KR101453535B1 - Apparatus for actuating slide core in injection molding - Google Patents

Abstract

A device for actuating a slide core of a PU mold according to the present invention is characterized by including: a lower core plate, which includes a resin filling recess in the upper part thereof and guide pins protruding from the lower part thereof and has a support function such that the resin filling recess is filled with polyurethane to shape a product; a sliding cylinder disposed at one of four corners of a lower surface of the lower core plate and installed at a side of a center axis of the lower core plate to provide power; a sliding block connected to an end of the sliding cylinder to move in a direction according to an operation of the sliding cylinder; a sliding rail disposed on the lower surface of the lower core plate and having a pair of support bars parallel to the sliding cylinder, wherein the guide pins are inserted in guide holes formed, respectively, on the support bars, so that the sliding rail can move along the guide holes in a direction opposite to that of the sliding block; a first link part, which has an end connected to the sliding block and the other end connected to a side of the sliding rail to transmit power from the sliding block to the sliding rail; stationary blocks vertically disposed on both sides of the sliding block and supporting a side surface of the sliding block; a second link part, which has an end rotatably connected to the stationary block and the other end rotatably connected to a side of the sliding rail to transmit power from the sliding rail; and the slide core, which is connected to an end of the second link part and is thus spaced apart from the lower core plate by the sliding block, and is continuously rotated by the second link part, and simultaneously, forms an inclination angle.

Description

[0001] Apparatus for actuating slide core in injection molding [0002]

The present invention relates to a PU mold slide core operating device, and more particularly, to a PU mold slide core operating device capable of enhancing productivity and durability by enhancing operating characteristics in which a slide core is continuously and constantly rotated while being slidably moved .

Generally, the injection foaming method is a method in which a mixture of a resin material such as EVA (Ethyl Vinyl Acetate) and a foaming agent is filled in a cavity of a predetermined shape formed in a mold, and then aged at a temperature of 170 to 190 degrees for 6 to 8 minutes When the mold is opened, a product expanded by about 30% or more from the cavity due to the expansion of the gas, that is, an injection foam is obtained.

Accordingly, the upper mold and the lower mold, which are capable of approaching and separating from each other and capable of forming a foam cavity corresponding to the shape of the foamed product, are provided, and at least one of the upper mold and the lower mold is provided with a heater Thereby producing an injection foaming product.

In the general injection molding technique, in the case of forming the undercut forming part, the slide core slidable in the upper mold or the lower mold is moved in the mold corresponding to the undercut forming part required for the foamed product by the slide core operating device, Is injected into a cavity of a mold and aged at a low temperature, and then the mold is opened to obtain a foamed product having a predetermined undercut forming portion.

A sliding cylinder rod provided on a lower plate of the PU foam mold to move the slide core in the front, rear, left and right directions, and a turn cylinder provided on one side of the sliding cylinder to rotate the sliding core are separately fastened, When the sliding cylinder is operated, the turn cylinder is sequentially operated to rotate the slide core to take out the molded article.

Such a conventional structure as described above has a risk that the turn cylinder is exposed to the outside and is liable to be damaged when impacted, and it is difficult to maintain the durability of the durability, and as the use time elapses, wear of the slide core and the mold, Therefore,

There is a problem that the endurance life of the apparatus is shortened and the quality of the mold apparatus is deteriorated, thereby deteriorating the quality of the foamed product.

In addition, since the turn cylinder is not located at the slide core center but mounted on one side, the force is not transmitted uniformly during the rotation operation of the slide core, resulting in poor durability.

 In addition, there is a problem that productivity is deteriorated due to malfunction due to back flow of oil in the turn cylinder.

Korean Patent No. 10-1247182

The present invention is characterized in that a link member rotatably connected to a sliding cylinder provided on a lower plate of a PU foaming mold is used without using a turn cylinder which is exposed to the outside so that the link member rotates the slide core according to a sliding operation, The present invention provides a PU mold slide core operation device capable of enhancing the operation characteristics of a slide core without the turn cylinder.

