A system and method for production of a customizable food and beverage cooler are disclosed. In one embodiment of the system, a mold includes two primary halves configured to produce an injection molded part that is a component of the food and beverage cooler. An aperture intersects one of the primary halves of the mold to accommodate an insertion block that includes a reverse image thereon such that molten plastic flow around the reverse image produces an integrally molded image on the component of the food and beverage cooler. Further, the aperture accommodates a combination insertion block and insertion plate having the reverse image thereon. One of the insertion block or combination insertion block and insertion plate is selected for disposing in the aperture based on the desired production run of the injection molded part.

Method for producing a plastic molded part (1), wherein, in the method, a mold insert (3) with a diffractive surface relief (32) is provided, the mold insert (3) is inserted into one mold half of an injection mold (5) which, together with at least one further mold half, forms a cavity for producing the plastic molded part (1), wherein the mold insert (3) is inserted into the injection mold (5) such that the diffractive surface relief (32) forms a partial area of the surface of the cavity formed by the mold half (5), and the plastic molded part (1) is molded by injection molding by means of the injection mold (5). The invention furthermore relates to a mold insert as well as an injection mold for such a method, as well as a plastic molded part produced in this way.

A modular pod for an injection mold includes a molding insert shaped to produce a molded part. The modular pod can be linked with a plurality of additional modular pods to form an injection mold. When a molding insert experiences a problem, the molding insert can be removed from the mold and replaced with a replacement insert. The modular pod employs a mechanical solution to eject the formed parts from the mold, without employing hydraulics.

An injection molding method that includes: (a) fitting an injection molding machine with an injection mold defining one or more molding cavities, with at least one mold plate provided with one or more channels for circulation of a tempering medium, (b) providing a feed of plastic material, (c) heating the molding cavities by circulating through the channels a first tempering medium, (d) injecting plastic material into the closed heated mold to fill the molding cavities, (e) cooling the molding cavities of the filled closed injection mold until at least partly solidifying the molded plastic parts by circulating through the channels a second tempering medium, (f) opening the injection mold by parting the injector plate from the ejector plate, (g) ejecting the at least partly solidified molded plastic parts by actuation of ejector pins of the ejector plate, and (h) repeating the cycle of steps (c)-(g).

Provided is a mold for a seat pad with a mesh fixed, which can easily fix a mesh to be inserted in a molding process. The mold includes a plurality of mold members overlapping each other and molding a seat pad by foaming a resin injected into a space formed between the mold members, the mold members are formed with a mesh accommodating groove accommodating a mesh, and the mesh is fitted into and fixed to the mesh-accommodating groove.

On a foam plastics molding machine, a molding unit, defined by a mold and an interface frame equipped with a number or quantity of plastic molding material and operating fluid inlets, is loaded into a raised window in a fixed frame of the machine by positioning the molding unit in a fixed position on a trolley; positioning the trolley astride a fixed platform; raising the platform so that vertical ribs on the interface frame slidably engage corresponding vertical guides forming part of the machine and on a level with the window; connecting the guides to the ribs; and moving the guides towards the window.

A molding die has a lower holder, an intermediate holder, an upper holder, a lock member, an upper link bar, a lower link bar, a restriction member, and a drive part. A movement of the lock member in a molding die opening direction or a molding die closing direction is restricted by the intermediate holder. The upper link bar has a first retaining groove in which the lock member fits when being located at a molding die closing position. The lower link bar has a second retaining groove in which the lock member fits and a release portion that enables the lock member to be released from the first retaining groove. The restriction member is movable between a restriction position that prevents the lock member from fitting in the second retaining groove and a free position that enables the lock member to fit in the second retaining groove.

A method for moulding a connector which includes a connecting element having a cylindrical body and, one arm extending along an arm axis for the L-shaped connector or, two arms extending along two different arm axes for the T-shaped connector, the body being capable of being connected to an injector, and each arm being capable of being connected to the end of a pipe. The moulding method includes a) providing a mould having a cavity for a T-shaped connecting element, the cavity including a cavity for a body and two cavities for arms and b) arranging an insert in the cavity for one of the two arms when an L-shaped connecting element is to be moulded.

The invention relates to a nozzle for use in a device for administering a liquid medical formulation, to a method for producing the nozzle in the form of a microfluidic component and to a tool for producing microstructures of the microfluidic component. The nozzle is formed by a plastics plate with groove-like microstructures which are covered by a plastics cover on the longitudinal side in a fixed manner. The production method includes a moulding process in which a moulding tool is used, which moulding tool has complementary metal microstructures which have been produced from a semiconductor material in an electrodeposition process by means of a master component.

Molding assemblies and molding processes are disclosed. The molding assemblies are for producing a product and include a first subassembly and a second subassembly for the producing of the product. The first subassembly includes a cavity insert arrangement corresponding with the design of the product, a movable insert abutting the cavity insert arrangement, and rail members securing the movable insert with interlocking features at a specific location, the specific location being one of multiple movable insert positions. The molding process includes molding a first product with the movable insert and the additional movable insert being positioned at a first movable insert portion, removing the subassembly from the second subassembly, re-positioning the movable insert and the additional movable insert to a second movable insert position, and molding a second product with the movable insert and the additional movable insert being positioned at the second movable insert portion.