KR20110062957A - Foam article molding apparatus with inner partition space - Google Patents

Abstract

PURPOSE: A foaming product molding device having inside compartment space is provided to reduce the consumption of steam and cooling water by compactly forming a heating and cooling space by a partitioning rib. CONSTITUTION: A foaming product molding device having inside compartment space comprises fixed and movable mold side bases(10,20). Each internal space of the fixed and movable mold side bases is divided into heating and cooling spaces by partition walls. The steam and cooling water pass through one or more heating and cooling spaces. The heating and cooling space surround the back side of a fixed mold(30). The mobile side mold base forms an internal space using a mobile side support plate(21), a mobile side back plate(23), and a mobile side frame(24). The heating and cooling spaces of the mobile side mold base surround the back side of a movable mold(40).

Description

FOAM ARTICLE MOLDING APPARATUS WITH INNER PARTITION SPACE}

The present invention relates to a mold apparatus for molding a foamed molding, and more particularly, to a rigid mold and a movable mold, and to a foam molding having an internal partition space that can significantly reduce the consumption of steam and cooling water. It relates to a mold apparatus.

Foamed resin moldings such as expanded polypropylene (hereinafter referred to as 'EPP') or expanded polystyrene (hereinafter referred to as 'EPS') have a wide range of applications, such as packaging containers and automobile bumpers.

The mold apparatus for molding such a foamed resin molding includes a stationary mold 3 and a movable mold 4, as shown in FIG. 1, and the stationary mold 3 is installed on the stationary mold base 1 side. The moving mold 4 is provided on the moving side mold base 2 side, and the moving side mold base 2 moves with respect to the fixed side mold base 1.

The stationary side mold base 1 includes a cavity plate 1a disposed around the stationary mold 3, a stationary side back plate 1c, a cavity plate 1a, and a stationary side arranged at the rear of the cavity plate 1a. It has the fixed side frame 1b to which the edge of the backplate 1c is fixed. A heating and cooling space 1d through which steam or cooling water passes is formed between the fixed side back plate 1c and the cavity plate 1a, and the inlet 1e for separately injecting steam and cooling water into the fixed side frame 1b. ) Is installed. The feeder 1f and the ejector pin 1g are installed through the fixed side back plate 1c and the fixed mold 1, the feeder 1f injects the raw material of the foamed resin, and the ejector pin 1g is The molded foamed resin molding is taken out.

The moving side mold base 2 includes a core plate 2a disposed around the moving mold 4, a moving side back plate 2c, a core plate 2a, and a moving side disposed on the rear surface of the core plate 2a. It has a moving side frame 2b to which the edge of the backplate 2c is fixed, respectively. A heating and cooling space 2d through which steam or cooling water passes is formed between the moving side back plate 2c and the core plate 2a, and an injection hole 2e for separately injecting steam and cooling water into the moving side frame 2b. ) Is installed.

When the movable mold base 2 moves to the fixed mold base 1 side and the fixed mold 3 and the movable mold 4 are in close contact with each other, the molding space is between the fixed mold 3 and the movable mold 4. (5) is formed.

However, in the conventional mold apparatus, as the heating and cooling spaces 1d and 2d of the fixed side and the moving side mold bases 1 and 2 extend to the peripheral regions of the fixed mold 3 and the moving mold 4, respectively. The total volume is large. As a result, the fixed mold 3 and the movable mold 4 could not be firmly supported and sag occurred. In addition, the consumption of steam or cooling water injected into the heating and cooling spaces 1d and 2d was greatly increased, and thus the manufacturing cost was increased. There was an increasing disadvantage.

The present invention has been made in view of the above, it is possible to more firmly support a fixed mold and a moving mold, and also to reduce the consumption of steam and cooling water required for heating and cooling, thereby producing a foamed molding It is an object of the present invention to provide a foam molding apparatus having an internal partition space which can greatly reduce costs.

