This Non-provisional application claims priority under 35 U.S.C. ยง119(a) on Patent Application No(s). 098114448 filed in Taiwan, Republic of China on Apr. 30, 2009, the entire contents of which are hereby incorporated by reference.
1. Field of the Invention
This invention relates to an injection mold and, more particularly, to an inclined ejector mechanism and the injection mold with the same.
2. Description of the Related Art
With continuous improvement of modern technology, various kinds of daily articles are also continuously developed. Particularly, components of consuming electronic products are mainly made by a mechanical manufacturing process in which a mold may be used. To finish a manufacturing process of the components, a mold for molding the product needs to be first provided. The mold at least includes a fixed mold and a movable mold. After the fixed mold and the movable mold are closed, a mold cavity is formed therebetween thus to produce the product by injecting a mold material. When the product is to be separated from the fixed mold or the movable mold, a mold-parting mechanism is usually needed to eject the product. The mold-parting mechanism usually is an inclined ejector mechanism for separating the product from the fixed mold or the movable mold.
Also as shown in
In the step of operating the inclined ejector mechanism 10, the ejector plate assembly 22 moves towards the first mold plate 18 along the center line C1 of the mold 1 for injection molding. At that moment, the pulling rod 102 also push and press towards the first mold plate 18 along the center line C1 of the mold 1 for injection molding, such that the sliding structure 1020 slides relative to the sliding groove 1000 to drive the inclined ejector pin 100 to slide inclinably in the ejector hole 180 and the ejector pin hole 200. Thereby, the end of the inclined ejector pin 100 pass through the ejector pin hole 200 of the first mold core 20 to successfully separate the injection molding product from the mold 1.
However, when the pulling rod 102 of the inclined ejector mechanism 10 pushes and presses towards the first mold plate 18 along the center line C1 of the injection mold 1, the inclined ejector pin 100 suffers latitudinal force and longitudinal force at the same time. Usually, the inclined ejector pin 100 is long-shaped. Therefore, the inclined ejector pin 100 is easy to bend and deform after repeatedly used. Thus, the position of the inclined ejector mechanism 10 in the injection mold 1 may be imprecise to affect dimensional precision of the injection molding product. In addition, when the inclined ejector mechanism 10 is to be disassembled or replaced for maintenance, repair or storage, the first mold core 20, the first mold plate 18, and the ejector plate assembly 22 of the injection mold 1 need to be disassembled step by step, such that the inclined ejector pin 100 and the pulling rod 102 of the inclined ejector mechanism 10 is completely removed. During the disassembling process, the injection mold 1 and the inclined ejector mechanism 10 may be damaged mindnessly, and the lifespan of the injection mold 1 and the inclined ejector mechanism 10 may be reduced.
One objective of this invention is to provide an inclined ejector mechanism. The inclined ejector mechanism includes a retaining element, an inclined ejector pin, and a pulling rod. The retaining element has a retaining portion. One end of the inclined ejector pin is operatively connected with the retaining portion, such that the inclined ejector pin is capable of limitedly moving relative to the retaining element. The pulling rod is connected with the retaining element.
Another objective of this invention is to provide an injection mold. The injection mold includes a first mold base and an inclined ejector mechanism. The first mold base includes a first mold plate, a first mold core, and an ejector plate assembly. The first mold core is disposed at the first mold plate. The inclined ejector mechanism is disposed in the first mold base. The inclined ejector mechanism includes a retaining element, an inclined ejector pin, and a pulling rod. The retaining element is capable of sliding in the first mold plate and is limited between the first mold plate and the first mold core. The retaining element has a retaining portion. The inclined ejector pin is disposed through the first mold plate and the first mold core. One end of the inclined ejector pin is operatively connected with the retaining portion, such that the inclined ejector pin is capable of limitedly moving relative to the retaining element. The pulling rod is disposed through the ejector plate assembly and the first mold plate and is connected with the retaining element. Thereby, when the pulling rod is separated from the retaining element, the retaining element and the inclined ejector pin can be taken out from the first mold base by separating the first mold core from the first mold plate.
Compared with the prior art, according to the inclined ejector mechanism and the injection mold in the invention, geometrical dimensional improvement and an enhanced mechanical design are mainly provided for the inclined ejector mechanism, such that the inclined ejector mechanism reciprocating in the injection mold will reduce friction between components thus to reduce abrasion thereof and to prolong the lifespan. In addition, according to the embodiment of the invention, disassembly and assembly of the inclined ejector mechanism are improved, such that assembling and disassembling procedure of the inclined ejector mechanism is simple and abrasion of the components is also reduced. Thereby, the dimensions of the inclined ejector mechanism is effectively reduced in the invention thus to greatly reduce limitation in designing an injection molding product by skilled persons.
These and other features, aspects, and advantages of the present invention will become better understood with regard to the following description, appended claims, and accompanying drawings.
This invention provides an inclined ejector mechanism and an injection mold. More particularly, geometrical dimensional improvement and an enhanced mechanical design are mainly provided for the inclined ejector mechanism, such that the inclined ejector mechanism reciprocating in the injection mold reduces friction between components thus to reduce abrasion thereof and to prolong the lifespan. Preferred embodiments of the invention are described in detail hereinbelow.
