KR100856932B1 - Dual injection mold for support motor - Google Patents

Abstract

The present invention relates to a double injection mold of a cleaner component for injecting a support motor molded from a resin of a heterogeneous material that is not chemically fused.

The double injection mold of the cleaner part according to the present invention has a lower mold having a main core plate constituting a part of the first and second cavities so as to mold different release materials, respectively, and the mold and the mold are separated from the lower mold. And an upper mold for partitioning the first and second cavities, an index shaft rotatably installed on the lower mold, and an upper portion coupled to the main core plate, and rotated by an actuator coupled to the index shaft and installed in the injection molding machine. And indexing means including an elevated portion.

The double injection mold of the cleaner component according to the present invention having the above configuration provides an advantage of automatically double injection of a support motor formed of two kinds of different resins through one mold.

Description

Dual injection mold for cleaner parts {Dual injection mold for support motor}

1 is an exploded perspective view illustrating a support motor injection molded from a double injection mold of a cleaner component according to the present invention;

Figure 2 is a partially cut perspective view showing an embodiment of a double injection mold of the cleaner component according to the present invention,

3 is a perspective view showing a lower surface of the upper mold of the embodiment of FIG.

4 is a perspective view showing a lower mold of the embodiment of FIG.

5 is a perspective view showing a rotation state of the main core plate of the embodiment of FIG.

<Explanation of symbols for main parts of the drawings>

100; Double injection mold of cleaner parts

One; Support motor 10; Upper mold

20; Bottom mold 21; Main core plate

40; Indexing means

The present invention relates to a double injection mold of the cleaner component, and more particularly to a double injection mold of the cleaner component for injecting a support motor formed of a resin of a different material that is not chemically fused.

In general, double injection means using a mold designed to enable double injection of two dissimilar resins or two identical resins of different colors with two injection devices. First, the first resin is filled into the first cavity to form a first molding. The second molding is filled into a second cavity formed between the first molding and the mold to mold the second molding to be bonded to the first molding.

Such double injection has less shape constraints, wider product application, and diversified designs. In addition, unlike the conventional one, which had to go through a second process of fusion or painting after two injection molding by injecting the product at once, it provides an advantage that the cost can be reduced and the production efficiency of the product can be increased.

However, the conventional double injection had to go through the process of moving the first molding to another cavity filled with different resins in order to secondaryly mold different kinds of resins or resins of different colors in the first molding formed first. In this case, in the process of taking out the first molding and transferring it to the cavity for secondary molding, foreign matters may be attached to the first molding or scratches may cause the quality of the finished product to be deteriorated, resulting in a complicated work process. In addition, in this case, there is a disadvantage that the price of the product rises due to an increase in the manufacturing cost.

An object of the present invention is to provide a double injection mold of a support member capable of molding a support motor in which resins of different materials are combined through one mold.

The dual injection mold of the cleaner component according to the present invention for achieving the above object is a lower mold having a main core plate forming a part of the first and second cavities so as to mold different release materials, respectively, and the lower mold and The mold is separated and mold-separated, the upper mold for partitioning the first and second cavities, the index shaft rotatably installed on the lower mold, the upper portion is coupled to the main core plate, and coupled to the index axis, the injection machine It is provided with indexing means including a connecting portion that is rotated and lifted by an actuator installed in.

The upper mold forming the second cavity is further formed with a molding space for filling the resin of the release material different from the first injection molded in the first cavity, the lower mold is upward through the main core plate It is preferable to further include a mill having an eject pin that protrudes and draws in, and an actuator provided on one side of the lower mold to lift and lower the mill.

Hereinafter, a double injection mold of the cleaner component according to the present invention will be described in detail with reference to the drawings.

The double injection mold 100 of the cleaner part according to the present invention is an injection mold for injecting the support motor 1 which is one of the parts of the cleaner as shown in FIG. 1.

