KR100719223B1 - Half nut of injection molding apparatus - Google Patents

Abstract

The present invention relates to a half nut of a direct-pressure injection molding machine. The half nut, which repeats the operation of holding and releasing a tie bar passing through the four corners of the movable plate of the injection molding machine, is formed with two divided nuts having a semicircular cross section. One end of each of the divided nuts is rotatably installed by two fixing pins fixed to the rear surfaces of the four corner portions of the movable plate, and one end of each of the left and right operation links is provided at the other ends of the two divided nuts. It is rotatably connected, and the other end of each of the left and right operation link is rotatably connected to the front end of the piston rod of the operation cylinder fixedly attached to the back of the movable plate, the piston rod of the operation cylinder As the split nuts on both sides rotate in opposite directions with respect to the tie bar, It is configured to allow the movement operation or to rotate to surround the tie bar and is engaged with the uneven portion of the tie bar to generate a clamping force for the movable mold of the movable plate to maintain the mold closing operation to the fixed mold of the fixed plate. It is an invention made.

Injection molding machine, movable plate, tie bar, half nut, half nut cylinder, operation link

Description

Half nut of Injection molding apparatus

1 and 2 are a side view and a front view showing a half nut installation state of the direct pressure injection molding machine for explaining the present invention.

Figure 3 is an exploded perspective view of the half nut and its supporting plate of the present invention.

4 and 5 is a half nut operating state of the present invention.

Figure 6 is a half nut cross-sectional view of the present invention.

7 and 8 are a plan view showing a half nut installation state of the prior art.

9 and 10 are cross-sectional views of the half nut operating state of the prior art.

※ Explanation of code for main part of drawing

1: Half nut 1a, 1b: Semi-circular split nut

11,12: incision groove 2a: movable plate

2b: fixed plate 21: movable mold

22: fixed mold 3: tie bar

31: uneven portion 4a, 4b: fixing pin

5a, 5b: Operation link 51,52: Connection pin

6: half nut cylinder 61: piston rod

62: bracket 7: fixing rod

8: support plate 81: bolt

82: center hole 83,84: first and second proximity sensor

9: working cylinder

The present invention relates to a half nut of a direct pressure injection molding machine, and more particularly, a movable mold combined with a fixed mold during injection operation does not appear to be relaxed due to the injection pressure, and thus maintains a mold closing state with the fixed mold. The half nut for generating the clamp force is improved to be opened and closed by rotation.

The half nut of the direct injection molding machine is applied to the two-platen direct rock method in order to reduce the installation area and generate the mold force as the machine is enlarged. Referring to the illustration of Figure 10 as follows.

The half nut 100 grips the uneven portion 310 formed on the tie bar 300 penetrating the four corners of the movable plate 200 of the injection molding machine to generate a clamping force on the movable plate 200. Or the movable plate 200 is responsible for releasing the uneven portion 310 of the tie bar to enable mold closing operation and mold opening operation, the half nut 100 is divided into two divided nut 110 ) And the other split nut 120 is installed on the two upper edges of the movable plate 200 so as to be slidably movable on two upper and lower support plates 400a and 400b fixedly attached to face each other at regular intervals. Both split nuts 110 and 120 are coupled by the half nut cylinder 500 in a state of wrapping the uneven parts 310 of the tie bar 300 or are relaxed in the uneven parts 310.

As shown in FIG. 10, when the piston nut 510 of the half nut cylinder 500 pushes the one side split nut 110 toward the tie bar 300 by the forward (appearing) operation, as shown in FIG. In response to the cylinder fixing plate 520, one end is attached to both sides, and the other end penetrates through both sides of the one side split nut 110 and is inserted into the other side of the split nut 120, so that both side guide bars 600 are screwed to the other side of the split nut. By pulling the 120, both side split nuts 110 and 120 hold the uneven portion 310 of the tie bar 300. The semicircular portions of the both side split nuts holding the uneven portion 310 are caught. The ring projection and ring groove is engaged with the concave-convex portion 310 is formed.

