Negative electrode sheet and lithium ion battery

1 . A negative electrode sheet, comprising: a negative electrode current collection layer; an active material layer, attached to an inner surface of the negative electrode current collection layer, wherein one end of the active material layer away from the negative electrode current collection layer is opened with a heat transport hole, and a length direction of the heat transport hole extends towards one end close to the negative electrode current collection layer; a heat transport structure, comprising a heat transport layer and a heat transport column, wherein an inner surface of the heat transport layer is attached to the one end of the active material layer away from the negative electrode current collection layer, one end of the heat transport column is attached to the inner surface of the heat transport layer, and the other end of the heat transport column is inserted into the heat transport hole; and a lithium replenishment layer, wherein the lithium replenishment layer is attached to an outer surface of the heat transport layer, and the lithium replenishment layer is obtained by performing a lithium replenishment procedure on an assembly of the negative electrode current collection layer, the active material layer, and the heat transport structure; wherein the heat transport layer is configured to absorb the heat generated in the lithium replenishment procedure, and transport the heat through the heat transport column to the negative electrode current collection layer, to achieve an effect of dissipating the heat generated in the lithium replenishment procedure. 2 . The negative electrode sheet according to claim 1 , wherein one end of the heat transport hole facing the negative electrode current collection layer has a first distance L 1 from the inner surface of the negative electrode current collection layer; and the heat transport column inserted into the heat transport hole has the first distance L 1 from the inner surface of the negative electrode current collection layer. 3 . The negative electrode sheet according to claim 1 , wherein the heat transport hole extends through an inner and an outer surface of the active material layer; and the heat transport column inserted into the heat transport hole is connected between the heat transport layer and the negative electrode current collection layer. 4 . The negative electrode sheet according to claim 2 , wherein the number of the heat transport hole is the same as that of the heat transport column, and is plural; and the size of the heat transport hole is the same as that of the heat transport column. 5 . The negative electrode sheet according to claim 4 , wherein in a width direction of the negative electrode sheet, the negative electrode sheet has an electrode sheet width, and the number of the heat transport hole is a first numerical value; in a length direction of the negative electrode sheet, the negative electrode sheet has an electrode sheet length, and the number of the heat transport hole is a second numerical value; and the electrode sheet width, the electrode sheet length, the first numerical value, and the second numerical value meet a first ratio relationship. 6 . The negative electrode sheet according to claim 5 , wherein the inner surface of the heat transport layer is provided with a plurality of the heat transport columns, and the plurality of the heat transport columns are perpendicular to the heat transport layer. 7 . The negative electrode sheet according to claim 6 , wherein the heat transport layer has a first thickness, the heat transport column has a second thickness, and the active material layer has a third thickness; and the first thickness and the third thickness meet a second ratio relationship, and the second thickness and the third thickness meet a third ratio relationship. 8 . The negative electrode sheet according to claim 1 , the lithium replenishment layer comprises a plurality of lithium replenishment blocks distributed in a rectangular array; and a second distance L 2 is present between two adjacent lithium replenishment blocks, wherein 0≤L 2 ≤5 mm. 9 . The negative electrode sheet according to claim 8 , wherein the material of the active material layer comprises a Si-graphite active material; and the material of the heat transport structure comprises one of graphite, graphene, carbon tubes or carbon fibers. 10 . A lithium ion battery, comprising: a battery core, an electrolyte solution, and a packaging film, the battery core and the electrolyte solution being both provided inside the packaging film; and the battery core comprising a positive electrode sheet, a separator, and a negative electrode sheet, the positive electrode sheet and the negative electrode sheet being separated by the separator and arranged in a stacked state, wherein the negative electrode sheet comprising: a negative electrode current collection layer; an active material layer, attached to an inner surface of the negative electrode current collection layer, wherein one end of the active material layer away from the negative electrode current collection layer is opened with a heat transport hole, and a length direction of the heat transport hole extends towards one end close to the negative electrode current collection layer; a heat transport structure, comprising a heat transport layer and a heat transport column, wherein an inner surface of the heat transport layer is attached to the one end of the active material layer away from the negative electrode current collection layer, one end of the heat transport column is attached to the inner surface of the heat transport layer, and the other end of the heat transport column is inserted into the heat transport hole; and a lithium replenishment layer, wherein the lithium replenishment layer is attached to an outer surface of the heat transport layer, and the lithium replenishment layer is obtained by performing a lithium replenishment procedure on an assembly of the negative electrode current collection layer, the active material layer, and the heat transport structure; the heat transport layer is configured to absorb the heat generated in the lithium replenishment procedure, and transport the heat through the heat transport column to the negative electrode current collection layer, to achieve an effect of dissipating the heat generated in the lithium replenishment procedure.