KR101907673B1 - Clamping device of dual injection molding machine - Google Patents

Abstract

The present invention relates to a mold coupler for a dual injection-molding machine. In particular, according to the present invention, the mold coupler for a dual injection-molding machine comprises: a plurality of pressing rods installed on a rear surface of a moving die horizontally moved along a guide rod; a plurality of insertion grooves formed in a piston of a mold coupling cylinder pressing the pressing rod such that the pressing rods are inserted into the insertion grooves; and a rotary plate installed on a front surface of the piston of the mold coupling cylinder in order to selectively pass or support the pressing rod. When the rotary plate supports the pressing rods in accordance with a rotational angle of the rotary plate to transfer coupling force of the piston to the moving die or to move the pressing rod, the pressing rod is inserted into the insertion groove formed in the piston to minimize a moving distance of the piston, thereby the length of a mold coupling unit is reduced.

Description

CLAMPING DEVICE OF DUAL INJECTION MOLDING MACHINE

The present invention relates to a mold insert for a dual injection molding machine, and more particularly, to a mold for a double injection molding machine in which a plurality of pressing rods are provided on a rear surface of a movable die moving left and right along a guide rod, Wherein a plurality of insertion grooves into which the plurality of pressure rods are inserted are formed, and a rotary plate for selectively passing or supporting the pressing rods is provided on a front surface of the piston of the rotary locking cylinder, The rotating plate supports a plurality of pressing rods to transmit the tightening force of the piston to the movable die or when the pressing rod is moved, the pressing rod is inserted into the insertion groove formed in the piston, thereby minimizing the moving distance of the piston, Wherein the length of the double injection molding machine It relates to a mold clamping coupled.

In the case of manufacturing a plastic product such as a key pad, a light guide plate, and a connector, the double injection is performed by injecting two molds into an injection molding machine in such a manner that one part is made of a material different from or different from the color, A mold is rotated by 180 ° so that a primary molded product can be molded by a secondary injection molding after a primary injection molding, and a secondary resin is injected into the cavity of the secondary molding mold and the space of the primary molding product for injection.

 The dual injection molding machine is largely divided into a mold cavity 100 and an injection cavity 200 which are provided on the base 10 and the base 10. At this time, the injection part 200 includes a first injection part 300 and a second injection part 400 provided in parallel. The mold clamping unit 100 includes a fixing plate 110, a movable die 210, and a fixing die 130. The fixing plate 110 is provided with a pair of clamping cylinders 111 and a pair of transferring cylinders 112. Each of the piston rods of the mold clamping cylinder 111 and the transfer cylinder 112 is connected to the movable die 210.

The fixing die 130 is provided on the base 10 at a predetermined distance from the fixing plate 110 and the fixing plate 110 and the fixing die 130 are connected by four guide rods 140. The guide rod 140 is provided with a movable die 210 and the movable die 210 is movable along the guide rod 140. The movable die 210 is connected to the respective piston rods of the mold clamping cylinder 111 and the transfer cylinder 112 and receives movement by the transfer cylinder 112 and mold clamping force by the mold clamping cylinder 111.

However, in the conventional mold insert for a dual injection molding machine, since the piston rod of the two mold clamping cylinders 111 fixed to the clamping plate 110 is directly connected to the movable die 210, the entire length of the mold clamp 100 Since it corresponds to the length of the piston of the clamping cylinder 111, there is a limit in reducing the length of the clamping fixture 100. [ That is, the conventional mold insert for a dual injection molding machine has a problem in that the volume and weight of the double injection molding machine are increased because the mold insert length for a conventional double injection molding machine becomes longer along the length of the piston of the mold clamping cylinder.

(0001) Registered Utility Model No. 20-0404213 (Registered on Apr. 21, 2004)

The present invention has been made in view of the above problems, and it is an object of the present invention to provide a mold insert for a dual injection molding machine capable of reducing the total volume and weight of the injection molding machine by minimizing the length of the mold insert, Thereby providing a mold-assembling body.

