A method of manufacturing the foamed shoe material and semi-finished product including the following steps. Step S1: a foamable material is injected into a cavity of a blank mold to solidify, thereby generating a semi-finished product of the shoe material and a runner waste that are unfoamed. The runner waste could be shed for reusing directly as the foamable material without a granulating process. Step S2: the semi-finished product is cooled down and put into a cavity of the foaming mold, and the semi-finished product is evenly foamed in the cavity of the foaming mold to obtain a shoe material wherein the waste generated during the method of manufacturing the foamed shoe material could be effectively reused, and the yield rate of the shoe material thereby enhanced.

A method of manufacturing the foamed shoe material and semi-finished product including the following steps. Step S1: a foamable material is injected into a cavity of a blank mold to solidify, thereby generating a semi-finished product of the shoe material and a runner waste that are unfoamed. The runner waste could be shed for reusing directly as the foamable material without a granulating process. Step S2: the semi-finished product is cooled down and put into a cavity of the foaming mold, and the semi-finished product is evenly foamed in the cavity of the foaming mold to obtain a shoe material wherein the waste generated during the method of manufacturing the foamed shoe material could be effectively reused, and the yield rate of the shoe material thereby enhanced.

A method of forming a vehicle interior foam article, the method including applying a mold release agent onto an inner surface of a mold, delivering a solution having aldehyde scavenger(s) to the mold such that a reaction of the aldehyde scavenger(s) with the mold release agent is prevented, delivering a foam material into the mold, and casting the article.

In a polypropylene-based foamed molded body of the present invention, a density which is measured on the basis of ISO1183 is greater than or equal to 0.15 g/cm.sup.3 and less than or equal to 0.54 g/cm.sup.3, thermal resistance (R) at 30° C. in a thickness direction which is measured on the basis of ASTM E1530 is greater than or equal to 0.020 m.sup.2.Math.K/W and less than or equal to 0.125 m.sup.2.Math.K/W, thermal capacity per unit area (Q) at 30° C. is greater than or equal to 1.0 kJ/m.sup.2.Math.K and less than or equal to 2.5 kJ/m.sup.2.Math.K, and Expression 1 described below is satisfied.

Q>1/(4×R.sup.1/2)  (Expression 1)

In a polypropylene-based foamed molded body of the present invention, a density which is measured on the basis of ISO1183 is greater than or equal to 0.15 g/cm.sup.3 and less than or equal to 0.54 g/cm.sup.3, thermal resistance (R) at 30° C. in a thickness direction which is measured on the basis of ASTM E1530 is greater than or equal to 0.020 m.sup.2.Math.K/W and less than or equal to 0.125 m.sup.2.Math.K/W, thermal capacity per unit area (Q) at 30° C. is greater than or equal to 1.0 kJ/m.sup.2.Math.K and less than or equal to 2.5 kJ/m.sup.2.Math.K, and Expression 1 described below is satisfied.

Q>1/(4×R.sup.1/2)  (Expression 1)

Provided are a method for molding a foamed resin molded article having a mounting hole which is formed with good dimensional precision without occurrence of shape sag and which has an improved load resistance, a mold therefor, and a foamed resin molded article thereby. A method for molding a foamed resin molded article 1 including a mounting section 11 and a non-mounting section 12, using a mold 3 including a first mold 31 having a non-mounting-section mold portion 31a and a mounting-section mold portion 31b, a second mold 32, and a cavity 4 having a non-mounting-section cavity portion 42 for molding the non-mounting section 12 and a mounting-section cavity portion 41 for molding the mounting section 11. The method includes: a filling step of filling a material to be molded into at least the mounting-section cavity portion 41; and a core-back step of moving at least one of the non-mounting-section mold portion 31a, the mounting-section mold portion 31b, and the second mold 32 so that a cavity width of the non-mounting-section cavity portion 42 is increased while a cavity width of the mounting-section cavity portion 41 is constant, the filling step and the core-back step being sequentially performed.

Provided are a method for molding a foamed resin molded article having a mounting hole which is formed with good dimensional precision without occurrence of shape sag and which has an improved load resistance, a mold therefor, and a foamed resin molded article thereby. A method for molding a foamed resin molded article 1 including a mounting section 11 and a non-mounting section 12, using a mold 3 including a first mold 31 having a non-mounting-section mold portion 31a and a mounting-section mold portion 31b, a second mold 32, and a cavity 4 having a non-mounting-section cavity portion 42 for molding the non-mounting section 12 and a mounting-section cavity portion 41 for molding the mounting section 11. The method includes: a filling step of filling a material to be molded into at least the mounting-section cavity portion 41; and a core-back step of moving at least one of the non-mounting-section mold portion 31a, the mounting-section mold portion 31b, and the second mold 32 so that a cavity width of the non-mounting-section cavity portion 42 is increased while a cavity width of the mounting-section cavity portion 41 is constant, the filling step and the core-back step being sequentially performed.

The present disclosure concerns a digital fabricating method for constructing 3D structures, comprising the following steps: (a) precursor consist of monomers and photo-initiator is introduced into reaction cell; (b) exposing the precursor to the DLP projector for several times to gain an inhomogeneous sheet; (c) swelling the sheet in solvent to gain 3D structure. The disclosure provides a simple and easy way to produce precise 3D structure.

A mold tool assembly includes a first tool having a protrusion for producing a respective hole in a foam body and a second tool configured to cooperate with the first tool to mold the foam body. The second tool defines a cavity corresponding to the protrusion. The mold tool assembly also includes a movable plunger for clearing flash corresponding to and located at least partially within the cavity in the second tool, and movable between a disengaged position when the first and second tools are separated, and an engaged position when the first and second tools are closed. The mold tool assembly also includes an actuator configured to move the movable plunger between the engaged position and the disengaged position. In the engaged position, the movable plunger contacts the protrusion to seal the cavity, and in the disengaged position, at least a portion of the movable plunger extends below a bottom surface of the second tool into the hole.

A mold tool assembly includes a first tool having a protrusion for producing a respective hole in a foam body and a second tool configured to cooperate with the first tool to mold the foam body. The second tool defines a cavity corresponding to the protrusion. The mold tool assembly also includes a movable plunger for clearing flash corresponding to and located at least partially within the cavity in the second tool, and movable between a disengaged position when the first and second tools are separated, and an engaged position when the first and second tools are closed. The mold tool assembly also includes an actuator configured to move the movable plunger between the engaged position and the disengaged position. In the engaged position, the movable plunger contacts the protrusion to seal the cavity, and in the disengaged position, at least a portion of the movable plunger extends below a bottom surface of the second tool into the hole.