KR100918904B1 - Supporting column for pulp mold manufacturing equipment - Google Patents

Abstract

The present invention relates to a support column of a pulp molded article manufacturing apparatus installed between the mold side and the support plate side so that a plurality of molds are supported on the support plate, which is installed in the pulp molded article manufacturing apparatus, and includes a fixed block made of metal and the fixed block. It is characterized in that it comprises a heat insulating block coupled between the and made of a heat insulating material, the heat generated from the mold side can be prevented from being transferred to the support plate side through the support column to protect the support plate and its components from the heat and This has the effect of significantly reducing the product failure rate.

Pulp molding, mold, support column, support plate, fixed block, insulating block

Description

Supporting column for pulp molding manufacturing apparatus

The present invention relates to a support column of a pulp molding apparatus, and more particularly, to support a plurality of molds on a support plate, but to prevent the heat generated from the mold side from being transferred to the support plate side to heat the support plate and its rear components at high temperature. It relates to a support column of the pulp molding production apparatus that can be protected from.

In general, pulp moldings are formed by processing pulp raw materials, and have been applied in various fields such as food packaging containers such as eggs and fruits, and shock absorbing packaging tools for electronic products. These pulp moldings are naturally friendly, so foods can be stored freshly, and there is an advantage that corrosion occurs quickly when used as landfills.

[0003] A pulp molding apparatus for producing pulp moldings usually includes a reservoir for storing pulp raw materials and a mold for shaping pulp raw materials in the form of a container or the like. The mold is disposed so that the upper mold and the lower mold face each other, and after the pulp material in the reservoir is placed on the lower mold, the upper mold and the lower mold are lifted together by a lifting means such as a cylinder to transfer the pulp material to a container. Mold into shape. At this time, a plurality of vacuum suction holes are formed in each mold, and the pulp raw material and the pulp molded product are vacuum sucked or blown to the opposite mold side on the mold. In addition, each mold has a separate heater plate in the rear, and heat-dry the pulp raw material and the pulp molding by the heat transferred from the heater plate.

1 is a cross-sectional view showing an example of a conventional pulp molding apparatus, which illustrates the mold of any one of the upper mold or the lower mold of the manufacturing apparatus for forming the egg seat by processing the pulp raw material. Referring to FIG. 1, in the conventional pulp molding apparatus, a plurality of molds 10 for molding a unit pulp container are continuously installed on a heater plate 12, and heating means such as a heating wire is installed in the heater plate 12. 14 is installed. The heater plate 12 is installed to be supported on the support plate 18 by the support column 16, and a cylinder, a vacuum line, and the like, which are not shown, are installed behind the support plate 18. In addition, a heat insulator 20 is provided between the heater plate 12 and the support plate 18 to reduce the transfer of high temperature heat generated from the heater plate 12 to the support plate 18 side.

However, in the above structure, the heat insulating material is filled between the heater plate 12 and the support plate 18 to insulate the heater plate 12 and the support plate 18, but the heater plate 12 is placed on the support plate 18. The support column 16 for supporting consists of metal materials. Therefore, the support column 16 acts as a heat conductor, so that the heat generated from the heater plate 12 is transferred to the support plate 18 by the support column 16, and the heat deformation and the support plate 18 of the support plate 18. It causes failure due to deterioration of components installed at the rear.

Thermal deformation of the support plate 18 usually occurs along the longitudinal direction of the support plate 18, and in general, in the structure in which a plurality of molds 10 are continuously arranged on the support plate 18, the positions of the molds 10 are moved in the horizontal direction. It causes a phenomenon that changes slightly. That is, in the conventional pulp molding production apparatus, the longer the operation time, the problem that the stationary summation between the upper mold and the lower mold according to the change of the position of the mold 10 is not generated, which causes the product failure rate increases .

Furthermore, in the conventional pulp molding apparatus, due to the problems caused by the insulation between the mold 10 and the support plate 18 as described above, the support structure of the mold 10 is designed in consideration of the thermal deformation of the support plate 18. Due to this, there is no choice but to place a limited number of molds (approximately two) on the heater plate 12, which acts as an obstacle to mass production.

