This application is entitled to the benefit of and incorporates by reference essential subject matter disclosed in International Patent Application No. PCT/JP2003/015972 filed on Dec. 12, 2003, Japanese Patent Application No. 2003-154582 filed May 30, 2003 and Japanese Patent Application No. 2003-310457 filed Sep. 2, 2003.
The present invention relates to a portable electromagnetic induction heating device for making a conductor generate heat by electromagnetic induction heating and for heating adhesive.
In order to bond a conductive member such as metal and a nonconductive member such as wood by the adhesive, a technique for making the conductive member generate heat by an induction coil, i.e., a heating coil and for heating the adhesive is disclosed in Japanese Patent Laid-Open Publication No. 8-73818. Also, in order to bond the nonconductive members to each other, a technique for interposing between the nonconductive members a metal sheet to whose surfaces adhesive layers are applied and for heating the adhesive layers and bonding the nonconductive members by making the metal sheet generate heat by the induction coil is disclosed in Japanese Patent Laid-Open Publication Nos. 63-308080, 5-340058, and 6-100840.
In these techniques, when a high-frequency current is supplied to the induction coil, magnetic force lines of an alternating magnetic field generated by the induction coil penetrate the conductive member and the metal sheet and an electromotive force is created in the conductive member such as the metal sheet by the electromagnetic induction effect As a result, an induction current flows in the conductive member and the Joule's heat is generated and the heat is transmitted to the adhesive, so that the adhesive is heated. This electromagnetic induction heating device carries the high-frequency current in the induction coil to create an eddy current, whereby a particular portion can be quickly made to generate heat Therefore, by making the conductive members generate heat, interior materials and exterior materials of a building can be bonded to a building body in a short time. Simultaneously, the interior materials and exterior materials can be peeled off in a short time in remodeling the building, so that the peeled interior materials and exterior materials can be recycled.
When such an electromagnetic induction heating device is used, operation efficiency of assembling the interior materials can be improved in comparison with the cases of attaching the interior materials to a building frame by, for example, nails, screws, and rivets. More specifically, when the interior materials are to be assembled by nails or the like, heads of the nails protrude from surfaces of the interior materials, so that the heads have to be concealed by ornaments or the like and further noise is generated during construction. Meanwhile, when the solvent adhesive is used to bond the interior materials or the like to the building frame by the adhesive, the noise is not generated. However, it takes time to cure until the adhesive solidifies.
In contrast, when the electromagnetic induction heating device with the induction coil is made to heat and melt thermoplastic adhesive and then cool and solidify it, the adhesive can be not only heated and melted but also solidified in a short time, so that a time required for constructing the building can be largely shortened. As described above, it has been found out that an adhesive heating method for heating the adhesive interposed between the conductive member such as metal and the nonconductive member such as wood by the electromagnetic induction heating device and for bonding both members or, in order to bond the nonconductive members to each other, an adhesive heating method for interposing between the nonconductive members the metal sheet to whose surfaces the adhesive layers are applied, heating the adhesive, and boding both members can be applied for various uses, for example, the cases of assembling a large quantity of products such as automobiles and electronic devices and of bonding the sheet-like members to one another without being limited to the interior materials and exterior materials of the building. For example, regarding automobile parts or the like produced by combining resin members and metal members, a production time can be shortened and concurrently the used parts can be disassembled by melting the adhesive and be reused.
As a conventional electromagnetic induction heating device, a coil formed into a disk-like shape by spirally winding a coil material has been used. Generally, a little eddy current is generated in a portion of a conductor facing a center portion of such a spiral round coil and, consequently, the coil has the characteristic that heating temperature of the adhesive at a portion corresponding to the center portion becomes low. When two members are to be bonded by the adhesive, heating the metal sheet by using the conventional coil is limited to donut-shaped heating or heating dependent on a donut-shaped induced electromotive force and a shape of the metal sheet. Therefore, limit has been imposed on the heating of target regions of the metal sheets of various shapes. For example, in heating a rectangular tape, only both ends of a tape portion facing the coil center portion are heated, whereby an end-burnt phenomenon is caused and there is in a state of being not usable in practice. Countermeasures of the conventional techniques include a hole-strewed tape and a tape whose both ends are cut into wave-like shapes. However, these are insufficient as the burnt-end countermeasures, and involve risks of fire. For bonding of, for example, tiles that require wide-region bonding, there is no corresponding model among conventional devices, so that since these devices aim at only regions capable of being heated by the conventional coils, the heating of the center portion and corner portions becomes insufficient. In the bonding of tiles, the respective induction coils capable of corresponding to the heating of only edge portions and an entire surface are required.
