JP7261438B2 - Induction heating roller device - Google Patents

Description

TECHNICAL FIELD The present invention relates to an induction heating roller device, and more particularly to a roller body provided with a secondary conductor.

The induction heating roller device includes a roller body made of a magnetic material and an induction heating mechanism provided in the roller body and having an induction coil. There are things that generate heat. In this induction heating roller device, the roller body constitutes both a magnetic circuit through which magnetic flux passes and a current circuit through which a short-circuit current flows due to electromagnetic induction. As a result, an impedance is generated in the roller body that makes it difficult for the short-circuit current to flow, and the power factor is lowered.

As a means for preventing the decrease in power factor, as shown in Patent Document 1, it has been considered to provide a secondary conductor made of a non-magnetic material on the inner peripheral surface of the roller body.

Conventionally, the method of providing the secondary conductor on the inner circumferential surface of the roller body is as follows.
First, a copper plate is bent and then joined by silver brazing or the like to form a cylindrical tubular body. This tubular body is brazed to the inner peripheral surface of the roller body. Thereby, the secondary conductor is provided on the inner peripheral surface of the roller body. In addition to brazing, there is also a method of press-fitting or shrink-fitting the tubular body into the roller body.

However, the above method requires many processing steps such as a step of manufacturing the tubular body from the copper plate and a step of mounting the tubular body on the roller body.

In addition, since it is difficult to braze the entire outer circumferential surface of the tubular body by brazing, it may not be suitable for a roller body that rotates at high speed. In addition, in mounting methods such as press-fitting and shrink fitting, the roller body and the secondary conductor are simply in close contact with each other, and there is a difference in thermal expansion between the roller body and the secondary conductor. and the secondary conductor loosens due to repeated temperature changes. As a result, there is also the problem that the thermal conductivity between the roller body and the secondary conductor is reduced.

In view of such problems, as shown in Patent Document 2, a secondary conductor is formed on the inner peripheral surface of the roller body by build-up welding. Here, the secondary conductor is also conceived to be helically welded and formed such that adjacent welded portions are in contact with each other and are continuous.

However, the overlay-welded secondary conductor has thickness unevenness in the circumferential direction, particularly in the width direction. This thickness unevenness causes heat generation unevenness. Therefore, conventionally, it is necessary to perform machining (flattening treatment) on the surface of the secondary conductor in order to make the thickness of the secondary conductor uniform. In addition, since the secondary conductor is formed thicker and removed by machining in consideration of the planarization of the secondary conductor, an extra material is required.

Japanese Utility Model Publication No. 45-29650 JP 2016-62681 A

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above problems, and its main object is to reduce uneven heat generation caused by overlay-welded secondary conductors without relying on machining.

That is, an induction heating roller device according to the present invention comprises a roller body rotatably supported, and an induction heating mechanism provided inside the roller body and having an induction coil for inducing heat generation in the roller body, An induction heating roller device for generating induction heat in the roller body by applying an AC voltage of commercial frequency to the induction coil, the jacket having a gas-liquid two-phase heating medium enclosed under reduced pressure within the thickness of the roller body. A chamber is formed, and a secondary conductor is formed on the inner peripheral surface of the roller body by overlay welding, the secondary conductor is made of copper or a copper alloy, and the surface of the secondary conductor is subjected to removal processing. It is characterized in that it is not subjected to planarization treatment by

In the present invention, since the secondary conductor is formed by build-up welding, the conventional tubular body forming process and tubular body mounting process can be omitted. As a result, it is possible to reduce the processing steps required to provide the secondary conductor on the inner peripheral surface of the roller body. In addition, only overlay welding is required, and the operation of attaching the secondary conductor to the inner peripheral surface of the roller body can be facilitated. Furthermore, since the secondary conductor is formed by overlay welding, the roller body and the secondary conductor are integrated and can be applied to high-speed rotation. There is no slack, and a decrease in thermal conductivity between the roller body and the secondary conductor can be suppressed.

The copper or copper alloy that has been build-up welded has some thickness unevenness in the circumferential direction and particularly in the width direction. However, if the weight of the copper or copper alloy to be welded is controlled, the average thickness in the winding width of the induction coil can be manufactured as calculated. As a result, it becomes possible to manufacture electric capacity and power factor as designed.