The present invention has been proposed to solve the above problems, the support column for installing the mold to be supported on the support plate by the structure of the fixed block made of a metal material and the insulating block made of a heat insulating material combined, the mold side and the support plate It is an object of the present invention to provide a support column of a pulp molding apparatus for improving the side insulation effect and protecting the support plate and its components from heat.

The support column of the pulp molded article manufacturing apparatus of the present invention for achieving the above object is installed in the pulp molded article manufacturing apparatus for molding the pulp material in the form of a mold, the mold side and the support plate side so that a plurality of molds are supported on the support plate In the support column of the pulp molding manufacturing apparatus installed therebetween, characterized in that it comprises a fixed block made of a metal material and the insulating block is coupled between the fixed blocks and made of a heat insulating material.

According to a preferred embodiment of the present invention, the fixed block has one end fixed to the mold or the support plate and the other end is coupled to the first fixed block, the one end is coupled to the insulating block and the other end is adjacent to It consists of a second fixed block coupled to the other fixed block.

In the embodiment, the fixed block and the insulating block is formed in the through hole in the center along the longitudinal direction, the fixed block has a locking jaw inside the contact portion with the insulating block, the connecting rod is inserted to pass through the through hole And, both ends of the connecting rod is provided with a head portion made of a heat insulating material to be caught on the locking step, it is preferable to be coupled to the insulating block and the fixed block by the connecting rod.

According to the support column of the pulp molding apparatus of the present invention, as the support column for supporting a plurality of molds on the support plate has a configuration in which the fixed block and the insulating block of the metal is combined, the heat generated on the mold side along the support column By preventing transmission to the support plate side, it prevents thermal deformation of the support plate, so that it is possible to maintain the static union between the upper mold and the lower mold even during long time operation, and to significantly reduce the defective rate of the product, and that the components behind the support plate deteriorate and fail. It is effective to prevent it.

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

The present invention relates to a support column for installing a plurality of molds to be supported on a support plate in a pulp molding apparatus, and includes a reservoir for storing pulp raw material, which is a general configuration of pulp molding, and an upper mold, a lower mold, and a cylinder. Detailed descriptions of the lifting means, the vacuum means and the like will be omitted. In addition, in the following description, "mold" refers to a mold of at least one side of the upper mold and the lower mold, and the support column is directly installed on the mold and the support plate, or the mold side and the support plate side through separate connection means. It can be installed to connect.

Figure 2 is a cross-sectional view showing a mold coupling structure of the pulp molding apparatus equipped with the present invention, Figure 3 is a cross-sectional view showing a coupling state of the support column according to the present invention, Figure 4 is a pulp molding manufacturing apparatus equipped with the present invention This is a cross-sectional view showing an example.

First, an example in which the support column of the present invention is installed will be described with reference to FIG. 2. Figure 2 shows the mold 50 and its supporting structure in the pulp molding apparatus for forming the egg seat plate. 2 is presented to help the understanding of the present invention, the molds are installed on the heater plate as in the prior art, the support column 60 may be installed between the heater plate and the support plate. Referring to the embodiment of Figure 2, the heating means 52 is embedded in the mold 50 corresponding to the shape of the egg seat plate. Heating means 52 is a heating wire or other various heating means. When the heating wire is selected as the heating means 52, although not shown, an electronic circuit for heating the heating wire will be connected to the heating means 52. In this way, the heating means 52 is embedded in the mold 50 so that the respective molds 50 can be directly heated individually without passing through a separate heat transfer member of the heating means 52.