 In addition, since the link member supporting the slide core rotatably supports both side ends of the slide core, power is uniformly transmitted to the slide core, thereby increasing the productivity and durability of the slide core. Lt; / RTI >

The apparatus for operating a PU die slide core according to an embodiment of the present invention includes a resin filling groove on an upper portion thereof and a plate-like shape having a guide pin protruded from a lower portion thereof. The resin filling groove is filled with polyurethane, A sliding cylinder provided in one of the four corners of the lower surface of the lower plate and provided in one direction with respect to the center axis of the lower plate for providing power, A sliding block moving in one direction in accordance with the operation of the sliding cylinder; a pair of supporting bars provided on a lower surface of the lower plate and installed parallel to the sliding cylinder; A guide pin is inserted, and a slider moving in a direction opposite to the sliding block along the guide hole A first link part connected to the sliding block at one end and connected to one side of the sliding rail to transmit power by the sliding block to the sliding rail, A fixed block for supporting a side surface of the sliding block, a first end rotatably connected to the fixed block, and a second end rotatably connected to one side of the sliding rail, And a slide core connected to one end of the second link portion and spaced apart from the lower plate by the sliding block and continuously rotating while forming an inclination angle by the second link portion. .

In the apparatus for operating a PU mold slide core according to an embodiment of the present invention, the first link portions are provided in pairs on the lower surface of the sliding block, respectively, and are installed in the moving direction of the sliding cylinder, A hinge bracket that moves in one direction and a hinge bracket that is rotatably connected to the hinge bracket at one end and is rotatably connected to the sliding rail at the other end so as to transmit power to the sliding rail in response to the operation of the hinge bracket, And a control unit.

 In the apparatus for operating a PU die slide core according to an embodiment of the present invention, the second link portions are provided on both sides of the fixed block, and are installed to be rotatable with respect to the fixed block, A turn block which rotates while forming an inclination angle from the lower plate; And a rotating link rotatably connected to one side of the sliding rail at one end and rotatably connected to one side of the turn block at the other end to transmit the power by the sliding rail to the turn block .

The PU mold slide core operating device according to an embodiment of the present invention is provided on both sides of the sliding cylinder and is installed through the sliding block adjacent to the lower plate, And a guide bush for guiding the guide member to be moved.

In the apparatus for operating a PU die slide core according to an embodiment of the present invention, the turn block includes a fixing pin for fixing the rotation angle of the slide core to be constant.

The present invention is characterized in that a link member rotatably connected to a sliding cylinder provided on a lower plate of a PU foaming mold is used without using a turn cylinder which is exposed to the outside so that the link member rotates the slide core according to a sliding operation, The operation characteristics of the slide core can be enhanced and there is no fear of breakage due to external impact due to no external exposure of the turn cylinder and the cost can be reduced by reducing the number of expensive imported cylinders.

 In addition, since the link member supporting the slide core rotatably supports both side ends of the slide core, the power is uniformly transmitted to the slide core, thereby increasing the productivity and durability and reducing the maintenance cost have.

FIG. 1 is a side view showing the overall structure of a conventional slide core operating device
2 is a perspective view showing the overall structure of a PU mold slide core operating apparatus according to an embodiment of the present invention.
3 is a side view showing the overall structure of a PU mold slide core operating apparatus according to an embodiment of the present invention
4 is a bottom view showing the overall structure of a PU mold slide core operating apparatus according to an embodiment of the present invention.
FIG. 5 is a partial front view of an apparatus for operating a PU mold slide core according to an embodiment of the present invention,
6 is a partial cross-sectional view of an apparatus for operating a PU mold slide core according to an embodiment of the present invention,

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to or limited by the embodiments. Like reference symbols in the drawings denote like elements.

FIG. 1 is a side view showing a general structure of a conventional slide core operating apparatus, FIG. 2 is a perspective view showing the overall structure of a PU mold slide core operating apparatus according to an embodiment of the present invention, and FIG. FIG. 4 is a bottom view showing the overall configuration of a PU mold slide core operating apparatus according to an embodiment of the present invention, and FIG. 5 is a cross-sectional view of a PU mold slide core operating apparatus according to an embodiment of the present invention. FIG. 6 is a partial cross-sectional view of an apparatus for operating a PU mold slide core according to an embodiment of the present invention. Referring to FIG.