Mold apparatus of the present invention for achieving the above object,

At least one stationary mold, a stationary side support plate installed around the stationary mold, a stationary side back plate disposed at the rear of the stationary side support plate, a stationary side frame installed at the edges of the stationary side support plate and the stationary side back plate Fixed side mold base having a; And

At least one movable mold, a movable side support plate installed around the movable mold, a movable side back plate disposed at a rear side of the movable side support plate, a movable side frame installed at edges of the movable side support plate and the movable side back plate. A moving mold base having a;

The fixed side mold base forms an inner space by the fixed side support plate, the fixed side back plate, and the fixed side frame, and the internal space partitions one or more heating and cooling spaces through which the steam and cooling water pass by the partition wall. The heating and cooling space surrounds the rear side of the stationary mold,

The movable mold base forms an inner space by the movable side support plate, the movable back plate and the movable frame, and the inner space partitions one or more heating and cooling spaces through which the steam and cooling water pass by the partition wall. The heating and cooling spaces are characterized by surrounding the rear surface of the moving mold.

The partition wall of the fixed side mold base is integrally connected to the fixed side frame via a connecting wall, and the partition wall of the movable side mold base is integrally connected to the moving side frame via a connecting wall. do.

The partition wall is formed in a lattice structure to partition the heating and cooling space into a plurality.

Each of the stationary and moving mold bases has a steam injection pipe, a cooling water injection pipe, and a discharge pipe communicating with a heating and cooling space, and a cooling water injection pipe communicating with the cooling water injection pipe is installed in the heating and cooling space. It features.

A guide groove and a guide protrusion are formed at portions adjacent to each other of the fixed side support plate and the moving side support plate.

The guide groove is composed of first and second guide grooves, the guide protrusion is composed of first and second guide protrusions, the first guide protrusion and the first guide groove is formed longer than the width, The second guide protrusion and the second guide groove are characterized in that the width is formed longer than the length.

According to the present invention as described above, the fixed mold and the movable mold can be more firmly supported by partitioning each inside of the fixed side and the moving side mold base through the partition ribs, and the heating and cooling spaces are compact by the partition ribs. As it is configured to reduce the consumption of steam and cooling water required for heating and cooling, there is an advantage that can significantly reduce the manufacturing cost of the foamed molding.

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

2 to 5 is a view showing a mold apparatus according to a first embodiment of the present invention.

As shown, the mold apparatus of the present invention includes a fixed mold 30 and a moving mold 40, the fixed mold 30 is installed on the fixed side mold base 10 side, the moving mold 40 is It is provided in the moving side mold base 20 side, and the moving side mold base 20 moves with respect to the fixed side mold base 10.

The stationary side mold base 10 includes a stationary side support plate 11 installed around the stationary mold 30, a stationary side back plate 13 disposed behind the stationary side support plate 11, and a stationary side support plate ( 11) and a fixed side frame 14 provided at the edge of the fixed side back plate 13. The fixed side mold base 10 has an inner space formed therein by the fixed side back plate 13, the fixed side support plate 11, and the fixed side frame 14, and the inside of the fixed side mold base 10. The partition wall 51 is formed in space.

The partition wall 51 divides the space into a heating and cooling space 15a and peripheral spaces 15b, 15c, 15d, and 15e disposed around the heating and cooling space 15a. Steam and cooling water pass through the heating and cooling space 15a, and the heating and cooling space 15a is formed to correspond to the rear surface of the fixed mold 30, thereby further heating and cooling the foamable resin in the fixed mold 30. It can be done quickly and easily.

In particular, the partition wall 51 is disposed between the rear side of the fixed side support plate 11 and the fixed side back plate 13 in a form surrounding the rear side of the stationary mold 30 so that the heating and cooling space 15a is formed. The fixed mold 30 may be formed to correspond to the rear surface of the fixed mold 30, and the fixed mold 30 and the fixed side support plate 11 may be firmly supported by the partition wall 51 to prevent sag and the like.

Then, the partition wall 51 is integrally connected to the inner side of the fixed side frame 14 through a connecting wall 51a, and one side of the partition wall 51 is fixed mold 30 or fixed side support plate ( 11) is hermetically adhered to 11, and the other side of the partition wall 51 is hermetically adhered to the fixed side back plate 13. In addition, one side and the other side of the partition wall 51a may be provided with a sealing member 71, whereby the heating and cooling space 15a in the partition wall 51 is the peripheral space (15b, 15c, 15d) , 15e) can be securely sealed.

In the peripheral spaces 15b, 15c, 15d, and 15e, a heat insulator 16 or the like may be incorporated to improve the heat insulation of the heating and cooling spaces 15a.

