JP7195604B2 - Induction heating roller device - Google Patents

Description

The present invention relates to an induction heating roller device.

As a conventional induction heating roller device, there is one in which a jacket chamber in which a gas-liquid two-phase heat medium is enclosed is provided in the side peripheral wall of a roller body that generates heat by induction, as shown in Japanese Unexamined Patent Application Publication No. 2002-100000. A jacket chamber in which a heat medium is enclosed functions as a heat pipe, and the temperature of the side peripheral wall of the roller body is made uniform.

By the way, at one axial end of the conventional jacket chamber, when the temperature of the side peripheral wall of the roller body rises abnormally and the steam pressure in the jacket chamber rises above a predetermined value, the pressure damages the roller body. A relief plug is provided to relieve pressure. Specifically, the jacket chamber is configured by an axially extending jacket chamber formed in the side peripheral wall of the roller body, and a relief plug is provided so as to close one end of the drill hole.

However, in the above configuration, the jacket chamber and the relief plug are provided coaxially, and the radial position of the roller body is the same for the jacket chamber and the relief plug. The temperature of the side peripheral wall of the roller body and the mounting temperature of the relief plug will become substantially equal. Therefore, the temperature of the side peripheral wall of the roller body is restricted by the temperature required to reliably operate the relief plug. In particular, when the relief plug is made of a soluble metal that melts at a predetermined temperature, and the pressure is released when the soluble metal melts, the heating temperature of the side peripheral wall of the roller body depends on the melting temperature of the soluble metal. be restricted.

JP-A-2001-23765

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above problems, and its main object is to make the heating temperature of the side peripheral wall of the roller body less likely to be restricted by the relief plug.

That is, an induction heating roller device according to the present invention includes 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. In the roller device, a jacket chamber in which a gas-liquid two-phase heat medium is enclosed is formed in the side peripheral wall of the roller body, and pressure is released from the jacket chamber to the end plate portion at the axial end of the roller body. A relief plug is provided in order to reduce the pressure, and the relief plug is provided radially inward of the jacket chamber in the end plate portion.

According to such an induction heating roller device, since the relief plug is provided radially inward of the jacket chamber in the end plate portion of the roller body, the heating temperature of the side peripheral wall of the roller body that is induced-heated by the induction heating mechanism is The temperature of the relief plug can be made lower than As a result, the heating temperature of the side peripheral wall of the roller body is less likely to be restricted by the relief plug, and the heating temperature of the side peripheral wall of the roller body can be set higher than the operating temperature of the relief plug.

As a specific mounting position of the relief plug, it is desirable that the end plate portion is provided in a region radially inward of the radially inner end of the jacket chamber.
With this configuration, the relief plug and the jacket chamber are provided radially inward so that they do not overlap when viewed from the axial direction. A relief plug will be attached at a distance. As a result, the heating temperature of the side peripheral wall of the roller body can be further prevented from being restricted by the relief plug.

It is desirable that the relief plug is made of a soluble metal that melts at a predetermined temperature, and releases pressure from the jacket chamber by melting the soluble metal.
With this configuration, the relief plug can be miniaturized, and an increase in the size of the roll body can be avoided. In addition, it is possible to increase the degree of freedom in the installation location of the relief plug, and it is possible to easily install the relief plug radially inward of the jacket chamber in the end plate portion of the roller body.

Specifically, it is desirable that the relief plug is provided at a position where the soluble metal does not melt even when the temperature of the side peripheral wall of the roller body reaches a temperature higher than the melting temperature of the soluble metal.
Thereby, the heating temperature of the side peripheral wall of the roller body can be set to a temperature higher than the melting temperature of the soluble metal.

When water is used as the heat medium, it is necessary to operate the side wall of the roller body at a temperature lower than the critical temperature of water (approximately 374° C.).
For this reason, it is desirable that the relief plug is provided at a position where the soluble metal melts when the side peripheral wall of the roller body reaches the critical temperature of water or a temperature just before that.
With this configuration, the pressure is released by the relief plug when the side peripheral wall of the roller body reaches the critical temperature of water or a temperature just before that.

In order to facilitate the filling of the heat medium in the jacket chamber of the roller body and the replacement of the heat medium, the relief plug is provided separately from the filling port for filling the heat medium in the jacket chamber. It is desirable to be
With this configuration, it is not necessary to give the sealing plug provided in the sealing port a function as a relief plug, so an inexpensive sealing plug can be used.