Further, if a jacket chamber in which a gas-liquid two-phase heat medium is decompressed is formed within the thickness of the roller body, even if uneven heat generation occurs due to uneven thickness of the copper or copper alloy, the jacket chamber The surface temperature of the roller body becomes a uniform temperature due to the uniform temperature action. Therefore, no machining is required to make the thickness of the secondary conductor uniform. In other words, there is no need to apply planarization treatment by removal processing to the surface of the secondary conductor. As a result, processing of the secondary conductor can be reduced, and unnecessary materials can be eliminated because the secondary conductor is not removed.

Here, the thickness of the copper or copper alloy to be overlay-welded is preferably a thickness for obtaining a target power factor (for example, 80% or more), and an equivalent electric circuit diagram ( (see FIG. 4) can be used for calculation.

The jacket chamber within the thickness of the roller body is formed by drilling holes along the axial direction from the end face of the roller body to form a drill hole within the thickness of the roller body and closing the opening of the drill hole. It is formed. Here, since the roller body has a long axial dimension, the drilled hole does not go straight and bends. In the case of a roller body with a small wall thickness, the drill may penetrate the surface or inner peripheral surface of the roller body and must be remade. In some cases, the surface of the roller body is subjected to a hardening treatment such as induction hardening in order to extend its service life.
By the way, when the secondary conductor is build-up welded to the inner peripheral surface of the roller body, the structure consists of the weld metal, the bond, the heat affected zone, and the base material raw part from the outside. The bond refers to the boundary line between the weld metal and the base metal, and the heat-affected zone is a few mm on the base metal side of the bond. When the arc passes through the heat-affected zone, which has reached a high temperature due to the welding heat, the temperature begins to drop rapidly and is rapidly cooled. This heating and rapid cooling causes the structure to differ from that of the original base material, resulting in increased hardness. . When copper or copper alloy is built up and welded, the hardness of the inner peripheral surface of the roller body increases, so the drill hole is less likely to bend toward the inner peripheral surface, and the drill hole penetrates the inner peripheral surface of the roller body. Such problems can be reduced.

In order to further improve the power factor of the induction heating roller device, it is preferable that the secondary conductor has a cylindrical shape continuously formed from one end portion to the other end portion in the axial direction of the roller body. desirable.

At high temperatures, copper is oxidized and becomes an oxide, which changes its electrical properties and changes its induction heating properties. Also, many types of copper alloys tend to oxidize at high temperatures. For this reason, it is desirable that the surface of the secondary conductor is subjected to antirust treatment.

As this antirust treatment, it is desirable to form a coating of metal or ceramics that can withstand the temperature of the roller body to be used and is not easily oxidized at that temperature. For example, if nickel plating is applied, it can be used up to about 400.degree.

Since the magnetic flux generated by the induction coil in the induction heating is concentrated at the center of the coil, the temperature of the roller body tends to be higher at the center in the axial direction. On the other hand, since the portion where the secondary conductor is thickly built up has a low resistance, a large current flows and a large amount of heat is generated. Therefore, if the portion corresponding to the end portion of the winding width of the induction coil is thickly overlaid, the amount of heat generated in the roller body can be made uniform in the axial direction. Also, by adjusting the build-up thickness, it is possible to partially increase or decrease the amount of heat generated in the roller body. For this purpose, it is desirable to change the thickness of the secondary conductor along the axial direction of the roller body.

It is desirable that the secondary conductors are formed in a ring shape at intervals on the inner peripheral surface of the roller body. Forming the secondary conductors at intervals in this manner facilitates the processing thereof.

In order to facilitate continuous processing of the secondary conductor while particularly facilitating processing of the secondary conductor, the secondary conductor is formed in a spiral shape at intervals on the inner peripheral surface of the roller body. is desirable.

In order to make the electrical characteristics of each induction heating roller device the same, it is desirable that the electrical characteristics of the induction heating roller device are adjusted by the weight of the secondary conductor. For example, if the specifications of each roller body are the same, by making the weight of the secondary conductors to be processed the same, the power factor and the electric capacity become the same, and the work management is extremely easy.

According to the present invention configured as described above, heat generation unevenness caused by the overlay-welded secondary conductor can be reduced without relying on machining.

