The invention relates generally to an injection molding apparatus and, in particular, to an injection molding apparatus having an actuator biased against a mold plate.
Injection molding heats a material (e.g., plastic) into a melt, injects the melt into a mold, and, after the melt cools and forms a solid article in the mold, ejects the article from the mold. Typically, an injection molding apparatus comprises heated components that are kept at the operating temperature of the melt, a requirement that presents challenges to components with an operating temperature below the operating temperature of the melt.
In an illustrated embodiment, an injection molding apparatus is provided. The injection molding apparatus comprises: an injection unit; a clamping unit; a mold assembly including a mold plate, a manifold, an actuator mounted on and upstream of the manifold, and at least one nozzle coupled to and downstream of the manifold, the actuator for reciprocating a valve pin between an open position allowing a melt to pass through the nozzle and a closed position preventing the melt from passing through the nozzle, the mold assembly further including a biasing mechanism biasing the actuator upstream towards the mold plate.
Specific embodiments of the present application are now described with reference to the figures. The following detailed description is merely exemplary in nature and is not intended to limit the concepts and uses of the concepts. Furthermore, there is no intention to be restricted by any expressed or implied theory in the present disclosure. In the description, “downstream” is used with reference to the direction of the moldable liquid flow from an injector to a mold cavity, and also with reference to the order of components, or features thereof, through which the mold material flows from the injector to the mold cavity, whereas “upstream” is used with reference to the opposite direction.
Mold assembly 20 comprises a plurality of nozzles 68 (and will henceforth be referred to individually as nozzle 68 and collectively as nozzles 68). Manifold 60 is a melt delivery body, which, depending on the application of injection molding apparatus 10, can include a network of melt channels (not shown) for distributing melt from injection unit 15 to nozzles 68. Core plate 40 includes a plurality of cores 65. Cavity plate 50 includes a plurality of cavities 70 (and will henceforth be referred to individually as cavity 70 and collectively as cavities 70).
In operation, clamping unit 25 closes mold assembly 20 and clamps mold assembly 20 shut, in a closed position, to prevent mold assembly 20 from opening under the pressure of melt being injected, by injection unit 15, into cavities 70. With mold assembly 20 clamped in the closed position, melt is injected in to a space 75, shaped and dimensioned to create an article (not shown), between core 65 and corresponding cavity 70. When the article is ready to depart mold assembly 20, the article clings to core 65. To remove the article from core 65, mold assembly 20 opens allowing stripper plate 45 to move upstream to eject the article from core 65.
Mold assembly 20 comprises manifold 60 housed in manifold plate 55, a mold plate 100 upstream and in contact with manifold plate 55, and an actuator 64 mounted on and upstream of manifold 60, between mold plate 100 and manifold 60. Mold plate 100 is actively cooled by cooling lines 101. In some embodiments, mold plate 100 is clamp plate 72. In some embodiments, mold assembly 20 comprises a plurality of actuators 64 (and will henceforth be referred to individually as actuator 64 and collectively as actuators 64).
Housing 80 includes a plurality of bores 115 spanning the length of housing 80. Mold assembly 20 further includes a plurality of fasteners 120, each fastener 120 passing though a respective bore 115, coupling housing 80 to manifold 60. Fasteners 120 are dimensioned to space radially from a wall 122 of bores 115 (i.e., circumferential surfaces of fasteners 120 do not touch wall 122 of bores 115). Consequently, housing 80 is longitudinally displaceable relative to fasteners 120. Each fastener 120 includes a nut 125 and a bolt 130 having a head 135 and a threaded end 140 distal from head 135 threadably secured to nut 125. Biasing mechanism 110 includes a biasing member 145, with bolt 130 passing through biasing member 145, positioned between nut 125 and housing 80. Nut 125 is supported by manifold 60 via a valve disc flange 150. Valve disc flange 150 is connected to nut 125 via a bolt 155. In the embodiment illustrated by
Bore 115 partially houses a respective nut 125, and includes an end portion 160 having an opening 165 proximal to manifold 60, and a shoulder 170. A respective biasing member 145 is retained between shoulder 170 and nut 125 (i.e., every bore 115 houses a biasing member 145 positioned between shoulder 170 and nut 125).
Housing 80 contacts fasteners 120 via biasing members 145. In operation, heat from manifold 60 can travel upstream via fasteners 120. The heat can then be transferred to housing 80 via at least an upstream surface 172 of biasing member 145 (see
As illustrated in
The axial distance of valve pin 97 relative piston 85 can be varied by rotating piston insert 180 relative to valve pin holder 195 via, for example, rotation of a tool inserted into non-circular bore 210. Once valve pin 97 is at a desired distance from piston 85, set screw 185 can be tightened against valve pin holder 195 to prevent valve pin holder 195 from rotating relative to piston insert 180, then nut 190 can be tightened against extension 207 of piston 85 to prevent piston insert 180 from rotating relative to extension 207. Tightening nut 190 against extension 207 also pulls a lower portion 215 of piston insert 180 against a shoulder 220 of extension 207.
While various embodiments according to the present application have been described above, it should be understood that they have been presented by way of illustration and example only, and not limitation. It will be apparent to persons of ordinary relevant skills in the relevant art that various changes in form and detail can be made therein without departing from the scope of the invention. It will also be understood that each feature of each embodiment discussed herein, may be used in combination with the features of any other embodiment, for example, heat reflector 240 can also be included in the embodiment illustrated by
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/CA2018/050559 | 5/11/2018 | WO | 00 |
Number | Date | Country | |
---|---|---|---|
62506010 | May 2017 | US |