, the condenser and the refrigerant input tube form a closed refrigerant circulation loop with a refrigerant filled therein. Gas pressure of a gas-phased refrigerant in the two spaces can be increased. With pressure difference between the refrigerant outlet and the refrigerant inlet, the gas-phased refrigerant can be accelerated to flow toward the refrigerant outlet and flowability of the refrigerant can be increased.

Abstract: A liquid heat-dissipating assembly has a heat-guiding tube assembly, multiple heat-dissipating units, and at least one heat-dissipating tube. The heat-guiding tube assembly has a first tube, a second tube, and a separating segment. The first tube has at least one first channel. The second tube has at least one second channel. The separating segment is mounted between the first tube and the second tube. The heat-dissipating units are connected with the heat-guiding tube assembly, and each heat-dissipating unit has a heat-dissipating body, a first pipe, and a second pipe. The heat-dissipating body has a passage. The first pipe is connected with the passage and the at least one first channel. The second pipe is connected with the passage and the at least one second channel. The at least one heat-dissipating tube is connected with the at least one second channel of the second tube.

Abstract: A refrigerant heat dissipation apparatus has an evaporator, a condenser having a first condensing tube and a second condensing tube, a first refrigerant tube, two second refrigerant tubes, and a refrigerant. The first refrigerant tube is connected between the top of the evaporator and an upper part of a first condensing tube. The second refrigerant tubes are respectively connected with a lower part of the first condensing tube and a lower part of the second condensing tube, so as to form a multi-flow closed-loop cycle. The refrigerant is filled into the multi-flow closed-loop cycle. The controlling of cycling direction of the refrigerant achieves the efficiency in heat dissipating of the refrigerant heat dissipation apparatus.

Abstract: A liquid-cooling heat sink has a heat-conductive tube and multiple heat-conductive units arranged adjacent to the heat-conductive tube. The heat-conductive tube has a first tube and a second tube. An isolation member having an isolation channel is located between the first tube and the second tube. The isolation member obstructs the heat exchange between the first tube and the second tube. A first delivery tube and a second delivery tube of each one of the heat-conductive bodies respectively connect to the first tube and the second tube of the heat-conductive tube, thereby integrating the first tube and the second tube and obstructing the heat exchange between the cooling liquids with different temperatures. Each of the heat-conductive units distributes the cooling liquids with different temperatures by the heat-conductive tube, thereby simplifying the pipeline setting and reducing the volume of the liquid-cooling heat sink.

Abstract: A refrigerant heat dissipation apparatus has an evaporator, a condenser having a first condensing tube and a second condensing tube, a first refrigerant tube, two second refrigerant tubes, and a refrigerant. The first refrigerant tube is connected between the top of the evaporator and an upper part of a first condensing tube. The second refrigerant tubes are respectively connected with a lower part of the first condensing tube and a lower part of the second condensing tube, so as to form a multi-flow closed-loop cycle. The refrigerant is filled into the multi-flow closed-loop cycle. The controlling of cycling direction of the refrigerant achieves the efficiency in heat dissipating of the refrigerant heat dissipation apparatus.

Abstract: An evaporator with heat dissipating fins and a refrigerant heat dissipating apparatus using the same are provided herein and the refrigerant heat dissipating apparatus comprises the evaporator, a condenser, two refrigerant tubes connected between the evaporator and the condenser and a refrigerant filled into the evaporator body. When the evaporator body absorbs heat, the refrigerant absorbs heat and is converted to the gaseous state. The refrigerant in the gaseous state flows upward and conducts heat to a top of the evaporator body. The heat dissipating fins conduct heat quickly to condense most of the refrigerant in the gaseous state back to the liquid state to absorb heat again. The rest of the refrigerant in the gaseous state passes through the condenser via the first refrigerant tube to be the liquid refrigerant. The liquid refrigerant flows back to the evaporator body via the second refrigerant tube to absorb heat again.

