Patent application number | Description | Published |
20080197470 | Stacked electronic component and manufacturing method thereof - A stacked electronic component comprises a first electronic component adhered on a substrate via a first adhesive layer, and a second electronic component adhered by using a second adhesive layer thereon. The second adhesive layer has a two-layer structure formed by a same material and having different modulus of elasticity. The second adhesive layer of the two-layer structure has a first layer disposed at the first electronic component side and a second layer disposed at the second electronic component side. The first layer softens or melts at an adhesive temperature. The second layer maintains a layered shape at the adhesive temperature. According to the stacked electronic component, occurrences of an insulation failure and a short circuiting are prevented, and in addition, a peeling failure between the electronic components, an increase of a manufacturing cost, and so on, can be suppressed. | 08-21-2008 |
20100035381 | METHOD OF MANUFACTURING STACKED SEMICONDUCTOR DEVICE - A first semiconductor element is mounted on a wiring board. A second semiconductor element having a portion projecting to an outer side of an outer periphery of the first semiconductor element is disposed on the first semiconductor element via an adhesive. The adhesive has a viscosity (μ | 02-11-2010 |
20100062566 | Method of manufacturing stack-type semiconductor device and method of manufacturing stack-type electronic component - A first semiconductor element is bonded on a substrate. A complex film formed of integrated dicing film and adhesive film is affixed on a rear surface of a semiconductor wafer which is to be second semiconductor elements, the dicing film having a thickness within a range of not less than 50 μm nor more than 140 μm and a room temperature elastic modulus within a range of not less than 30 MPa nor more than 120 MPa, and the adhesive film having a thickness of 30 μm or more and a room temperature elastic modulus before curing within a range of not less than 500 MPa nor more than 1200 MPa. The semiconductor wafer together with the adhesive film is divided into the second semiconductor elements. The second semiconductor element is picked up from the dicing film to be bonded on the first semiconductor element. | 03-11-2010 |
20100207252 | Manufacturing method of semiconductor device - An adhesive layer of which thickness is over 25 μm and a dicing tape are laminated on a rear surface of a semiconductor wafer. The semiconductor wafer is cut together with a part of the adhesive layer by using a first blade of which cutting depth reaches the adhesive layer. The adhesive layer is cut together with a part of the dicing tape by using a second blade of which cutting depth reaches the dicing tape and of which width is narrower than the first blade. A semiconductor element sectioned by cutting the semiconductor wafer with the adhesive layer is picked up from the dicing tape, and is adhered on another semiconductor element or a circuit board. | 08-19-2010 |
20110079629 | Method and apparatus for manufacturing stacked-type semiconductor device - A method of manufacturing a stacked-type semiconductor device, comprises: arranging a plurality of stacked chips obtained by stacking semiconductor chips on a plurality of stages on a support substrate; connecting a semiconductor chip of each stage in each stacked chip and the support substrate by wire while performing heating in units of stacked chips; performing plastic molding of each stacked chip; and separating the stacked chips from each other. | 04-07-2011 |
20110263076 | Stacked semiconductor device - A stacked semiconductor device includes a first semiconductor element bonded on a circuit base. The first semiconductor element is electrically connected to a connection part of the circuit base via a first bonding wire. A second semiconductor element is bonded on the first semiconductor element via a second adhesive layer with a thickness of 50 μm or more. The second adhesive layer is formed of an insulating resin layer whose glass transition temperature is 135° C. or higher and whose coefficient of linear expansion at a temperature equal to or lower than the glass transition temperature is 100 ppm or less. | 10-27-2011 |
20110281396 | Stacked electronic component and manufacturing method thereof - A stacked electronic component comprises a first electronic component adhered on a substrate via a first adhesive layer, and a second electronic component adhered by using a second adhesive layer thereon. The second adhesive layer has a two-layer structure formed by a same material and having different modulus of elasticity. The second adhesive layer of the two-layer structure has a first layer disposed at the first electronic component side and a second layer disposed at the second electronic component side. The first layer softens or melts at an adhesive temperature. The second layer maintains a layered shape at the adhesive temperature. According to the stacked electronic component, occurrences of an insulation failure and a short circuiting are prevented, and in addition, a peeling failure between the electronic components, an increase of a manufacturing cost, and so on, can be suppressed. | 11-17-2011 |
20120306103 | STACKED ELECTRONIC COMPONENT AND MANUFACTURING METHOD THEREOF - A stacked electronic component comprises a first electronic component adhered on a substrate via a first adhesive layer, and a second electronic component adhered by using a second adhesive layer thereon. The second adhesive layer has a two-layer structure formed by a same material and having different modulus of elasticity. The second adhesive layer of the two-layer structure has a first layer disposed at the first electronic component side and a second layer disposed at the second electronic component side. The first layer softens or melts at an adhesive temperature. The second layer maintains a layered shape at the adhesive temperature. According to the stacked electronic component, occurrences of an insulation failure and a short circuiting are prevented, and in addition, a peeling failure between the electronic components, an increase of a manufacturing cost, and so on, can be suppressed. | 12-06-2012 |