Moreover, in order to melt the adhesive applied on the wide region in a short time, the large current has to flow in the induction coil. In the electromagnetic induction devices developed thus far, the current amount has been limited in terms of electrical power, heating efficiency is low, and control of the bonding region is limited. The present invention provides actually practical techniques which compensate for such problems of the conventional techniques.
Meanwhile, several techniques for utilizing iron cores in induction heating coils are known. Such an iron core depends on a kind and shape of a magnetic conductor, normal conductor, or the like used as unheated metal, so that the optimum polarity and shape of the core are specified with respect to heating conditions. In the conventional techniques, the core shape optimum to the heating conditions is not considered, and a U-shaped, E-shaped, or T-shaped core is uniformly used presently.
In the present invention, the magnetic poles and the shapes of a core portion can be changed under design in which a generation state of a magnetic flux loop relating to a magnetic flux emitting portion and a magnetic flux collecting portion of the core is considered with respect to the kind, shape, and position of unheated metal and to the heating conditions, whereby the above problems are solved. In terms of techniques, this is the same case as the case of changing of the position and polarity of the spiral coil. However, uniform heating of a large area, which cannot be performed by the conventional techniques, is prevented by such design that ends of the core are increased. Also, regarding control of the heating time, if the bonding portion is an ignitable member, over heating is extremely dangerous, so that detecting the heating temperature and controlling the supplied power are essential. The conventional techniques lack consideration for performing such strict heating control. The present invention provides specific techniques for solving the practical problems.
An object of the present invention is to provide a portable electromagnetic induction heating device with small size and light weight.
Another object of the present invention is to provide a portable electromagnetic induction heating device capable of carrying a large amount of currents in an induction coil.
Another object of the present invention is to provide a portable electromagnetic induction heating device capable of aligning a region of a heating portion so as to correspond to a shape, perforations, and incisions of a conductor to be heated.
A portable electromagnetic induction heating method of the present invention is a method for carrying an induction current in a conductor, making said conductor generate heat by Joule's heat, and heating adhesive by the heat generating conductor, and comprises the steps of: connecting in series a plurality of coil bodies to form a heating induction coil generating a magnetic force line supplied to said conductor by a high-frequency current from a high-frequency generation circuit; and changing a center distance of said plurality of coil bodies or reversing at least any one of said coils upside down to change a polarity and a position of the magnetic force lines formed by said heating induction coil.
A portable electromagnetic induction heating method of the present invention is a method for carrying an induction current in a conductive sheet to whose surface adhesive is applied, making said sheet to generate heat by Joule's heat, and heating the adhesive by the heat generating sheet, and comprises the steps of forming a resistance barrier portion constituted by an incision, a perforation, or the like in said sheet in which the induction current is generated by a magnetic force line of a heating induction coil to which a high-frequency current is supplied from a high-frequency generation circuit; and changing the number of eddies and flow of an eddy current generated in said sheet to adjust a heat generation distribution.
A portable electromagnetic induction heating method of the present invention is a method for carrying an induction current in a conductor, making said conductor generate heat by Joule's heat, and heating adhesive by the heat generating conductor, and comprises the steps of: supplying a high-frequency current from a high-frequency generation circuit, to a heating induction coil generating a magnetic force line supplied to said conductor, and controlling a current carrying time to said heating induction coil based on a detection signal from a temperature sensor detecting temperature and temperature variation of said adhesive.
A portable electromagnetic induction heating device of the present invention is a device for carrying an induction current in a conductor, making said conductor generate heat by Joule's heat, and heating adhesive by the heat generating conductor, and comprises: a power-supply unit for supplying electric power; a heating head provided with a high-frequency generation circuit for converting a current supplied from said power-supply unit to a high-frequency current; and a heating induction coil to which a current from the high frequency generation circuit is supplied and which generates an induction current in said conductor, wherein said heating induction coil has a facing surface including a flat surface or curved surface facing said conductor, and is formed by a coil body with a shape of a single or plurality of circles, ovals, or polygons to be capable of surface-heating a complex three-dimensional curved surface.
The portable electromagnetic induction heating device of the present invention is such that efficiency of generating an eddy current is improved by winding said coil body around a magnetic core with a tip surface facing said conductor and by forming a magnetic circuit concentrating a facing magnetic force line and converging a magnetic force line in a space opposite to the conductor.
