The present invention relates to a material for preparing an intraocular lens. In particular, it relates to an ophthalmic medical material suitable for manufacture of micro-incision intraocular lens, having suitable water content and a suitable refractive index.

A mold includes: a first molding surface configured to form a lens surface of a scanning lens being elongated in a main-scanning direction; and a first coolant passage, which is disposed within the mold and through which a coolant to control the temperature of the first molding surface flows, wherein the first coolant passage includes: a first passage portion corresponding to a first lens portion which is a portion protruding most in an optical axis direction in the lens surface; and a second passage portion corresponding to a second lens portion which is a portion retreated most in the optical axis direction in the lens surface, and the second passage portion is located to be closer to the second lens portion than a virtual plane, which passes through the first passage portion and is orthogonal to the optical axis direction.

An ophthalmic lens incorporating an array of microlenses.

An optical lens molding device includes a raw material supplying unit for providing a solid-state optical material, a feeding unit for transporting the solid-state optical material along a feeding direction, a heating unit including a heating body and a heating conduit in spatial communication with the supplying unit for entering of the solid-state optical material, and a molding unit. The heating conduit has a downstream part extending in the heating body to heat and melt the solid-state optical material in the heating conduit into a fluid-state optical material. The molding unit defines a cavity and a sprue in communication between the cavity and the downstream part to permit the molten fluid-state optical material to be pressed by the solid-state optical material and to flow in and fill the cavity through the sprue.

A method for manufacturing an optical lens includes pressing a fluid-state optical material by using a solid-state optical material to inject the fluid-state optical material molten from the solid-state optical material into a cavity. The solid-state optical material is molten only at the part adjacent to the cavity to form the fluid-state optical material, which facilitates transport of the optical material and minimizes residual waste. The pressing force applied to the solid-state optical material can be controlled to hence control the moving rate of the solid-state optical material, thereby precisely controlling the injection volume and injection rate of the fluid-state optical material.

An injection molding method includes the steps of:(A) preparing a molding unit and an injection unit, the molding unit including a first mold having a protruding portion, and a second mold having a movable post cooperating with an inner peripheral surface thereof to define a cavity; (B) moving the molds toward each other until the protruding portion cooperates with the second mold to define a forming space; (C) activating the injection unit for injecting the molten optical material into the forming space; (D) cooling the molding unit; and (E) moving the molds away from each other and subsequently activating the movable post to push a solidified optical material out of the forming space.

A method, a computer program product, and a system for determining an optical parameter of an optical lens, as well as a related method for producing the optical lens by adjusting the optical parameter are disclosed. The method includes: a) capturing an image picturing the optical lens by using a camera; and b) determining an optical parameter of the optical lens by processing the image, wherein the camera generates a signal related to a position of a focus, and the optical parameter of the optical lens is determined by using the signal related to the position of focus.

The method and the system allow determining the optical parameter of the optical lens in a direct fashion by applying the signal related to the position of the focus as generated by the camera as a measured value for the optical parameter of the optical lens.

A manufacturing facility for manufacturing an optical element according to a prescription includes a first station configured for surfacing and polishing a second face of a lens blank and pre-cleaning the second face of the lens blank including a finishing drying which allows the lens blank to be put on hold, a second station configured for deep cleaning the second face of the lens blank and hard coating the second face of the lens blank, a tunnel oven configured to degas the lens blank, a vacuum box coater configured to apply an antireflection (AR)-coating, and a third station configured to deblock the processed lens blank from the block piece.

A method for manufacturing an optical element (100) from a curable material (50) using an additive manufacturing technology comprising steps of: providing a first portion of curable material (50), forming a first part of the optical element by irradiating the surface (55) of the curable material with a first curing surface energy, the first curing surface energy being strictly lower than a first predetermined energy threshold and higher than a second predetermined threshold, and forming, after the irradiation of the first part with the first curing surface energy, at least a second part of the optical element, distinct from the first part of the optical element, by irradiating, with at least a second curing surface energy, the surface of the curable material, the second curing surface energy irradiating both the second part of the optical element (100) and at least a portion of the first part of the optical element, the sum of the first curing surface energy and the at least second curing surface energy being higher than or equal to the first predetermined energy threshold. A manufacturing system (1) for manufacturing an optical element.

Systems and methods for lens creations are disclosed. The method includes initiating light transmission from a light source through a diffuser into a container holding resin and a substrate. The light transmission is performed according to an irradiation pattern wherein each point in the resin is illuminated by at least 10% of the diffuser. This causes a lens to be formed. To achieve this illumination, at least 15% of the diffuser receives light from the light source. Further, a diameter of the diffuser is greater than or equal to a diameter of the substrate. The system performing the methods includes a polymerization apparatus and may include a resin conditioning and reservoir apparatus, a metrology unit, a resin drainage apparatus and an optional postcuring apparatus.