In order to ensure the safety of the surrounding environment when the pressure of the relief plug is released, it is desirable that a protective plate is provided outside the relief plug to block the heat medium vapor when the pressure is released by the relief plug.

In order to further ensure the safety of the surrounding environment when the pressure of the relief plug is released, the end plate portion provided with the relief plug is provided with a heating medium vapor that flows inside the roller body when the pressure is released by the relief plug. It is desirable that a channel for guiding is formed.

In order to determine whether or not the pressure of the relief plug is released, a plurality of temperature sensors are provided on the side peripheral wall of the roller body at different positions in the axial direction. It is desirable to provide a judgment part for judging whether or not the relief plug is operated based on the above.

According to the present invention configured as described above, since the relief plug is provided radially inward of the jacket chamber in the end plate portion of the roller body, the heating temperature of the side peripheral wall of the roller body is higher than the operating temperature of the relief plug. A higher temperature can be set. Further, when the temperature of the side peripheral wall of the roller body rises to, for example, the critical temperature of water or higher, the relief plug operates to release the steam pressure in the jacket chamber, thereby preventing damage to the roll body.

1 is a cross-sectional view schematically showing the configuration of a double-supported induction heating roller device according to a first embodiment; FIG. It is a partially enlarged cross-sectional view showing the end plate portion of the roll body according to the same embodiment. FIG. 4 is a schematic diagram showing the positional relationship between the jacket chamber and the relief plug according to the same embodiment as seen from the axial direction; FIG. 10 is a cross-sectional view schematically showing the configuration of a cantilevered induction heating roller device according to a second embodiment; It is a partially enlarged cross-sectional view showing the end plate portion and the open end portion of the roll body according to the same embodiment. It is a schematic diagram which shows the modification of a pressure release path. FIG. 5 is a schematic diagram showing an example in which a protection plate is provided on the end plate portion of the roll body; 1 is a schematic diagram showing a system for detecting operation of a relief plug; FIG.

<First embodiment>
A first 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.

Specifically, as shown in FIG. 1, the induction heating roller device includes a roller body 2 that is rotatably supported, and an induction heating mechanism 3 that is provided inside the roller body 2 and causes the roller body 2 to generate heat by induction. , which supports the roller body 2 from both sides in the axial direction.

The roller body 2 includes a cylindrical roll shell portion 2a, journal portions 2b provided at both ends in the axial direction of the roll shell portion 2a and serving as end plate portions for closing openings at both ends of the roll shell portion 2a, and journals It has a hollow drive shaft portion 2c extending from the portion 2b on the rotation center axis of the roll shell portion 2a outside the roll shell portion 2a. The drive shaft portion 2c is rotatably supported by a machine base 5 via a bearing 4 such as a rolling bearing. 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. The roller body 2 is provided with a temperature sensor (not shown) for detecting the temperature of the roll shell portion 2a.

The induction heating mechanism 3 includes, for example, a cylindrical iron core 31 and an induction coil 32 wound around the outer peripheral surface of the iron core 31 . A support shaft 6 is attached to each end of the core 31 . The support shafts 6 are inserted through the drive shaft portion 2c, respectively, and are rotatably supported with respect to the drive shaft portion 2c via bearings 7 such as rolling bearings. As a result, the induction heating mechanism 3 is held stationary with respect to the roller body 2 inside the rotating roller body 2 . A lead wire L1 is connected to the induction coil 32, and an AC power supply V for applying an AC voltage is connected to the lead wire L1.

When an AC voltage is applied to the induction coil 32, the induction heating mechanism 3 generates an alternating magnetic flux, which passes through the roll shell portion 2a, which is the side peripheral wall of the roller body 2. As shown in FIG. Due to this passage, an induced current is generated in the roll shell portion 2a, and the induced current causes Joule heat in the roll shell portion 2a. At this time, the temperature of the roll shell portion 2a is feedback-controlled based on the temperature detected by the temperature sensor.

In the induction heating roller device 100 of the present embodiment, the roll shell portion 2a of the roller body 2 is formed with a jacket chamber 21 in which a gas-liquid two-phase heat medium is sealed. A relief plug 8 for releasing the pressure in the jacket chamber 21 is provided on the journal portion 2b which is the end plate portion of the end portion. The heat medium of the present embodiment is, for example, water such as pure water, but is not limited to this.