The steam injection pipe 14a, the cooling water injection pipe 14b, the discharge pipe 14c, etc. are installed in the stationary side mold base 10 so as to communicate with the heating and cooling space 15a. The steam injection pipe 14a communicates with the heating and cooling space 15a through the fixed side frame 14 and the partition wall 51. The coolant injection pipe 14b penetrates through the fixed side frame 14 and the partition wall 51, and the coolant injection pipe 14b is connected in communication with the coolant injection pipe 14b, and the coolant injection pipe 14d is connected. Is disposed along the inner side of the partition wall 51. Thus, the cooling water injection pipe 14d is located in the heating and cooling space 15a, and the cooling water injection pipe 14d is provided with a plurality of injection nozzles (not shown), and the cooling water is heated and cooled by the injection nozzle 15a. And into). In addition, the discharge pipe (14c) is formed to communicate with the outside through the partition wall 51 and the other side of the fixed side frame 14, the discharge pipe (14c) and the like to steam and cooling water in the heating and cooling space (15a) Configured to discharge.

A feeder (not shown) and an ejector pin (not shown) pass through the fixed side back plate 13 and the fixed mold 10, and the feeder (not shown) injects raw material of the foamed resin, and the ejector pin ( Not shown) takes out the molded foamed resin molding.

The moving side mold base 20 includes a moving side support plate 21 disposed around the moving mold 40, a moving side back plate 23 disposed on the rear side of the moving side support plate 21, and a moving side support plate. 21 and a moving side frame 24 to which edges of the moving back plate 23 are fixed, respectively. The moving side mold base 20 has an inner space 25 formed therein by a moving side back plate 23, a moving side support plate 21, and a moving side frame 23. In the partition wall 52 is formed.

By the partition wall 52, the inner space 25 of the moving side frame 23 is heated and cooled in the space 25a, and surrounding spaces 25b and 25c disposed around the heating and cooling space 25a, 25d, 25e). Steam and cooling water pass through the heating and cooling space 25a, and the heating and cooling space 25a is formed to correspond to the rear surface of the moving mold 40, thereby further heating and cooling the foamable resin in the moving mold 40. It can be done quickly and easily.

In particular, the partition wall 52 is disposed between the rear side of the movable side support plate 21 and the movable side back plate 23 in a form surrounding the rear side of the movable mold 40 so that the heating and cooling space 25a is formed. The movable mold 40 may be formed to correspond to the rear surface of the movable mold 40, and the movable mold 40 may be firmly supported by the partition wall 52 to prevent sag or the like.

Then, the partition wall 52 is integrally connected to the inner surface of the moving side frame 24 through the connecting wall 52a, and one side surface of the partition wall 52 is the movable mold 40 or the moving side support plate ( 21 is hermetically adhered to 21, and the other side of the partition wall 52 is hermetically adhered to the moving back plate 23. In addition, one side and the other side of the partition wall 52 may be provided with a sealing member 72, whereby the heating and cooling space 25a in the partition wall 52 is the peripheral space (25b, 25c, 25d) , 25e) can be securely sealed.

In addition, the heat insulating material 26 or the like may be incorporated in the peripheral spaces 25b, 25c, 25d, and 25e to improve the heat insulating property of the heating and cooling space 25a.

The steam injection pipe 24a, the coolant injection pipe 24b, the discharge pipe 24c, and the like are installed in the moving side mold base 20 so as to communicate with the heating and cooling space 25a. The steam inlet tube 24a communicates with the heating and cooling space 25a through the moving side frame 24 and the partition wall 52. The coolant injection pipe 24b penetrates the moving side frame 24 and the partition wall 52, and the coolant injection pipe 24b is connected to communicate with the coolant injection pipe 24d, and the coolant injection pipe 24d is connected. Is disposed along the inner side of the partition wall 52. Thus, the cooling water injection pipe 24d is located in the heating and cooling space 25a, and the cooling water injection pipe 24d is provided with a plurality of injection nozzles (not shown), and the cooling water is heated and cooled through the injection nozzle 25a. And into). In addition, the discharge pipe 24c is configured to discharge steam, cooling water, and the like in the heating and cooling space 25a through the second partition wall 52 and the moving side frame 24.

