JP2002367762A - High frequency induction heating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a high frequency induction heating device with which no fluctuation occurs in heating temperature and heating time with can lids conveyed at constant intervals and speed. SOLUTION: The high frequency induction heating device is structured of a conveyor part made of screws 11 conveying can lids 30, a heating part made of coils 12 set so as to surround the outer periphery of the screws 11, a cooling part 13 cooling laminated can lids 30 heated in the heating part, a high frequency current oscillating part outputting high frequency current to the coils 12, and a control part controlling rotating speed of the screws 11 output of the high frequency current oscillating part.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high-frequency induction heating apparatus used in the production of a can lid, and more particularly to the residual stress of a laminated film in the production of a laminated can lid composed of a laminated film and a can lid material plate. Relaxation,
The present invention relates to a high-frequency induction heating device for preventing feathering from occurring in an opening when a laminated can lid is opened and improving corrosion resistance.

[0002]

2. Description of the Related Art In general, cans such as beer cans, liquor cans, and juice cans comprise a bottomed cylindrical can body and a can lid for closing an open end of the can body. There are various types of can lids, and the main one is an easy-open type can lid that can be easily opened by attaching a tab or the like. As a can lid, there is a can lid obtained by producing a pre-coated material coated on both sides of an aluminum thin plate with an epoxy or vinyl chloride paint and molding the pre-coated material. Such a precoat material is intended to prevent corrosion and protect contents. However, since epoxy-based and vinyl chloride-based paints contain bisphenol-A and organic solvents, as a countermeasure to reduce the environmental load, a laminate film has been attracting attention as a coating material in place of these paints.

[0003] As a can lid, on both sides of an aluminum sheet,
In the case of using a laminate material coated with a laminate film, in particular, the film on the inner surface side of the can lid has a problem that feathering occurs when the can is opened. The reason why feathering occurs when the can is opened is that the laminated film peels off from the aluminum sheet without breaking when opening the can because of the weak adhesion between the laminated film and the aluminum sheet. Is the cause. In the method of thermocompression bonding a laminated film to an aluminum thin plate,
There is a problem that the adhesion is inferior to the conventional method of coating a thin aluminum plate with a paint or an adhesive. Also, after manufacturing the laminated can lid, the corrosion resistance is degraded due to residual stress during processing on the laminated film, or the adhesion between the laminated film and the aluminum sheet is impaired, or feathering in the opening as described above. There is a problem that occurs.

FIG. 3 is a schematic configuration diagram showing a conventional high-frequency induction heating device. This high-frequency induction heating device is schematically composed of a heating device main body 1, a heating device 2, a heating furnace 3, a V-shaped tray 4, a belt conveyor 5, and a down stacker 6. This high-frequency induction heating device dries a can lid 8 having its surface coated with an epoxy or vinyl chloride paint for the purpose of preventing corrosion and protecting the contents, and removes the solvent of the epoxy or vinyl chloride paint. Is a device that volatilizes and covers the can lid. The high-frequency induction heating device is a heating device that can heat a body to be heated to a predetermined temperature in a short time. Therefore, it is an effective device when a drying process is required in the production process.

[0005] The outline of the process of drying the can lid 8 coated with an epoxy or vinyl chloride paint using this high-frequency induction heating apparatus will be described below. The can lid 8 coated with an epoxy-based or vinyl chloride-based paint is continuously supplied onto the belt conveyor 5 by the down stacker 6 in a state where these are laminated, and the heating furnace of the heating device main body 1 is introduced from the inlet 7. Introduce into 3. The can lid 8 is heated at a high frequency of about 70 ° C. by the heating device 2 in the heating furnace 3 to reach about 70 ° C., so that the solvent of the epoxy or vinyl chloride paint is volatilized. The can lid 8 that has passed through the heating furnace 3 is extruded as it is onto the V-shaped tray 4, and the drying step is completed.

[0006]

In this high-frequency induction heating apparatus, when the number of can lids 8 supplied into the heating furnace 3 exceeds a certain amount, the stack of the can lids 8 moving on the belt conveyor 5 is removed. Until the end is no longer present at the end of the belt conveyor 5 on the side of the inlet 7, the can lid 8 is newly placed on the belt conveyor 5.
Not supplied on. The transport of the can lid 8 in the process before the inlet 7 is performed by the force of pressing the can lid 8 at the front thereof with the can lid 8 at the rear thereof. From the above, the can lid 8 was not conveyed at a constant speed, and the residence time of the can lid 8 in the heating furnace 3 also varied.

In the conventional high-frequency induction heating apparatus, when a steel can lid is transported, the can lid can be transported at equal intervals by the repulsion of magnetic force, utilizing the fact that steel is a magnetic material. The function is provided. However,
This function cannot be applied to an aluminum can lid, and there has been a problem that the aluminum can lid cannot be conveyed at equal intervals in a conventional high-frequency induction heating apparatus. When the can lids are transported in a stacked state, the can lids adhere to each other, and there is a problem that the coating material such as an epoxy-based or vinyl chloride-based paint or a laminated film is damaged. Furthermore, if the can lid is not conveyed at regular intervals and at a constant speed, the heating temperature and the heating time vary, and there is a problem that the stress of the laminated film of the laminated can lid cannot be sufficiently relaxed.