2 to 3, the apparatus 100 for operating a PU mold slide core according to an embodiment of the present invention includes a lower plate 10 of a PU foaming mold for supporting a product to be molded, A sliding block 30 which moves according to the operation of the sliding cylinder 20 and a sliding block 30 which is provided on the lower plate 10 and moves in a direction opposite to the sliding block 30 A first link portion 50 for transmitting power generated by the sliding block 30 to the sliding rail 40, a fixing block 60 for supporting a side surface of the sliding block 30, A second link portion 70 connected to the fixed block 60 to transmit power and a slide core 80 rotated while forming an inclination angle by the second link portion 70 .

The lower plate 10 is a lower mold of a PU foaming mold for molding a product, and is provided in a plate shape. A resin filling groove is formed along the upper edge of the lower plate 10. The resin filling groove is filled with polyurethane (PU) to form a product.

Referring to FIG. 4, a plurality of guide pins are protruded from the lower surface of the lower plate 10. A first guide pin 11 protruding from one of the four corners of the lower surface of the lower plate 10 and a second guide pin 12 formed at a predetermined interval in a straight line with the first guide pin 11 A third guide pin 13 formed to be symmetrical with respect to the first guide pin 11 with respect to the center axis of the lower plate 10 and a second guide pin 13 which is spaced apart from the third guide pin 13 in a straight line The fourth guide pin 14 is formed symmetrically with respect to the second guide pin 12 with respect to the center axis of the lower plate 10.

The first and second guide pins 11 and 12 and the third and fourth guide pins 13 and 14 are inserted into a sliding rail 40 to be described below, And supports the sliding rail 40 so as to slide on the lower surface of the sliding door 10.

The sliding cylinder 20 is provided on any one of the four lower corners of the lower plate 10. The sliding cylinder 20 is installed in one direction with respect to the central axis of the lower plate 10. That is, the sliding block 30 is installed so as to face the outer side of the lower plate 10 to separate the sliding block 30 from the lower plate 10 in the outward direction, .

The sliding block (30) is provided on the lower side of the lower plate (10). The sliding block 30 forms a plate-shaped body and one side of the sliding cylinder 20 is connected to one side of the body facing the lower plate 10, The sliding block 30 is separated from the lower plate 10 in the outward direction or returned to the original direction in the inner direction.

The sliding rail 40 is provided on the lower surface of the lower plate 10. The sliding rail (40) is formed with a pair of supporting bars which are installed in parallel with the sliding cylinder (20). The first support bar 41, which is one of the pair of support bars, has first and second guide holes 43 and 44 at positions corresponding to the first and second guide pins 11 and 12 along the longitudinal direction Respectively.

The first and second guide holes 43 and 44 are symmetrical with respect to the fixed hinge shaft 47 formed at the center of the first support bar 41, The first guide pin 11 is inserted into the first guide hole 43 and the second guide pin 12 is inserted into the second guide hole 44. [

As the sliding block 30 is moved in one direction, the sliding rail 40 is interlocked with the sliding block 30 in a direction opposite to the moving direction of the sliding block 30. At this time, the first guide pin 11 is guided along the inner surface of the first guide hole 43, and the second guide pin 12 is guided along the inner surface of the second guide hole 44 , The sliding rail (40) is moved.

The second supporting bar 42, which is another one of the pair of supporting bars, is installed to be symmetrical with respect to the first supporting bar 41 with respect to the sliding cylinder 20.

The second support bar 42 is provided with third and fourth guide holes 45 and 46 at positions corresponding to the third and fourth guide pins 13 and 14 along the longitudinal direction in the same manner as the first support bar 41 Respectively.

The third and fourth guide holes are symmetrical with respect to the third guide hole 45 and the fourth guide hole 46 with respect to the fixed hinge shaft 47 formed at the center of the second support bar 42, The third guide pin 13 is inserted into the third guide hole 45 and the fourth guide pin 14 is inserted into the fourth guide hole 46.

As the sliding block 30 is moved in one direction, the sliding rail 40 is interlocked with the sliding block 30 in a direction opposite to the moving direction of the sliding block 30. At this time, the third guide pin 13 is guided along the inner surface of the third guide hole 45, and the fourth guide pin 14 is guided along the inner surface of the fourth guide hole 46 , The sliding rail (40) is moved.

Guide bushes 90 are provided on the lower surface of the lower plate 10 and are installed on both sides of the sliding cylinder 20, respectively. The guide bush 90 is formed as a cylindrical support shaft and is installed through one surface of the sliding block 30 adjacent to the lower plate 10.