1 is a diagram schematically showing the configuration of an induction heating roller device according to this embodiment; FIG. FIG. 4 is a cross-sectional view schematically showing a formation pattern of secondary conductors according to the same embodiment. It is a schematic diagram which shows the formation method of the secondary conductor which concerns on the same embodiment. 1 is an equivalent electric circuit diagram of an induction heating roller device; FIG. FIG. 10 is a cross-sectional view schematically showing a formation pattern of secondary conductors according to a modified embodiment; FIG. 10 is a cross-sectional view schematically showing a formation pattern of secondary conductors according to a modified embodiment;

An embodiment of an induction heating roller device according to the present invention will be described below with reference to the drawings.

The induction heating roller device 100 according to the present embodiment can be used, for example, in a continuous heat treatment process for continuous materials such as sheet materials such as plastic films, paper, cloth, non-woven fabrics, synthetic fibers, and metal foils, web materials, and wire (thread) materials. It is used.

<1. Device configuration>
Specifically, as shown in FIG. 1, this apparatus comprises a hollow cylindrical roller body 2 supported rotatably and an induction heating mechanism 3 provided inside the roller body 2 .

Hollow drive shafts 21 are provided at both ends of the roller body 2 , and the drive shafts 21 are rotatably supported by a machine base 9 via bearings 8 such as rolling bearings. The drive shaft 21 has a flange 211 connected to the axial end face of the roller body 2 (see FIG. 2). The roller body 2 including the drive shaft 21 is made of a magnetic material such as carbon steel. The roller body 2 is configured to be rotated by a driving force externally applied by a rotation driving mechanism (not shown) such as a motor. A jacket chamber 2A in which a gas-liquid two-phase heat medium is sealed under reduced pressure is formed in the side peripheral wall 201, which is the thick portion of the roller body 2 of the present embodiment. The jacket chambers 2A extend in the longitudinal direction (rotational axis direction) in the side peripheral wall 201, and are formed in plural at regular intervals in the circumferential direction.

The induction heating mechanism 3 includes a cylindrical iron core 31 having a cylindrical shape and an induction coil 32 wound around the outer peripheral surface of the cylindrical iron core 31 .

Support shafts 33 are provided at both ends of the cylindrical iron core 31, and the support shafts 33 are inserted through the drive shaft 21 and are rotatable on the drive shaft 21 via bearings 10 such as rolling bearings. supported by As a result, the induction heating mechanism 3 is held stationary with respect to the base 9 (fixed side) inside the rotating roller body 2 .

An external lead wire L1 is connected to the induction coil 32, and a power supply device 5 is connected to the external lead wire L1 for applying AC voltage of commercial frequency (50 Hz or 60 Hz). The power supply device 5 has a power supply section 51 that supplies AC power to the induction heating mechanism 3 and a temperature control section 52 that controls the temperature of the roller body 2 by controlling the power supply section 51 . The temperature control unit 52 is a dedicated or general-purpose computer having a CPU, an internal memory, an input/output interface, an AD converter, etc., and controls the power supply unit 51 based on a set temperature signal input by the user to control the rollers. It controls the surface temperature of the main body 2 so as to be the set temperature. Note that the temperature control unit 52 may be configured by an analog circuit.

When an AC voltage is applied to the induction coil 32 , an alternating magnetic flux is generated by the induction heating mechanism 3 , and the alternating magnetic flux passes through the side wall 201 of the roller body 2 . Due to this passage, an induced current is generated in the roller body 2, and the induced current causes the roller body 2 to generate Joule heat. Moreover, the temperature distribution of the side peripheral wall 201 of the roller body 2 in the rotation axis direction becomes uniform due to the jacket chamber 2A.

Thus, the secondary conductor 4 is formed on the inner peripheral surface of the roller main body 2 of this embodiment by build-up welding. Here, the material (cladding material) of the secondary conductor 4 is copper or a copper alloy. Examples of copper alloys include non-magnetic copper alloys with high corrosion resistance, such as aluminum bronze (alloy of aluminum and copper), cupronickel (cupronickel, alloy of copper and nickel), nickel silver (nickel silver, alloy of copper, zinc and nickel). ), red copper (an alloy of copper and gold), gunmetal (a gunmetal, an alloy of copper and tin), or combinations thereof.

Specifically, the secondary conductor 4 is formed on the inner peripheral surface 201 a of the roller body 2 over the entire circumferential direction, and is formed continuously along the rotation axis direction of the roller body 2 .