The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a high-frequency induction heating apparatus in which can lids are conveyed at equal intervals and at a constant speed, and there is no variation in heating temperature and heating time. .

[0009]

An object of the present invention is to provide a transport unit including a screw for transporting a can lid, a heating unit including a coil surrounding the screw, and a high-frequency current oscillating unit for sending a high-frequency current to the coil. It can be solved by a high frequency induction heating device. It is preferable that the high-frequency induction heating device includes a cooling unit that cools the can lid heated in the heating unit. It is preferable that the high-frequency induction heating device further includes a control unit that controls a rotation speed of the screw and an output of the high-frequency current oscillating unit.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below in detail with reference to FIGS. The high-frequency induction heating apparatus according to the present invention includes a transport unit including four screws 11 for transporting the can lid 30, a heating unit including the coil 12 provided around the outer circumference of the screw 11, and heating in the heating unit. A cooling unit 13 for cooling the can cover 30, a high-frequency current oscillating unit (not shown) for outputting a high-frequency current to the coil 12, and a control unit for controlling the rotation speed of the screw 11 and the output of the high-frequency current oscillating unit (not shown). ). here,
The can lid 30 is provided on both sides of a can lid material plate made of aluminum alloy,
It is a laminated can lid covered with a laminated film.

The screw 11 forming the transport section is made of a heat-resistant resin such as a polyamide-imide resin, a glass fiber reinforced polyphenylene sulfide resin, ceramics, or the like. The rod body has spiral grooves formed at regular intervals. From the viewpoint of moldability and the like, a polyamideimide-based resin is preferably used. The coefficient of linear expansion of the polyamideimide resin used in the present invention is 2.5 × 10 ^−5.
/ ° C. to 3.0 × 10 ⁻⁵ / ° C., preferably 2.75.
× a 10 ^-5 /℃~2.85×10 ^-5 / ℃. If the coefficient of linear expansion is less than 2.5 × 10 ⁻⁵ / ° C., the screw 11 is too hard, and the can lid 30 may be deformed at the time of transport.
If the temperature exceeds × 10 ⁻⁵ / ° C., the screw 11 expands due to heating and is bent in the outer diameter direction, so that the can lid 30 may fall off. Further, the tensile strength of the polyamideimide resin used in the present invention is preferably 44 MPa or more at 250 ° C. If the pressure is less than 44 MPa, the screw 11 may bend when the can lid 30 is transported, and the can lid 30 may fall off.
The deflection temperature under load of the polyamide-imide resin used in the present invention is preferably equal to or higher than the temperature at which the can lid 30 is heated, and specifically, is preferably equal to or higher than 250 ° C. If the temperature is lower than 250 ° C., the screw 11 may bend when the can lid 30 is heated, and the can lid 30 may fall off.

The four screws 11 are arranged so that four of them form a quadrilateral.
An inlet 14 for the can lid 30 is provided. The can lid 30 is fitted into the screw 11 from the fitting inlet 14 and fitted into a spiral groove formed on the outer periphery of the screw 11.
Since the can lid 30 is conveyed along the spiral groove with the rotation of the screw 11, the can lid 30 is conveyed to the heating unit and then to the cooling unit 13 at regular intervals and at a constant speed. The screw 11 is driven by a pulley 16 attached to a tip of a motor 15 via a timing belt 17.
Each of the four screws 11 is connected to a pulley 18 attached thereto, and the rotation of the motor 15 causes the screws 11 to rotate.
A relay cable 19 is connected to the motor 15, and the relay cable 19 is further connected to a control unit (not shown). Since the screw 11 is rotated at a constant speed by the motor 15, the can lid 30 fitted in the screw 11 can be forcibly conveyed.

The coil 12 is formed by processing a metal wire into a coil shape, and is provided so as to surround four screws 11. The coil 12 is connected to a high-frequency current oscillating unit including a high-frequency current oscillator (not shown) via a relay cable (not shown), and the high-frequency current oscillating unit is connected to a control unit.

The control section controls the rotation speed of the motor 15 and the high-frequency current output from the high-frequency current oscillating section to the coil 12 to adjust the heating temperature and the heating time of the can lid 30. In order to adjust the heating temperature of the can lid 30, when the high-frequency current output to the coil 12 is constant, the rotation speed of the screw 11 is controlled to adjust the time during which the can lid 30 stays in the heating unit, or This is performed by fixing the rotation speed of the screw 11 and controlling the amount of high-frequency current flowing through the coil 12. With such a mechanism of the high-frequency induction heating device, the can lid 30 can be quickly and stably heated to a predetermined temperature.