The portable electromagnetic induction heating device of the present invention is such that a region of the generated eddy current is adjusted by connecting windings of a plurality of said magnetic cores at respective rear ends thereof and by changing a polarity and a position of a magnetic force line formed by said heating induction coil.
According to the present invention, the heating induction coil is formed by connecting the plurality of coil bodies in series, so that since the center-to-center distances of the coil bodies are changed or/and the coil bodies are reversed upside down, the polarity and position of the magnetic force line can be changed, which makes it possible to perform the heating in a state suitable for the conductor serving as an object to be heated.
According to the present invention, when the conductor is formed into a sheet-like shape and the adhesive applied to the surface of the sheet-like conductor is heated, by forming the resistance barrier portion formed by an incision or the like in the sheet, the flow of the eddy current in one sheet can be changed and the heat generation distribution can be changed.
According to the present invention, the heating temperature can be controlled by detecting the temperature of the adhesive and automatically adjusting the current carrying time.
According to the present invention, even when the conductor to be heated by the coil body has any of a flat surface and a complex three-dimensional curved surface, the conductor can be reliably heated.
According to the present invention, since the coil body is wound around the magnetic core, the magnetic force line generated by the coil body can be concentrated and the efficiency of generating the eddy current can be improved.
According to the present invention, since the heating induction coil is formed by the plurality of magnetic cores and the respective magnetic cores are connected at the rear ends, a leakage of the magnetic flux is prevented from occurring to intensively guide the magnetic force line to the conductor, whereby the efficiency of generating the eddy current can be improved.
According to the present invention, since the polarities of the magnetic force lines formed by the coil bodies are changed, the generation region of the eddy current can be adjusted and the conductor can be heated at the optimum temperature.
Now having described the invention in general terms, embodiments of the invention shall be described in details with reference to the drawings in which:
In
The portable electromagnetic induction heating device has a heating head 10 and a power-supply unit 30, wherein these are connected by a cable 40. The cable 40 is detachably connected to the heating head 10 by a plug 40a, and all of a plurality of heater heads 10 are attachable/detachable with respect to the power-supply unit 30. Accordingly, among the plurality of heating heads 10 different in size, the arbitrary heating head 10 can be connected to the power-supply unit 30. The heating head 10 has a head body 12 to which a handle 11 is provided, wherein a coil unit 13 is provided to a front surface of the head body 12. If the coil unit 13 is set to become attachable/detachable to the head body 12, the coil unit 13 with arbitrary size can be attached to the single head body 12 by preparing a plurality of coil units 13.
As the power-supply unit 30, a unit having a rectifier circuit for converting commercial power supply used in household or the like to DC power supply or a unit having a charging type battery in addition to a rectifier circuit for converting AC power supply to the DC power supply can be used, whereby the size and weight of the power-supply unit 30 can be reduced. Furthermore, a unit having only a battery can be used as the power-supply unit 30.
The coil body 21 shown in
The two coil bodies 21 and 22 are mutually stacked so that a center portion of the coil body 21 overlaps with the coil body 22, and at least one of the two coil bodies 21 and 22 is movable for adjustment along the other coil body so that a stacking position can be changed. Accordingly, positions of the magnetic force lines formed by the respective coil bodies 21 and 22 can be changed.
Furthermore, one of the two coil bodies 21 and 22 can be reversed upside down.
The heating induction coil 13a shown in
In the case of the heating induction coil 13a shown in
Furthermore, as shown in
Meanwhile,
If the flows of the currents in the overlapping portion are set in the opposite directions to each other as shown in
Thus, since the heating induction coil 13a is constituted by a plurality of coil bodies 21 to 24 and each of the coil bodies are overlapped with the other coil bodies, the adhesive corresponding to the overlapping portion can be heated at the temperature different from that of the other portion. Therefore, when the heating head 10 provided with the heating induction coil 13a having such a structure is operated to heat the adhesive, the adhesive can be sufficiently heated while poorly heated portions are eliminated by making the head correspond to the object to be heated.
The heating induction coil 13a shown in
Meanwhile, as shown in
A step-down transformer 35 is built in the power-supply unit 30, so that the commercial power supply is transformed to have a low voltage by the step-down transformer 35 and the current is sent to an IPM (intelligent power module) driving power-supply circuit 36 and a control power-supply circuit 37. A direct current is supplied from the control power-supply circuit 37 to a system controlling circuit 38, and a control signal is sent from an IPM driving circuit to the high-frequency generation circuit 25 by a PWM (pulse wide modulation) signal from the system controlling circuit 38. Consequently, the control signal is sent from the power-supply unit 30 to each of the switching elements, which are built in the heating head 10 and constitute the high-frequency generation circuit 25, whereby a high-frequency current with a predetermined frequency, for example, a wavelength of 200 kHz is supplied to the LC circuit 28.