The support motor 1 is formed of polypropylene resin and is coupled to the body 2 having a cylindrical portion 3 extending upward, and to the body 2 so as to surround the outer circumferential surface of the cylindrical portion 3, vinyl chloride. A cushion portion 4 formed of resin is provided. Since the body 2 and the cushion part 4 are molded with different dissimilar resins so as to suit the role played by them, a double injection mold for easily performing double injection is used.

Referring to FIG. 2, the double injection mold 100 of the cleaner component may lift and rotate the upper and lower molds 20 and the main core plate 21 of the lower mold 20, which are combined and separated from each other. It is provided with an indexing means 40 installed in the lower mold (20).

The upper mold 10 is installed to be lifted and lowered in an injection molding machine (not shown), and the lower mold coupled to the lower mold 20 is coupled to the main core plate 21 of the lower mold 20 to be described later. First and second cores 11 and 12 are formed to form the second cavity.

The first core 11 is joined with the main core plate 21 to form a first cavity in which the body 2 of the support motor 1 is molded, and the first core 11 forms the body 2. In order to communicate with the first sprue bush and the first runner filled with a polypropylene resin.

The second core 12 is joined with the main core plate 21 to form a second cavity in which the cushion portion 4 of the support motor 1 is molded, and the second core 12 forms the cushion portion 4. The second sprue bush and the second runner filling the vinyl chloride resin for molding are in communication with each other. The cushion portion 4 is formed to surround the cylindrical portion 3 formed on the upper side of the body 2, the body 2 is located in the space of the second cavity, between the body 2 and the second cavity The vinyl chloride resin is filled in the separation space, and the cushion portion 4 is injection molded.

The first and second sprue bushes and the first and second runners communicating with the first and second cavities for forming the body 2 and the cushion portion 4 of the support motor 1 are respectively different. They are separated from each other because they are formed to fill kinds of resins.

The lower mold 20 is installed so as to be combined with the upper mold 10 and separated from each other, and the main core plate is coupled to the first and second cores 11 and 12 to form first and second cavities. (21), the indexing means (40) installed in the lower mold (20) or the injection machine so as to elevate and rotate the main core plate (21), and the support motor (1) molded in the second cavity can be taken out. The take-out unit 30 provided below the main core plate 21 is provided.

The main core plate 21 is located above the lower mold 20 and is installed to be coupled to and detachable from the upper plate 25. The main core plate 21 is composed of a first portion 22 and a second portion 23, the first portion 22 and the second portion 23 is the rotation axis of the index axis 41 which will be described later is located The first and second cores 11 and 12 of the upper mold 10 having mutually symmetrical about the origin and having the first and second portions 22 and 23 and the first and second portions 22 and 23. Are combined with each other to form first and second cavities, respectively.

The take-out unit 30 is for taking out the finished product, and is attached to the lower plate 20 so that the lower plate 20 can be lifted and attached to the lower plate 31. It is provided with a mill pin 32 which protrudes and pulls in the upper part of the board 21, and the actuator 33 which is provided in the side surface of the lower mold 20, and raises and lowers the said mill board 31. As shown in FIG. In this embodiment, the hydraulic cylinder is applied as the actuator 33, the hydraulic cylinder is connected to the coupling rod (not shown) coupled to the edge of the mill 31 to drive the mill 31.

The plate 31 is installed on the side where the second core 12 on which the cushion portion 4 of the upper mold 10 is formed is formed. When the support motor 1 is formed in the second cavity, the plate 31 is actuated. The lifting pins 32 are lifted by 33 and the support pins 1 coupled to the plate 31 are separated from the main core plate 21 and taken out.

In the present embodiment, three actuators 33 are installed in the lower mold 20 to drive the mill 31, and hydraulic cylinders are applied as the actuator 33, but the actuator 33 is different from the mill 31. If the operation of elevating or lowering the operation can be made easily, the driving device of the various kinds of plates 31 can be applied, the number of the actuator 33 is not limited by this embodiment.

