KR20120096321A - Injection mold apparatus - Google Patents

Abstract

PURPOSE: An injection mold apparatus is provided to rotate a rotation mold by converting the straight reciprocation of a moving mold without additional power units like a servo motor. CONSTITUTION: An injection mold apparatus comprises moving molds(10), a rotary mold(30), and a rotating unit for a mold(100). The moving molds are installed to be straightly reciprocated. The rotary mold is installed between the moving molds to be rotated. The rotary mold comprises a mounting surface for a lower core(21) fitted with an upper core(13). The rotating unit for a mold is installed between the moving molds and rotary mold and converts the straight reciprocation of the moving molds into the rotation of the rotary mold.

Description

Injection Mold Apparatus {Injection Mold Apparatus}

The present invention relates to an injection mold apparatus having a rotating mold rotating device.

The injection molding apparatus mounts two molds consisting of one set in a mold clamping apparatus, and combines the two molds to form a cavity identical to the shape of the product to be molded, and the resin in the molten state in the cavity. It is a device to mold the product by injecting it at high pressure.

When injecting through an injection molding apparatus, in particular, in order to increase productivity, in order to proceed with the next process such as simultaneously ejecting a plurality of ejections or ejecting ejections, a mold other than a device for molding and opening a set of molds There is a need for a device to move the.

One aspect of the present invention is to provide an injection mold apparatus for rotating the rotating mold by converting the rotational movement of the movement of the moving mold without a separate driving device for generating power such as a servo motor.

The injection mold apparatus according to an aspect of the present invention is installed to move forward and backward in a direction opposite to each other and a pair of moving molds, each of which is installed with an upper core, rotatably installed between the moving molds and to the combination with the upper core. A rotating mold having a surface on which a lower core forming a cavity is disposed, and a mold rotating installed between the moving mold and the rotating mold to convert the moving mold into and out of the rotating mold. Device.

The mold rotating device includes a rack coupled to the movable mold to move forward and backward with the movable mold, and a pinion engaged with the rack to rotate according to the movement of the rack.

In addition, the mold rotating device includes a shaft bearing coupled to the rotating shaft of the rotating mold body, a pinion bearing installed coaxially with the pinion, and a link connected to and interlocked between the shaft bearing and the pinion bearing. It includes more.

The pinion bearing is rotatably installed with respect to the pinion, and an interlocking protrusion is elastically supported on the opposite side of the pinion bearing and the pinion so that the pinion bearing is elastically supported. A guide groove formed in an arc shape is provided to allow relative rotational movement between the pinion bearing and the pinion in a state where the interlocking protrusion is accommodated.

The guide groove has a step formed of a vertical surface such that the pinion bearing is interlocked with respect to the one-way rotation of the pinion, and an inclined surface formed to be inclined upwardly from the step.

1 is a perspective view of an injection mold apparatus according to an embodiment of the present invention.
Figure 2 is a perspective view of an exploded perspective view of a mold rotating apparatus according to an embodiment of the present invention.
3 is an exploded perspective view of the pinion and pinion shaft.
4 is a cross-sectional view showing the structure of the interlocking protrusion and the guide groove and the coupling relationship thereof.
5 to 9 is a plan view showing an operating state of the injection mold apparatus according to an embodiment of the present invention.

Hereinafter, an injection mold apparatus according to an embodiment of the present invention will be described with reference to the drawings.

As shown in Figures 1 to 4, the injection mold apparatus according to an embodiment of the present invention, the injection mold apparatus is a pair of moving molds (10) and two moving molds (10) provided to be capable of moving forward and backward in the horizontal direction. Rotational mold 20 is disposed between the two, and the mold rotating apparatus 100 is installed between the two moving mold 20 and the rotating mold (20).

The moving mold 10 includes a top plate 11 disposed on the inner side facing the rotating mold 20, a fixed plate 12 disposed on the outside, and an upper core 13 installed on the top plate 11. Include. The movable mold 10 is disposed in pairs on both sides of the injection molding apparatus, and the rotating mold 20 is disposed between the two movable molds 10.

The rotating die 20 is composed of a cube, and the rotating die 20 is provided with a lower core 21 that forms a cavity by combining with the upper core 13.

The lower core 21 is installed on two surfaces of the rotating mold 20 in diagonal directions so that the moving mold 10 and the rotating mold 20 are in close contact with each other. .

Also, at least one of the two moving molds 10 is formed with a sprue bush (not shown) for injecting resin to be injected into the cavity formed by the upper core 13 and the lower core 21, and a rotating mold ( A flow path may be formed inside the resin 20).

The moving mold 10 and the rotating mold 20 have a retreat movement that repeats approaching and spacing at predetermined intervals. Between the two moving molds 10 and the rotating mold 20 to guide the retreat movement, Guide rod 30 is installed.