A trigger switch 14 to be operated by an operator is provided to the heating head 10, so that when the switch 14 is operated, the signal thereof is sent to the system controlling circuit 38 of the power-supply unit 30 and supply of a high-frequency current to the heating induction coil 13a is started. A current carrying time for the heating induction coil 13a is set by a signal from an operation timer 41 to the system controlling circuit 38, and the current carrying time can be set to an arbitrary time by adjusting the timer 41. Furthermore, a buzzer 42 is provided in the power-supply unit 30, so that although the buzzer 42 operates while a current is supplied to the heating induction coil 13a, an LED may be lighted instead. Note that the buzzer 42 may operate or the IMP driving power-supply circuit 36 may stop when an error occurs, for example, when the current or voltage exceeds a set value or the temperature is equal to or higher than a predetermined value. Also, the LED may be lit up only when an appropriate current is supplied to the heating induction coil 13a.
A detection signal from a temperature sensor 43 for detecting the temperature of the adhesive is send to the system controlling circuit 38. When the adhesive reaches the predetermined temperature, the current carried to the induction coil is stopped before a time set by the timer 41 elapses. When the adhesive does not reach the predetermined temperature even after the time set by the timer 41 elapses, the time set by the timer 41 is corrected so that the current carrying time is extended up to a certain time at most. Furthermore, a detection signal from an outside air temperature sensor 44 for detecting outside air temperature is send to the system controlling circuit 38, so that the time set by the timer 41 is corrected in accordance with the outside air temperature. However, whether the time set by the timer 41 is corrected by one or both of the temperature sensor 43 and the outside air temperature sensor 44 or whether the current carrying time is set only by the timer 41 may be selected by a selector switch.
As described above, since the LC circuit 28 is constituted by the heating induction coil 13a and the compensating capacitor 26 connected thereto in series, AC resistance of the LC circuit 28 can be reduced by using the serial type LC circuit 28. For example, when a value of the compensating capacitor 26 is adjusted in the case where a high-frequency current of 20 kKz is generated by the high-frequency generation circuit 25 and supplied to the LC circuit 28, the inductance of the LC circuit 28 can be reduced to one tenth, i.e., from 600 μH to about 60 μH, and the AC resistance of the LC circuit 28 can be set at about 10 Ω. Consequently, the current supplied to the heating induction coil 13a can be increased about ten times, whereby a magnetic flux density is increased. Thus, since a resistance value required for the LC circuit 28 is set, a value of the current flowing in the heating induction coil 13a is increased, whereby a heating capability can be improved. By combining these devices, even adhesive applied to a large region can be efficiently heated.
As shown in
The heating head 10 connected to the power-supply unit 30 via the cable 40 is attachable/detachable to the power-supply unit 30, and the heating head 10 can be separated from the power-supply unit 30. When the interior material or the like of the building is bonded by using the portable electromagnetic induction heating device as shown in
Since the above-described portable electromagnetic induction heating device is used to make the sheet M serving as a conductor generate heat and to heat the adhesive, the interior materials or exterior materials of the house can be attached to the building frame by the adhesive. For example, by using the sheet M shown in
As shown in the Figures, when the sheet M is divided into a plurality of regions by perforations T or incisions Ta, the metal structure is not continuous at portions cut for forming the perforations, so that the electrical resistance at a portion along the perforations T or incisions Ta becomes larger than that of the other portions and the portion of the perforations T or incisions Ta serves as a barrier portion with large electrical resistance. Therefore, when the current flows in the heating induction coil 13a, a large quantity of eddy currents as shown by arrows flow in each of regions divided and included in a state in which the metal structure is continuous, so that the eddy currents are dispersed and generated in the sheet M. That is, when the perforations T are not provided, a portion of the sheet M intensively generates heat since the eddy currents flow intensively in a donut-shaped portion corresponding to a shape of an outer peripheral portion of the heating induction coil 13a. However, when the sheet M is divided into the plurality of regions by the resistance barrier portions comprising the perforations T, incisions Ta, or the like, the eddy current divided by the resistance barrier portions such as the perforations T as boundaries flow in an opposite direction. As a result, no bias of a heat generating portion occurs and the heat generation temperature is dispersed in whole.