Further, the present invention provides mold clamping and pressing means capable of selectively supporting a piston of a mold clamping cylinder, thereby minimizing the length of the mold clamping unit, thereby reducing the total volume and weight of the injection molding machine. Shaped < / RTI >

As a means for achieving the object of the present invention, a mold insert for a dual injection molding machine according to the present invention comprises:

A plurality of guide rods provided horizontally on an upper portion of the base, and a plurality of guide rods disposed horizontally above the base, the guide rods being capable of being moved laterally along the guide rods in the center of the guide rods A fixed die fixed to one end of the guide rod and provided with two fixed dies so as to correspond to the two movable dies; a movable die fixed to the other end of the guide rod and having two mold clamping cylinders And two transfer cylinders provided between the fixing plate and the movable die for moving the movable die in the left and right direction of the fixed section,

Further comprising die clamping and pressing means provided between the two clamping cylinders and the movable die for selectively supporting the movable die,

Wherein the die clamping and pressing means comprises: a plurality of pressing rods provided on a rear surface of the movable die so as to extend a predetermined length;

A plurality of insertion grooves formed in the pistons of the two clamping cylinders so that the plurality of pressing rods can be inserted;

Two rotating plates rotatably mounted on the front surface of the piston of the mold clamping cylinder and having a plurality of through holes for allowing the plurality of pressing rods to pass therethrough;

And a rotating plate driving means for rotating the two rotating plates in opposite directions.

In the present invention, a fixing plate for rotatably fixing the two rotary plates is further provided on the front surface of the fixing plate.

The rotating plate driving means includes a rotating plate cylinder installed on the front surface of the fixed plate so as to be positioned between the two rotating plates;

Two rotating plate fixing pieces respectively fixed to the edges of the two rotating plates;

A rod fixing piece fixed to a front end of a rod of the rotating plate cylinder;

And two links rotatably installed between the rod fixing piece and the two rotary plate fixing pieces.

Wherein a mold fixing plate is rotatably mounted on the front surface of the movable die so that the two movable molds can be installed and rotated 180 degrees so as to change the positions of the two movable molds, The rotational force of the servo motor is transmitted through a driving gear provided on a motor shaft of the servo motor and a driven gear provided on the mold fixing plate.

Wherein two ejection cylinders are provided on the rear surface of the movable die, and a plurality of ejection pins penetrating the movable die and the movable die are connected to the rod ends of the ejection cylinders, the piston of the mold- Receiving grooves are formed to have a certain size so that they can be inserted.

According to the present invention, since the piston of the mold clamping cylinder can be selectively supported through the mold clamping and pressing means provided between the two mold clamping cylinders and the processing die, the length of the mold clamping unit can be minimized, And the weight can be reduced.

1 is a perspective view showing an example of a mold insert for a dual injection molding machine according to the present invention;
Fig. 2 is a plan sectional view showing a mold-assembling portion of a mold-release joint for a double injection molding machine shown in Fig. 1,
FIG. 3 is a side cross-sectional view showing a mold clamping portion of a mold insert for a dual injection molding machine according to the present invention shown in FIG. 2,
4 is a perspective view showing a plurality of pressing rods formed on the rear surface of the movable mold according to the present invention,
FIG. 5 is a front view showing two rotating plates installed on a front surface of a fixing plate according to the present invention;
6 is a front view showing a mold fixing plate provided on the front face of the movable mold according to the present invention,
FIG. 7 is a side view showing a servomotor and a mold fixing plate installed on the upper side of the movable mold according to the present invention,
FIG. 8 is a plan view showing the action of the mold clamping portion of the mold insert for a dual injection molding machine according to the present invention,
9 is a side view showing the operation of the mold clamping portion of the mold insert for a dual injection molding machine according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, a preferred embodiment of a mold insert for a dual injection molding machine according to the present invention will be described in detail with reference to the accompanying drawings.

In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. Further, the following terms are defined in consideration of the functions of the present invention, and this may vary depending on the intention or custom of the user, the operator, and the like, so that the definition of the mold- Based on the contents of this specification.

FIG. 1 is a perspective view showing an example of a double injection part having a mold half for a double injection molding machine according to the present invention, FIG. 2 is a plan sectional view showing a preferred embodiment of a mold half for a double injection molding machine according to the present invention, 2 is a side cross-sectional view of the mold cavity for a double injection molding machine shown in Fig. 2; Fig.

Referring to FIG. 1, a dual injection molding machine 100 having a mold insert for a dual injection molding machine according to the present invention comprises a base 101, a mold-assembling part 200 provided on the base 101, And an injection part 300 including first and second injection parts 300a and 300b. The injection section 300 is the same as the conventional injection section and is well known in the art, and therefore, a detailed description thereof will be omitted herein.

