KR102257227B1 - Forming Apparatus with Heat Shielding Structure of Chamber Wall - Google Patents

Abstract

The molding apparatus of the present invention comprises: a main chamber for molding an object to be formed; A plurality of chamber walls forming an exterior of the main chamber; A shutter that is insulated to open and close the viewing window formed on the chamber wall and to block the release of heat lost through the viewing window; It may include.

Description

Forming Apparatus with Heat Shielding Structure of Chamber Wall}

The present invention relates to a molding apparatus having a chamber wall insulating structure.

Conventionally, a flat glass has been used in a portable terminal, but recently, in order to improve a grip feeling or to improve information display, glass having a curved portion is widely used. Curved glass with bent left and right sides or upper and lower sides is widely used for the front window or rear back cover of the latest smartphones.

Meanwhile, a glass having a curved portion may be used as a lens for a camera.

When the object to be molded is placed in a mold and the mold is heated and pressurized, a glass or lens having a desired 3D shape can be molded.

The present invention provides a molding apparatus having a chamber wall insulation structure so that heat is not lost through the chamber wall of the main chamber.

The molding apparatus of the present invention comprises: a main chamber for molding an object to be formed; A plurality of chamber walls forming an exterior of the main chamber; A shutter that is insulated to open and close the viewing window formed on the chamber wall and to block the release of heat lost through the viewing window; It may include.

In the present invention, the viewing window may be made of a glass material so that a part of the chamber wall can be seen from the outside. Because heat insulation is not properly performed in the viewing window, heat existing inside the chamber is released to the outside, and electrical energy may be lost.

Insulation is provided by providing an openable shutter on the viewing window formed on the chamber wall, so that heat inside the chamber can be prevented from being easily released to the outside.

A heat insulating plate may be provided on the second side of the chamber wall to exhibit a heat insulating function. The inner wall of the main chamber is wrapped with an insulating material to block heat, while an opening is formed in the insulating material so that the inside of the main chamber can be observed through the viewing window, but the opening and the viewing window are opened and closed with a shutter. It can prevent heat from being released to the outside.

1 is a side view of the molding apparatus of the present invention.
2 is a schematic view for explaining the molding apparatus of the present invention.
3 is a perspective view showing a structure of a chamber wall provided in a chamber of the molding apparatus of the present invention.
4 is a rear view of FIG. 3.

Hereinafter, specific details for carrying out the present invention will be described in detail with reference to the accompanying exemplary drawings.

1 is a side view of the molding apparatus of the present invention, and FIG. 2 is a schematic view of the molding apparatus of the present invention.

The main chamber 3 may be installed on the base 1. The mold unit 200 forming a curved portion on the object to be molded passes through the interior of the main chamber 3 and may be preheated, molded, or cooled.

The object to be molded may be put into the main chamber 3 while being accommodated in the mold unit 200.

In the preheating unit 10, the mold unit 200 may be preheated at a preheating temperature.

The molding unit 30 may heat the mold unit 200 at a molding temperature.

When the molding temperature is higher than the preheating temperature, it is a heat molding method. The molding unit 30 may heat and press the mold unit 200 to form a molded object.

On the other hand, while the molding unit 30 gradually cools the mold unit 200, the object to be molded may be molded at a molding temperature lower than the preheating temperature. When the molding temperature is lower than the preheating temperature, it is a cooling molding method.

An injection chamber 2 into which the mold unit 200 is introduced into the main chamber 3 may be provided at the entrance side of the main chamber. An injection cylinder 5 for pushing the mold unit 200 may be provided in the injection chamber 2.

A preheating unit 10, a forming unit 30, and a cooling unit 40 may be sequentially arranged in the main chamber 3 along a direction from the main chamber inlet side toward the main chamber outlet side. A discharge chamber 4 for discharging the mold unit 200 passing through the main chamber 3 to the outside may be provided at the outlet side of the main chamber.

The preheating unit 10 may heat the mold unit 200 injected into the main chamber 3 through the injection chamber 2 to a preheating temperature.

On the downstream side of the preheating unit 10, a molding unit 30 may be provided that heats the preheated mold unit 200 to a molding temperature, presses the mold unit 200 with a predetermined pressing force, and forms a curved portion on the object. .

A cooling unit 40 may be provided on the downstream side of the molding unit 30 to gradually cool the mold unit 200 in which the molding of the object to be formed is completed. The cooling unit 40 is not limited to that shown in FIG. 1, and the cooling unit 40 may be provided outside the main chamber 3, and may be provided both inside and outside the main chamber 3.

The mold unit 200 passing through the preheating unit 10 and the forming unit 30 may be discharged from the main chamber 3 to the discharge chamber 4.

