JP2011238449A - Electromagnetic induction heating device, and heating and hot-water supply device using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electromagnetic induction heating device hardly producing heat dissipation, obtaining high temperature in a short time and being easy to make germs and viruses extinct.SOLUTION: The electromagnetic induction heating device includes: an internal first heating element 1; a second heating element 2 located outside the first heating element 1; a first flow path F1 disposed outside the second heating element 2; and a second flow path F2 disposed between the first heating element 1 and the second heating element 2. A non-heating medium introduced in the first flow path F1 flows in the first flow path F1 and the second flow path F2, without contacting to the second heating element 2 and the first heating element 1. The second heating element 2 generates heat by the application of alternating power to the second heating element 2, and also, the first heating element 1 generates heat by an electromagnetic induction function between the second heating element 2 and the first heating element 1. The non-heating medium introduced in the first flow path F1 is heated by the second heating element 2 in the first flow path F1 and by the first heating element 1 and the second heating element 2 in the second flow path F2.

Description

    The present invention relates to an electromagnetic induction heating device and a heating / hot water supply device using the same.

2. Description of the Related Art Conventionally, boilers that heat water with heat generated by burning fuel such as heavy oil have been generally used as heating devices that are provided in heating devices and hot water supply devices.
On the other hand, many electromagnetic induction heating devices configured to heat water with heat generated by electromagnetic induction have been proposed.
For example, in Japanese Patent Laid-Open No. 2001-263810, by arranging a heater made of an iron plate that generates heat by electromagnetic induction inside a pipe through which water flows, and energizing by winding a coil around the pipe, A configuration has been proposed in which the temperature raising device provided in the pipe is heated by electromagnetic induction to heat water passing through the pipe.
However, in this conventional example, a heater made of an iron plate capable of electromagnetic induction heating is provided inside a pipe through which water flows, and a work coil (solenoid coil) is formed by winding an electric wire outside the pipe. Since the water flowing through the pipe is heated, the temperature riser and the water come into contact with each other, resulting in large heat loss and low thermal efficiency.
As for other electromagnetic induction heating devices, most of the types in which a heating element such as the above-mentioned temperature riser comes into contact with water to heat the water (JP 2002-022107 A, JP 2003-297537 A). Gazette, JP-A-2005-233572, JP-A-2005-327738, JP-A-2006-064358, JP-A-2007-178089, JP-A-2008-202922, JP-A-2008-204927, JP 2009-174768 A)

JP 2001-263810 A, JP 2002-022107 A, JP 2003-297537 A, JP 2005-233572 A, JP 2005-327738 A, JP 2006-064358 A, JP JP 2007-178089 A, JP 2008-202922 A, JP 2008-204927 A, JP 2009-174768 A.

The object of the present invention is to provide a technique capable of eliminating the above-described drawbacks of the prior art.
Other objects and novel features of the present invention will become apparent from the following specification and drawings.

