KR20110034323A - Rotation core device of multi component injection mold for double injection molding - Google Patents

Abstract

PURPOSE: A rotation device of a multi-injection mold having a rotary core for double injection molding is provided to facilitate the replacement of a rotary core since a drive unit is easily coupled and separated. CONSTITUTION: A rotation device of a multi-injection mold having a rotary core for double injection molding comprises first and second molds, a core mold(30), and a core rotary unit. The first and second mold are engaged with and separated from each other. The first and second molds have first and second molding spaces formed on the planes facing each other. The core mold is installed between the first and second molds. The rotating core of the core mold has the third and fourth molding spaces upon the upper and lower sides thereof. The third and fourth molding spaces form first and second cavities with the first and second molding spaces. The core rotary unit is installed in the core mold. The core rotary unit rotates the rotating core.

Description

Rotating core device of multi component injection mold for double injection molding

The present invention relates to a multi-injection mold rotating apparatus, and more particularly, the core is rotated to rotate the multi-injection mold having a rotary core for double injection in which two injection moldings can be made in one mold. Relates to a device.

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.

The present invention is to solve the above problems, a multi-injection mold rotary device having a rotary core for double injection is improved, the coupling structure of the core is rotatably coupled so that the cavity can be formed on the upper and lower surfaces respectively; The purpose is to provide.

Rotating device of a multi-injection mold with a rotary core for double injection according to the present invention for achieving the above object is installed to enable mutual molding and mold separation, and the first and second molding spaces are formed on the opposite sides, respectively. It is installed between the first and second molds, and the first and second molds, respectively, on the upper and lower surfaces to form the first and second cavities for injection molding together with the first and second molding spaces. A core mold having a rotating core having a third and a fourth molding space, and the rotation to be installed on the core mold so that the third and fourth molding spaces of the rotating core can be combined with the first and second molding spaces. And a core rotating unit for rotating the core, wherein the core rotating unit includes a first core coupling unit coupled to one side of the rotating core, a driving unit providing a rotation driving force to the rotating core, and the driving unit and the first core coupling. Power to wealth Core driving means including a power transmission for connecting so as to enable transmission, and the core support means for supporting the rotating core installed on the other side of the rotary core rotated by the core driving means against the core mold.

The core coupling part includes a coupling member which is screwed by fastening bolts on one side of the rotating core, and has a coupling groove formed at a predetermined depth into a front surface exposed toward the power transmission unit, and the power transmission unit is coupled to the coupling member. A fastening member fitted to the coupling groove to transmit rotational force to the cylindrical member, a cylindrical member extending from the fastening member and having a spline groove formed at a rear end thereof, and inserted into the cylindrical member so as to extend along a longitudinal direction of the cylindrical member; And an end portion fixed to a screw groove formed in the coupling groove of the coupling member to fix the cylindrical member and the coupling member to the core coupling portion, and fitted into the spline groove to transfer the driving force to the cylindrical member. It is preferable to have a spline shaft.

In addition, an annular locking jaw having an outer diameter relatively larger than the diameter of the cylindrical member is formed between the fastening member and the cylindrical member, and the core driving means allows the cylindrical member to easily rotate within the core mold. The bearing member is provided with an inner diameter to which the cylindrical member is fitted so as to surround one side of the cylindrical member, and a bearing support part installed on the core mold to rotatably support the bearing member and the cylindrical part. The bearing support part is fitted in the upper and lower portions of the core mold and coupled to each other, and the first and second support members having support grooves formed therein to support the bearing member and the locking jaw, respectively, and the first and second support members. Two on the upper and lower surfaces where the first and second supports are in contact with each other so as to guide the coupling position when It is preferable to include two guide keys which are fitted in the key grooves each formed, and the core support means preferably includes a cooling water supply line for moving the cooling water supplied to the rotating core.

Rotating device of a multi-injection mold equipped with a rotary core for double injection according to the present invention is easy to replace and rotate the rotating core to form a heterogeneous product because it is easy to combine and separate the drive unit for driving the core There is an advantage that rotational drive is possible.

