KR100967799B1 - Heat treat apparatus for tempering a thin glass - Google Patents

Abstract

PURPOSE: A heat treatment apparatus for tempering a thin glass is provided to induce stable and smooth flow in a procedure of automatically performing heat treatment, to reduce a moving time between processes, and to improve the productivity. CONSTITUTION: A heat treatment apparatus for tempering a thin glass comprises a first driving unit(50) and a second driving unit(80). The first driving unit is installed to make a transfer cart(40) move along an upper rail(52) which is parallelly installed on the upper side of a preheating furnace(10), a main body channel(20), and a cooling channel. The second driving unit includes a rack(61) for accepting the thin glass within the transfer cart. The second driving unit which is connected to a rack elevating unit, a muffle, and the lower side of the preheating furnace, the main body channel, and the cooling channel.

Description

Heat Treat apparatus for tempering a thin glass

The present invention relates to a thin glass reinforcement heat treatment apparatus, in particular, in the process of automatically performing heat treatment for the surface hardening of thin glass induces a stable and smooth flow between processes and shorten the movement time between processes to improve quality stability and productivity and The present invention relates to a thin glass reinforced heat treatment apparatus capable of shortening the working time.

Tempered glass, which is generally used in mobile phones, PCs, PDAs, navigation, building and various industrial glass, has a thin plate shape, generates less scratches, and has excellent light transmittance. However, in order to maintain these characteristics, it is necessary to undergo surface hardening heat treatment, and it is also urgent to secure mass production quality and productivity based on automated facilities.

For example, according to Korean Registered Utility Model No. 0432508, the overall configuration conveyed by the mobile unit is automatically strengthened after passing through the preheating furnace, the salt bath, the slow cooling furnace, the hot water furnace, the hydrothermal furnace and the drying furnace by the transfer unit. Disclosed is an apparatus for manufacturing tempered glass for a display window, which can produce tempered glass having a constant angle, thickness, and transmittance of glass.

However, according to this method, if the periphery is thermally expanded due to the heat of hot tempered glass in the process of passing through the preheating furnace and the salt bath, the transfer phenomenon is easily delayed, and accordingly, the heat treatment temperature is outside the set range. This will eventually affect the quality.

Accordingly, the applicant of the present application preheats thin glass in a sequential process by including a preheating furnace, a main body, a cooling furnace and a rail installed thereon, a support roller installed on the rail, a traveling wheel, and a transfer bogie in Korean Patent Registration No. 0866844. A heat treatment apparatus for heating, cooling and cooling has been disclosed.

The present invention has been invented to solve the problems of the prior art as described above, inducing a stable and smooth flow between processes in the process of automatically performing heat treatment for the surface hardening of the thin glass glass to reduce the transfer time between processes quality An object of the present invention is to provide a thin glass reinforced heat treatment apparatus capable of improving stability, improving productivity, and reducing work time.

In order to achieve the above object, the present invention provides a preheating furnace, a main body, a cooling furnace continuously provided in the apparatus for preheating, heating and cooling the thin glass in a sequential process, the preheating furnace, the main body, cooling First traveling means installed to move the transport cart along the upper rail installed parallel to the upper side of the furnace; Rack lifting means for receiving a thin plate glass in the interior of the transport cart, and performs the vertical movement of the rack in a stable state; A muffle provided on the main body to perform indirect heating; The preheating furnace, the main body, provided on the lower side of the cooling furnace provides a thin glass reinforced heat treatment apparatus comprising a second running means for moving the preheating furnace, the main body, the cooling furnace by the power means.

The thin glass reinforcement heat treatment apparatus according to the present invention thus induces a stable and smooth flow between the processes in the process of automatically performing the heat treatment for the surface hardening of the thin glass, shorten the movement time between the processes to improve quality stability and productivity and There is an advantage that can reduce the work time.

