▎ 摘　　要

NOVELTY - The module (100) is configured to dissipate heat of a heat source (200) and comprises a first heat conduction element (110) comprising a first metallic layer, a second metallic layer, and a graphene layer. The graphene layer is located between the first metallic layer and the second metallic layer. The first metallic layer is in thermal contact with the heat source. A second heat conduction element (120) comprises a first end (E1) and a second end (E2) opposite to each other. The first end is in thermal contact with the second metallic layer. A heat dissipation element (130) is in thermal contact with the second end. The heat generated by the heat source is transferred to the second end of the second heat conduction element sequentially through the first heat conduction element and the first end of the second heat conduction element and is dissipated out of the remote heat exchanging module through the heat dissipation element. USE - Remote heat exchanging module for electronic apparatus such as portable computer, tablet computer, smartphone, and navigator. ADVANTAGE - The remote heat exchanging module is applicable to a light, thin and small portable electronic apparatus. The first heat conduction element is easily post-processed and assembled. The graphene layer is prevented from damaged by an external force. The first heat conduction element is correspondingly smoothly combined with the second heat conduction element through soldering. The first heat conduction element is abutted between the carrier and the heat source, to achieve both assembly convenience and a good heat conduction property. The integrity of the graphene layer is maintained, and component combination and assembly are easier, so that the heat dissipation efficiency and service life is improved. The thermal contact resistance between thermal transfer components through a great heat conduction characteristic of the graphene layer is efficiently reduced, and a component temperature from soaring is prevented since of heat congestion is made on a heat transfer path of the remote heat exchanging module or the remote heat exchanging module. Concentrated hot points are rapidly dispersed to achieve a good thermal diffusion effect, so that local overheating is relieved and the service life of related components is improved. The heat conduction material is used to fill the air gaps to reduce the thermal contact resistance and improve heat dissipation performance. The first heat conduction element obtained through combination in the foregoing manner includes the graphene layer with a great heat conductivity, and is easily processed because of the first metallic layer and the second metallic layer on an outer side. The efficiency of thermal contact between the first heat conduction element and the heat source is improved. The remote heat exchanging module includes a soldering material and a heat conduction material to smoothly combine the first heat conduction element with the heat source and the second heat conduction element without correspondingly reducing heat transfer efficiency. The problem of system heat dissipation through heat exchange is solved. The first heat conduction element is easily post-processed and assembled, and the graphene layer is prevented from being easily damaged by an external force. The heat conduction element or a thin-layered heat conduction structure formed by cladding a graphene layer between metallic layers is mechanically characterized by both high heat dissipation efficiency and applicability to processing and combination. DESCRIPTION OF DRAWING(S) - The drawing shows a schematic view of a remote heat exchanging module. Remote heat exchanging module (100) First heat conduction element (110) Second heat conduction element (120) Heat dissipation element (130) End of heat conduction element (E1, E2)