Hereinafter, with reference to the accompanying drawings will be described in more detail the rotary injection device of the multi-injection mold (hereinafter referred to as' rotating device of the multi-injection mold) equipped with a rotary core for double injection according to the present invention.

Referring to Figure 1, the multi-injection mold rotating apparatus according to the present invention is for rotating the rotary core 40 of the multi-injection mold (1) for dual injection, the multi-injection mold (1) is the first, first The two molds 10 and 20 and the core mold 30 are mutually joined to form a first and a second cavity in which injection molding can be performed at the upper and lower portions of the core mold 30 so that double injection can be performed. It is.

The sprue bush 11 is formed in the first mold 10 to inject molten resin, and a first molding space (not shown) is formed on the bottom surface of the first mold 10.

The second mold 20 is installed below the first mold 10, and the second molding space 12 is formed on an upper surface of the second mold 10 facing the lower surface of the first mold 10.

The core mold 30 is installed between the first and second molds 10 and 20, and the rotating core 40 is rotatably installed therein.

The first and second molds 10 and 20 and the core mold 30 are mutually molded and separated from each other by an injection molding machine. The first and second molds 10 and 20 and the core mold 30 are separated from each other by the injection molding machine. 4 The molding space 31 (not shown) is joined to form first and second cavities in which injection molding can be performed.

Since the third and fourth molding spaces are formed in the same shape, the shape of the first cavity in which the first injection is made even when the third and fourth molding spaces are alternately combined with the first molding space while the rotating core 40 is rotated is rotated. Will always be the same.

In the multi-injection mold 1 of the present embodiment, double injection can be performed simultaneously in one mold, and resin is filled in the first cavity formed by the combination of the first molding space and the third molding space 31. When the primary molded product is injected, the rotating core 40 is rotated while the primary molded product is attached to the third molding space 31 so that the third molding space 31 is positioned on the second molding space 12 side. When the first and second molds 10 and 20 and the core mold 30 are combined, the fourth molding space is combined with the first molding space to form a first cavity, and the third molding in which the primary molded product is mounted. The space 31 is joined with the second molding space 12 to form a second cavity.

The molten resin is injected into the first cavity again to inject the first molded article, and the molten resin is injected into the second cavity to inject the second molded article to complete the secondary molding.

When the molds are separated, the finished product that has been injected to the second molded product is separated and removed from the second cavity, and the rotating core 40 is rotated again so that the fourth molding space in which the first molded product is molded is directed downward and the product is removed. The third molding space 31 faces upward to prepare for the next injection molding.

Thus, the multi-injection mold 1 according to the present invention is formed on both sides of the rotating core 40 to form a molding space for forming the product, respectively, the injection of the product is made by the rotation of the rotary core 40 There is an advantage to this.

Rotation of the rotating core 40 is made by the core rotating unit (100).

The core rotating unit 100 is installed in the core mold 30 to support and rotate the rotating core 40, and the core driving means 110 and the core supporting means respectively coupled to one side and the other side of the core mold 30. 150.

As shown in FIG. 2, the core driving unit 110 includes a core coupling part 111 coupled to the rotating core 40, a driving part 121 supplying rotational force to the core coupling part 111, and a driving part ( It includes a power transmission unit 131 for transmitting the driving force of the 121 to the core coupling portion 111.

The core coupling portion 111 includes a coupling member 112 coupled to one side of the rotating core 40, the coupling member 112 is coupled to the rotating core 40 by a plurality of fastening bolts 113, A coupling groove 114 for coupling with the power transmission unit 131 is formed on the front surface.

Since the coupling groove 114 is formed to transmit the rotational force of the driving unit 121 to the coupling member 112 through the power transmission unit 131 which will be described later, it is formed in a square shape, and various shapes other than circular to enable power transmission. It may be formed in the form of a polygon.

A screw groove 115 for fastening the power transmission unit 131 to be described later is formed at the center of the coupling groove 114. Since the coupling member 112 is coupled to the rotary core 40 by the fastening bolts 113, the coupling member 112 may rotate integrally with the rotary core 40.