1, 2, and 3, a mold insert 200 (hereinafter referred to as a mold insert) for a dual injection molding machine according to the present invention is installed horizontally on the upper portion of the base 101 A movable die 210 installed at the center of the guide rod 250 so as to be movable left and right along the guide rod and having two movable molds 211a and 211b installed on the front side thereof, A fixing die 220 fixed to one end of the guide rod 250 and provided with two fixed dies 221a and 221b corresponding to the two movable dies, And a fixing plate 240 to which the two mold clamping cylinders 230a and 230b are fixed.

Two transfer cylinders 260a and 260b are provided between the fixing plate 240 and the movable die 210 to move the movable die 210 in the left and right sides of the movable die 210. The two transfer clamping cylinders 230a (500) installed between the movable die (230) and the movable die (210) to selectively support the movable die (210).

3 and 4, the mold clamping and pressing means 500 includes a plurality of pressing rods 511 integrally provided on the rear surface of the movable die 210 and a plurality of pressing rods 511 fixed to the fixing rods 240 Two rotating plates (rotatably mounted on the front surface of the piston 232 of the two mold clamping cylinders 230a and 230b) and having a plurality of through holes 522 through which the plurality of pressing rods 511 can pass, A plurality of insertion grooves 233 formed in the piston 232 of the two mold clamping cylinders 230a and 230b to allow the plurality of pressing rods 511 to be inserted therein, And a rotating plate driving means 530 for rotating the rotating plates 520a and 520b.

2 and 5, the rotating plate driving unit 530 is fixed to the front surface of the fixing plate 240 so that the two rotating plates 520a and 520b can be rotatably fixed, A rotating plate cylinder 533 vertically installed on the front surface of the fixed plate 531 so as to be positioned between the two rotating plates 520a and 520b; A rod fixing piece 537 fixed to the front end of the rod 534 of the rotary plate cylinder 533 and two rod fixing pieces 537 fixed to the edge of the rod fixing cylinder 537, And two links 538a and 538b rotatably installed between the rotating plate fixing pieces 536a and 536b.

The movable die 210 is further provided with a movable mold rotating means 400 for rotating the movable molds 211a and 211b by 180 ° so as to change the positions of the two movable molds 211a and 211b. 3, 6 and 7, the movable mold rotating means 400 is rotatably installed on the front surface of the movable die 210, and two movable molds 211a and 211b are installed on the front surface thereof And a mold clamping plate driving means 402 installed at the upper end of the movable die 210 for rotating the mold clamping plate 401.

The mold clamping plate driving means 402 includes a servo motor 403 provided on the upper surface of the movable die 210, a drive gear 405 provided on the rotary shaft of the servo motor 403, And a driven gear 407 provided on the rear surface of the mold fixing plate 401 so as to engage with each other.

Further, ejector means 600 for ejecting an injection-molded product is provided on the rear surface of the movable die 210. The ejector means 600 includes two ejector cylinders 601a and 601b provided on the rear surface of the movable die 210 and a plurality of ejector pins 601a and 602b provided on the tip of the piston rod 602 of the ejector cylinder 601. [ (603). At this time, receiving grooves 235 are formed at the centers of the pistons 232 of the two mold clamping cylinders 230a and 230b so that the ejector cylinders 601a and 601b can be inserted. The movable die 210 And the movable mold 211 are formed with through holes 606 through which a plurality of ejector pins 603 pass.

A plurality of pressing rods 511 are provided on the rear surface of the movable die 210 and the piston 232 of the mold clamping cylinders 230a, The pressing rod 511 is selectively supported on the entire surface of the piston 232 of the mold clamping cylinders 230a and 230b by forming a plurality of insertion grooves 233 into which the plurality of pressing rods 511 are inserted. A plurality of through holes 522 through which the pressing rod 511 can pass can be formed on the upper surface of the rotating plate 520. The plurality of pressing rods 511 A plurality of pressing rods 511 are provided on the rotation plate 520 when the movable gantry 210 is retracted or a locking force is applied so that the movable die 210 is not pushed when the rotary gantry 500 is supported by the rotary plate 520, Through the through hole 522 formed in the piston 232 and inserted into the insertion groove 232 formed in the piston 232 By so to allow to minimize the travel distance of the piston 232 of the clamping cylinder 230 and thereby Dara reduce the overall length of the associated clamping (200).