A plurality of jacket chambers 21 are formed in the roll shell portion 2a of the roller body 2 along the axial direction. A plurality of jacket chambers 21 are provided, for example, at regular intervals in the circumferential direction of the roll shell portion 2a. Also, the plurality of jacket chambers 21 are configured to communicate with each other through a communicating passage 22 at at least one axial end. Thereby, the heat medium can flow from one jacket chamber 21 to another jacket chamber 21 . Note that the plurality of jacket chambers 21 may not be configured to communicate with each other, and may be independent one by one.

In addition, as shown in FIG. 2, the jacket chamber 21 is connected to a sealing passage 23 for sealing a heat medium. The enclosing passage 23 is formed in the journal portion 2b of the roller main body 2, and the sealing plug 9 is provided at the opening (enclosing port 23H) of the enclosing passage 23. As shown in FIG. The sealing plug 9 is removed from the sealing port 23H when the heat medium is sealed in the jacket chamber 21, and is attached to the sealing port 23H after the heat medium is sealed in the jacket chamber 21. FIG.

The relief plug 8 releases the pressure in the jacket chamber 21 when the pressure in the jacket chamber 21 exceeds a predetermined pressure. In this embodiment, pressure rise and temperature rise correspond to each other according to the equation of state of gas. A pressure relief plug is used. Specifically, the relief plug 8 is made of a soluble metal 81 such as solder that melts at a predetermined temperature, and releases the pressure in the jacket chamber 21 by melting the soluble metal 81 . The relief plug 8 has an internal passage filled with a soluble metal 81 for releasing pressure. It is configured such that the road is open.

The relief plug 8 is provided in a pressure release passage 10 communicating with the jacket chamber 21, as shown in FIG. The pressure release path 10 is formed in the journal portion 2b of the roller body 2, and the relief plug 8 is provided in the journal portion 2b of the roller body 2. As shown in FIG. The pressure release path 10 of this embodiment is connected to the sealing path 23 at the journal portion 2b. The enclosure path 23 is formed coaxially with the jacket chamber 21, and the pressure release path 10 is connected to the enclosure path 23 at the journal portion 2b so as to be perpendicular to the enclosure path 23, for example. As described above, the relief plug 8 of the present embodiment is provided separately from the sealing port 23H for sealing the heat medium in the jacket chamber 21 (specifically, at different radial positions in the same journal portion 2b). Configuration. Alternatively, the sealing port 23H may be provided in one journal portion 2b in the axial direction, and the relief plug 8 may be provided in the other journal portion 2b in the axial direction.

3, the relief plug 8 is provided radially inside the jacket chamber 21 in the journal portion 2b of the roller body 2. As shown in FIG. That is, the relief plug 8 is provided radially inward of the jacket chamber 21 when viewed from the axial direction. Specifically, the relief plug 8 is provided in a region R1 (mesh portion) radially inward of the radially inner end 21x of the jacket chamber 21 in the journal portion 2b.

The relief plug 8 is provided at a position where the soluble metal 81 does not melt even when the temperature of the roll shell portion 2a of the roller body 2 reaches a temperature higher than the melting temperature of the soluble metal 81 . Further, in the present embodiment, water is used as the heat medium, so that the relief plug 8 is designed so that the soluble metal 81 will not dissipate when the roll shell portion 2a of the roller body 2 reaches the critical temperature of water or a temperature just before that. It is provided in a position where it melts. With this configuration, the roll shell portion 2a can be used in a temperature range equal to or higher than the melting temperature of the soluble metal 81 and lower than the critical temperature of water.

<Effects of the first embodiment>
According to the double-supported induction heating roller device 100 configured as described above, the relief plug 8 is provided radially inward of the jacket chamber 21 in the journal portion 2b, which is the end plate portion of the roller body 2. The temperature of the relief plug 8 can be made lower than the heating temperature of the roll shell portion 2a of the roller body 2 which is induced-heated by the heating mechanism 3 . As a result, the heating temperature of the roll shell portion 2a of the roller body 2 is less likely to be restricted by the relief plug 8, and the heating temperature of the roll shell portion 2a can be set to a temperature higher than the operating temperature of the relief plug 8. can be done. Specifically, the heating temperature of the roll shell portion 2 a of the roller body 2 can be set to a temperature higher than the melting temperature of the soluble metal 81 .

Further, since the relief plug 8 is provided at a position different from the filling port 23H, it is possible to easily fill the heat medium into the jacket chamber 21 of the roller body 2 and replace the heat medium. Furthermore, since the sealing plug 9 provided in the sealing port 23H does not need to have a pressure releasing function, an inexpensive sealing plug 9 can be used.