Here, the secondary conductor 4 is formed in a helical shape (spiral shape), and is formed so that welded portions adjacent to each other are in contact with each other and are continuous. That is, it is formed continuously over the entire winding width of the induction coil 32 in the rotation axis direction of the roller body 2 . In other words, the secondary conductor 4 has a cylindrical shape formed along the rotation axis direction of the roller body 2 . Further, the surface of the secondary conductor 4 configured in this manner is subjected to antirust treatment. Examples of the rust-preventive treatment include plating such as nickel plating and vapor deposition such as aluminum vapor deposition.

Next, an example of build-up welding work for forming the secondary conductor 4 on the inner peripheral surface 201a of the roller body 2 will be described with reference to FIG.
The roller body 2 is mounted on a rotating device 11 that rotates the roller body 2 . The welding torch 12 is inserted into the roller body 2 in this state, and while the roller body 2 is being rotated by the rotating device 11, the welding torch 12 is relatively moved with respect to the roller body 2 in the direction of the rotation axis. A shaped secondary conductor 4 is formed on the inner peripheral surface 201 a of the roller body 2 . In this overlay welding, welding pretreatment conditions such as preheating of the roller body 2, size and material of the welding wire, torch angle, torch position, voltage, current, rotation speed of the roller body 2, moving speed of the welding torch 12 (pulling Various secondary conductors 4 can be formed by appropriately setting welding conditions such as pitch) and post-welding treatment conditions such as post-heating of the roller body 2 . After that, the surface of the secondary conductor 4 is subjected to antirust treatment.

In addition, since the jacket chamber 2A is formed in the side peripheral wall 201 of the roller body 3, the surface temperature of the roller body 3 is maintained even if heat generation is uneven due to uneven thickness of the copper or copper alloy. becomes a uniform temperature. Therefore, in this embodiment, machining for making the thickness of the secondary conductor 4 uniform is not required. In other words, the surface of the secondary conductor 4 is not planarized by removal processing for removing the protrusions.

Next, the results of the power factor test of the induction heating roller device are shown. The roller body used in this test has a diameter of 237 mm, a face length of 400 mm, and a wall thickness of 22 m. Thirty jacket chambers each having a diameter of 10 mm and a length of 380 mm are arranged at regular intervals in the center of the roller body having a thickness of 22 mm. The axial width of the secondary conductor is 380 mm. The electrical specifications are that the input is single phase 60 Hz 220 V and the capacity is 5 kW with no secondary conductors.

Table 1 below shows the power factor in the case of no build-up and the case of copper build-up welding (build-up thicknesses of 0.5 mm, 1.0 mm, and 1.5 mm). Note that the build-up thickness (mm) is an average value in the axial direction.

As can be seen from Table 1, by forming the secondary conductor 4 by build-up welding of copper, the power factor is improved compared to the case where build-up welding is not performed, and the target power factor (80%) That's it. Also, the build-up thickness at which the target power factor (80%) or more can be calculated using an equivalent circuit diagram for induction heating at commercial frequencies.

In this induction heating roller device 100, the temperature that can be set by the temperature control section 52 is set to 500° C. or less, for example. In other words, it is configured such that the user cannot set the temperature higher than 500°C. This settable temperature is determined according to the type of antirust treatment applied to the surface of the secondary conductor 4 . For example, if the antirust treatment is nickel plating, the settable temperature is 400° C. or less, and if the antirust treatment is aluminum vapor deposition, the settable temperature is 500° C. or less.

<2. Effect of the present embodiment>
According to the induction heating roller device 100 configured as described above, since the secondary conductor 4 is formed by build-up welding, the conventional tubular body forming process and tubular body mounting process can be omitted. As a result, the number of processing steps required to provide the secondary conductor 4 on the inner peripheral surface 201a of the roller body 2 can be reduced. In addition, only overlay welding is required, and the operation of attaching the secondary conductor 4 to the inner peripheral surface 201a of the roller body 2 can be facilitated. Furthermore, since the secondary conductor 4 is formed by build-up welding, the roller body 2 and the secondary conductor 4 are integrated and can be applied to high-speed rotation. There is no looseness due to the difference in expansion coefficient, and a decrease in thermal conductivity between the roller body 2 and the secondary conductor 4 can be suppressed.