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

1 is an overall front configuration diagram of a first embodiment of a thin glass reinforced heat treatment apparatus according to the present invention, FIG. 2 is a plan configuration diagram of FIG. 1, and FIG. 3 is a side configuration diagram of FIG. 1. 4 is an overall front configuration diagram of a second embodiment of a thin glass reinforced heat treatment apparatus according to the present invention, FIG. 5 is a plan configuration diagram of FIG. 4, and FIG. 6 is a side configuration diagram of FIG. 4. 7 is a front configuration diagram of the third embodiment of the thin glass strengthening heat treatment apparatus according to the present invention, FIG. 8 is a plan view of FIG. 7, and FIG. 9 is a side view of FIG. 7.

The present invention relates to an apparatus for preheating, heating, cooling and heat-treating thin glass in a sequential process. 1 to 9, the thin glass reinforcement heat treatment apparatus according to the present invention includes a preheating furnace 10 of a heat insulation wall structure that can be opened and closed upward, a main body furnace 20 of a plurality of fireproof wall structures that can be opened and closed upward, and In a heat treatment apparatus in which a plurality of cooling paths 30 having a plurality of heat insulation wall structures that can be opened and closed upwardly are continuously provided and a transfer bogie is provided on an upper side thereof, a first run installed to move the transfer bogie 40. The means 50 and the rack lifting means 60, which is provided in the transport cart 40 and performs the vertical movement of the rack 61 to accommodate the thin glass, the preheating furnace 10 and the main body 20 ), The second driving means 80 is provided on the lower side of the cooling furnace (30).

The preheating furnace 10 is a heat insulation wall structure that can be opened and closed upward, and is configured to alternately include a pipe heater and a far infrared heater and to control the temperature using a blower, and the main furnace 20 has a plurality of fireproof wall structures that can be opened and closed upward. As a laminated structure using a refractory brick and having a strip heater on the lower side of the muffle 70 for indirect heating, the cooling furnace 30 is a plurality of thermal insulation wall structures that can be opened and closed upwards. The furnace 33 and the cold water furnace 35 are provided and are installed so as to maintain proper cooling by using a heater and a blower together.

More detailed descriptions of the preheating furnace 10, the main body 20 and the cooling furnace 30 will be omitted since they are shown in detail in Korean Patent No. 0866844 of the applicant.

The transfer truck 40, which is installed to be sequentially moved along the preheating furnace 10, the main body 20 and the cooling furnace 30, can be opened and closed downward and has one chamber 41 without a heater and two with a heater. It consists of a chamber 42.

An upper rail 52 is installed in parallel with the upper side of the preheating furnace 10, the main body 20, and the cooling furnace 30 so as to move the transport cart 40, and is transported along the upper rail 52. The first traveling means 50 is provided to move the cart 40.

The first driving means 50 is satisfactory if the transfer cart 40 is a structure that can be sequentially moved on the preheating furnace 10, the main body 20 and the cooling furnace 30. Examples thereof include one or more selected from an LM guide driver, a ball screw driver, a rack gear, a ball spline, a roller, a pneumatic driver, and a square iron driver.

Although not shown in detail, the LM guide driver is provided with a guide rail and a spiral shaft and induces the driving of the feed cart 40 while the block is linearly moved by the rotation of the motor, and the ball screw driver is moved to both sides. It is driven by supporting the feed cart 40 by the provided spiral shaft and connecting the nut to the feed cart 40.

In addition, the rack gear is installed in engagement with the pinion gear, which rotates the pinion gear on the feed cart 40 by the rotation of the motor, and the ball spline performs a linear motion by interposing a plurality of balls on the groove. It can also be driven by manual force.

In addition, the roller is attached to the bottom surface of the feed cart 40 and can be driven by manual force along a separate rail, and the pneumatic pneumatic actuator replaces the feed cart 40 on a separate rail and connects the piston rod of the operation cylinder. The square iron driver is a method of stably seating the traveling wheel of the feed cart 40 inside the rail of the C-shaped cross section and performing a linear movement while winding or unwinding the wire in front and rear.

The LM guide driver, ball screw driver, rack gear, ball spline, roller, pneumatic actuator, square iron driver may be used separately by section, and instead of the automatic drive by the motor, the manual drive by the reducer and the handle You can also apply In other words, if the handle is turned with a small force, a large force is generated through the speed reducer, thereby replacing the power of the motor.