The guide rod 30 is formed in a rod shape and is installed to penetrate four corner portions of the two moving molds 10, and an intermediate plate 40 is installed between the guide rod 30 and the rotating mold body 20.

Similar to the moving mold 10, the intermediate plate 40 penetrates the guide rod 30 and rotatably supports the rotating shaft 22 of the rotating mold 20 so that the rotating mold 20 is rotatably supported. do. The intermediate plate 40 is disposed in the same structure on the upper and lower portions of the rotating mold 20.

As such, the two moving molds 10 may be guided by the guide rod 30 between the two moving molds 10 and the intermediate plate 40 so as to move forward and backward about the rotating mold body 20.

The moving mold 10 may be guided to move forward and backward through a hydraulic or pneumatic cylinder (not shown) on both sides or one side, which corresponds to the known art, and thus detailed description thereof will be omitted.

The movement of the moving mold 10 is for shaping and opening the upper core 13 and the lower core 21, and the rotating mold 20 rotates by using the moving movement of the moving mold 10. A mold rotating device 100 is provided between the moving mold 10 and the rotating mold 20 so as to be possible.

Mold rotating apparatus 100 according to an embodiment of the present invention is a rack (rack) 110 and parallel to the advancing direction of the moving mold 10 between the moving mold 10 and the intermediate plate 40, Pinion 120 that is engaged with the rack 110 and rotates according to the linear motion of the rack 110, and a shaft bearing 150 and pinion 120 coupled to the rotation shaft 22 of the rotating mold 20. And a pinion bearing 130 installed coaxially with the shaft 140 and a link 140 connected to and interlocked between the shaft bearing 150 and the pinion bearing 130.

 The rack 110 is the middle of the first rack 111 and the other side of the movable mold 10 and the middle of the movable mold 10 installed between the movable mold 10 and the middle plate 40 so that the movement amount of the movable mold 10 on both sides is matched. It may include a second rack (112) installed between the plates 40, each pair may be disposed in the front and rear directions symmetrically about the rotating shaft 22 of the rotating mold 20 for a stable forward and backward movement. have.

The intermediate plate 40 is provided with a guide roller 41 for guiding the retreat movement of the rack 110.

The pinion 120 is disposed between the first rack 111 and the second rack 112 and rotates as the first rack 111 and the second rack 112 move in and out of the pinion 120. Bearing 130 is installed. The pinion bearing 130 is coupled to the rotation shaft 133 at the center hole 121 of the pinion 120 so that the pinion bearing 130 and the pinion 120 are coaxially arranged so that their rotation centers coincide with each other. 130 is rotatably coupled with respect to pinion 120.

The pinion 120 and the pinion bearing 130 may be interlocked by the interlocking protrusion 122 and the guide groove 132, which will be described later, or the pinion 120 may rotate alone.

The interlocking protrusion 122 may have a front end portion formed in a hemispherical shape, and a spring 123 is disposed at a rear end thereof so as to be elastically supported in a protruding state on an upper surface of the pinion 120, and prevents the spring 123 from being separated. The fixing member 124 is installed behind the spring 123.

The rear end portion of the interlocking protrusion 122 is provided with a flange portion 122a having a larger diameter than the front end portion, and the pinion 120 is provided with an installation hole 125 to install the interlocking protrusion 122. The shape of the 125 also accommodates and supports the flange portion 122a so as to guide the forward and backward movement of the interlocking protrusion 122, the diameter of which is larger than the portion accommodating the front end of the interlocking protrusion 122. Therefore, the interlocking protrusion 122 is not separated from the upper side in the installed state.

 The guide groove 132 is provided to accommodate the interlocking protrusion 122 on the lower surface of the pinion bearing 130 facing the pinion 120, and the interlocking protrusion 122 rotates by the rotation of the pinion 120. It may be formed in an arc shape on the trajectory.

The guide groove 132 includes a stepped portion 132a having a vertical surface and formed in a concave shape, and an inclined surface 132b formed between the bottom surface of the pinion bearing 130 from the stepped portion 132a.

When the interlocking protrusion 122 passes between both sides of the guide groove 132 by the interlocking protrusion 122 and the guide groove 132, the pinion bearing 130 is not constrained to the rotation of the pinion 120. Only the pinion 120 rotates, but when the linkage protrusion 122 is in contact with the step 132a of the guide groove 132, the pinion bearing 130 is constrained by the rotation of the pinion 120 to rotate together. .

That is, the interlocking protrusion 122 and the guide groove 132 allow the pinion bearing 130 to interlock only with respect to the one-way rotation of the pinion 120, but with respect to the rotation of the pinion 120 in the opposite direction of the pinion bearing ( 130 can be rotated only without pinion (120).

In the present embodiment, the linkage protrusion 122 is an example provided on the upper surface of the pinion 120, the guide groove 132 is provided on the lower surface of the pinion bearing 130, the position of the two may be changed.