As shown in FIG. 9, when the piston rod 510 of the half nut cylinder 500 pulls one side split nut 110 in the opposite direction to the tie bar 300 by the reverse (immersion) operation, both guide bars at this time. Since the 600 pushes the other split nut 120 to relax in the tie bar 300, both side split nuts 110 and 120 are configured to relax in the uneven portion 310 of the tie bar.

As described above, the piston rod 510 of the half nut cylinder 500 moves forward or backward, and the half nut 100 coupled or relaxed to the tie bar 300 by the reaction of both guide bars 600 is an injection molding machine. It will play a very important function in generating the clamping force on the movable mold 210 during the injection operation of the. That is, when the movable plate 200 is operated in the open state (opened state) as shown in FIG. 7, the split nuts 110 and 120 on both sides of the half nut 100 are relaxed to each other and the movable plate 200 is moved. ) Can be moved toward the fixed plate 700, so that the operation cylinder 800 moves the movable plate 200 to the fixed plate 700 for the product injection operation, the movable mold 210 is fixed to the fixed plate 700 As soon as the mold 710 is in the closed state (mold closed state), the half nut cylinder 500 is actuated immediately so that the split nuts 110 and 120 on both sides of the half nut wrap the uneven portion 310 of the tie bar. While maintaining the mold closing state of the 210 and at the same time the pressure-increasing cylinder (not shown) mounted on the injection main body is activated to generate a pressure to move the tie bar 300 in the direction of the fixed plate 700 accordingly Half nut 100 is coupled to the uneven portion 310 in a state The pressure generated by the pressure cylinder acts on the movable plate 200 to generate a clamping force to maintain the mold closing operation in the stationary mold 710 in the movable mold 210, and thus plastic raw material injected from the injection base body. Even if the injection pressure of the instantaneous acting on the movable mold 210, the movable mold 210 does not appear to be a fine language phenomenon in the fixed mold 710 without maintaining the mold closing operation as it is a genuine product Injection molding is possible.

Therefore, the large-scale direct injection molding machine to which the half nut 100 is applied has a mechanical characteristic because the injection molding of the product and the operation of taking out the product by ejecting the product are performed in a short time and repeatedly continuously. Repeated operation of holding and releasing the tie bar 300 must be made precisely so that a defect of the product does not occur.

However, the half nut 100 of the related art has the following problems.

The half nut 100 is concentrated on the lower support plate 400b which is lower than the upper support plate 400a formed on the upper side of the split nut 110 and 120. The friction coefficient with the lower support plate 400b increases when moved to the right, so that the wear of the guide bars 610 and 620 installed on the lower guide bar 600 is not only rapidly progressed, but also divided nuts 110 and 120 on both sides. The wear of the slice plates 111 and 121 interposed on the lower and lower support plates 400b also progresses rapidly, and thus the replacement cycle of the guide bar bush and the slide plates is shortened, and the half nut cylinder 500 Stopper protruding on both ends of each of the divided nut, since the moment of moment of momentary moment of both the split nut 110, 120 to be operated by the action and reaction by the forward and backward operation of the piston rod 510 of the Protrusions 112,113 (122,123) A phenomenon occurs that collides with the stopper keys 410, 420, and 430 formed on the upper and lower support plates 400a, 400b, respectively. Such collisions may cause damage to the parts, but may be caused by vibrations caused by the collision. The problem of loosening of the screw 600 and a cause of breakage of the piston rod 510 of the operation cylinder 500 occurs.

In addition, the conventional half nut 100 detects a movement state of the sensor touch bars 114 and 124 formed at each of the split nut 110 and 120 at each side to control the operation cylinder 500 in total. (440 ~ 470) is used, the number of installation of the proximity sensor is also pointed out as a problem to be improved.