The indexing means 40 is a device for lifting and rotating the main core plate 21 by 180 degrees to form the cushioning portion 4 on the body 2 of the support motor 1 formed in the first cavity. The upper end portion includes an index shaft 41 coupled to the main core plate 21, and a connecting portion 42 coupled to the index shaft 41 and rotated and lifted by a driving device installed in the injection molding machine.

The actuator may be applied to various actuators capable of raising and lowering the connecting portion 42, such as a hydraulic or pneumatic cylinder.

When the connecting portion 42 is raised and rotated by the drive device, the index shaft 41 is operated accordingly to lift and rotate the main core plate 21. The main core plate 21 should be rotated to have a rotation angle of 180 °. When the main core plate 21 is rotated, the main core plate 21 must be accurately aligned with the first and second cores 11 and 12 when the main core plate 21 is rotated. This is because the first and second cavities are only formed to have the correct molding space. Therefore, in the present embodiment, the protrusion member 26 protruding upward from the upper plate 25 of the lower mold 20 and the coupling hole formed to be coupled to the protrusion member 26 at the edge of the main core plate 21 ( 24, the rotation angle of the index axis 41 can be controlled. Alternatively, a separate rotation angle control means may be provided on the index shaft 41 to limit the rotation angle of the main core plate 21 to 180 °. For example, although not shown, the main core plate 21 is provided on the outer circumferential surface of the index shaft 41 by a stopper installed in the groove and the lower mold 20 at a predetermined angle and elastically biased toward the groove by a spring. It is possible to control the rotation angle of the index axis 41 for rotating the.

The operation process of the double injection mold 100 of the cleaner component according to the present invention configured as described above is as follows.

First, when the upper mold 10 and the lower mold 20 are combined, the main core plate 21 of the lower mold 20 and the first and second cores 11 and 12 of the upper mold 10 are combined. . At this time, the first portion 22 and the first core 11 of the main core plate 21 form the first cavity, and the second portion 23 and the second core 12 form the second cavity. do.

In the first injection molding, since the main body of the support motor 1 is not molded in the second cavity, the filling of the resin through the second sprue bush is cut off, and the polypropylene resin is passed through the first sprue bush in the first cavity. Is filled. The filled polypropylene resin solidifies according to the shape of the first cavity to form the main body of the support motor 1.

When the molding of the main body is completed in the first cavity, the upper mold 10 is lifted upward to be separated from the lower mold 20, and the take-out unit is operated.

The hydraulic cylinder installed in the lower mold 20 moves the mill plate 31 upward with respect to the lower mold 20 when the mold separation is completed. As the plate 31 moves upward in the installation space formed in the lower mold 20, the pin pin 32 coupled to the upper portion of the plate 31 protrudes upward through the main core plate 21. However, since the filling of the resin is controlled in the second part 23 of the main core plate 21 on which the mill pin 32 protrudes after the first injection molding is completed, no product is taken out. After a certain time, the hydraulic cylinder lowers the plate 31 again, the main core plate 21 is now rotated.

The rotation of the main core plate 21 is made by the indexing means 40. When the connecting portion 42 is lifted and lowered by an actuator 33 installed in the injection molding machine, the index is connected to the connecting portion 42. The main core plate 21 is also separated from the upper plate 25 of the lower mold 20 by the shaft 41 and lifts upward. When the main core plate 21 rotates, the index shaft 41 moves the index shaft 41 when the main core plate 21 is lifted upwardly from the upper plate 25 so that the main core plate 21 is not interrupted by the protruding member 26 and the mil pin 32. It is rotated 180 ° by a separate actuator 33 installed to rotate. As the index shaft 41 rotates, the main core plate 21 also rotates, and the first part of the main core plate 21 in which the main body of the support motor 1 is formed due to the rotation of the main core plate 21. (22) is moved to a position that can be combined with the second core 12 of the upper mold (10).