The discharging means may move the mold unit 200 from the main chamber outlet to the inside of the discharging chamber 4. The discharging means may comprise a discharging cylinder 6 and a discharging bar 7.

The preheating unit 10 may include a plurality of preheating lower blocks 14 installed on the bottom of the main chamber 3. The preheating lower block 14 may support or heat the lower portion of the mold unit 200.

At the top of the preheating unit 10, a plurality of preheating cylinders 11 for vertically operating the preheating piston 12 using, for example, pneumatic pressure may be installed. The pneumatic pressure may serve not only as a pressure transmission means, but also as an elastic means or damping means to relieve an excessive load from being applied.

A preheating upper block 13 facing the upper part of the mold unit 200 may be installed at an end of the preheating piston 12. The preheating upper block 13 transfers heat to the upper part of the mold unit 200.

The molding unit 30 includes a plurality of molding lower blocks 34 installed on the bottom of the main chamber 3, a molding piston 32 moving up and down in the main chamber 3, and a plurality of molding pistons 32. It may include at least one of the forming cylinder 31 and the forming upper block 33 connected to the forming piston 32.

The molding lower block 34 is installed on the floor inside the main chamber, and the lower part of the mold unit 200 may be heated so that the mold unit 200 maintains the molding temperature.

The mold unit 200 may be heated and pressurized at a molding temperature by contacting the molding upper block 33 moving together with the molding piston 32 on the upper part of the mold unit 200.

The cooling unit 40 is connected to a plurality of cooling lower blocks 44 and cooling upper blocks 43 installed on the bottom of the main chamber 3 and is configured to lift the cooling piston 42 and the cooling piston 42 moving up and down. It may include a plurality of cooling cylinders (41).

The cooling lower block 44 is installed on the floor inside the main chamber, and controls the temperature of the mold unit 200 so that the mold unit 200 is cooled to a predetermined cooling temperature at a predetermined cooling rate.

The cooling upper block 43 is coupled to the cooling piston 42, and the cooling lower block 44 and the cooling upper block 43 may cool the mold unit 200. The mold unit 200 may be cooled in a state in which the cooling upper block 43 is in contact with the upper part of the mold unit 200 and the cooling lower block 44 is in contact with the lower part of the mold unit 200.

A transfer means 60 for sequentially transferring the mold unit 200 to the preheating unit 10, the molding unit 30, and the cooling unit 40 in the main chamber 3 may be provided.

The interior of the main chamber 3 may be maintained at a high temperature for controlling the preheating temperature or molding temperature. At this time, when the temperature reaches the outside of the main chamber 3, problems such as energy loss and worker burns may occur. Accordingly, a cooling water passage 70 for circulating cooling water in the frame may be provided in order to cool the frame surface of the main chamber 3.

The main chamber 3 may be formed with a chamber wall 300 that is divided and assembled in a plurality.

Referring to FIG. 3, the chamber wall 300 may be formed of a glass plate, and a see-through window 310 may be formed to allow the interior of the main chamber 3 to be visible. ,

The viewing window 310 of the chamber wall 300 may be provided above and below, and when viewed from the first surface 301 of the chamber wall 300, a frame 320 may be formed at the edge of the viewing window 310. have.

The frame 320 may be detachably coupled to the chamber wall 300 by screw assembly, and a hinge 321 may be provided on one surface of the frame 320 to allow opening and closing.

In addition, a heat insulating plate 330 may be formed on the second surface of the chamber wall 300.

The heat insulating plate 330 may have openings 331 and 332 through which the see-through window 310 is visible. An open connection passage may be formed between the openings 331 and 332. The connection passage part is a part of the heat insulating plate 330 is cut to connect the openings 331 and 332 to each other, and the operation unit 360 may be installed in the connection passage part.

A shutter 340 is provided on the second surface 302 of the chamber wall 300. The shutter 340 may be made of an insulating material, and may be provided to be movable at a position corresponding to the viewing window 310.

A rotatable operation handle 350 may be provided on the first surface 301 of the chamber wall 300. An operation unit 360 for moving the shutter 340 while operating by the operation of the operation handle 350 may be provided in the connection passage portion of the second surface 302 of the chamber wall 300.

The operation unit 360 may include a pinion 361 and a pair of racks 362 that are engaged with both sides of the pinion 361 and perform linear motion.

Shutters 340 may be connected to the pair of racks 362, respectively.

The case 364 surrounding the contact point of the pinion 361 and the rack 362 of the operation unit 360 may be detachably assembled.

When viewing the inside of the main chamber 3 through the viewing window 310 formed on the chamber wall 300, when the operation handle 350 formed on each chamber wall 300 is rotated in one direction, the shutter 340 Can be moved to the open position.