The cooling unit 13 is provided below the coil 12 in the screw 11, and is capable of rapidly cooling the can lids 30 conveyed at equal intervals as they are. The cooling unit 13 is provided with a cooling device (not shown), and the can lid 30 is rapidly cooled by cooling air to a temperature lower than the melting point of the laminated film. In the high-frequency induction heating device of the present invention, since the can lid 30 is cooled while maintaining the same intervals, heat is easily dissipated and rapid cooling is possible. In addition, since the can lid 30 is cooled to a temperature lower than the melting point of the laminated film in the cooling unit 13, even if the can lid 30 is discharged from the outlet 20 and then stacked as it is, the laminated film is not covered by another can lid. 30
Does not fuse to

The process of heating the can lid 30 using the high-frequency induction heating apparatus of the present invention will be described below. First, the can lid 30 is fitted into the screw 11 from the fitting port 14 provided in the upper part of the high-frequency induction heating device, and is conveyed to the heating section of the screw 11 by rotating the screw 11 by the motor 15. The can lid 30 conveyed to the heating unit is heated at 80 to 210 ° C. by the coil 12 provided in the heating unit to 5 to 30 °
Heated for a second. More preferred heating temperature and heating time are 120 to 150 ° C. and 5 to 10 seconds. When the heating temperature is lower than 80 ° C., the heating time becomes long, which is not suitable in terms of productivity. When the heating temperature exceeds 210 ° C., the heat shrinkage of the laminate film itself is remarkable, and wrinkles may be generated in the film. In addition, the aluminum alloy that is the base material of the can lid 30 is softened by heat, causing a problem that the strength is reduced. Can lid 3
By setting the temperature and time for heating 0 to the above ranges, the adhesion of the laminated film to the can lid material plate is improved, and the stress remaining in the laminated film during the production of the can lid 30 is reduced. can do. As a result, it is possible to prevent the occurrence of feathering in the opening when the can lid 30 is opened.

In the easy-open type can lid, it is required that when the can is opened, the score film is broken and the laminated film coated on the laminated can lid is also broken along the same. The breakability of the score portion is affected by the adhesion of the laminate film to the can lid material plate and the physical properties of the laminate film. That is,
The higher the adhesion of the laminated film, the more easily and sharply the film is broken along the score portion. ADVANTAGE OF THE INVENTION According to the high frequency induction heating apparatus of this invention, while a sufficient adhesive force is obtained between a laminated film and a can lid material plate, sharp breakage of the laminated film along a score part is performed. Therefore, feathering does not occur in the opening when the can is opened.

According to the high-frequency induction heating apparatus of the present invention, the can lid can be heated to a predetermined temperature in a short time, so that productivity does not decrease in the production line of the laminated can lid. Further, since the can lid can be heated without directly contacting the heating element with the can lid, the laminated film is softened at the time of heating and does not fuse to the heating element.

[0019]

As described above, the high-frequency induction heating apparatus according to the present invention comprises a conveying section including a screw for conveying a can lid, a heating section including a coil surrounding the screw, and a high-frequency current sent to the coil. Since the high-frequency current oscillating unit is provided, even if the inside of the heating furnace is filled with the can lid, the supply of the can lid to the heating furnace and the discharge from the heating furnace are performed without interruption, so that the Can be continuously heated. Further, the residence time of the can lid in the heating furnace can be made constant. Further, the can lid can be transported at equal intervals in the heating furnace. Further, the surface of the can lid covered with the epoxy-based or vinyl chloride-based paint or laminate film is not damaged. Further, since the stress remaining in the laminated film can be sufficiently reduced, the adhesion of the laminated film to the can lid material plate is improved, and when the laminated lid is opened, the laminated can lid is opened. The laminate film coated on the outer surface of the film is easily torn, and feathering does not occur in the opening. Further, since the high-frequency induction heating device of the present invention is provided with a cooling unit that cools the can lid heated in the heating unit, the can lid is cooled while maintaining equal intervals, so that heat is radiated. Rapid cooling is possible. In addition, since the can lid is cooled to a temperature lower than the melting point of the laminated film in the cooling section, even after the can lid is discharged from the outlet, as it is, the laminated film is fused to another can lid. Never.

[Brief description of the drawings]

FIG. 1 is a front view showing an example of a high-frequency induction heating device of the present invention.

FIG. 2 is a bottom view showing an example of the high-frequency induction heating device of the present invention.

FIG. 3 is a schematic configuration diagram showing a conventional high-frequency induction heating device.

[Explanation of symbols]

11 ... screw, 12 ... coil, 13 ... cooling unit,
14 ... fitting entrance, 15 ... motor, 16, 18 ... pulley, 17 ... timing belt, 19 ... relay cable,
20 ... outlet

Claims (3)

[Claims] 1. A high-frequency induction unit comprising: a transport unit including a screw for transporting a can lid; a heating unit including a coil surrounding the screw; and a high-frequency current oscillating unit for sending a high-frequency current to the coil. Heating equipment. 2. The high-frequency induction heating apparatus according to claim 1, further comprising a cooling unit that cools the can lid heated in the heating unit. 3. The high-frequency induction heating apparatus according to claim 1, further comprising a control unit that controls a rotation speed of the screw and an output of the high-frequency current oscillating unit.