The claims of the present invention are as follows.
(Claim 1) An inner first heating element, a second heating element located outside the first heating element, a first flow path provided outside the second heating element, and the first heating element And a second flow path provided between the second heating element and the non-heating medium introduced into the first flow path without contacting the second heating element and the first heating element. By flowing through the first flow path and the second flow path and applying alternating power to the second heating element, the second heating element generates heat, and electromagnetic induction action with the first heating element causes the The first heating element generates heat, and the non-heating medium introduced into the first flow path is heated by the first heating element and the second heating element in the second flow path, and also in the second flow path. The electromagnetic induction heating device is configured to be heated by the first heating element and the second heating element.
(Claim 2) An inner first heating element, a second heating element located outside the first heating element, a first channel and a second channel provided outside the second heating element, A third flow path provided between the first heating element and the second heating element, and the non-heating medium introduced into the first flow path is connected to the second heating element and the first heating element. By flowing through the first flow path, the second flow path, and the third flow path without contact, and applying alternating power to the second heating element, the second heating element generates heat, and the first heating element And the non-heating medium introduced into the first flow path is heated by the second heat generating element in the second flow path, and An electromagnetic induction heating device configured to be heated by the first heating element and the second heating element in a third flow path .
(Claim 3) An inner first heating element, a second heating element located outside the first heating element, a third heating element provided outside the second heating element, and the third heating element A first flow path provided outside the body, a second flow path provided inside the third heating element, and a third flow provided between the first heating element and the second heating element. A non-heating medium introduced into the first flow path without contacting the third heat generating element, the second heat generating element, and the first heat generating element. By flowing alternating current to the second heating element through the flow path, the second heating element generates heat, and the electromagnetic induction action between the first heating element and the third heating element causes the first heating element to generate heat. The one heating element and the third heating element generate heat, and the non-heating medium introduced into the first flow path is heated by the third heating element in the first flow path. The second heating element is heated by the second heating element and the third heating element in the second flow path, and is heated by the first heating element and the second heating element in the third flow path. An electromagnetic induction heating device.
(Claim 4) The first heat generating element is characterized in that a heat generating / storing material capable of generating heat and storing heat by heating is incorporated in a metal cylinder. The electromagnetic induction heating device described in 1.
(Claim 5) The electromagnetic induction heating device according to claim 1, 2, 3 or 4 is connected to a part or facility that requires heating, and the heating medium is supplied by the heating medium supplied from the electromagnetic induction heating device. A heating apparatus using an electromagnetic induction heating apparatus, wherein a part or facility that requires heating is heated.
(Claim 6) The electromagnetic induction heating device according to claim 1, 2, 3, or 4 is connected to a part or facility that requires hot water, and the part that requires the hot water from the electromagnetic induction heating apparatus or A hot water supply apparatus using an electromagnetic induction heating apparatus, wherein hot water is supplied to equipment.

The effects obtained by the representative ones of the inventions disclosed in the present application will be briefly described as follows.
That is, according to the present invention, in the invention according to claim 1, the electromagnetic induction heating device includes an inner first heating element, a second heating element positioned outside the first heating element, and the second heating element. A first flow path provided outside the body and a second flow path provided between the first heating element and the second heating element, the non-heating medium introduced into the first flow path is The second heating element generates heat by flowing through the first flow path and the second flow path without contacting the second heating element and the first heating element, and applying alternating power to the second heating element. In addition, the first heating element generates heat due to the electromagnetic induction effect with the first heating element, and the non-heating medium introduced into the first flow path is caused by the second heating element in the first flow path. It is configured to be heated and heated by the first heating element and the second heating element in the second flow path. Thus, when alternating power is applied to the second heating element, the second heating element generates heat, and the first heating element also generates heat due to electromagnetic induction with the first heating element. The non-heating medium introduced into the first flow path is heated by the second heating element in the first flow path, and both by the first heating element and the second heating element in the second flow path. Since it can be heated, it can be heated with extremely high thermal efficiency, and the electromagnetic induction heating device of the present invention hardly dissipates wasteful heat, and both the first heating element and the second heating element are generated by electromagnetic induction. It can be used for heating the non-heating medium without wasting the heat generated from the heat, the heating of the high-speed non-heating medium is raised and the temperature becomes high in a short time, and the bacteria and viruses are easily killed. Further, the first flow path and the second flow path are Unheated media spent has a molecular level is reduced, it becomes nano-level.
The second flow path is provided between the sealed (covered) first heating element and the second heating element, and the first flow path is provided outside the sealed (covered) second heating element. Therefore, since the non-heating medium flows through the first flow path and the second flow path without contacting the second heating element and the first heating element, the heat loss is small and the thermal efficiency is high.
That is, the first heating element and the second heating element are covered with a metal cylinder or the like, so that they can be prevented from being exposed to a non-heating medium or the like, and the exciting coil in the second heating element is damaged (corroded). And the reliability of the device can be increased.
In the invention according to claim 2, in addition to the above-mentioned advantages, the number of non-heating medium channels of the electromagnetic induction heating device is three, and the first channel, the second channel, and the third channel are provided. Thus, the inlet of the non-heating medium and the flow of the non-heating medium can be changed.
In the invention according to claim 3, in addition to the above-mentioned advantages by providing a third heating element in addition to the first heating element and the second heating element, when alternating power is applied to the second heating element, Since both the first heating element and the third heating element on both sides generate heat, the heating of the high-speed non-heating medium is further increased and the temperature is increased in a short time, and the bacteria are further increased. In addition, the non-heated medium is further reduced in molecular level and becomes nano level. Similarly to the invention according to claim 2, since there are three non-heating medium flow paths of the electromagnetic induction heating device, the first flow path, the second flow path, and the third flow path are provided. The introduction port of the non-heating medium and the flow of the non-heating medium can be changed.
In the invention according to claim 4, the first heating element is formed by incorporating a heat generation / heat storage material capable of generating heat and storing heat inside the metal cylinder. -The heat storage material can be heated to a desired temperature in a high temperature range of 500 ° C. or higher, preferably 600 ° C. to 900 ° C. by heating, and in particular, if a solid mass is used as the heat generation / heat storage material, The heating efficiency of the non-heating medium by the heat generation / heat storage material can be improved, and since the heat generation / heat storage material can store heat together with the heat generation, the non-heating medium is circulated between the heater and the like. However, it can be heated with extremely high thermal efficiency without cooling.
In the invention according to claim 5, the heating device of the non-heating medium provided in the heating device is configured by the electromagnetic induction heating device as described above, and the electromagnetic induction heating device and a part or facility that requires heating, Is connected, and the part or facility that requires heating is heated by the heating medium supplied from the electromagnetic induction heating device, so that efficient heating can be performed and the temperature can be increased in a short time. Therefore, the heat generation / storage material in the first heating element can store heat as well as heat generation, so even if the non-heating medium is circulated between the heater and the like, it will not be cooled and heated with extremely high thermal efficiency. If the non-heating medium is made of an antifreeze liquid, heating can be performed satisfactorily without freezing even in heating in a cold region.
In the invention described in claim 6, the electromagnetic induction heating device and a part or facility that requires hot water are connected, and the hot water is supplied from the electromagnetic induction heating device to the part or facility that requires the hot water. In addition to the advantages of the electromagnetic induction heating device described above, the hot water can be heated with a very high thermal efficiency without cooling even when the hot water is circulated between the hot water heater and the like in a short time. Can do.