As shown in FIG. 2, a plurality of molds 50 are disposed on the support plate 54. Each mold 50 is supported and installed on the support plate 54 via the support column 60, and the heat insulating material 56 is filled in the space between the mold 50 and the support plate 54. The heat insulator 56 prevents heat generated in the mold 50 from being transferred to the support plate 54, thereby preventing thermal deformation of the support plate 54. At this time, preferably, as shown in Figure 3, the support column 60 is also fixed block 62 made of a metal material to block the heat generated in the mold 50 is transferred to the support plate 54 And a heat insulating block 64 made of a heat insulating material. As the heat insulating material 56 filled between the mold 50 and the support plate 54, a soft heat insulating material is selected, and a hard heat insulating material is selected as the heat insulating material of the heat insulating block 64 constituting the support column 60. It is preferable.

Figure 3 is a cross-sectional view showing a coupling state of the support column in the present invention, a partially enlarged view of the mold support structure shown in FIG. Referring to this, the support column 60 is composed of a plurality of fixed blocks 62 and the insulating block 64 is coupled between the fixed blocks 62. As described above, in the structure in which the fixing block 62 and the insulating block 64 are coupled, the fixing block 62 made of metal is fastened to the fastening portion of the mold 50 or the support plate 54 to have a more firm fastening force, and the fixing is performed. The insulating block 64 may be coupled between the blocks 62 to block heat generated from the mold 50 from being transferred to the support plate 54 through the support column 60.

More specifically, the fixed block 62 is fixed to the mold 50 or the support plate 54, the other end of the first fixing block 62a is coupled to the insulating block 64, and one end of the insulating block It is coupled to 64 and the other end is composed of a second fixed block 62b coupled to the other fixed block (62). Of course, the configuration of the support column 60 shown in Figure 3 is only one embodiment of the present invention, the number of stages of the fixed block 62 and the insulating block 64 can be added or subtracted.

The first fixing block 62a has a bolt fastening portion at one end thereof, or is fixed to the mold 50 or the support plate 54 by a separate connector 76 as shown in the figure. The connector 76 is screwed to the first fixing block 62a, the other side is provided with a screw groove or bolt shaft. In the illustrated example, the upper connector 76 has a screw groove, is fastened to the bolt 78 through the mold 50 is fixed to the mold 50 side. The lower connector 76 has a bolt shaft, which is bolted to a screw groove formed on the support plate 54 and fixed to the support plate 54. The insulating block 64 is coupled between the first fixing block 62a and the second fixing block 62b, and the other end of the second fixing block 62b is screwed with another neighboring second fixing block 62b. .

Preferably, the fixing block 62 and the insulating block 64 are formed with through-holes 66 at the center along the longitudinal direction, respectively, and each of the fixing blocks 62 is in contact with the insulating block 64. The locking jaw 68 is formed. As shown in FIG. 3, the connecting rod 70 is inserted into the through hole 66 of the fixing block 62 and the insulating block 64. Both ends of the connecting rod 70 is provided with a head portion 72 made of a heat insulating material to be caught by the locking step 68 formed in the fixing block 62. Head portion 72 is fixed to the insulating block 64 is fixed between the fixing block 62, blocking the contact between the connecting rod 70 and the fixing block 62 to prevent heat transfer through the connecting rod 70. do.

On the other hand, Figure 4 illustrates a pulp molding production apparatus to which the support column 60 of the present invention described above. Referring to this, the illustrated pulp molding apparatus has a plurality of upper mold 50a and the lower mold 50b spaced apart from each other. As described above, the heating means 52 is embedded in each mold 50. At the rear of each mold 50, a support plate 54 supporting the molds 50 is installed so that a plurality of molds 50 are continuously arranged. Each mold 50 is supported on the support plate 54 by the support column 60 of the present invention described above.

Although the illustrated example illustrates that three molds 50 are supported on the support plate 54, a larger number of molds 50 may be installed on the support plate 54. In this way, a large number of molds 50 can be installed on the support plate 54, which means that the heat generated from each mold 50 side in the present invention is transferred to the support plate 54 by the support column 60. This is because by blocking, the position of the mold 50 is not changed even after a long time operation by minimizing thermal deformation of the support plate 54 so that the stationary coupling between the upper mold 50a and the lower mold 50b is possible. Installing a larger number of molds 50 on the support plate 54 enables mass production of pulp moldings.