<Second embodiment>
Next, a second embodiment of the induction heating roller device according to the present invention will be described with reference to the drawings.

The induction heating roller device 100 according to the present embodiment is, like the first embodiment, made of sheet material such as plastic film, paper, cloth, non-woven fabric, synthetic fiber, metal foil, web material, wire (thread) material, or the like. It is used in the continuous heat treatment process of the continuous material.

Specifically, as shown in FIG. 4, the induction heating roller device 100 includes a roller body 2 that is rotatably supported, and an induction heating mechanism 3 that is provided inside the roller body 2 and causes the roller body 2 to generate heat by induction. It is of a so-called cantilever type that supports the roller body 2 from one side in the axial direction.

The roller main body 2 includes a cylindrical roll shell portion 2a, a flange portion 2d provided at one axial end portion of the roll shell portion 2a and serving as a end plate portion that closes the one end opening of the roll shell portion 2a, and the roll shell portion 2a. It has a boss portion 2e extending from the flange portion 2d in the roll shell portion 2a on the rotation center axis of the roll shell portion 2a.

A shaft fitting portion 2f is provided on the boss portion 2e, and a rotation support shaft 11 for rotatably supporting the roller body 2 is fitted and fastened to the shaft fitting portion 2f by bolts and nuts. ing. The rotation support shaft 11 is rotatably supported by a fixed base 13 via a bearing 12, and is rotated by a rotation drive mechanism (not shown) such as a motor. In this embodiment, the fixed base 13 may be configured by a drive mechanism such as a motor, or a drive mechanism may be provided separately from the fixed base 13 . This drive mechanism can rotate the roller body 2 and the rotation support shaft 11 . In this embodiment, the rotation support shaft 11 is rotatably supported on the fixed table 13, but the present invention is not limited to this.

The induction heating mechanism 3 includes a cylindrical iron core 31 and an induction coil 32 wound around the iron core 31 , and is supported by the support 14 . The support 14 is held stationary on the fixed table 13 . A lead wire L1 is connected to the induction coil 32, and an AC power supply V for applying an AC voltage is connected to the lead wire L1.

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 roll shell portion 2 a of the roller body 2 . Due to this passage, an induced current is generated in the roll shell portion 2a, and the induced current causes the roll shell portion 2a to generate Joule heat. At this time, the temperature of the roll shell portion 2a is feedback-controlled based on the temperature detected by a temperature sensor (not shown) that detects the temperature of the roll shell portion 2a.

In the induction heating roller device 100 of the present embodiment, as shown in FIG. 4, the roll shell portion 2a of the roller body 2 is formed with a jacket chamber 21 in which a gas-liquid two-phase heat medium is enclosed. A relief plug 8 for releasing pressure from the jacket chamber 21 is provided on the flange portion 2d at one axial end of the roller body 2. As shown in FIG. The heat medium of the present embodiment is, for example, water such as pure water, but is not limited to this.

A plurality of jacket chambers 21 are formed in the roll shell portion 2a of the roller body 2 along the axial direction. A plurality of jacket chambers 21 are provided, for example, at regular intervals in the circumferential direction of the roll shell portion 2a. Also, the plurality of jacket chambers 21 are configured to communicate with each other through a communicating passage 22 at at least one axial end. Thereby, the heat medium can flow from one jacket chamber 21 to another jacket chamber 21 . Note that the plurality of jacket chambers 21 may not be configured to communicate with each other, and may be independent one by one.

In addition, as shown in FIG. 5, the jacket chamber 21 is connected to a sealing passage 23 for sealing a heat medium. The sealing path 23 is formed at one axial end of the roller body 2, and a sealing plug 9 is provided at the opening of the sealing path 23 (sealing port 23H). The sealing plug 9 is removed from the sealing port 23H when the heat medium is sealed in the jacket chamber 21, and is attached to the sealing port 23H after the heat medium is sealed in the jacket chamber 21. FIG.

The relief plug 8 releases the pressure in the jacket chamber 21 when the pressure in the jacket chamber 21 exceeds a predetermined pressure. Similar to the first embodiment, the relief plug 8 of this embodiment is a plug that releases pressure from the jacket chamber 21 when the temperature of the roll shell portion 2a of the roller body 2 or the jacket chamber 21 exceeds a predetermined temperature. is used. Specifically, the relief plug 8 is made of a soluble metal 81 such as solder that melts at a predetermined temperature, and releases the pressure in the jacket chamber 21 by melting the soluble metal 81 . The relief plug 8 has an internal passage filled with a soluble metal 81 for releasing pressure. It is configured such that the road is open.