The drive unit 121 is to supply the rotational force of the rotary core 40 in this embodiment was applied to the geared motor 122. Rotating core 40 is preferably rotated at an appropriate speed that can be rotated in a state in which the production speed of the product and the molded first molded article is combined without departing from the rotating core 40. Therefore, the geared motor 122 supplies a reduced rotational force so that the rotation core 40 can rotate at an appropriate speed.

The power transmission unit 131 is to transfer the driving force of the drive unit 121 to the core coupling portion 111 is installed in the core mold (30).

The power transmission unit 131 is fastened to the fastening member 132 fitted into the coupling groove 114, the cylindrical member 134 extending a predetermined length to the rear of the fastening member 132, and the cylindrical member 134. A spline shaft 138.

The fastening member 132 is formed to correspond to the shape of the coupling groove 114 is inserted into the coupling groove 114 to transmit power.

Between the fastening member 132 and the cylindrical member 134 is formed a locking jaw 133 having a larger diameter than the cylindrical member 134, the locking jaw 133 is coupled to the bearing member 147 to be described later It is for.

The cylindrical member 134 extends a predetermined length from the locking step 133 toward the driving unit 121, and a spline groove 135 is formed at an end thereof. The spline groove 135 may be formed in various forms capable of transmitting power unlike the present embodiment.

And the inside of the cylindrical member 134 is formed with a hollow 136 extending in the longitudinal direction to insert the fixing member 137, the hollow 136 extends through the binding member. Therefore, the fixing member 137 is inserted from the rear end of the cylindrical member 134 and the end of the fixing member 137 protruding from the fastening member 132 is screwed into the screw groove 115 formed in the coupling groove 114. By being coupled, the cylindrical member 134 and the fastening member 132 are coupled to the coupling member 112.

When the cylindrical member 134 and the fastening member 132 are fastened to the coupling member 112 by the fixing member 137, the bearing member 147 is inserted to surround the cylindrical member 134 and the bearing support 141 is fastened. It is fastened to the core mold 30 to support the bearing member 147 and the power transmission unit 131.

The bearing support part 141 is composed of first and second supports 142 and 143 fastened to each other by the coupling bolt 146.

The first and second supports 142 and 143 have support grooves formed to support the locking jaw 133, the bearing member 147, and the first housing 50, which will be described later, and an upper portion of the core mold 30. It is fitted at each of the and the bottom and are mutually coupled.

Since the bearing support 141 is formed of the first and second supports 142 and 143 separated up and down, the bearing support 141 for supporting the bearing member 147 and then supporting the bearing support 141 to the core mold 30 is installed. It is easy. In addition, two key grooves 144 are formed in the first and second supports 142 and 143, respectively, on contact surfaces which are in contact with each other, and the guide keys 145 are fitted into the key grooves 144. Accordingly, when the first and second supports 142 and 143 are joined by the guide key 145, the coupling position can be easily adjusted.

The core mold 30 is coupled to the first housing 50 surrounding the cylindrical member 134 to protect the cylindrical member 134.

One end of the spline shaft 138 is fastened to the spline groove 135 and is connected to the other end so as to receive a rotational force from the driving unit 121 through the second housing 60. Accordingly, when the driving unit 121 is driven, the spline shaft 138 rotates, thereby rotating both the cylindrical member 134 and the coupling member 112 to rotate the rotating core 40.

Core support means 150 is coupled to the other side of the rotary core 40 is to support the rotating core 40 to the core mold 30 rotatably.

As shown in FIG. 3, the core support means 150 includes a coupling member 112 coupled to the rotary core 40 and a coupling member fitted into the coupling groove 114 formed in the coupling member 112. 132 and a cylindrical member 151 extending rearward of the fastening member 132.

The cylindrical member 151 and the fastening member 132 are fastened by being screwed to the coupling member 112 by the fixing member 137.

