Nanofluid superconductive radiator

Abstract

The invention discloses a nanofluid superconductive radiator. The nanofluid superconductive radiator comprises a heat dissipation shell and a pump bin, heat absorption pipes are fixedly connected in the heat dissipation shell, the pump bin is arranged on the rear side of the heat dissipation shell, the tops of the heat absorption pipes are connected with the pump bin through first heat dissipation pipes, the bottoms of the heat absorption pipes are connected with the pump bin through second heat dissipation pipes, nanofluid superconductive media are contained in the heat absorption pipes, the pump bin, the first heat dissipation pipes and the second heat dissipation pipes, the nanofluid superconductive radiator further comprises a motor, and a fan blade set is driven by the motor. The nanofluid superconductive radiator has the beneficial effects that power is generated by the motor, the nanofluid superconductive media flow in the heat absorption pipes, the pump bin, the first heat dissipation pipes and the second heat dissipation pipes by means of the pump bin, when the nanofluid superconductive media flow through the positions of the heat absorption pipes, heat in the heat dissipation shell is absorbed, when the nanofluid superconductive media pass through the positions of the first heat dissipation pipes and the heat dissipation pipes, the fan blade set is made to rotate through the motor, and therefore the air flowing speed at the positions of the first heat dissipation pipes and the second heat dissipation pipes is increased, and the heat dissipation effect is improved.

Description

technical field [0001] The invention relates to the technical field of radiators, in particular to a nanofluid superconducting radiator. Background technique [0002] For large-scale integrated combined LED lamps, the problem of heat dissipation is more prominent. Because aluminum alloys are cheap, light in weight and have good thermal conductivity, aluminum alloy shells are generally used as heat sinks for LEDs. However, large-scale integrated When the combined LED lamp is working, the power is relatively large, so it generates a lot of heat. Only relying on the aluminum alloy shell to dissipate the heat can not dissipate the heat in time, resulting in the accumulation of heat, which will accelerate the aging of electrical appliances. and create a fire risk. Contents of the invention [0003] In order to solve the above problems, the present invention provides a nanofluid superconducting radiator, which is achieved through the following technical solutions. [0004] A n...

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Problems solved by technology

[0002] For large-scale integrated combined LED lamps, the problem of heat dissipation is more prominent. Because aluminum alloys are cheap, light in weight and have good thermal conductivity, aluminum alloy shells are generally used as heat sinks for LEDs. However, large-scale integrated When the combined LED lamp is working, the power is relatively large, so it generates a lot of heat. Only relying on the aluminum alloy shell to dissipate the heat can not dissipate the heat in time, resulting in the accumulation of heat, which will accelerate the aging of electrical appliances. and create a risk of fire

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