As shown in
In one embodiment, the retaining portion of the retaining element 302 is in the form of a sliding groove 3020, and the end of the inclined ejector pin 300 can have a sliding structure 3000 corresponding to the sliding groove 3020 of the retaining element 302, such that the inclined ejector pin 300 slides relative to the retaining element 302. Thereby, after the sliding structure 3000 of the inclined ejector pin 300 is fastened to the sliding groove 3020 of the retaining element 302, the pulling rod 304 drives the inclined ejector pin 300 to push or pull in a direction vertical to a sliding direction of the sliding structure 3000 relative to the sliding groove 3020.
In the conventional inclined ejector mechanism 10, the sliding structure 1020 of the pulling rod 102 slides in the sliding groove 1000 of the inclined ejector pin 100. However, according to the inclined ejector mechanism 30 in the embodiment of the invention, the sliding structure 3000 of the inclined ejector pin 300 slides in the sliding groove 3020 of the retaining element 302. According to experience of using the conventional inclined ejector mechanism 10, after repeatedly used, the sliding groove 1000 of the inclined ejector pin 100 is often seriously damaged, the whole injection mold usually needs to be disassembled and a new inclined ejector pin 100 is needed. Therefore, in the inclined ejector mechanism 30 in the embodiment of the invention, the sliding structure 3000 is disposed at the inclined ejector pin 300, and the sliding groove 3020 is disposed at the retaining element 302. Thereby, a contacting area of a sliding portion of the inclined ejector pin 300, i.e. the sliding structure 3000, is effectively reduced thus to greatly reduce probability of damaging the inclined ejector mechanism 30, to prolong the lifespan, and to be free from complicated procedure for replacing damaged components.
The inclined ejector mechanism 30 in
Also as shown in
In the step of operating the inclined ejector mechanism 30, the ejector plate assembly 42 moves towards the first mold plate 38 along the center line C2 of the mold 3 for injection molding. At that moment, the pulling rod 304 can also push and press towards the first mold plate 38 along the center line C2 of the mold 3 for injection molding, such that the sliding structure 3000 of the inclined ejector pin 300 slides relative to the sliding groove 3020 of the retaining element 302 connected with the pulling rod 304 to drive the retaining element 302 to slide along the sliding track 39 and to allow the inclined ejector pin 300 to slide inclinably in the ejector pin hole 400. Thereby, the other end of the inclined ejector pin 300 can pass through the ejector pin hole 400 of the first mold core 40 to successfully separate the injection molding product from the mold 3.
When the conventional inclined ejector mechanism 10 is taken out from the mold 1 for injection molding, the whole mold 1 for injection molding needs to be disassembled. However, when the inclined ejector mechanism 30 in the embodiment of the invention is to be taken out from the mold 3 for injection molding, as long as the first mold core 40 is separated from the first mold plate 38 to take out the first mold core 40 from the mold 3 for injection molding and the pulling rod 304 is separated from the retaining element 302, the retaining element 302 and the inclined ejector pin 300 are taken out together, and the whole mold 3 for injection molding does not need to be disassembled. That is, the first mold base does not need to be completely disassembled, and the pulling rod 304 is left between the ejector plate assembly 42 and the first mold plate 38. Besides saving space, the components can further be prevented from being damaged when the mold is disassembled.
In one embodiment, the retaining element 302 has a screw hole 3022, and one end of the pulling rod 304 have a screw 3040 correspondingly screwed to the screw hole 3022 for connecting the retaining element 302. Certainly, a screw hole may also be disposed at the end of the pulling rod 304, and a screw may correspondingly be disposed at the retaining element 302. However, the invention is not limited thereto. According to particular needs in an actual application or limitation in design, skilled persons in the art choose various kinds of connecting mechanisms to connect the pulling rod 304 and the retaining element 302.
In addition, in one embodiment, the pulling rod 304 and the screw 3040 can be integrally formed.
To sum up, in one embodiment, the other end of the pulling rod 304 sandwiched between the positioning plate 420 and the fixing plate 422 can have a hex socket for fastening a hex screwdriver. Further, the hex screwdriver can pass through the fixing plate 422 to be fastened to the hex socket. However, the invention is not limited thereto. According to particular needs in an actual application or limitation in design, the skilled persons in the art can choose various kinds of fastening mechanisms to be fastened to the other end of the pulling rod 304. Thereby, by rotating the hex screwdriver, the pulling rod 304 can be driven to rotate relative to the retaining element 302 thus to be separated from the retaining element 302. At that moment, the pulling rod 304 is still sandwiched between the positioning plate 420 and the fixing plate 422. Further, the inclined ejector pin 300 and the retaining element 302 can be taken out after the first mold core 40 is separated from the first mold plate 38.
According to the above detailed description about the preferred embodiments of the invention, geometrical dimensional improvement and an enhanced mechanical design are mainly provided for the inclined ejector mechanism, such that the inclined ejector mechanism reciprocating in the injection mold reduces friction between the components thus to reduce abrasion thereof and to prolong the lifespan. In addition, disassembly and assembly of the inclined ejector mechanism are improved, such that assembling and disassembling procedure of the inclined ejector mechanism is simple and abrasion of the components can also be reduced. Thereby, in the embodiments of the invention, the dimensions of the inclined ejector mechanism can be effectively reduced thus to greatly reduce limitation in designing the injection molding product by the skilled persons.
Although the present invention has been described in considerable detail with reference to certain preferred embodiments thereof, the disclosure is not for limiting the scope of the invention. Persons having ordinary skill in the art may make various modifications and changes without departing from the scope and spirit of the invention. Therefore, the scope of the appended claims should not be limited to the description of the preferred embodiments described above.
Number | Date | Country | Kind |
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098114448 | Apr 2009 | TW | national |