Abstract: A molded product (consisting of resin compact and substrate) is formed by sealing and molding an electronic component mounted on a substrate in a resin compact by injecting/charging a heated/molten resin material into a cavity. Then, when a pressing member presses an ejector plate urged in a return direction (downward) in an ejective direction (upward) through a presser, a return pin guides mold releasing pins fixedly provided on the ejector plate, thereby ejecting and releasing the molded product from a mold with the mold releasing pins. Upon defective sliding of the mold releasing pins, the mold releasing pins can be returned to return positions by pressing the return pin with an upper mold section.

Abstract: There is provided a method of sealing and molding an optical device with resin by employing a die including a top piece, a bottom piece, an intermediate piece, and a mold release film pinched between the bottom and intermediate pieces. Thus, tensioned as prescribed to cover the bottom piece's cavity, when the bottom piece is heated, the mold release film expands and thus closely contacts the cavity's entire surface along the cavity's geometry so that the optical device can be sealed in transparent set resin shaped as desired.

Abstract: There is provided a method of sealing and molding an optical device with resin by employing a die including a top piece, a bottom piece, an intermediate piece, and a mold release film pinched between the bottom and intermediate pieces, Thus, tensioned as prescribed to cover the bottom piece's cavity, when the bottom piece is heated, the mold release film expands and thus closely contacts the cavity's entire surface along the cavity's geometry so that the optical device can be sealed in transparent set resin shaped as desired.

Abstract: There is provided a method of sealing and molding an optical device with resin by employing a die including a top piece, a bottom piece, an intermediate piece, and a mold release film pinched between the bottom and intermediate pieces and thus tensioned as prescribed to cover the bottom piece's cavity, when the bottom piece is heated, and the mold release film expands and thus closely contacts the cavity's entire surface along the cavity's geometry so that the optical device can be sealed in transparent set resin shaped as desired.

Abstract: In a resin sealing and molding method of an electronic component, a mold assembly of a three-piece structure of upper, intermediate and lower molds, and a mold release film are used. When the mold release film covers a cavity surface, it is forcibly attracted toward a lower mold cavity surface. Thus, the entire surface of the cavity, including a cavity surface formed of cavity side surface, cavity partition surface and communication path surface, in addition to the lower mold cavity surface, is covered with the mold release film applied with tension. Molten resin within the cavity is distributed uniformly into blocks constituting the cavity, via a communication path, and the electronic component in each block is sealed and molded while being completely immersed in the molten resin. This ensures close contact of the mold release film with the cavity along its shape, and prevents warpage of the finished, sealed substrate.

Abstract: There is provided a method of sealing and molding an optical device with resin by employing a die including a top piece, a bottom piece, an intermediate piece, and a mold release film pinched between the bottom and intermediate pieces and thus tensioned as prescribed to cover the bottom piece's cavity, when the bottom piece is heated, and the mold release film expands and thus closely contacts the cavity's entire surface along the cavity's geometry so that the optical device can be sealed in transparent set resin shaped as desired.

Abstract: An upper mold, a lower mold, a middle mold, and a release film are used in a method of resin sealing of an electronic component. The release film is sandwiched between the lower mold and the middle mold and held under a prescribed tension to cover a cavity of the lower mold. A cavity side surface is also covered with the release film. Therefore, releasability of a cured resin from the cavity side surface is increased. As a result, the cured resin is prevented from being damaged near the cavity side surface.

Abstract: There is provided a method of sealing and molding an optical device with resin by employing a die including a top piece, a bottom piece, an intermediate piece, and a mold release film pinched between the bottom and intermediate pieces and thus tensioned as prescribed to cover the bottom piece's cavity, when the bottom piece is heated, and the mold release film expands and thus closely contacts the cavity's entire surface along the cavity's geometry so that the optical device can be sealed in transparent set resin shaped as desired.

Abstract: A substrate with a plurality of semiconductor chips mounted thereon is set in a die. The die is then clamped. The die thus clamped forms a space, into which resin is introduced. In doing so, a member is provided to fill a gap between an upper surface of each chip and the die. The member is elastic and thus elastically deforms when the die is clamped. Thus from the elastic member to each chip's upper surface a substantially uniform pressure is exerted. The elastic member is a film extending substantially parallel to each chip's upper surface and contacts the upper surface as the member is tensioned in its in-plane direction. The above resin introduction step can prevent the semiconductor chip from having an upper surface with resin flash.

Abstract: A substrate with a plurality of semiconductor chips mounted thereon is set in a die. The die is then clamped. The die thus clamped forms a space, into which resin is introduced. In doing so, a member is provided to fill a gap between an upper surface of each chip and the die. The member is elastic and thus elastically deforms when the die is clamped. Thus from the elastic member to each chip's upper surface a substantially uniform pressure is exerted. The elastic member is a film extending substantially parallel to each chip's upper surface and contacts the upper surface as the member is tensioned in its in-plane direction. The above resin introduction step can prevent the semiconductor chip from having an upper surface with resin flash.