 The guide bushes 90 are spaced from the lower plate 10 in the outward direction while the sliding blocks 30 are moved along the outer circumferential surface of the guide bushing 90 in accordance with the operation state of the sliding cylinder 20 And the sliding block 30 is supported so as to be returned to the inner side in the circumferential direction.

The first link portion 50 is provided at a lower portion of the lower plate 10. One end of the first link portion 50 is connected to the sliding block 30 and the other end is rotatably connected to one side of the sliding rail 40.

The first link portion 50 may include a hinge bracket 51 and a sliding hinge 52.

A pair of the hinge brackets 51 are respectively installed in the moving direction of the sliding cylinder 20 and one end is supported by the sliding block 30 and the tread is rotatably connected to the sliding hinge 52 , And is moved together with the sliding block (30) according to the operating state of the sliding cylinder (20).

The other end of the pair of sliding hinges 52 connected to the hinge bracket 51 is rotatably supported by the first supporting bar 41 of the sliding rail 40 and the fixed hinge shaft 42 of the second supporting bar 42, (47), and is configured to be symmetrical with respect to the sliding cylinder (20). Therefore, the hinge bracket 51 rotates in accordance with the moving direction of the hinge bracket 51.

The tread of the sliding hinge 52 connected to the sliding rail 40 rotates in a direction opposite to the moving direction of the hinge bracket 51 to transmit power to the sliding rail 40.

The fixed block 60 is vertically provided on both sides of the sliding block 30 to support the side surface of the sliding block 30. And is rotatably connected to the turn block 71 to be described below.

The second link portions 70 are provided at both ends of the fixed block 60. One end of the second link portion 70 is rotatably connected to the fixed block 60, and the tarton is connected to one side of the sliding rail 40 so as to be rotatable.

The second link portion 70 may include a pair of turn blocks 71 and a pair of rotation links 72.

The turn block 71 is rotatably connected to a side end portion of the fixed block 60 and one end of the turn block 71 is connected to a slide core 80 to be described later, 72, respectively.

The rotary link 72 includes a first hinge portion 74 one end of which is rotatably supported on one side of the sliding rail 40 and a second hinge portion 74 which is rotatably supported on one side of the turn block 71, And a hinge portion 75.

The first hinge portion 74 is supported and rotated in accordance with the moving direction of the sliding rail 40 and the second hinge portion 75 is engaged with the first hinge portion 74, So that the turn block 71 is rotated about 45 degrees from the lower plate 10.

The slide core 80 is provided at the upper edge of the lower plate 10 and is connected to one end of the turn block 71. The slide core (80) has a protrusion for forming a groove in an edge undercut portion of the product.

  The slide core 80 is moved in the outward direction from the lower plate 10 in accordance with the operation state of the sliding cylinder 20 so that the slide core 80 is moved to the lower plate 10 In the outward direction.

The slide rail 80 is moved from the lower plate 10 to the lower side by rotating the turn block 71 while supporting the turn block 71 while continuously moving the sliding rail 40 in the direction opposite to the sliding block 30. [ 45 °.

The fixing pin 73 is provided on one side of the turn block 71. The fixing pin 73 fixes the rotation axis of the turn block 71 or controls the rotation angle so that the rotation angle of the slide core 80 can be maintained constant.

The operation of the PU mold slide core operating apparatus 100 having the above structure will be described below.

5 to 6, the slide core 80 is first brought into contact with the lower plate 10 to form a groove in the edge undercut of the product, and then the product is molded.

The sliding cylinder 20 fixed to the lower plate 10 is advanced to take out the molded product.

A release agent is applied to the lower plate 10 to easily take out the molded product.

The sliding cylinder 20 is connected to the sliding block 30 so that the sliding block 30 is spaced outward from the lower plate 10 due to the forward movement of the sliding cylinder 20.

Also, the hinge bracket 51 fixed to the sliding block 30 moves together to operate the sliding hinge 52 connected to the hinge bracket 51, which is rotatably connected.

The sliding rail 40 is moved by the rotation of a pair of the sliding hinges 52 connected to the fixed hinge shafts 47 of the first and second support bars 41 and 42 of the sliding rail 40 .

The sliding rail 40 is formed of a pair of first and second support bars 41 and 42 so that the first and second support bars 41, The first and second guide pins 11 and 12 are inserted into the guide holes 45 and 46 formed in the second support bar 42, (13, 14), respectively.