Abstract: A heat dissipation device of a vehicle lamp and an interposing element thereof are provided. The heat dissipation device is installed in a lamp room which is divided by the interposing element into a front partition and a rear partition. A heat sink is installed in the interposing elements. An air feeding fan is disposed in an air feeding channel of the interposing element, for drawing air in the front partition to the rear partition through the air feeding channel. Further, a back flow fan is disposed in the rear partition, for drawing air in the rear partition to the front partition through a back flow channel. Whereby, the air in the front partition is cooled down through an external air flow passing through the lamp cover. Then, the heat sink dissipates heat of the air flow with the relatively low temperature in the front partition to the rear partition.

Abstract: A heat dissipation device has an inlet pipeline, an outlet pipeline, at least one heat-dissipating unit and at least one actuator. Each of the at least one heat-dissipating unit is connected to the inlet pipeline and the outlet pipeline and includes multiple heat-dissipating elements being connected to each other. The at least one actuator is mounted on the inlet pipeline. The heat dissipation device is mounted around a large-sized electronic appliance to absorb and dissipate the heat generated by the large-sized electronic appliance so as to effectively reduce the working temperature of the electronic appliance to normal level. Therefore, the large-sized electronic appliance can work safely and is power-saving and environmental friendly.

Abstract: A liquid cooling device is mounted in a large-sized overhead projector to absorb heat generated by a light-generating device. The liquid cooling device has a water tank, a heat sink, a liquid block assembly and a pump. The water tank has an outlet hole formed on the middle of the water. The heat sink communicates with the water tank. The liquid block assembly contacts the light-generating device and is filled with a coolant and communicates with the heat sink via an inlet duct. The pump is mounted in the large-sized overhead projector and is in fluid communications with the water tank via an outlet duct mounted in the outlet hole of the water tank. Therefore, when the large-sized overhead projector is put upright or turned upside down, the outlet hole is always in the middle of the water tank, preventing the pump from idling and being damaged as the amount of coolant is reduced.

Abstract: A heat dissipation device of a vehicle lamp and an interposing element thereof are provided. The heat dissipation device is installed in a lamp room which is divided by the interposing element into a front partition and a rear partition. A heat sink is installed in the interposing elements. An air feeding fan is disposed in an air feeding channel of the interposing element, for drawing air in the front partition to the rear partition through the air feeding channel. Further, a back flow fan is disposed in the rear partition, for drawing air in the rear partition to the front partition through a back flow channel. Whereby, the air in the front partition is cooled down through an external air flow passing through the lamp cover. Then, the heat sink dissipates heat of the air flow with the relatively low temperature in the front partition to the rear partition.

Abstract: A vehicle lamp has a lamp holder, an LED array, an interior heat sink and a heat exchanger. The lamp holder is hollow and has a heat conductive portion. The LED array is mounted in the lamp holder. The interior heat sink is mounted on the LED array and has an inner conductor attached between the LED array and the heat conductive portion. The heat exchanger is mounted on an outer side of the heat conductive portion. Therefore, the vehicle lamp can efficiently dissipate heat generated by the LED array by the interior heat sink and the heat exchanger with little or no dust entering the lamp holder and accumulating on the LED array for improved lifespan and constant heat dissipating performance.

Abstract: A liquid cooling device for multiple electronic components has two liquid blocks, a heat-dissipating plate, a pump and a heat sink. The two liquid blocks and the heat sink are connected and communicated with other via tubing. The pump operates to make a coolant circulate among the two liquid blocks and the heat sink. The heat-dissipating plate is integrally formed with one liquid block. The heat-dissipating plate is disposed on another separate electronic component for absorbing heat. Therefore, the liquid cooling device has only two liquid blocks, but can dissipate heat generated by three electronic components.

Abstract: A liquid cooling device includes a liquid block, a heat-dissipating plate, a thermal-conductive pipe, a pump and a heat sink. The liquid block, the pump, and the heat sink are connected by ducts. The pump drives a coolant to circulate among them. The thermal-conductive pipe is mounted on the heat-dissipating plate. Both ends of the thermal-conductive pipe are connected to the liquid block for the coolant to flow through. The liquid block and the heat sink are respectively mounted on the corresponding electronic devices to absorb heat using the circulating coolant. The heat sink is used to dissipate heat from another heat-generating electronic device. Therefore, one less liquid block is required, and the production cost becomes lower.