The rack lifting means 60 is installed inside the transfer cart 40 so that the rack 61 in which the thin glass is accommodated may be sent to the hook 63. The rack 61 is a portion for loading a large number of thin glass test products, the hook 63 performs a locking, releasing function at the top of the rack 61. The rack lifting means 60 performs a function of entering and exiting the rack 61 in the preheating furnace 10, the main body furnace 20, and the cooling furnace 30 according to the process order.

At this time, the rack lifting means 60 is configured with one or more selected from LM guide driver, ball screw driver, hydraulic pneumatic driver, chain driver.

The LM guide driver is provided with a guide rail and a spiral shaft vertically and connects the hook 63 through a wire. The ball screw driver installs a spiral shaft provided with both vertical sides and a hook 63 through a wire. How to configure the connection. In addition, the pneumatic actuator is a method of connecting the hook 63 to the end of the piston rod of the operation cylinder via a wire, the chain driver is a method of connecting the hook 63 via a wire on a vertical guide rail. .

On the main body furnace 20 of the present invention, a muffle 70 for performing indirect heating is provided. Muffle 70 is not good thermal efficiency, but because the indirect heating method does not touch the flame can be uniformly heated and advantageous to prevent contamination of the thin glass.

The muffle 70 has a rectangular, circular, oval, pentagonal, hexagonal, octagonal, pentagonal, or decagonal shape with at least one side of the container-shaped body 72 or the upper opening 75 as shown in FIG. 10. It consists of a form that is selected. The muffle 70 is mainly formed of a stainless steel body 72 and the opening 75 is preferably formed in a rectangular structure such as a conventional refractory furnace. However, it can be embodied as a round, oval, pentagonal, hexagonal, octagonal, 10-sided, 12-sided, etc. This is to consider that the size or shape of the thin glass according to the type of the final product and the appearance that is optimally accommodated in the rack 61 may be different. In either case, only the body 72 may be deformed, only the opening 75 may be deformed, and the body 72 and the opening 75 may be deformed in the same manner.

Meanwhile, the preheating furnace 10, the main body 20, and the lower side of the cooling furnace 30 are the preheating furnace 10, the main body 20, and the cooling furnace 30 by the power means. The second driving means 80 to be moved independently of the 50 is provided with a connection.

In the first embodiment of the second running means 80 as shown in Figures 1 to 3, the transfer bogie 40 moves to the lower side of the preheating furnace 10, the main body passage 20, and the cooling passage 30. The lower rail 82 is installed on the bottom in the direction parallel to the traveling direction, and the lower rail 82 is provided with a moving means driven by the second traveling motor 85.

As described above, when the moving direction of the second traveling means 80 and the first traveling means 50 are the same, when the transfer cart 40 by the first traveling means 50 proceeds forward for the next process, Since the preheating furnace 10, the main body 20, and the cooling furnace 30 are driven backward by the two driving means 80, the movement time between the processes can be shortened.

In addition, referring to the second embodiment, as shown in FIGS. 4 to 6, the moving progress direction of the transfer cart 40 is located on the lower side of each of the preheating furnace 10, the main body furnace 20, and the cooling furnace 30. The lower rail 82 is installed on the bottom in an orthogonal direction, and the lower rail 82 is provided on the lower rail 82 to provide a moving means driven by the second driving motor 85.

In this case, the second driving means 80 may be configured at the lower side of the preheating furnace 10, the main body furnace 20, and the cooling furnace 30, respectively, and the preheating furnace 10, the body furnace 20, and the cooling furnace An entire furnace may be integrally connected to the lower side of the 30 to be moved.

As described above, when the traveling direction of the second traveling means 80 and the first traveling means 50 becomes perpendicular to each other, the traveling direction of the transport cart 40 by the first traveling means 50 is perpendicular to the traveling direction (front and rear). Since it can be pulled out to one left or right side, it is advantageous when the preheating furnace 10, the main body furnace 20, and the cooling furnace 30 are repaired or replaced due to failure of the second traveling means 80.