As shown in FIG. 4, the pulp molding apparatus may include a reservoir 80 for storing pulp raw materials. In this case, one side of the reservoir 80 is provided with an inlet port 82 through which the pulp material is introduced, and the inlet port 82 is connected to the pulp material supply line.

The upper mold 50a and the lower mold 50b are arranged to have a plurality of rows, and the lower mold 50b of any one of the plurality of rows of the lower molds 50b is immersed in the reservoir 80. The lower mold 50b, which is freshwater in the water storage tank 80, is loaded with pulp raw material on its upper surface, and is elevated to the upper mold 50a side by elevating means such as a cylinder. At this time, fine molds (not shown) are formed in each of the molds 50, which are connected to the vacuum line 84. Therefore, when the pulp material is deposited on the lower mold 50b, the vacuum line open / close valve 86 is opened so that the pulp raw material is adsorbed on the lower mold 50b.

Pulp material is alternately adsorbed to the upper mold (50a) and the lower mold (50b), and shifted to the neighboring heat in any one mold 50, gradually heated by the heating means 52, such as egg seat plate Molded into pulp moldings.

The support column of the pulp molding apparatus of the present invention as described above, the plurality of molds 50 are installed so as to be supported on the support plate 54, the mold 50 and the support plate 54 side is fixed to the site The metal fixing block 62 is installed, and the intermediate connection portion has a structure in which the heat insulating block 64 is installed. Therefore, the heat generated on the mold 50 side is prevented from being transferred to the support plate 54 by the intermediate insulating block 64, thereby preventing thermal deformation of the support plate 54 and deterioration of components behind the support plate 54. prevent. By preventing the thermal deformation of the support plate 54, the left and right positions of the molds 50 are not changed, so that even when the pulp molding apparatus is operated for a long time, the stationary summation between the upper mold 50a and the lower mold 50b is maintained. It is possible to significantly reduce the product failure rate.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the technical field of the present invention without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

1 is a cross-sectional view showing a mold coupling structure of a conventional pulp molding apparatus

Figure 2 is a cross-sectional view showing the mold coupling structure of the pulp molding apparatus equipped with the present invention

Figure 3 is a cross-sectional view showing a coupling state of the support column according to the present invention

Figure 4 is a cross-sectional view showing an example of the pulp molded article manufacturing apparatus equipped with the present invention

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

50: mold 52: heating means

54 support plate 56 heat insulating material

60: support column 62: fixed block

62a: first fixed block 62b: second fixed block

64: insulation block 66: through hole

68: hanging jaw 70: connecting rod

72: head

Claims (3)

It is installed in the pulp molding apparatus for molding the pulp raw material in the form of a mold, the pulp molding manufacturing apparatus installed between the mold 50 side and the support plate 54 so that a plurality of molds 50 are supported on the support plate 54 In the supporting column of The support column of the pulp molding production apparatus, characterized in that it comprises a fixed block (62) made of a metal material, and the insulating block (64) coupled between the fixing blocks (62) and made of a heat insulating material. The method of claim 1, The fixed block 62 has one end fixed to the mold 50 or the support plate 54 and the other end of the fixing block 62a is coupled to the insulating block 64, and one end thereof is the insulating block ( 64 is coupled to the other end of the support column of the pulp molding production apparatus, characterized in that composed of a second fixed block (62b) coupled to the other fixed block (62). The method according to claim 1 or 2, The fixing block 62 and the insulating block 64 is formed with a through hole 66 in the center along the longitudinal direction, the fixing block 62 is a locking jaw (68) inside the contact area with the insulating block 64 And a connecting rod 70 is inserted to penetrate the through hole 66, and both ends of the connecting rod 70 are provided with a head portion 72 made of a heat insulating material to be caught by the locking jaw 68. , Support column of the pulp molding production apparatus, characterized in that the insulating block 64 and the fixed block 62 is coupled by the connecting rod (70).

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