Meanwhile, as illustrated in FIGS. 3, 4, and 5, the first and second guide grooves 61 and 63 are formed in the fixed side support plate 11, and the first and second portions of the fixed side support plate 11 are formed. The first and second guide protrusions 62 and 64 of the movable side support plate 21, which will be described later, are guided to the second guide grooves 61 and 63 to move the support plate 21 and the fixed side support plate 11. Can be precisely matched to each other.

The first and second guide protrusions 62 and 64 are formed on the movable side support plate 21, and the first and second guide protrusions 62 and 64 of the movable side support plate 21 are fixed as described above. By being guided into the first and second guide grooves 61 and 63 of the side support plate 11, the movable side support plate 21 and the fixed side support plate 11 can be precisely aligned with each other.

In particular, as shown in FIG. 5, the length L1 of the first guide protrusion 62 of the present invention is longer than that of the width W1, and correspondingly, the first guide groove 61 is also longer than the width thereof. Is formed long. The second guide protrusion 64 has a width W2 longer than the length L2, and correspondingly, the second guide groove 63 also has a length longer than the width L2.

 That is, since the first guide protrusion 62 and the first guide groove 61 are formed longer than the width, the first guide protrusion 62 and the first guide groove 61 can guide the movement in the longitudinal direction precisely, and the second guide protrusion 64 and the second guide groove ( Since the width 62 is longer than the length, the movement in the width direction can be precisely guided. In this way, the present invention is to accurately guide the mobility of the moving side support plate 21 in the longitudinal direction and the width direction to greatly improve the movement precision of the fixed mold 30 and the moving mold 40 is easy to precisely There is an advantage.

The operation relationship of the mold apparatus of the present invention configured as described above will be described in detail as follows.

When the moving mold base 20 moves toward the fixed mold base 10, the fixed mold 30 of the fixed mold base 10 and the moving mold 40 of the movable mold base 20 are adjacent to each other. The predetermined molding space 50 is formed. Spherical bead resin (primary foamed solid form) is injected into the molding space 50.

Then, steam is injected into the heating and cooling spaces 15a and 25a through the steam injection pipes 14a and 24a of the stationary and moving mold bases 10 and 20, thereby fixing the mold 30 and the movable mold. The bead resin injected into the molding space 50 between 40 is heated, and the shape of a foamed molding is formed by volume expansion. In particular, the heating and cooling spaces 15a and 25a of the present invention are partitioned by the partition walls 51 and 52, which are more compactly formed, which can significantly reduce steam consumption.

Subsequently, cooling water is injected into the heating and cooling spaces 15 and 25 through the cooling water injection pipes 14b and 24b of the fixed and moving mold bases 10 and 20, and the cooling water is supplied to the cooling water injection pipes 14d and 24d. Through the injection into the heating and cooling spaces (15a, 25a) it is possible to more quickly cool (harden) the foamed molding in the molding space (50). In particular, the heating and cooling spaces 15a and 25a of the present invention are partitioned by the partition walls 51 and 52 to be more compact, thereby reducing the consumption of cooling water and significantly reducing the cooling time by the cooling water. Can be.

In particular, the present invention reduces the consumption of steam as the heating and cooling spaces 15a, 25a of the stationary and moving mold bases 10, 20 are formed in a more compact size by the partition walls 51, 52. In addition, by greatly reducing the cooling time by the cooling water, there is an advantage that can reduce the manufacturing cost and shorten the manufacturing process.

In addition, the present invention effectively prevents the deflection of the fixed mold 30 and the movable mold 40 as the partition walls 51 and 52 firmly support the rear surfaces of the fixed mold 30 and the movable mold 40 individually. There is an advantage that can be.

In addition, the present invention is a precise fitting by the guide groove (61, 63) and the guide projections (62, 64) of each of the support plates (11, 21) in which the fixed side and the moving side mold base (10, 20) are adjacent to each other. There is an advantage that it becomes easy.

On the other hand, Figure 6 to Figure 10, when a plurality of fixed mold 30 and the moving mold 40 is disposed, the plurality of heating and cooling spaces (15a, 25a) as a plurality of partition walls 51, 52 are formed in a lattice structure As a diagram illustrating a structure partitioned into various shapes, a plurality of heating and cooling spaces (15a, 25a) may individually surround the back of the plurality of stationary mold 30 and the moving mold (40).