In this case, although not shown, the second driving means 80 may be configured to be parallel and orthogonal to the first driving means 50 in parallel with the two methods.

In addition, referring to the third embodiment, as shown in FIGS. 7 to 9, the preheating furnace 10, the main body 20, and the lower side of the cooling furnace 30 are pivoted in the moving progress direction of the transport bogie 40. The preheating furnace 10, the main body 20, and the cooling furnace 30 are provided with a base plate 87 so that the fixture is integrally fixed, and a rotation shaft 86 driven by a motor is installed at the center thereof to implement the turntable method. And, the lower portion of the support plate 87 is provided with a wheel to allow the rotation of the shaft.

When configured as described above has the same ease of repair and replacement as in the second embodiment, it is also possible to reduce the installation space of the preheating furnace 10, the main body furnace 20, the cooling furnace 30.

Operation of the thin glass reinforcement heat treatment apparatus is moved from the preheating furnace 10 to the slow cooling furnace of the cooling furnace 30 by using the heaterd portion of the transport cart 40, and the hot water furnace of the cooling furnace 30. In the cold and cold water passages, the heaterless part moves. The main passage 20 and the cooling passage 30 are open at the top and open and close the door by a cylinder. Due to the first travel means 50 and the second travel means 80 of the present invention, accurate position control of the feed cart 40 is carried out through the preheating furnace 10, the main body furnace 20, and the cooling furnace 30. It is possible to reduce the transit time between processes, and contribute to quality stability and productivity improvement.

1 is a front configuration diagram of a first embodiment of a thin glass reinforced heat treatment apparatus according to the present invention,

2 is a plan view of FIG.

3 is a side configuration diagram of FIG. 1;

4 is a front configuration diagram of a second embodiment of a thin glass reinforced heat treatment apparatus according to the present invention;

5 is a plan view of FIG.

6 is a side configuration diagram of FIG. 4;

7 is a front configuration diagram of a third embodiment of a thin glass reinforced heat treatment apparatus according to the present invention;

FIG. 8 is a plan view of FIG. 7;

9 is a side configuration diagram of FIG. 7;

10 is a configuration diagram showing various embodiments of the muffle according to the present invention.

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

6: pipe heater 8: conveyor

10: preheating 20: main body

30: cooling furnace 31: slow cooling furnace

33: hot water furnace 35: cold water furnace

40: feed cart 41: 1 chamber

42: 2 chamber 50: First driving means

52: upper rail 55: the first driving motor

60: rack lifting means 61: rack

63: hook 65: lifting motor

70: muffle 80: second driving means

82: lower rail 83: cylinder

85: second driving motor 86: rotation axis

87: support plate 88: drive roller

91: LM Guide

Claims (6)

In the preheating furnace, the main body, the cooling furnace is provided continuously to preheat, heat and cool the thin glass glass in a sequential process, First traveling means 50 installed to move the transport cart 40 along the upper rail 52 installed parallel to the upper side of the preheating furnace 10, the main body 20, the cooling furnace 30. And, the rack 61 for accommodating the thin glass in the transfer cart 40 is provided with a rack lifting means 60 to perform the vertical movement of the rack 61 in a stable state, and the main body path 20 It is provided on the muffle (70) for performing indirect heating, the preheating furnace 10, the main body 20, the lower side of the cooling furnace 30 is provided and connected to the preheating furnace 10 by the power means In addition, the main body 20, the cooling furnace 30 is made to include a second driving means 80 to move independently of the first driving means 50, The first driving means 50 is provided with one or more selected from LM guide driver, ball screw driver, rack gear, ball spline, roller, hydraulic pneumatic driver, square iron driver, The second driving means 80 is provided with a lower rail 82 on the floor in a direction parallel to the moving progress direction of the feed cart 40, the preheating furnace 10, the main body furnace 20, the cooling furnace 30 Thin glass reinforcement heat treatment apparatus characterized in that the movement means driven by the motor is provided on the lower side. delete delete delete delete delete

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