When the operation handle 350 is rotated in one direction, the pinion 361 provided on the second surface 302 of the chamber wall 300 may be rotated together with the operation handle 350.

As the pinion 361 rotates, the racks 362 meshed with both sides of the pinion 361 may move linearly.

Since the shutters 340 are provided at the end sides of the racks 362, respectively, the shutters 340 may also be moved at the same time as the racks 362 move.

The shutter 340 may move within the openings 331 and 332 of the heat insulating plate 330 and may move to the open position while being guided along the side surfaces of the openings 331 and 332.

As the shutter 340 moves to the open position, the viewing window 310 is opened so that the inside of the main chamber 3 can be seen.

When there is no need to look inside the main chamber 3, the shutter 340 may be moved to the closed position in order to prevent heat loss of the viewing window 310. When the operation handle 350 is rotated in a direction opposite to that when the shutter 340 is opened, the shutter 340 is the opening 331 of the heat insulating plate 330 according to the rotation of the pinion 361 and the linear movement of the rack 362 Guided along the side of 332, it is possible to return to the closed position.

Therefore, since the viewing window 310 is usually covered by the shutter 340 and the shutter 340 is made of an insulating material, heat in the main chamber 3 is released through the viewing window 310, which is a glass material, thereby reducing heat loss. It can be prevented from causing.

In addition, since the first surface 301 of the chamber wall 300 is provided with an insulating plate 330 made of an insulating material, heat loss through the chamber wall 300 can be prevented.

Since the pinion 361 is constrained inside the case 364, a rotational operation is performed while reliably maintaining a state of engagement with the rack 362, and accordingly, the linear movement of the rack 362 is also performed by the case 364 and the rack ( Linear movement may be guided according to the sliding contact structure of the assembly surface of 362).

1...base 2...feeding chamber
3...main chamber 4...drain chamber
5...intake cylinder 6...discharge cylinder
7...Drain bar 10...Preheating unit
11...preheating cylinder 12...preheating piston
13...preheating upper block 14...preheating lower block
30...Molding unit 31...Molding cylinder
32... molded piston 33... molded upper block
34...molding lower block 40...cooling unit
41...cooling cylinder 42...cooling piston
43...cooling upper block 44...cooling lower block
60...transport means 70...coolant passage
200... mold unit
300: chamber wall 301: first surface
302: second side 310: viewing window
320: frame 321: hinge
330: insulation plate 331,332: opening
340: shutter 350: operation handle
360: operation unit 361: pinion
362: rack 364: case

Claims (6)

A main chamber for forming an object to be formed;
A plurality of chamber walls forming an exterior of the main chamber;
A shutter that is insulated to open and close the viewing window formed on the chamber wall and to block the release of heat lost through the viewing window; Including,
According to the arrangement of the plurality of chamber walls, a plurality of first surfaces corresponding to the outside of the chamber wall are connected to form an exterior of the main chamber, and a plurality of second surfaces corresponding to the inside of the chamber wall are connected, and the main Forms the interior of the chamber,
The shutter is installed adjacent to the viewing window and movably installed on the chamber wall,
An operable operation handle is exposed on the first surface of the chamber wall,
An operation unit connected to the operation handle is provided on the second surface of the chamber wall,
The operation handle extends from the first surface to the second surface through the chamber wall and is connected to the operation unit,
When the operation handle is operated outside the main chamber, the operation unit moves, and the shutter connected to the operation unit moves to open and close the viewing window.
The method of claim 1,
The operation unit,
A molding apparatus comprising a rotating operation handle, a pinion connected to the operation handle and rotating, and a rack that is engaged with both sides of the pinion to move the shutter while performing linear motion when the pinion is rotated.
The method of claim 1,
A first opening and a second opening are provided in one of the chamber walls,
A first viewing window faces the first opening and a second perspective window faces the second opening,
The first viewing window is opened and closed by a first shutter, and the second viewing window is opened and closed by a second shutter,
The first shutter and the second shutter are connected to the operation unit,
When the operation handle is operated, the first shutter and the second shutter connected to the operation unit move simultaneously.
The method of claim 1,
A heat insulating plate is provided on the second surface of the chamber wall,
An opening is formed in the heat insulating plate, the shutter is guided through the opening, and the shutter moves along the opening to open and close the viewing window.
The method of claim 1,
The viewing window and the shutter are sequentially positioned in the opening of the chamber wall from the first surface toward the second surface,
The viewing window is connected to the first surface by a hinge,
When the viewing window is rotated toward the outside of the first surface, the opening of the chamber wall is opened. delete

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