More specifically, as shown in Figs. 1 and 2, the mold-clamping fixture 200 is configured such that two movable molds 211a, 211b and fixed molds 221a, 221b are closed or opened to enable injection molding A fixing plate 240 fixed to the left end of the guide rod 250 and a fixing plate 240 fixed to the left end of the guide rod 250 at the right end of the guide rod 250. [ A fixing die 220 fixed to the fixing plate 220 and provided with two fixing dies 221 and a fixing die 220 installed between the fixing plate 240 and the fixing die 220 to horizontally move along the guide rod 250, And a movable die 210 provided with a movable mold 211.

A movable mold rotating means 400 for rotating the two movable molds 511a and 511b by 180 ° is provided on the front surface of the movable die 210 to enable double injection. 3, the movable mold rotating means 400 includes a mold fixing plate 401 rotatably mounted on the front surface of the movable die 210, a mold fixing plate 401 for rotating the mold fixing plate 401, And driving means (402).

Therefore, a molding space is formed between the home die 211 and the stationary mold 221. By moving the movable die 210 to the left and right, the movable mold 211 and the stationary mold 221 can be engaged or disengaged to perform injection molding. As described above, the mold clamping unit 200 according to the present invention performs the injection molding operation by moving the movable die 210 in the left and right of a certain section.

To this end, the mold clamping unit 200 is provided with two transfer cylinders 260a and 260b as means for moving the movable die 210 to the left and right. The two transfer cylinders 260a and 260b are installed between the fixed plate 240 and the movable die 210. The transfer cylinder 260 includes a cylinder body and a piston rod inserted into the cylinder body. Accordingly, when hydraulic pressure is supplied to the cylinder body, the piston rod extends to the right and the movable die 210 moves to the right. When the movable die 210 moves to the right side, the movable mold 211 and the stationary mold 221 are engaged with each other. On the contrary, when the piston rod of the cylinder body of the transfer cylinder 260 is contracted to the left, the movable die 210 moves to the left and the movable mold 211 and the stationary mold 221 are separated from each other.

At this time, the transfer cylinder 260 uses a cylinder having a small flow rate to move the movable die 210 quickly. Accordingly, when the high-pressure molten resin flows between the movable mold 211 and the stationary mold 221, the movable die 210 is pushed to the left by the pressure. The present invention further includes two clamping cylinders 230a and 230b to prevent the movable die 210 from being pushed to the left.

That is, the two mold clamping cylinders 230 are formed of cylinders having a large flow rate to support the movable die 210 in the injection moldability so as not to be pushed to the left. For this purpose, the two clamping cylinders 230 are fixed to the fixing plate 240. The mold clamping cylinder 230 includes a cylinder body 231 and a piston 232 inserted into the cylinder body 231. Further, a hydraulic pressure supply device (not shown) is connected to the mold clamping cylinder 230. The hydraulic supply device (not shown) includes a hydraulic tank and a hydraulic pump. Accordingly, when the hydraulic pressure is supplied to the mold clamping cylinder 230, the piston 232 is extended to the right. When the hydraulic pressure is discharged from the mold clamping cylinder 230, the piston 232 contracts to the left.

The mold clamp 200 according to the present invention is further provided with a clamp clamping means 500 between the piston 232 of the two clamp clamping cylinders 230 and the movable die 210. The mold clamping and pressing means 500 has a structure capable of selectively supporting the movable die 210. That is, a mold clamping and pressing means 500 capable of selectively transmitting the clamping force of the piston 232 of the mold clamping cylinder 230 to the movable die 210 is required.

3 and 4, the mold clamping and pressing means 500 includes a plurality of pressing rods 511 extending to a predetermined length on the rear surface of the movable die 210. [ The pressing rod 511 may be a cylinder having a predetermined diameter and extending to a predetermined length, but is not limited thereto. The pressure rods 511 are spaced apart from each other at a predetermined interval so as to distribute the force. The pressure rods 511 are arranged in the circumferential direction, 510a and 510b, but is not limited thereto.

The piston 232 of the mold clamping cylinder 230 is formed with an insertion groove 233 into which the plurality of pressing rods 511 are inserted. The insertion groove 233 allows the movement distance of the piston 232 and the length of the shaped body 200 to be minimized by accommodating the pressing rod 511.

