KR20110071438A - Metallic pattern - Google Patents

Abstract

PURPOSE: A mold is provided to prevent thermal stress by preventing the heat of a nozzle from becoming transferred to a nozzle plate, a connecting plate and a forming plate, which are adjacent to the nozzle. CONSTITUTION: A mold comprises a nozzle unit(100), a nozzle plate(210), a forming plate(230) and a dummy cavity(224). The nozzle unit discharges cold slag. The nozzle plate supports the nozzle unit. The forming plate comprises a forming cavity(232), which is filled with the cold slag. The cold slag is filled in the dummy cavity. For the forming cavity to be insulated, the dummy cavity is formed between the nozzle unit and the forming cavity.

Description

Mold {Metallic Pattern}

The present invention relates to a mold.

The mold is a device in which a cavity having a predetermined shape is formed therein, and filled with the molten resin in the cavity, and cured to form a molded article.

At this time, the mold may be provided with a nozzle portion for discharging the resin in the cavity. The nozzle portion may have a heating portion for heating the resin to reduce the amount of resin and improve the quality of the molded article, whereby a local temperature rise occurs on the side adjacent to the nozzle of the cavity.

The local temperature rise of the mold causes a temperature difference with the rest of the mold, causing a thermal stress to be generated in the mold.

The present invention is to provide a mold having a heat transfer prevention structure.

According to an aspect of the invention, the nozzle unit for discharging the resin; A nozzle plate supporting the nozzle unit; A molding plate on which a molding cavity filled with resin is formed; There is provided a mold including a dummy cavity interposed between the nozzle portion and the molding cavity so that the resin is filled to insulate the molding cavity.

Here, the mold may further include a connection plate interposed between the nozzle plate and the molding plate, and a connection flow path for connecting the nozzle unit and the molding cavity is formed.

At this time, the dummy cavity may be formed in the connection plate so as to be interposed between the nozzle portion and the connection passage.

The nozzle unit may include a nozzle in which a supply passage through which the resin is supplied is formed; A heating unit for heating the resin supplied to the supply passage; And a bush into which the nozzle is inserted.

Here, the mold may further include a first air gap interposed between the nozzle and the bush.

The mold may further include a support part interposed between the nozzle part and the nozzle plate to support the nozzle part, and may further include a second air gap interposed between the support part and the bush.

In addition, the mold may further include a third air gap interposed between the support and the nozzle plate.

According to an embodiment of the present invention, it is possible to prevent the rows of nozzles from being cut into the rest of the mold adjacent thereto.

The features and advantages of the present invention will become apparent from the following drawings and detailed description of the invention.

Hereinafter, an embodiment of a mold according to the present invention will be described in detail with reference to the accompanying drawings, in the description with reference to the accompanying drawings, the same or corresponding components are given the same reference numerals and duplicate description thereof It will be omitted.

1 is a perspective view showing a mold 1000 according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing a part of the mold 1000 according to an embodiment of the present invention. 1 to 2, the mold 1000 according to an embodiment of the present invention is the nozzle unit 100, the nozzle 130, the plate 210, the connecting plate 220, the forming plate 230 And a support 150, a dummy cavity 224, a first air gap 310, a second air gap 320, and a third air gap 330, thereby transferring heat from the nozzle 130 to the adjacent plate side. Can be prevented.

The mold 1000 may have a form in which the nozzles 130, the plate 210, the connection plate 220, the molding plate 230, and the plurality of auxiliary plates 202, 204, 206, 208, 212, and 214 are stacked. have.

Nozzle 130 The plate 210 may be formed with a groove for supporting the nozzle unit 100 therein.

The nozzle unit 100 may include a nozzle 130, a heating unit 120, and a bush 140.

The nozzle 130 may have a supply passage 110 through which resin is supplied. A heating unit 120 may be formed around the supply passage 110 to heat the resin flowing into the supply passage 110.

The heating unit 120 may include a heating wire that generates heat when electricity is supplied. The supply passage 110 including the heating unit 120 may be referred to as a hot runner.

The nozzle 130 may be inserted into the bush 140. The bush 140 may have a structure surrounding the nozzle 130 and may form an appearance of the nozzle unit 100. In this case, a groove filled with air, that is, a first air gap 310 may be interposed between the nozzle 130 and the bush 140.

The first air gap 310 may prevent the heat of the nozzle 130 from being transferred to the nozzle 130, the plate 210, the connection plate 220, and the forming plate 230 adjacent to the nozzle 130. .

