A replaceable mold part according to the present invention comprises: a depressed portion remained near a cavity; and a detachable portion, the detachable portion having a marking portion or a gas-releasing function, and being caught by a catch mechanism within the depressed portion. When a magnet is brought into proximity of the detachable portion through the cavity and an external magnetic field is applied, a magnet support portion's position is shifted from the fixed location to the released location within the depressed portion so that the catch mechanism of the detachable portion by the depressed portion is switched from the fixed state to the released state, thereby the detachable portion can easily be removed from the depressed portion through the cavity.

In embodiments described herein, it may be determined when to replace a degraded slush mold with a non-degraded slush mold by a method that may comprise monitoring a sample media while repeatedly contacting a surface of the sample media with an abrasive material to determine the number of contactings required to reduce a grain height of the surface of the sample media to a threshold grain height. The repeated contactings of the abrasive solution with the surface of the sample media may reduce the grain height of the sample media. The surface of the sample media may comprise a material substantially identical to the material of at least a portion of a forming surface of the slush mold.

In embodiments described herein, it may be determined when to replace a degraded slush mold with a non-degraded slush mold by a method that may comprise monitoring a sample media while repeatedly contacting a surface of the sample media with an abrasive material to determine the number of contactings required to reduce a grain height of the surface of the sample media to a threshold grain height. The repeated contactings of the abrasive solution with the surface of the sample media may reduce the grain height of the sample media. The surface of the sample media may comprise a material substantially identical to the material of at least a portion of a forming surface of the slush mold.

A tooling system may comprise a tool scanner, a tool database, and a user interface device. The tool scanner may be configured to scan a tool identifier on a tool. The tool database may have tool information associated with the tool identifier. The user interface device may be in communication with the tool scanner and the tool database. The user interface device may receive tool information from the tool database in response to the scan by the tool scanner, concurrently display a tool issue description and a tool issue image from the tool information of the tool database, receive a tool area selection with respect to the tool issue image, and provide access to a tool issue history from the tool database in response to the tool area selection.

A tooling system may comprise a tool scanner, a tool database, and a user interface device. The tool scanner may be configured to scan a tool identifier on a tool. The tool database may have tool information associated with the tool identifier. The user interface device may be in communication with the tool scanner and the tool database. The user interface device may receive tool information from the tool database in response to the scan by the tool scanner, concurrently display a tool issue description and a tool issue image from the tool information of the tool database, receive a tool area selection with respect to the tool issue image, and provide access to a tool issue history from the tool database in response to the tool area selection.

A method for determining residual moisture on and/or within a lens forming surface of a mold half includes the steps of carrying out an infrared inspection of at least a central portion of the lens forming surface of the mold half with the aid of an infrared camera, collecting measurement values resulting from the infrared inspection, which represent a degree of residual moisture on and/or within the lens forming surface, comparing the collected measurement values with a predefined threshold value representing a maximum tolerable residual moisture on and/or within a lens forming surface of a reference mold half, and, upon detection of an exceedance of the predefined threshold value representing the maximum tolerable residual moisture, preventing the inspected mold half from being used further.

The present invention provides a method for producing microparticles in which a porous micromold is degassed such that a precursor solution is quickly loaded into the micromold through the suction force of the micromold regardless of the viscosity and wettability of the precursor solution.

The present invention provides a method for producing microparticles in which a porous micromold is degassed such that a precursor solution is quickly loaded into the micromold through the suction force of the micromold regardless of the viscosity and wettability of the precursor solution.

An injection molding system includes a conveyor apparatus that moves a mold, and an injection molding apparatus that performs, using an injection cylinder and a screw, injection molding with the mold, wherein the improvement of the injection molding system includes at least one structure located in proximity to at least a part of the conveyor apparatus, wherein the at least one structure includes at least one element that is moveable, and wherein, when the screw is removed from the injection cylinder, the at least one element is in a position to prevent the at least one element from contacting the screw.

Provided is a management system for managing a count value of a counting device capable of displaying a screen indicating a count value of a number of shots of a mold. The management system is configured to: obtain a first image obtained by imaging the screen; obtain first read data including the count value by performing character recognition on the first image; and accumulate the first read data in a server.