Two swing plates 520a and 520b for selectively supporting the pressing rod 511 are installed on the front surface of the piston 232 of the two clamping cylinders 230a and 230b. The two rotation plates 520a and 520b are rotatably installed on the front surface of the piston 232 of the two mold clamping cylinders 230a and 230b. The two rotating plates 520 are formed with a plurality of through holes 522 through which the plurality of pressing rods 511 can pass, The neighboring through holes 522 are spaced apart from each other by a predetermined distance so as to selectively support the tip of the rod 511 to form the contact surface 522a. That is, the contact surface 522a refers to a space between neighboring through holes 522. [

That is, the tip ends of the plurality of pressing rods 511 formed on the rear surface of the movable die 210 are in a free-end state. Therefore, when the movable die 210 moves to the left, the tip ends of the plurality of pressing rods 511 pass through the plurality of through holes 522 in accordance with the rotation angle of the rotary plate 520, And the tip of the plurality of pressing rods 511 is inserted into the insertion groove 233 formed in the piston 232 of the movable die 230 to contact the contact surface 522a between the through holes 522, ). In other words, when the movable die 210 is moved to the right and the movable mold 211 and the stationary mold 221 are coupled to each other to perform injection molding, a plurality of pressing rods (not shown) provided on the rear surface of the movable die 210 The clamping force of the piston 232 of the mold clamping cylinder 230 is transmitted to the movable die 210 while the tip of the movable die 210 is supported by the contact surface 522a of the rotating plate 520, 210 can be prevented from being pushed.

Preferably, the plurality of through holes 522 formed in the rotary plates 520a and 520b are circularly arranged to correspond to the plurality of pressing rods 511. [ Further, a contact surface 522a is formed at which a constant gap is formed between the adjacent through holes 522 and the end of the pressing rod 511 is in contact. The plurality of pressing rods 511 pass through the through holes 522 in accordance with the rotation angle of the rotary plates 520a and 520b so that the movable die 210 can be moved to the left side, The tip of the movable die 511 contacts the contact surface 522a to support the movable die 210 so as not to be pushed.

The two rotary plates 520a and 520b are fixed to a fixing plate 531 provided on the front surface of the fixing plate 210. [ The fixing plate 531 is formed with two openings through which the two rotary plates 520a and 520b can pass. The fixed plate 531 is provided with a rotating plate driving means 530 for rotating the two rotating plates 520a and 520b.

2 and 5, the rotating plate driving means 503 includes a rotating plate cylinder 533 vertically installed on the front surface of the fixed plate 531 so as to be positioned between the two rotating plates 520a and 520b, And two rod fixing members 536a and 536b fixed to the edges of the two rotation plates 520a and 520b and a rod fixing member 536b fixed to the tip of the piston rod 534 of the rotation plate cylinder 533. [ And two links 538a and 538b which are rotatably installed between the two rotary plate fixing members 536a and 536b and the rod fixing member 537. [ The rotating plate cylinder 533 includes a cylinder body and a rod inserted into the cylinder body.

Therefore, when the piston rod of the rotating plate cylinder 533 is extended upward, the two links 538a and 538b are moved upward, and the rotating plate fixing piece 536a 536b. Then, the two rotary plates 520a and 520b rotate about the central axis, and the two rotary plates 520a and 250b rotate outward. On the other hand, when the rod of the rotating plate cylinder 533 is contracted to the lower side, the two links 538a and 538b move downward to rotate the rotating plate fixing piece 536a 536b. Then, the two rotating plates 520a and 520b rotate about the center axis, and the two rotating plates 520a and 250b rotate inward.

 The plurality of through holes 522 formed in the rotating plate 520 and the plurality of pressing rods 511 are aligned or shifted in a straight line when the rotating plate 520 is rotated at a predetermined angle. That is, when the plurality of through holes 522 and the pressing rod 511 are arranged in a straight line, when the movable die 210 moves to the left, the plurality of pressing rods 511 pass through the through holes 522 And inserted into the insertion groove 233 of the piston 232. On the other hand, when the plurality of through holes 522 and the pressing rod 511 are displaced, when the piston 232 of the clamping cylinder 230 is extended to the right, And contacts the contact surface 522a of the rotary plate 520 to press the movable die 210.