As illustrated in FIG. 6, the auxiliary partition walls 53 and 54 are connected to the partition walls 51 and 52 in the stationary and moving mold bases 10 and 20, and the auxiliary partition walls 53 and 54 are connected to each other. The partition walls 51 and 52 have a lattice structure, and the auxiliary partition walls 53 and 54 may divide the heating and cooling spaces 15a into a plurality. Thus, each of the support plates 11 and 21 of the fixed side and the moving side mold bases 10 and 20 may be provided with a plurality of fixed molds 30 and moving molds 40.

As illustrated in FIG. 7, the auxiliary partition walls 53 and 54 are connected to the inside and the outside of the partition walls 51 and 52 to further vary the respective inner spaces of the fixed side and the moving side mold bases 10 and 20. It can be partitioned so that, a plurality of the fixed mold 30 and the movable mold 40 can be laid out in more various ways.

In addition, as illustrated in FIGS. 8 to 10, the partition walls 51 and 52 of the present invention have a plurality of horizontally and vertically extending the plurality of fixed molds 10 and the movable molds 20. can do.

1 is a cross-sectional view illustrating a conventional mold apparatus.

2 is a cross-sectional view showing a foam molding apparatus according to an embodiment of the present invention.

Figure 3 is an exploded perspective view showing a fixed side mold base of the foam molding apparatus according to the present invention.

Figure 3a is a plan view showing a fixed side frame of the foam molding apparatus according to the present invention.

Figure 4 is an exploded perspective view showing a moving mold base of the foam molding apparatus according to the present invention.

Figure 4a is a plan view showing a moving side frame of the foam molding apparatus according to the present invention.

FIG. 5 is a cross sectional view of the fixed side mold base and the moving side mold base shown along the line A-A of FIG. 3 and the line B-B of FIG.

6 to 10 are plan views showing the fixed side and the moving side frame according to another embodiment of the present invention.

Brief description of symbols for the main parts of the drawings

10: fixed side mold base 15a: heating and cooling space

20: moving mold base 25a: heating and cooling space

30: fixed mold 40: moving mold

51, 52: partition walls 61, 63: first and second guide grooves

62, 64: first and second guide protrusions

Claims (6)

At least one stationary mold, a stationary side support plate installed around the stationary mold, a stationary side back plate disposed at the rear of the stationary side support plate, a stationary side frame installed at the edges of the stationary side support plate and the stationary side back plate Fixed side mold base having a; And At least one movable mold, a movable side support plate installed around the movable mold, a movable side back plate disposed at a rear side of the movable side support plate, a movable side frame installed at edges of the movable side support plate and the movable side back plate. A moving mold base having a; The fixed side mold base forms an inner space by the fixed side support plate, the fixed side back plate, and the fixed side frame, and the internal space partitions one or more heating and cooling spaces through which the steam and cooling water pass by the partition wall. The heating and cooling space surrounds the back of the stationary mold, The movable mold base forms an inner space by the movable side support plate, the movable back plate and the movable frame, and the inner space partitions one or more heating and cooling spaces through which the steam and cooling water pass by the partition wall. And wherein said heating and cooling spaces surround said backside of said moving mold. The method of claim 1, The partition wall of the fixed side mold base is integrally connected to the fixed side frame via a connecting wall, and the partition wall of the movable side mold base is integrally connected to the moving side frame via a connecting wall. Foam molded product mold apparatus having an inner compartment space. The method of claim 1, The partition wall is formed in a lattice structure foam molding apparatus having an internal partition space, characterized in that partitioning the plurality of heating and cooling spaces. The method of claim 1, Each of the stationary and moving mold bases has a steam injection pipe, a cooling water injection pipe, and a discharge pipe communicating with a heating and cooling space, and a cooling water injection pipe communicating with the cooling water injection pipe is installed in the heating and cooling space. Foam molded article mold apparatus having an inner compartment space. The method of claim 1, Foam molding apparatus having an internal partition space, characterized in that the guide groove and the guide projection is formed in the adjacent portions of the fixed side support plate and the moving side support plate. The method of claim 5, The guide groove is composed of first and second guide grooves, the guide protrusion is composed of first and second guide protrusions, the first guide protrusion and the first guide groove is formed longer than the width, The second molded protrusion and the second guide groove is a foam molding apparatus having an inner partition space characterized in that the width is formed longer than the length.

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