An injection molding tool for producing a molded part and a corresponding method are disclosed. The injection mold tool comprises a first tool mold half and a second tool mold half, which together with a first slider and at least one second slider define a free space for the molded part to be produced. A lever which is pretensioned with an elastic element is assigned to an end switch such that a movable and free end of the lever cooperates with the end switch due to a movement of the first slider.

An injection mold, in particular for encapsulating rotors of electric machines, has a mold, wherein the mold has an arrangement of mold segments. The arrangement forms, along a longitudinal axis, a cavity for a component to be arranged. An exchange unit is provided, which is designed to remove at least one mold segment from and/or insert at least one mold segment into the arrangement, with the result that a size of the cavity can be changed.

Disclosed herein, amongst other things, is a method for converting a design of an original preform that is blow moldable to form a container into a converted preform having less molding material that is blow moldable to form the same container. The method includes retaining a neck finish and body of the original preform on the converted preform. The method further includes replacing the original base of the original preform with a converted base having an outer base surface that joins with an outer body surface of the body at an base split-line of the original base and that fits offset within an outer body surface of the original base, whereby the converted preform has a reduced total length, disregarding any gate vestige that may be formed thereon, relative to a total length of the original preform.

The invention presents molding tools, in which a position of a molding tool within a base tool or a position of molding cores relative to each other can be set by adjusting a position of base tools by means of controllable adjustment elements.

A mold conveyance guide apparatus includes: a linear guide that is attached along a conveyance direction of a mold to a mold attachment surface of at least one of a fixed platen or a movable platen to which the mold is fixed; a slider that is movably attached to the linear guide; and a coupling arm that is swingably attached to the slider in a direction coming closer to or separating from the mold attachment surface and is coupled to the mold in an engageable and disengageable manner.

A polymer injection-molding mold having a polymer injection-molding mold having a core insert and a cavity insert; at least two rear-wall glass-filled polyimide insulation plates, one of the rear-wall insulation plates being inset into a rear-exterior wall of the core insert and one of the rear-wall insulation plates being inset into a rear-exterior wall of the cavity insert; at least two side-wall glass-filled polyimide insulation plates, one of the side-wall insulation plates being inset into a side-exterior wall of the core insert and one of the side-wall insulation plates being inset into a side-exterior wall of the cavity insert; the at least two rear-wall glass-filled polyimide insulation plates and the at least two side-wall glass-filled polyimide insulation plates being inset into each of their respective walls such that a substantially planer surface of each insulation plate is substantially flush with an exterior planar surface of the respective wall into which it is inset; the rear-wall and side-wall glass-filled polyimide insulation plates having the following physical properties: i) thermal conductivity of about 0.30 W/mk; ii) a coefficient of expansion (in length and width) of about 1110.sup.6 1/K; iii) a compressive strength of about 750 N/mm.sup.2 at 23 C.; iv) a compressive strength of about 500 N/mm.sup.2 at 200 C.; v) a bending strength of about 720 N/mm.sup.2 at 23 C.; and vi) a density of about 2 g/cm.sup.3; the rear-wall and side-wall glass-filled insulation plates having a thickness ranging from 3 to 5 millimeters; the cavity insert and core insert having a plurality of cooling holes, the cooling holes having a diameter ranging from 3 to 6 millimeters; a plurality of substantially cylindrical fluid-cooling channels that are respectively positioned within the cavity insert and core insert at a relative distance from a cavity-insert molding surface or a core-insert molding surface, wherein the relative distance for each fluid-cooling channel is substantially equal to the fluid-cooling channel's cross-sectional diameter, wherein the relative distance is also the shortest distance between a fluid-cooling channel's wall and a cavity-insert molding surface or a core-insert molding surface; and a temperature-sensing thermocouple that is located within the cavity insert or core insert in a position that is substantially adjacent to an estimated last volume of space to be filled by polymer-mold flow.

Techniques disclosed herein relate to molding inserts with improved cooling performance. A mold insert includes a body and a plurality of heat sink elements coupled to the body. The body includes an area with a recessed surface that has different depths in a plurality of different regions. The plurality of heat sink elements is configured to provide different thermal resistances in the plurality of different regions of the mold insert, where a thermal resistance of the mold insert in a region with a higher recessed surface depth is lower than a thermal resistance of the mold insert in a region with a lower recessed surface depth. In some embodiments, the plurality of heat sink elements form cooling channels that are configured to conduct a cooling fluid from regions of the mold insert with higher recessed surface depths to regions of the mold insert with lower recessed surface depths.

A method for injection molding of a weld line free minus power lens element comprises injecting a melt of thermoplastic material at a temperature higher than a glass transition temperature (Tg) of the thermoplastic material in an initial molding cavity delimited by two facing mold inserts, wherein the melt of thermoplastic material comprises at least one UV absorber. During the injecting, the two facing mold inserts are moved toward one another to define a final molding cavity whose volume is less than that of the initial molding cavity. After cooling and disassembling of the two facing mold inserts, the weld line free minus power lens element is recovered. One of the two facing mold inserts comprises a flat surface facing the initial molding cavity, thereby to form a flat surface on one side of the weld line free minus power lens element. The other of the two facing mold inserts comprises a convex surface facing the initial molding cavity, thereby to form a concave surface on an opposite side of the weld line free minus power lens element.

A mold insert has at least one filament cavity and a stack of at least a first and second insert plates, wherein the first plate has a front face that closely abuts a front face of the second insert plate. A portion of the a filament cavity is provided in at least one of the front faces of the first and second insert plates such that the filament cavity is open at a top surface of the mold insert but does not extend to a bottom surface of the mold insert. A venting cavity is provided in the same front face of the insert plate in which the portion of the at least one filament cavity is provided. The venting cavity, which is in air-conducting connection with the blind-hole end of the filament cavity, has a depth between 1 m and 20 m. A method of manufacturing the mold insert includes providing first and second insert plates, forming a portion of a filament cavity into at least one of the front faces of the insert plates, forming a venting cavity into the front face with the filament cavity, and bringing the front faces of the plates into close abutment to form a filament cavity.

A mold assembly 100 for forming a microneedle array, wherein the mold assembly facilitates expulsion of trapped gasses from the molding system. The mold assembly may comprise a first mold portion 102 comprising a plurality of recesses 104 formed therein, a second mold portion 106 disposed adjacent the first mold portion, wherein a surface of the second mold portion and the plurality of recesses of the first mold portion define a mold cavity, a mold film insert 112 disposed within the mold cavity between the first mold portion and the second mold portion of the mold assembly, the mold film insert comprising a plurality of perforated layers 114, each of the perforated layers comprising a plurality of perforations.