Further, if the jacket chamber 2A in which the gas-liquid two-phase heat medium is decompressed is formed within the thickness of the roller body 2, even if uneven heat generation occurs due to uneven thickness of the copper or copper alloy, the jacket The surface temperature of the roller body 2 becomes uniform due to the uniform temperature action of the chamber 2A. Therefore, machining for making the thickness of the secondary conductor 4 uniform is not required. In other words, it is not necessary to apply a flattening treatment by removal processing to the surface of the secondary conductor 4 . As a result, the processing of the secondary conductor 4 can be reduced, and since the secondary conductor 4 is not removed, unnecessary materials can be eliminated.

<3. Modified Embodiment of the Present Invention>
It should be noted that the present invention is not limited to the above embodiments.

For example, the secondary conductor 4 may have a thickness adjusted along the rotation axis direction of the roller body 2 . That is, the thickness of the secondary conductor 4 may be varied along the rotation axis direction of the roller body 2 . With this configuration, the amount of heat generated in the roller body 2 can be partially increased or decreased.

Furthermore, the secondary conductor is formed in an annular shape on the inner peripheral surface of the roller body, and may be formed in a plurality continuously in the rotation axis direction of the roller body.

Moreover, a plurality of secondary conductors may be intermittently formed in the rotation axis direction of the roller body. For example, as shown in FIG. 5, the secondary conductor 4 may be formed in a ring shape with a gap on the inner peripheral surface 201a of the roller body 2, or as shown in FIG. The secondary conductors 4 may be spirally formed on the inner peripheral surface 201a of the roller body 2 at intervals. By forming the secondary conductors 4 at intervals in this manner, the processing can be facilitated compared to the processing of forming them continuously. Moreover, as shown in FIG. 6, the secondary conductor 4 can be continuously processed by forming it in a spiral shape.

Additionally, the electrical properties of the induction heating roller device can be adjusted by the weight of the secondary conductor. For example, if the specifications of each roller body are the same, by making the weight of the secondary conductors to be processed the same, the power factor and the electric capacity become the same, and the work management is extremely easy. The following table shows the electrical properties when the weight of the secondary conductor is the same, and it can be seen that the electrical properties are substantially the same if the weight of the secondary conductor is the same. In the following, the dimensions of the roll body are 300 mm in diameter, 280 mm in inner diameter, and 189 mm in face length, the secondary conductor is pure copper, and its weight is about 800 g.

In addition, the present invention is not limited to the above-described embodiments, and it goes without saying that various modifications are possible without departing from the spirit of the present invention.

DESCRIPTION OF SYMBOLS 100... Induction-heating roller apparatus 2... Roller body 201a... Inner peripheral surface 3... Induction-heating mechanism 32... Induction coil 4... Secondary conductor

Claims (6)

A roller body rotatably supported; and an induction heating mechanism provided inside the roller body and having an induction coil for inducing heat generation in the roller body, and applying a commercial frequency AC voltage to the induction coil. A method for manufacturing an induction heating roller device in which the roller body is induction-heated by
Forming a secondary conductor made of copper or a copper alloy on the inner peripheral surface of the roller body by overlay welding,
forming a drill hole by drilling along the axial direction from the end surface of the roller body within the thickness of the roller body in which the secondary conductor is formed on the inner peripheral surface;
A jacket chamber is formed in which a gas-liquid two-phase heat medium is sealed under reduced pressure by closing the opening of the drill hole,
A method of manufacturing an induction heating roller device, wherein the surface of the secondary conductor is not flattened by removal processing. 2. The method of manufacturing an induction heating roller device according to claim 1, wherein the secondary conductor is formed continuously from one axial end portion to the other axial end portion of the roller body to have a cylindrical shape. 3. The method of manufacturing an induction heating roller device according to claim 1, wherein the surface of said secondary conductor is subjected to antirust treatment. 4. The method of manufacturing an induction heating roller device according to claim 1, wherein the thickness of said secondary conductor is varied along the axial direction of said roller body. 5. The method of manufacturing an induction heating roller device according to claim 1, wherein the secondary conductor is formed in a ring shape with a space on the inner peripheral surface of the roller body. 5. The method of manufacturing an induction heating roller device according to claim 1, wherein the secondary conductor is spirally formed on the inner peripheral surface of the roller body with a space therebetween.

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