On the front surface of the movable die 210, movable mold rotating means 400 for rotating the two movable molds 211a and 211b by 180 ° are provided. The movable mold rotating means 400 includes a mold fixing plate 401 rotatably mounted on a surface facing the fixed die 220 and provided with two movable molds 211. The mold fixing plate 401 is installed on the front surface of the movable die 210 so as to be rotated by 180 ° around the central axis.

The movable die 210 is provided at its upper end with a mold clamping plate driving means 402 for rotating the mold clamping plate 401. The mold clamping plate driving means 401 includes a servo motor 403 provided at the upper end of the movable die 210 to provide a rotational force to the mold clamping plate 401, 401). The power transmitting means includes a driving gear 405 provided on the motor shaft of the servo motor 403 and a driven gear 407 provided on the mold fixing plate 401 to be engaged with the driving gear 405. Therefore, when the servomotor 403 rotates, the mold fixing plate 401 rotates in the normal direction by 180 ° and reversely rotates to change the positions of the two movable molds 211a and 211b.

Two ejection cylinders 601 are provided on the rear surface of the movable die 210. As shown in FIG. 3, the ejection cylinder 601 includes a cylinder body and a piston rod 602 inserted into the cylinder body. A plurality of eject pins 603 are formed at the tip of the piston rod 602. The plurality of eject pins 603 are installed to pass through the through holes formed in the movable die 210, the mold fixing plate 401, and the movable mold 211. A receiving groove 235 is formed in the center of the piston 232 of the mold clamping cylinder 230 so that the ejection cylinder 601 is inserted. Therefore, when the movable die 210 moves to the left, the ejection cylinder 601 is inserted into the receiving groove 235. The plurality of eject pins 603 are contracted when the mold fixing plate 401 rotates to allow the mold fixing plate 401 to freely move.

Hereinafter, the operation of the mold insert for a dual injection molding machine according to the present invention will be described.

First, FIG. 8A shows a mold release state. The piston rod of the two transfer cylinders 260 and the piston 232 of the mold clamping cylinder 230 are contracted to the left and the movable die 210 is moved to the left. The plurality of pressing rods 511 formed on the movable die 210 are inserted into the insertion holes 233 formed in the piston 232 through the through holes 522 of the rotary plate 520 formed on the front surface of the piston 232, Respectively. The ejection cylinder 601 is inserted into the receiving groove 235 formed in the piston 232.

Next, FIG. 8B shows the state of the mold engagement. The piston rod of the two transfer cylinders 260 is extended to the right and the movable die 210 is moved to the right to engage the movable mold 211 and the stationary mold 221. A plurality of pressing rods 511 provided on the rear surface of the movable die 210 are inserted into the plurality of insertion grooves 233 formed in the piston 232 of the mold clamping cylinder 230 and the pistons of the mold clamping cylinder 230 232 from the through hole 522 of the rotating plate 20 provided on the front surface of the rotating plate 20. The ejection cylinder 601 also escapes from the receiving groove 235 of the piston 232. When the piston 232 of the mold clamping cylinder 230 is extended to the right, the piston 232 presses the plurality of pressing rods 511 through the rotary plate 520. Then, the plurality of pressing rods 511 press the movable die 210 and support it so as not to be pushed to the left.

Next, FIG. 8C shows the injection molded article taken out state. The piston 232 of the mold clamping cylinder 230 and the piston rod of the two transfer cylinders 260 are contracted to the left so that the movable mold 211 and the stationary mold 221 are separated. The two ejection cylinders 601 provided on the rear surface of the movable die 210 extend the piston rod 602 to the right. A plurality of eject pins 603 formed at the tip of the piston rod 602 penetrate the through holes formed in the movable die 210, the mold fixing plate 401 and the movable mold 211 to take out the injection molded product.

9A and 9B show a state in which the rotary plate 520 installed on the front surface of the piston 232 of the mold clamping cylinder 230 and the rotary plate 520 are fixed It shows the angle rotation status. 9A, when the piston rod of the rotating plate cylinder 533 is extended upward, the two links 538a and 538b are moved upward, and the ends of the rotating plates 520a and 520b And the installed rotary plate fixing pieces 536a and 536b are moved upward. Then, the two rotating plates 520a and 520b rotate around the central axis, and the two rotating plates 520a and 250b rotate outward at a certain angle. The contact surface 522a between the through holes 522 formed in the rotating plate 520 is arranged to correspond to the plurality of pressing rods 511. [ In this state, when the piston 232 of the mold clamping cylinder 230 is extended to the right, the movable mold 211 and the stationary mold 221 are brought into close contact with each other and the movable die 210 is moved to the left It can be supported not to be pushed.