The bush 140 may be supported by the support 150. The support part 150 may have a shape extending in the length direction corresponding to the shape of the nozzle part 100, and a hollow part may be formed therein, and the nozzle part 100 may be inserted into the hollow part.

The end of the bush 140 may be formed in a conical shape in which the cross-sectional area decreases toward the lower end, and the groove, ie, the second air, is filled with air between the inclined portion of the conical bush 140 and the support 150. The gap 320 may be formed. The second air gap 320 may prevent the heat of the nozzle 130 from being transferred to the nozzle 130, the plate 210, the connection plate 220, and the forming plate 230 adjacent to the nozzle 130. .

The support unit 150 may be supported by a nozzle 210 and a plate 210 in which a groove into which the support unit 150 may be inserted is formed. The nozzles 210 and the plate 210 may receive the support 150 therein and may support both sides of the support 150.

At this time, a groove filled with air, that is, a third air gap 330 may be formed between the support part 150 and the nozzle plate 210. The third air gap 330 may prevent the heat of the nozzle 130 from being transferred to the nozzle 130, the plate 210, the connection plate 220, and the forming plate 230 adjacent to the nozzle 130. .

The connection plate 220 may be coupled to the bottom of the forming plate 230. In the connection plate 220, a connection passage 222 penetrating the connection plate 220 up and down corresponding to the position of the supply passage 110 may be formed.

The connection passage 222 may be interposed between the molding cavity 232 and the supply passage 110, which will be described later, to provide a passage through which the resin discharged through the supply passage 110 may flow into the molding cavity 232. have. At this time, a flow path that does not include a heating device, such as the connection flow path 222, may be referred to as a cold runner.

A dummy cavity 224 may be formed around the connection channel 222 of the upper surface of the connection plate 220. The dummy cavity 224 may provide a space for the resin to be filled between the supply passage 110 and the connection passage 222.

The resin discharged through the supply passage 110 may be introduced into the cavity along the connection passage 222 after being filled in the dummy cavity 224.

Therefore, when the resin (cold slag) initially discharged through the supply passage 110 is not flowed smoothly and immediately filled in the molding cavity 232, the resin may cause a defect of the molded article. The resin 1000 may be filled in the dummy cavity 224 to prevent the defect of the molded article from occurring.

In addition, the resin filled in the dummy cavity 224 acts as a heat insulating material between the nozzle unit 100 and the connecting plate 220, the heat of the nozzle 130 is transferred to the connecting plate 220 and the forming plate 230. Can be prevented.

The forming plate 230 may be coupled to a lower end of the connection plate 220. A molding cavity 232 having a predetermined shape may be formed at a portion corresponding to the position of the connection passage 222 of the molding plate 230. The molding cavity 232 may be filled with a resin therein, and the resin may be cured to form a molded article having a predetermined shape.

As a result, the mold 1000 of the present exemplary embodiment includes the first air gap 310, the second air gap 320, the third air gap 330, and the dummy cavity 224, so that the heat of the nozzle 130 may be reduced. The nozzle 130 and the nozzle 130 adjacent to the plate 210, the connection plate 220, and the molding plate 230 may be prevented from being transferred to prevent the thermal stress from occurring in the mold 1000.

In addition, the dummy cavity 224 accommodates the resin initially drawn through the supply passage 110, thereby preventing a defective product from the initial discharge resin.

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

1 is a perspective view showing a mold according to an embodiment of the present invention.

2 is a cross-sectional view showing a part of a mold according to an embodiment of the present invention.

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

100: nozzle unit 210: nozzle plate

220: connection plate 222: connection euro

224: dummy cavity 232: molding cavity

Claims (8)

A nozzle unit for discharging a resin; A nozzle plate supporting the nozzle unit; A molding plate on which a molding cavity filled with the resin is formed; And a dummy cavity interposed between the nozzle part and the molding cavity so that the resin is filled to insulate the molding cavity. The method of claim 1, And a connection plate interposed between the nozzle plate and the molding plate and having a connection flow path for connecting the nozzle portion and the molding cavity. The method of claim 2, The dummy cavity is And a mold formed on the connection plate so as to be interposed between the nozzle part and the connection flow path. The method of claim 1, The nozzle part A nozzle in which a supply passage through which the resin is supplied is formed; A heating unit for heating the resin supplied to the supply passage; And And a bush in which the nozzle is inserted. 5. The method of claim 4, And a first air gap interposed between the nozzle and the bush. 5. The method of claim 4, And a support part interposed between the nozzle part and the nozzle plate to support the nozzle part. The method of claim 6, And a second air gap interposed between the support and the bush. The method of claim 6, The mold further comprises a third air gap interposed between the support and the nozzle plate.

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