The present invention is proposed in order to solve the general problems occurring in the conventional half nut as described above, in order to prevent the linear friction action occurring in the half nut as in the prior art to rotate the split nut on both sides of the half nut By improving the operation, the friction coefficient of the parts of the rotating part is reduced, and the rotating speed and force decreases at the moment of opening and closing of the split nuts on both sides, while the rotating speed and the rotation speed when the split nuts on both sides are opened and closed. It is invented for the purpose of protecting the piston rod of the operation cylinder which opens and closes the nut on both sides so that the opening and closing operation of the half nut is quick and smooth so that an impact is not generated.

The present invention as a means for achieving the above object,

It is an operation to hold the uneven parts formed in a certain section on each of the plurality of tie bars that penetrate the four corners of the movable plate of the injection molding machine to generate a clamping force on the movable mold during the injection molding of the product. In the half nut is provided on each of the four corners of the back side of the movable plate to repeat the operation of releasing the tie bar,

The half nut,

It is formed by two semicircular split nuts of semicircular cross section.

One end of each of the two semi-circular partition nut is rotatably installed by two fixing pins fixed to the back of each of the four corners of the movable plate,

One end of each of the left and right actuating links is rotatably connected to each other end of the two semicircular split nuts, and the other end of each of the left and right actuating links is connected to the piston rod end of the half nut cylinder fixed to the rear surface of the movable plate. Rotatably connected structure,

As the piston rod of the half nut cylinder is sunk and operated, the split nuts on both sides rotate in opposite directions with respect to the tie bar, and are relaxed in the tie bar to allow movement of the movable plate or rotate in a state of surrounding the tie bar. It is characterized in that the movable mold of the movable plate is engaged with the concave-convex portion of the movable plate to generate a clamping force to maintain the mold closing operation of the fixed mold of the fixed plate.

In addition, the half nut is a plurality of fixing rods fixed on both sides of the semi-circular split nut, both sides, and the support plate is fixedly attached to the distal end of these fixing rods as bolts to cover both semi-circular split nuts to enable rotational operation and the One side of the center hole formed to have a diameter larger than the tie bar in the center of the support plate and one side of the fixed plate further comprises a plurality of proximity sensors which are each installed to control the piston rod inlet operation of the half-nut cylinder do.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 are a side view and a front view showing a half nut installation state of the direct-pressure injection molding machine for explaining the present invention, Figure 3 is an exploded perspective view of the half nut and its supporting plate of the present invention, Figures 4 and 5 It is a state of the half nut operation of the invention, Figure 6 shows a cross-sectional view of the half nut of the present invention.

In the drawing, reference numeral 1 denotes a half nut, and the half nut 1 is formed on each of the four corners of the back side of the movable plate 2a of the injection molding machine, thereby forming the four corner portions of the movable plate 2a. On each of the four tie bars 3 penetrating, the ring protrusion and the ring groove are alternately repeatedly installed so as to hold or release the uneven portions 31 formed at the same time.

The half nut 1 is composed of two semicircular split nuts 1a and 1b having a semicircular cross section, and one end of each of the two semicircular split nuts 1a and 1b is movable plate 2a. ) Is rotatably attached to two fixing pins (4a) and (4b) fixed to one another side by side at a predetermined distance from the tie bar (3) on the back corner of the back side, and the other ends rotate in opposite directions. Or rotate in a direction facing each other.

Cutting grooves 11 and 12 are formed at the other end of each of the two semicircular split nuts 1a and 1b, and the pair of left and right operation links 5a are formed in the two cutting grooves 11 and 12, respectively. (5b) is rotatably connected by connecting pins 51 and 52 in a state where one end of each of the two ends is fitted, and the other end of each of the left and right operation links 5a and 5b is a half nut cylinder 6 Is rotatably connected to the tip of the piston rod (61).

One end of each of the left and right actuating links 5a and 5b is rotatably connected to each of the connecting pins 51 and 52 by the link bush 53, and also includes the cutout grooves 11 and 12. Each of the link guides 54 supporting one end of the left and right operation links 5a and 5b are always in place, and are provided with the connecting pins 51 and 52 wrapped therein. The 51 and 52 are fixed to the two semicircular piece split nuts 1a and 1b by the keys 55 and 56.