In the lower plate 10, the sliding rail 40 is guided along the inner surface of the guide hole and slides in a direction opposite to the moving direction of the sliding block 30. [

The pair of rotation links 72 connected to the sliding rail 40 are rotated according to the operation of the sliding rail 40.

The rotary link 72 rotates by supporting one end of a turn block 71 rotatably connected to both ends of the sliding block 30.

The slide core 80 connected to the turn block 71 also rotates about 45 degrees from the lower plate 10 due to the rotation of the turn block 71 so that the molded product can be easily taken out The release agent and the residue remaining in the lower plate 10 can be easily removed.

A pair of first links (not shown) configured to be symmetrical with respect to each other so that the power of the sliding cylinder (20) is transmitted to the center of the sliding block (30) and the power is evenly transmitted to both side ends of the sliding block And the pair of second link portions 70 uniformly transmit the rotational power to the slide core 80 to enhance the operational characteristics of the slide core 80. [

On the contrary, when the sliding cylinder 20 retracts, the slide core 80 operates in the reverse order of the above sequence, and the slide core 80 returns to its original state.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Various modifications and variations are possible in light of the above teaching. Accordingly, the embodiments of the present invention should be understood only by the appended claims, and all equivalents or equivalent variations thereof are included in the scope of the present invention.

10. Lower plate 11. First guide pin
12. Second guide pin 13. Third guide pin
14. Fourth guide pin 20. Sliding cylinder
30. Sliding block 40. Sliding rail
41. First support bar 42. Second support bar
43. First guide hole 44. Second guide hole
45. Third guide hole 46. Fourth guide hole
47. Fixed hinge shaft 50. First link portion
51. Hinge bracket 52. Sliding hinge
60. Fixed block 70. Second link portion
Turn block 72. Turn link
73. Fixing pin 74. First hinge part
75. Second hinge part 80. Slide core
90. Guide bush

Claims (5)

A lower plate supporting a resin filling groove on an upper portion and a lower portion formed with a guide pin projecting therefrom and filling the resin filling groove with polyurethane to form a product;
A sliding cylinder provided in any one of the four corners of the lower surface of the lower plate and installed in one direction with respect to the center axis of the lower plate to provide power;
A sliding block connected to one end of the sliding cylinder and moving in one direction according to an operation of the sliding cylinder;
A pair of support bars provided on a lower surface of the lower plate and parallel to the sliding cylinder are formed and the guide pins are inserted into guide holes formed in the support bars, A sliding rail that moves in the direction of the arrow;
A first link part connected to the sliding block at one end and connected to one side of the sliding rail to transmit power by the sliding block to the sliding rail;
A fixing block vertically provided on both sides of the sliding block and supporting a side surface of the sliding block;
A second link portion rotatably connected to the fixed block at one end and rotatably connected to one side of the sliding rail, the second link portion transmitting power by the sliding rail;
And a slide core connected to one end of the second link portion and spaced apart from the lower plate by the sliding block and continuously rotating while forming an inclination angle by the second link portion,
Wherein the first link portion includes:
A pair of hinge brackets provided on the lower surface of the sliding block, the hinge bracket being installed in the moving direction of the sliding cylinder and moving in one direction corresponding to the sliding block; And
And a sliding hinge rotatably connected to the hinge bracket at one end and rotatably connected to the sliding rail at the other end to transmit power to the sliding rail in response to the operation of the hinge bracket Features a PU die slide core operating device. delete The method according to claim 1,
Wherein the second link portion includes:
A turn block rotatably installed on both sides of the fixed block and rotatable relative to the fixed block and interlocking with the sliding rail to form an inclined angle from the lower plate; And
And a rotary link rotatably connected to one side of the sliding rail at one end and rotatably connected to one side of the turn block at the other end to transmit the power by the sliding rail to the turn block Features a PU die slide core operating device. The method according to claim 1,
And guide bushes provided on both sides of the sliding cylinder and penetrating the sliding block adjacent to the lower plate to guide the sliding block to move according to the operation of the sliding cylinder. PU mold slide core operating device. The method of claim 3,
The turn-
And a fixing pin for fixing the rotation angle of the slide core so that the rotation angle of the slide core can be maintained constant.

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