9B shows a state in which the piston rod of the rotating plate cylinder 533 is contracted to the bottom so that the two links 538a and 538b are moved downward and the rotating rod 520a, The fixing pieces 536a and 536b are moved downward. Then, the two rotating plates 520a and 520b rotate about the center axis, and the two rotating plates 520a and 250b are rotated inward by a certain angle. The through holes 522 formed in the rotating plate 520 are arranged to correspond to the plurality of pressing rods 511. When the piston rod of the transfer cylinder 260 is contracted to the left in this state, a plurality of pressing rods 511 provided on the rear surface of the movable die 210 pass through the through hole 522 of the rotating plate 520 And inserted into the insertion groove 233 of the piston 232. The ejection cylinder 601 is also inserted into the receiving groove 235 of the piston 232.

A plurality of pressing rods 511 provided on the rear surface of the movable die 210 are rotated by the rotation of the rotating plate 520 so that the piston of the mold clamping cylinder 230 The length of the molded body 200 can be reduced by allowing the molded body 200 to be inserted into the insertion groove 233 formed in the body 232. As the length of the mold-clamping unit 200 is shortened, the moving distance of the transfer cylinder 260 and the mold clamping cylinder 230 is shortened, thereby reducing the flow rate and saving energy. In addition, the piston rod of the transfer cylinder 260 can be moved quickly, and the travel distance of the piston can be shortened, thereby reducing wear and heat generation.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

100: Double injection molding machine 101: Expectation
200: mold clamp 210: movable die
211: movable mold 221: stationary mold
220: Fixing die 230: Mold clamping cylinder
232: piston 233: insertion groove
240: fixed plate 250: guide rod
400: movable mold rotating means 300:
401: mold fixing plate 402: mold fixing plate driving means
403: Servo motor 405: Driving gear
407: driven gear 500: clamping and pressing means
511: pressing rod 530: rotating plate driving means
531: Fixing plate 533: Rotating plate cylinder
536: Spindle fixing piece 537: Rod fixing piece
538: Link 600: Ejector means
601: Ejector cylinder 603: Ejector pin

Claims (5)

A plurality of guide rods provided horizontally on an upper portion of the base, and a plurality of guide rods provided in the middle of the guide rods, A stationary die fixed to one end of the guide rod and provided with two stationary molds so as to correspond to the two movable molds; a movable die fixed to one end of the guide rod and provided with two stationary molds; A mold insert for a dual injection molding machine, comprising: a fixed plate fixed to an end of a mold and fixed with two mold clamping cylinders; and two transfer cylinders provided between the fixed plate and the movable die for moving the movable die in left and right directions,
A plurality of pressing rods extending to a predetermined length on the rear surface of the movable die; a plurality of insertion grooves formed in the pistons of the two type clamping cylinders so that the plurality of pressing rods can be inserted; And a plurality of through holes formed in the front surface of the movable die so as to allow the plurality of pressure rods to pass therethrough, the movable die being provided between the two type clamping cylinders and the movable die, A clamping and pressing means for supporting the clamping means;
A fixing plate for rotatably fixing the two rotation plates on the front surface of the fixing plate; a rotating plate cylinder installed on the front surface of the fixing plate so as to be positioned between the two rotation plates; A rod fixation piece fixed to the tip of the rod of the rotary plate cylinder and two links rotatably installed between the rod fixation piece and the two rotary plate fixation pieces, And a rotating plate driving means for rotating the rotating body in the opposite direction.
delete delete The method according to claim 1,
Wherein a mold fixing plate is rotatably mounted on the front surface of the movable die so that the two movable molds can be installed and rotated 180 degrees so as to change the positions of the two movable molds, Wherein a rotational force of the servo motor is transmitted through a driving gear provided on a motor shaft of the servo motor and a driven gear provided on the mold fixing plate.
5. The method of claim 4,
Wherein two ejection cylinders are provided on a rear surface of the movable die, and a plurality of ejection pins penetrating the movable die and the movable die are connected to the rod ends of the ejection cylinders, and the piston of the mold- Wherein the receiving recess is formed in a predetermined size so that the receiving recess can be inserted into the receiving recess.

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