The heating induction coil 13a has four rod-like magnetic cores 50a to 50d, each of which is made of a magnetic material with high magnetic permeability such as ferrite or iron. Coil bodies 51 to 54 are wound around the magnetic cores 50a to 50d, respectively, and the four magnetic core coils 50a to 50d are combined. When tip surfaces of the magnetic cores 50a to 50d are faced to the conductor W and the currents are carried to the coil bodies 51 to 54, as shown in
Thus, since the coil bodies 51 to 54 are wound around the magnetic cores 50a to 50d, efficiency of generating the eddy currents is improved and the eddy currents I are created in a state of having a little bias in whole close to, for example, corners of the rectangular conductor W, whereby the entirety of the conductor W can be heated.
Regarding winding directions of the coil bodies 51 to 54 shown in
Regarding the winding directions of the coil bodies 51 to 54 shown in FIG. 13A, the outside coil body 51 and the inside coil body 52 adjacent thereto have the same direction and the outside coil body 54 and the inside coil body 53 adjacent thereto have the same direction. However, the direction of the two coil bodies 51 and 52 and that of the two coil bodies 53 and 54 are opposite to each other. Therefore, when the tips of the two magnetic cores 50a and 50b have south poles, the two magnetic cores 50c and 50d have north poles. Since the winding directions are set in the above-described manner, as shown in
Also in the cases shown in
As described above, when the heating induction coil 13a is constituted by the plurality of coil bodes, the plurality of coil bodies may be connected in series or in parallel. When it is constituted by the four coil bodies, two of them may be connected in series to each other to form a pair of coil assemblies, whereby two pairs of coil assemblies may be connected to each other in parallel.
When the metal to whose both surfaces the adhesive is applied is used, the interior material or exterior material serving as an object to be heated by the portable electromagnetic induction heating device of the present invention is not limited to a wooden member and may be any member as long as it is a nonconductive member such as a rubber sheet, gypsum board, or tile. Therefore, the present invention can be used to bond a rubber sheets to a ceiling of the house or bond a finishing cloth to a surface of the interior material. In addition, even when the members are peeled off or separated by melting the adhesive in the state in which these are bonded, the portable electromagnetic induction heating device can be used.
Also, when the nonconductive member such as a plaster board is bonded to a metallic pillar, without using the conductor such as metal foil or a metal net and in a state in which the adhesive is interposed between the metallic pillar and the nonconductive member, the metallic pillar is made to generate heat by the portable electromagnetic induction heating device and the adhesive is heated and melted by the generated heat Thereby, both can be bonded and the two members bonded can be separated by melting the adhesive. Similarly thereto, the portable electromagnetic induction heating device of the present invention can be used even in the case of bonding two metallic members by the adhesive or separating the two bonded members by melting the adhesive.
As described above, as long as both of or one of the two members to be bonded to each other is a conductive member(s), in a state of interposing the adhesive therebetween, the object(s) to be bonded per se is made to generate heat by the portable electromagnetic induction heating device and the generated heat is transmitted to the adhesive. Thereby, it is possible to bond the members or separate the bonded members. In contrast, when both members are nonconductive, in a state in which aluminum or steel metal foil or a metal net to whose both surfaces the adhesive is applied is interposed between the both members, the metal foil or metal net is made to generate heat and the generated heat is transmitted to the adhesive. Thereby bonding or separation can be carried out.
Therefore, since the portable electromagnetic induction heating device is used to melt the adhesive, the two members to be bonded by the adhesive or separated from the bonded state are not limited to the interior materials and/or exterior materials and the building frame, and bonding and separation of various members can be performed.
For example, when tents or domes produced by using the sheet materials are produced, the portable electromagnetic induction heating device of the present invention can be applied for heating the adhesive in bonding the sheet materials to each other by the adhesive and also applied for bonding and separation of the sheet materials such as carpets. In addition, the device can be applied even when a large quantity of products such as automobile parts and electronic parts are bonded by the adhesive, and can be also applied for reusing the members by meting the adhesive and disassembling them.
The present invention can be applied for joining the two members by using the adhesive and for separating the two bonded members from each other, and can be applied to both of the cases where both of the members to be bonded are nonconductive members and where at least one of them is a conductive member.
While the present invention has been illustrated and described with respect to a particular embodiment thereof, it should be appreciated by those of ordinary skill in the art that various modifications to this invention may be made without departing from the spirit and scope of the present invention.
Number | Date | Country | Kind |
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2003-154582 | May 2003 | JP | national |
2003-310457 | Sep 2003 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP03/15972 | 12/12/2003 | WO | 00 | 11/30/2005 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2004/107820 | 12/9/2004 | WO | A |
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