The core supporting means 150 has a configuration in which the driving part 121 and the spline shaft 138 of the core driving means 110 are omitted, and the rest of the components are the core driving means 110 except for the configuration of the cylindrical member 151. ) And the same number, and detailed description thereof will be omitted.

The cylindrical member 151 of the core support means 150 is not rotated as shown in the spline groove 135 is formed at the end instead of the rotating core 40 around the hollow 136, the fixing member 137 is installed A plurality of cooling water supply line 152 is provided extending toward.

After the resin is injected into the first and second cavities, cooling water for cooling the mold is supplied through the cooling water supply line 152.

In the rotary device of the multi-injection mold of the present invention, since the core rotating unit 100 for rotating the rotating core 40 can be easily combined with and separated from the rotating core 40, the rotation core 40 is replaced or maintained. Easy to repair

1 is a perspective view showing one embodiment of a multi-injection mold with a rotary core for double injection according to the present invention;

Figure 2 is an exploded perspective view showing the core driving means of the core rotating unit of Figure 1,

3 is an exploded perspective view showing the core support means of the core rotating unit of FIG.

<Explanation of symbols for the main parts of the drawings>

One; Multi injection mold with rotating core for double injection

10; First mold

20; 2nd mold

30; Core mold

40; Rotating core

100; Core rotating unit

110; Core driving means

150; Core support means

Claims (4)

It is installed between the first and the second mold and the first and the second mold, the first and second mold spaces are formed to be mutually matched and the mold separation, and the first and second molding spaces are formed on the opposing surfaces, respectively. In the multi-injection mold comprising a core mold having a rotating core having a third and fourth molding space on the upper and lower surfaces, respectively, to form first and second cavities for injection molding together with the second molding space. A first installed in the core mold to rotate the rotating core so that the third and fourth forming spaces of the rotating core can be combined with the first and second forming spaces, and coupled to one side of the rotating core. A core driving unit including a core coupling unit, a driving unit providing a rotation driving force to the rotating core, and a power transmission unit connecting the driving unit and the first core coupling unit to transmit power; And a core rotating unit installed on the other side of the rotating core, the core rotating unit including a core supporting means supporting the rotating core rotated by the core driving means with respect to the core mold. Rotating device of the multi injection mold provided. The method of claim 1, The core coupling part includes a coupling member which is screwed by fastening bolts on one side of the rotating core, and has a coupling groove formed at a predetermined depth in the front surface exposed toward the power transmission unit, The power transmission unit includes a fastening member fitted to the coupling groove so as to transmit rotational force to the coupling member, a cylindrical member extending from the fastening member and having a spline groove formed at a rear end thereof, and extending along the longitudinal direction of the cylindrical member. A fixing member inserted into the cylindrical member and having an end thereof fastened to a screw groove formed in the coupling groove of the coupling member to fix the cylindrical member and the coupling member to the core coupling portion; Rotating device of a multi-injection mold with a rotary core for double injection, characterized in that it comprises a spline shaft for transmitting to the cylindrical member. 3. The method of claim 2, An annular locking jaw having an outer diameter relatively larger than the diameter of the cylindrical member is formed between the fastening member and the cylindrical member. The core driving means has a bearing member which has an inner diameter to which the cylindrical member can be fitted so that the cylindrical member can easily rotate in the core mold, and is installed to surround one side of the cylindrical member; Further comprising a bearing support portion installed in the core mold to rotatably support the bearing member and the cylindrical portion, The bearing support portion is fitted in the upper and lower portions of the core mold and coupled to each other, and the first and second support members are formed with support grooves to support the bearing member and the locking jaw, respectively; Two guide keys are inserted into the key grooves formed on the upper and lower surfaces of the first and second supports, respectively, which are in contact with each other so as to guide the coupling position when the first and second supports are coupled. Rotating device of a multi injection mold equipped with a rotary core for injection. The method of claim 3, wherein The core support means is a rotary injection device of the multi-injection mold with a rotary core for dual injection, characterized in that it comprises a cooling water supply line for moving the cooling water supplied to the rotary core.

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