Pin portions (131, 151) are formed on the upper surface of the shaft bearing 150 and the pinion bearing 130, which are coupled to the rotating shaft 22 of the rotating die 20, and two pin portions. The pinhole 141 of the link 140 is rotatably coupled between the 131 and the 151. Accordingly, the shaft bearing 150 has the pinion bearing 130 for a certain period with respect to the rotational movement of the pinion bearing 130. It can be interlocked opposite to the rotation direction of.

The following describes the operation of the injection mold apparatus according to an embodiment of the present invention with reference to FIGS.

 According to FIG. 5, the movable mold 10 and the rotating mold 20 are closed and the injection is made in the cavity between the upper core 13 and the lower core 21.

Since the pinion 120 is rotated by the movement of the rack 110 when the movable mold 10 is opened and retracted slightly as shown in FIG. 6, the pinion bearing 130 has an interlocking protrusion 122 at one side of the guide groove 132. In Figure 4 it can be maintained without stopping while moving to the step 132a of the guide groove 132 as shown in FIG.

As such, when the pinion bearing 130 is stopped by the interlocking protrusion 122 and the guide groove 132 at the initial stage of the opening operation of the movable mold 10, the movable mold 10 and the rotating mold body 20 The rotation of the rotating mold 20 is started in a state in which the gap is somewhat spaced apart so that interference between the moving mold 10 and the rotating mold 20 can be prevented during the rotation of the rotating mold 20.

 If the pinion 120 continues to rotate after the interlocking protrusion 122 is moved to the step 132a of the guide groove 132 as shown in FIG. 7, the pinion bearing 130 is constrained by the rotation of the pinion 120 to rotate together. In the process of opening, the clockwise rotation of the pinion bearing 130 induces the counterclockwise rotation of the shaft bearing 150 by the link 140 so that the rotating mold 20 rotates as shown in FIG. 7. After that, as shown in FIG. 8, when the rotating mold 20 rotates 90 ° in the first mold closed state, the opening operation of the moving mold 10 ends.

In this state, the ejection of the injection molded product P in the state of being injected into the lower core 21 of the rotating mold 20 can be made.

In the next process, the movable mold 10 is mold-closed with the rotating mold 20. At this time, since the rotation direction of the pinion 120 is reversed, the interlocking protrusion 122 is not caught by the step 132a and the inclined surface ( Since the pinion bearing 130 is not affected by the rotation of the pinion 120 because the pinion bearing 120 is moved along the 132b, the mold closing operation proceeds while maintaining the stationary state.

When the mold closing operation is completed, the cycle returns to the state of FIG. 5 and completes one cycle.

According to this embodiment, the two upper cores 13 and the two lower cores 21 are formed in the same shape, respectively, so that two injection moldings having the same shape are produced through one injection and at the same time rotated by 90 ° for the injection moldings. Withdrawal is possible.

The present invention is not limited to the embodiments described above, and it is apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit of the present invention. Accordingly, modifications or variations are intended to fall within the scope of the appended claims.

10: moving mold 20: rotating mold
30: guide rod 40: intermediate plate
100: mold rotation device 110: rack
120: pinion 130: pinion bearing
140: link 150: shaft bearing

Claims (5)

A pair of moving molds installed to move forward and backward in opposite directions, and each of which an upper core is installed;
A rotating mold body rotatably installed between the movable molds and having a surface on which a lower core is formed to form a cavity by joining with the upper core;
And a mold rotating device installed between the moving mold and the rotating mold body to convert the advancing and moving movement of the moving mold into the rotating movement of the rotating mold body. The method of claim 1,
The mold rotating device is coupled to the movable mold rack to move forward and backward with the movable mold,
An injection mold apparatus including a pinion engaged with the rack to rotate in accordance with the advancing and retracting motion of the rack. The method of claim 2,
The mold rotating device further includes a shaft bearing coupled to the rotating shaft of the rotary mold body, a pinion bearing installed coaxially with the pinion, and a link connected to and interlocked between the shaft bearing and the pinion bearing. Injection mold apparatus comprising a. The method of claim 3, wherein
The pinion bearing is rotatably installed with respect to the pinion, and an interlocking protrusion is elastically supported to be retractably supported on one surface of the pinion bearing and the pinion, and the other surface of the pinion bearing and the pinion that is opposite to the pinion. Injection mold apparatus provided with a guide groove formed in an arc shape to enable a relative rotational movement between the pinion bearing and the pinion in the state that the linkage projection is accommodated. The method of claim 4, wherein
The guide groove is an injection mold apparatus having a stepped end formed with a vertical surface so that the pinion bearings interlock with respect to the one-way rotation of the pinion, and an inclined surface formed to be inclined upwardly from the stepped end.

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