In addition, the half nut cylinder 6 in the above is composed of a total of four so as to operate the half nut 1 installed on each of the four corners of the moving plate (2a), each half nut in the present invention, unlike the prior art The cylinder 6 is installed in a state fixed to the rear surface of the movable plate 2a by the bracket 62.

One end of a total of four fixing rods 7 protrudes around the half nut 1 in the state of being screwed into the four corners of the rear surface of the movable plate 2a, and each of the plurality of fixing rods 7 On the protruding end, a four corner portion of the support plate 8 covering the half nut 1 is attached, and the support plate 8 is installed in a state that allows rotation of both semi-circular split nuts 1a and 1b. .

The support plate 8 is fixedly attached by screwing a plurality of bolts 81 inserted into the assembling holes formed at the corners thereof to the female threaded holes formed at the tips of the respective fixing rods 7. In addition, one side of the center hole 82 and one side of the support plate formed at a diameter larger than the tie bar 3 in the center of the support plate 8 detects the opening or closing operation of the half nut 1 so that the half nut cylinder 6 First and second proximity sensors 83 and 84 for controlling operation are provided.

The operation of the present invention configured as described above will be described.

The half nut 1 is installed in each of the four corners of the rear surface of the movable plate 2a of the direct pressure injection molding machine, as shown in FIGS. 1 and 2, and is provided in the uneven portion 31 of the tie bar 3. The actuating mold 21 which maintains the clamping force so that the movable mold 21 closed on the fixed mold 22 is not pushed out by the injection pressure during the injection molding, and after the injection operation is completed, the movable plate 21 is relaxed in the above-mentioned concave-convex portion 31. The operation 2a and the movable mold 21 are allowed to return to their original positions.

4 shows an operating state in which the half nut 1 is engaged with the uneven portion 31 of the tie bar 3 wrapped.

As described above, the closing operation in which the half nut 1 is engaged with the uneven portion 31 is operated by first operating the operating cylinder 9 to move the movable plate 2a toward the fixed plate 2b in order to eject the product. The mold 21 is made in a state in which the mold closing operation in contact with the fixed mold 22 is completed. At this time, when the half nut cylinder 6 is operated to immerse (reverse) the piston rod 61, the left and right operation links ( 5a) and 5b also move in the direction in which the piston rod 61 is immersed, so that the semi-circular split nuts 1a and 1b on both sides have the tie bar 3 with the fixing pins 4a and 4b as the starting point. Rotating toward the wrap around the concave-convex portion 31. Since the inner surface of each of the two semi-circular split nut (1a) (1b) is formed in the inner surface of each of the concave-convex portion (symbol omitted) is formed on both sides semi-circular The split nuts 1a and 1b are engaged with the uneven portion 31 of the tie bar 3 wrapped. In the first proximity sensor 83 mounted at one side of the center hole 82 of the support plate 8, the left and right actuating links 5a and 5b have both semicircular split nuts 1a and 1b. 31, it detects the time when the closing operation is completed (in the figure shows a state in which the left operating link is detected).

The first proximity sensor 83 which detects that the closing operation of the half nut 1 is completed as described above controls the half nut cylinder 6 to inject the product into the closed mold 21 and the fixed mold 22. The half nut 1 is kept closed until the completion of the operation. When the movable mold 21 is mold-opened at the stationary mold 22 after the product injection operation is completed, the half nut cylinder 6 is closed. The piston rod 61 is actuated (advanced) to operate.