  Next, embodiments of the present invention will be described with reference to the drawings.

  As shown in FIGS. 1 and 2, the electromagnetic induction heating device E of the present invention includes an inner first heating element 1, a second heating element 2 positioned outside the first heating element 1, and the second heating element 1. A first flow path F1 provided outside the heat generating body 2 and a second flow path F2 provided between the first heat generating body 1 and the second heat generating body 2 are provided.

The inner first heating element 1 is formed, for example, by incorporating a heat generation / heat storage material 101 inside a metal cylinder 100.
The metal cylinder 100 constituting the inner first heating element 1 may be made of a diamagnetic metal such as copper or a paramagnetic metal such as aluminum, but is a nonmagnetic metal (alloy). This is preferable because there is an advantage that rust can be prevented without deteriorating the electromagnetic induction heat generation performance. Here, non-magnetic does not include ferromagnetism and means diamagnetism or paramagnetism.
The heat generation / heat storage material 101 is an electromagnetic induction type heat generation material capable of generating heat to a desired temperature in a high temperature range of 500 ° C. or more, preferably 600 ° C. to 900 ° C. by electromagnetic induction, and stores heat. In the second flow path F2, an exothermic / heat storage material that can heat the non-heating medium W by heat storage is used. For example, it can be composed of a magnetic material such as metal or carbon. Specifically, for example, a kneaded mixture of metal particles and a solid material (glass, ceramic, cement, etc.), or a metal wire wire or metal waste material is cut and solidified with a solid material similar to the above. Things. As the heat generation / heat storage material 101, a material solidified by sintering is preferable in that the heat generation / heat storage function is excellent.
The heat-generating / heat-storage material 101 is a solidified lump, and a large number of the heat-generating / heat-storing material 101 is filled in the metal cylinder 100 as illustrated.