The relief plug 8 is provided in a pressure release passage 10 communicating with the jacket chamber 21, as shown in FIG. The pressure release path 10 is formed in the flange portion 2d of the roller body 2, and the relief plug 8 is provided in the flange portion 2d of the roller body 2. As shown in FIG. The pressure release path 10 of this embodiment is connected to the jacket chamber 21 . The pressure release path 10 is connected to the jacket chamber 21 at the flange portion 2d so as to be inclined, for example. As described above, the relief plug 8 of the present embodiment is provided separately from the inlet 23H for enclosing the heat medium in the jacket chamber 21 (specifically, on the side opposite to the inlet 23H in the axial direction). is. When the relief plug 8 and the sealing port 23H are provided in the flange portion 2d, they may be provided at different radial positions in the flange portion 2d.

The relief plug 8 is provided radially inward of the jacket chamber 21 at the flange portion 2d of the roller body 2 (see FIG. 3). That is, the relief plug 8 is provided radially inward of the jacket chamber 21 when viewed in the axial direction. Specifically, the relief plug 8 is provided in a region R1 of the flange portion 2d of the roller body 2, which is radially inner than the radially inner end 21x of the jacket chamber 21. As shown in FIG.

The relief plug 8 is provided at a position where the soluble metal 81 does not melt even when the temperature of the roll shell portion 2a of the roller body 2 reaches a temperature higher than the melting temperature of the soluble metal 81 . Further, in the present embodiment, water is used as the heat medium, so that the relief plug 8 is designed so that the soluble metal 81 will not dissipate when the roll shell portion 2a of the roller body 2 reaches the critical temperature of water or a temperature just before that. It is provided in a position where it melts. With this configuration, the roll shell portion 2a can be used in a temperature range equal to or higher than the melting temperature of the soluble metal 81 and lower than the critical temperature of water.

<Effects of Second Embodiment>
According to the cantilever type induction heating roller device 100 configured as described above, the relief plug 8 is provided radially inward of the jacket chamber 21 in the flange portion 2d which is the end plate portion of the roller body 2. The temperature of the relief plug 8 can be made lower than the heating temperature of the roll shell portion 2a of the roller body 2 which is induced-heated by the heating mechanism 3 . As a result, the heating temperature of the roll shell portion 2a of the roller body 2 is less likely to be restricted by the relief plug 8, and the heating temperature of the roll shell portion 2a can be set to a temperature higher than the operating temperature of the relief plug 8. can be done.

Further, since the relief plug 8 is provided at a position different from the filling port 23H, it is possible to easily fill the heat medium into the jacket chamber 21 of the roller body 2 and replace the heat medium. Furthermore, since the sealing plug 9 provided in the sealing port 23H does not need to have a pressure releasing function, an inexpensive sealing plug 9 can be used.

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

For example, in each of the above embodiments, the sealing plug 9 and the relief plug 8 are separately provided as separate members, but a single plug having the functions of the sealing plug 9 and the relief plug 8 may be used. good. Even in this case, the relief plug 8 is located radially inward of the jacket chamber 21 at the end plate portion (journal portion 2b or flange portion 2d). Also, the pressure release path 10 provided with the relief plug 8 functions as a sealing path when the heat medium is sealed.

Further, in each of the above-described embodiments, the pressure releasing direction of the relief plug 8 was the outside of the roller body 2, but as shown in FIG. . In this case, in the case of the double-supported roller body 2, the relief plug 8 is provided on the inner wall surface of the journal portion 2b, and in the case of the cantilevered roller body 2, it is provided on the inner wall surface of the flange portion 2d. The configuration is such that a relief plug 8 is provided. With this configuration, it is possible to prevent the high-temperature heat-medium vapor spouting when the relief plug 8 is released from leaking to the outside of the roller body 2, thereby ensuring the safety of the surrounding environment.

Furthermore, when the relief plug 8 is provided on the outer wall surface of the end plate portion (journal portion 2b or flange portion 2d), as shown in FIG. A configuration in which a protection plate 15 for blocking steam may be provided. In the case of the double-supported roller body 2, the protective plate 15 is provided so as to cover the outer wall surface of the journal portion 2b. In the case of the cantilevered roller body 2, the outer wall surface of the flange portion 2d is A protective plate 15 is provided so as to cover it. With this configuration, the high-temperature heat medium steam that blows out when the relief plug 8 releases the pressure is blocked by the protection plate 15 and does not spread to the outside, so that the safety of the surrounding environment can be ensured.