When the positions of the first part 22 and the second part 23 are switched with each other along the rotation of the main core plate 21, the actuator 33 coupled with the connecting part 42 is lowered downward to form a main core plate ( 21 is coupled to the upper plate 25 of the lower mold (20). In this process, the coupling position with the upper plate 25 of the main core plate 21 may be accurately set through the coupling of the protrusion member 26 and the coupling hole 24 formed on the upper plate 25.

When the main core plate 21 is combined with the upper plate 25, the upper mold 10 is lowered so that the secondary molding can be performed, and is combined with the lower mold 20 again. When the upper mold 10 and the lower mold 20 are combined, the main core plate 21 and the first and second cores 11 and 12 are combined to form first and second cavities again. At this time, the second cavity is formed by the first portion 22 and the second core 12 of the main core plate 21 in which the main body of the support motor 1 is molded, and the first cavity is formed by the main core plate ( It is formed by the second part 23 and the first core 11 of 21.

When the first and second cavities are formed through the combination of the first and second cores 11 and 12 and the main core plate 21, the molding resin is filled into the cavities through the first and second sprue bushes. In the first injection molding, the second cavity is controlled to prevent the vinyl chloride resin from filling. However, from the injection molding, the first and second cavities are filled with both the polypropylene resin and the vinyl chloride resin. In the first cavity, the polypropylene resin is filled so that the main body is injection molded, and in the second cavity, the cushion portion 4 is secondary molded so as to surround the cylindrical portion 3 of the previously formed main body.

After the filling of the resin through each sprue bush and the runner is completed, after a predetermined time for the resin to solidify, the upper mold 10 is lifted from the lower mold 20 to separate each mold.

When the mold separation of the upper mold 10 and the lower mold 20 is completed, the pressure plate 31 is elevated by the hydraulic cylinder again as in the previous process, and thus the pins 32 move the main core plate 21. It protrudes upward through. In the first injection molding, the product was not ejected because the finished product was not molded, but after the injection molding, since the support motor 1 combined with the cushion part 4 is formed every time the mold is separated, the mill pin 32 is used. The support motor 1 is taken out from the main core plate 21. When the extraction of the product is completed, the wheat plate 31 is lowered again and the main core plate 21 is rotated by the indexing means 40.

Since the body is molded in the first cavity while the cushion portion 4 is secondaryly molded in the second cavity in which the main body is molded, the main body is continuously formed in the first cavity through this series of continuous processes. In the cavity, the cushion portion 4 is continuously molded secondarily in the molded body.

The double injection mold of the cleaner component according to the present invention having the above configuration provides an advantage of automatically double injection of a support motor formed of two kinds of different resins through one mold.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (3)

A main cavity for forming a first cavity for forming a first cavity, and a main core plate forming part of a second cavity for forming a second injection molded with a release material different from the first injection, which is combined with the first injection; Lower mold; An upper mold which is combined with the lower mold and separated from the lower mold, and which is combined with the lower mold to form the first and second cavities; An indexing means rotatably mounted to the lower mold and having an index portion having an upper portion coupled to the main core plate, and a connection portion coupled to the index axis and rotated and lifted by an actuator installed in the injection machine; And When the main core plate is raised and rotated by the indexing means and then lowered again to be coupled to the lower mold, the rotation restricting the rotation angle of the main core plate to 180 ° so that the main core plate can be accurately engaged. Each control means; Dual injection mold of the cleaner component, characterized in that it comprises a. The method of claim 1, The upper mold forming the second cavity is a double injection mold of the cleaner part, characterized in that the molding space is further formed with a resin of a different release material and the first injection molded in the first cavity is formed. The method according to claim 1 or 2, The lower mold is a wheat plate having an eject pin protrudes and pulled upward through the main core plate; The double injection mold of the cleaner component, characterized in that it further comprises an actuator installed on one side of the lower mold for raising and lowering the mill plate.

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