Abstract: A package structure with a heat spreader and manufacturing method thereof is disclosed. The package structure includes a substrate, a ground pad, a heat spreader, a non-conductive adhesive layer, and a pre-solder layer. A die is seated on the substrate, and the ground pad is disposed on the surface of the substrate. The manufacturing method of the package structure includes the following steps: (a) providing the substrate; (b) forming the pre-solder layer on the ground pad by solder paste printing; (c) forming the non-conductive adhesive layer on the substrate surface for being adjacent to the pre-solder layer by adhesive dispensing; (d) disposing the heat spreader onto the non-conductive layer and the pre-solder layer; and (e) heating the non-conductive adhesive layer for solidification and continuing to heat the pre-solder layer for solder reflow so that the heat spreader is adhered to the substrate via the non-conductive adhesive layer and coupled to the ground pad via the pre-solder layer.

Abstract: A manufacturing method of a flip chip package mainly comprises the following steps. Initially, a chip having an active surface with a plurality of bumps formed thereon is provided. Next, the active surface of the chip is faced to and disposed on an upper surface of a substrate. In such manner, the chip will be electrically connected to the substrate and a gap between the chip and the substrate will be formed. Afterwards, an underfill is filled in the gap and then a first curing process is performed to have the underfill partially hardened to have the underfill transformed into a partially hardened underfill. Finally, the combination of the chip, the substrate and the partially hardened underfill is flipped over to have the substrate located above the chip, then a second curing process is performed to have the partially hardened underfill into a fully hardened underfill, and then flipping over the combination of the chip, the substrate and the fully hardened underfill.

Abstract: A manufacturing method of a flip chip package mainly comprises the following steps. Initially, a chip having an active surface with a plurality of bumps formed thereon is provided. Next, the active surface of the chip is faced to and disposed on an upper surface of a substrate. In such manner, the chip will be electrically connected to the substrate and a gap between the chip and the substrate will be formed. Afterwards, an underfill is filled in the gap and then a first curing process is performed to have the underfill partially hardened to have the underfill transformed into a partially hardened underfill. Finally, the combination of the chip, the substrate and the partially hardened underfill is flipped over to have the substrate located above the chip, then a second curing process is performed to have the partially hardened undefill into a fully hardened underfill, and then flipping over the combination of the chip, the substrate and the fully hardened underfill.

Abstract: A package structure with a heat spreader and manufacturing method thereof is disclosed. The package structure includes a substrate, a ground pad, a heat spreader, a non-conductive adhesive layer, and a pre-solder layer. A die is seated on the substrate, and the ground pad is disposed on the surface of the substrate. The manufacturing method of the package structure includes the following steps: (a) providing the substrate; (b) forming the pre-solder layer on the ground pad by solder paste printing; (c) forming the non-conductive adhesive layer on the substrate surface for being adjacent to the pre-solder layer by adhesive dispensing; (d) disposing the heat spreader onto the non-conductive layer and the pre-solder layer; and (e) heating the non-conductive adhesive layer for solidification and continuing to heat the pre-solder layer for solder reflow so that the heat spreader is adhered to the substrate via the non-conductive adhesive layer and coupled to the ground pad via the pre-solder layer.