In the structure provided with the protection plate 15, as shown in FIG. 7, the end plate portion (journal portion 2b or flange portion 2d) provided with the relief plug 8 is supplied with high-temperature heat medium steam when the pressure is released by the relief plug 8. A channel 24 leading to the inside of the roller body 2 may be formed. In the case of the double-supported roller body 2, the passage 24 is formed in the journal portion 2b, and in the case of the cantilevered roller body 2, the passage 24 is formed in the flange portion 2d. becomes. Here, in order to make it easier for the high-temperature heat medium steam to flow from the relief plug 8 into the flow path 24, a communication groove 25 (right side in FIG. 7 (see figure) may be formed. With this configuration, the high-temperature heat medium steam jetted out when the relief plug 8 is released from the pressure flows into the roller body 2 and does not spread outside, so that the safety of the surrounding environment can be further ensured. Forming the flow path 24 also contributes to weight reduction of the roller body 2 .

Moreover, in order to determine whether the relief plug 8 has released pressure, the induction heating roller device 100, as shown in FIG. T1, T2, and a determination unit C that determines whether or not the relief plug 8 is operated based on the temperatures detected by the plurality of temperature sensors T1, T2 may be provided. When the relief plug 8 is not in operation, the temperature equalization effect of the jacket chamber 21 keeps the temperature difference detected by the plurality of temperature sensors T1 and T2 within a predetermined range. On the other hand, after the relief plug 8 operates to release the pressure, the uniform temperature action of the jacket chamber 21 becomes insufficient, and the difference in the temperatures detected by the plurality of temperature sensors T1 and T2 falls outside the predetermined range. . When judging that the temperature detected by the plurality of temperature sensors T1 and T2 is out of a predetermined range, the judging section C judges that the relief plug 8 has been activated and notifies the user, for example. Alternatively, the induction heating roller device 100 is stopped.

In addition, in the above-described embodiment, the relief plug 8 is positioned radially inward of the jacket chamber 21 . . In this configuration, the roll body becomes large, so the configuration of each embodiment described above is preferable.

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.

100... Induction heating roller device 2... Roller main body 2a... Roll shell portion (side peripheral wall)
2b... journal (end plate)
2d... Flange part (head plate part)
21 Jacket chamber 23H Sealing port 3 Induction heating mechanism 32 Induction coil 8 Relief plug 81 Soluble metal 15 Protective plates T1, T2 Temperature Sensor C: Judgment part

Claims (9)

An induction heating roller device comprising 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,
A jacket chamber in which a gas-liquid two-phase heat medium is enclosed is formed in a side peripheral wall of the roller body,
a relief plug for releasing pressure from the jacket chamber is provided on the end plate portion at the axial end of the roller main body,
The induction heating roller device, wherein the relief plug is provided radially inward of the jacket chamber in the end plate portion. 2. The induction heating roller device according to claim 1, wherein said relief plug is provided in a region of said end plate portion radially inward of a radially inner end of said jacket chamber. 3. The induction heating roller according to claim 1, wherein the relief plug is made of a soluble metal that melts at a predetermined temperature, and the melting of the soluble metal releases the pressure in the jacket chamber. Device. 4. The induction heating roller device according to claim 3, wherein the relief plug is provided at a position where the soluble metal does not melt even when the temperature of the side peripheral wall of the roller body reaches a temperature higher than the melting temperature of the soluble metal. . The heat medium is water,
5. The induction heating roller device according to claim 4, wherein the relief plug is provided at a position where the soluble metal melts when the side peripheral wall of the roller body reaches the critical temperature of water or a temperature just below it. 6. The induction heating roller device according to claim 1, wherein said relief plug is provided separately from a sealing port for sealing said heat medium in said jacket chamber. 7. The induction heating roller device according to any one of claims 1 to 6, wherein a protective plate is provided outside the relief plug to block heat medium vapor when pressure is released by the relief plug. 8. The induction heating roller device according to claim 7, wherein the end plate portion provided with the relief plug is formed with a flow path for guiding heat medium vapor to the inside of the roller body when the pressure is released by the relief plug. A plurality of temperature sensors are provided at different positions in the axial direction on the side peripheral wall of the roller body,
The induction heating roller device according to any one of claims 1 to 8, further comprising a determination unit that determines whether or not the relief plug is operated based on the temperatures detected by the plurality of temperature sensors.

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