When the piston rod 61 of the half nut cylinder pushes the left and right actuating links 5a and 5b in an emergent operation, the facing semi-circular split nut 1a and 1b rotates the fixing pins 4a and 4b. As shown in Fig. 5, the semicircular split nut 1b on one side is one side of the support plate 8 when it is released from the uneven portion 31 of the tie bar 3 as shown in FIG. The second proximity sensor 84 controls the half nut cylinder 6 so that the piston rod 61 appears (advances) in a state of being rotated and moved up to the second proximity sensor 84 formed at the predetermined time. To be maintained during Therefore, the operation cylinder 9 is operated in the state in which the half nut 1 is relaxed in the uneven portion 31 and the opening operation is completed to return the movable plate 2a to its original position (pre-injection position).

As described above, the half nut cylinder 6, which rotates to open and close the semi-circular split nuts 1a and 1b of the half nut 1, is fixed to the rear surface of the movable plate 2a. It is possible to keep the working distance of the constant at all times, and also as the angle (α) in the direction of the force "F" and "Y" axial direction shown in Figs. 1a) and 1b are rotation speeds controlled at the opening and closing operation.

That is, the larger the angle α, the faster the opening operation of both semicircular split nuts 1a, 1b, while the smaller the angle α, the closer the closed semicircular split nuts 1a, 1b. The speed of operation will slow down.

Therefore, when the half nut 1 is opened, the opening speeds of both semicircular split nuts 1a and 1b are gradually increased. On the contrary, when the half nuts 1 are opened, the closing speeds of both semicircular split nuts 1a and 1b are As it gradually slows down, the free ends of the semicircular split nuts on both sides do not collide with each other, so that the closing operation is performed smoothly.

According to the present invention as described above, the friction action generated during the opening and closing operation by opening and closing the half nut rotationally, the contact portion of the connecting pins on both sides connected to the fixing pins on both sides and the two operating links rotatably supporting the semicircular split nuts on both sides. Since it appears only in the conventional technology, the friction area can be much reduced compared to the linear opening and closing operation as in the prior art, and the friction noise can be reduced, and the collision noise is also almost reduced since the two half-circular split nuts do not collide with each other during the half nut opening and closing operation. It is effective in preventing the occurrence of damage, and since the semi-circular split nuts on both sides do not collide with each other, it is possible to prevent the damage of parts due to the collision, which not only prolongs the service life of the half nut, To increase the accuracy and control the half nut cylinder Even if the number of installation of the proximity sensor is reduced to two, it is possible to accurately control the opening and closing operation of the half nut, thereby providing an advantage of improving the reliability of the direct injection molding machine.

Claims (2)

It is an operation to hold the uneven parts formed in a certain section on each of the plurality of tie bars that penetrate the four corners of the movable plate of the injection molding machine to generate a clamping force on the movable mold during the injection molding of the product. In order to repeat the operation of releasing the tie bar, one half nut is provided on each of the four corners of the rear side of the movable plate. It is formed by two semicircular split nuts with a semicircular cross section. One end of each of the two semi-circular split nut is rotatably installed by two fixing pins fixed to the rear surface of each of the four corner portions of the movable plate, One end of each of the left and right actuating links is rotatably connected to each other end of the two semicircular split nuts, and the other end of each of the left and right actuating links is connected to the piston rod end of the half nut cylinder fixed to the rear surface of the movable plate. Rotatably connected structure, As the piston rod of the half nut cylinder is sunk and operated, both semicircular split nuts are rotated in opposite directions with respect to the tie bar, and are relaxed in the tie bar to allow movement of the movable plate or rotate to tie the tie bar. In the half nut of the direct pressure injection molding machine, which is engaged with the uneven portion of the bar and is configured to generate a clamping force that maintains the movable mold of the movable plate in the mold closing operation of the fixed plate. The half nut includes a plurality of fixing rods fixed on both sides of the semi-circular split nuts on both sides, and a support plate and the support plate which are fixedly attached to the distal ends of these fixing rods as bolts to cover both semi-circular split nuts for rotational operation. One side of the center hole formed to have a larger diameter than the tie bar in the center and one side of the fixed plate further comprises a plurality of proximity sensors which are respectively installed one by one to control the piston rod outgoing operation of the half-nut cylinder Half nut of the injection molding machine. delete

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