The second heating element 2 positioned outside the first heating element 1 has a structure in which a heating element 202 is built in, for example, an inner body 200 and an outer body 201 as shown in the figure. .
The inner body 200 is made of, for example, a metal cylinder. The metallic cylinder is made of, for example, a nonmagnetic metal (alloy), specifically, for example, nonmagnetic stainless steel.
Although not shown in the drawings on the peripheral surface of the inner body 200, an electric insulator is wound, and a heating element 202, for example, an exciting coil (electric wire) 202 is wound on the electric insulator to work coil (solenoid) The second heating element 2 is formed. Examples of the exciting coil (electric wire) 202 include an enameled wire, and the enameled wire may be wound spirally to form a solenoid body. The electrical insulator is wound with an electrical insulator that does not inhibit heat conduction and has excellent heat resistance. The exciting coil 202 is pulled out from the solenoid body, and alternating power is applied from the lead wire 203 so that the second heating element 2 is heated.
Similarly to the inner body 200, the outer body 201 is made of, for example, a metal cylinder. The metallic cylinder is made of, for example, a nonmagnetic metal (alloy), specifically, for example, nonmagnetic stainless steel.
The electrical insulator is preferably made of a synthetic resin, a rubber material, or the like, for example, and is preferably a material that has the advantage of not deteriorating the electromagnetic induction heat generation performance similar to that of the inner body 200 and the outer body 201.

  As shown in FIGS. 1 and 2, in the electromagnetic induction heating device E, the lead wire 203 drawn from the exciting coil 202 of the second heating element 2 is electrically connected to a power supply line (not shown), and the electromagnetic induction heating is performed. When alternating power is applied to the excitation coil 202 of the second heating element 2 in the device E, the second heating element 2 generates heat, and the second heating element 2 and the first heating element 1 are in an alternating magnetic field. The first heating element 1 is heated by induction current loss and hysteresis loss due to induction heating of the second heating element 2, and the metal cylinder 100 in the first heating element 1 generates heat, and the metal heating element 1 is heated. The heat generation / heat storage material 101 inside the cylindrical body 100 generates heat to, for example, about 800 ° C. by heating.

As shown in FIGS. 1 and 2, the second heating element 2 is located between the cylindrical body 100 of the inner first heating element 1 and the inner body 200 of the second heating element 2 located outside the first heating element 1. A flow path F2 is provided.
A first flow path F1 is provided outside the second flow path F2 and outside the second heat generating element 2.
The first flow path F <b> 1 is formed between the electromagnetic induction heating device main body I and the outer body 201 of the second heating element 2.

The non-heating medium W introduced into the first flow path F1 from the inlet 4 of the non-heating medium W of the electromagnetic induction heating device E is the second heating element 2 and the first heat generation as shown in FIGS. It flows through the first flow path F1 and then the second flow path F2 without contacting the body 1.
As shown in FIGS. 1 and 2, the non-heating medium W introduced into the first flow path F1 moves down the first flow path F1 and then flows up the second flow path F2.
The non-heating medium W joins at the upper part of the inner body 200 of the second heating element 2 and is discharged from the discharge port 5 of the non-heating medium W of the electromagnetic induction heating device E. The non-heating medium W discharged from the discharge port 5 is circulated between a heater and the like as will be described later.

  As described above, the second heating element 2 has the excitation coil 202, and by applying alternating power to the excitation coil 202 of the second heating element 2, the second heating element 2 generates heat, and the Due to the electromagnetic induction action with the first heating element 1, an eddy current is generated and the first heating element 1 generates heat, so that the non-heating medium W introduced into the first flow path F1 is as described above. Since it is heated by the second heating element 2 in the first flow path F1 and heated by the first heating element 1 and the second heating element 2 in the second flow path F2, it is heated with extremely high thermal efficiency. can do. The heat generation / heat storage material 101 in the first heating element 1 generates heat to, for example, about 800 ° C. by heating and can store heat, so even if the non-heating medium W is circulated between the heater and the like, The non-heating medium W that has been circulated again with extremely high thermal efficiency without being cooled can be heated.

In the electromagnetic induction heating device E of the present invention, the second heating element 2 is heated and the first heating element 1 and the second heating element 2 are heated in the second flow path F2. The temperature of the medium W is increased at a high speed, becomes high temperature in a short time, the bacteria and viruses are easily killed, the molecular level is small, and the molecular level is small and the nano level.
Since the non-heating medium W flows through the first flow path F1 and the second flow path F2 without being in contact with the second heat generating element 2 and the first heat generating element 1, the heat loss is small and the heat efficiency is high.
The first heating element 1 includes a heat generation / storage material 101 that generates heat by heating inside a metal cylinder 100, and is heated to a temperature as high as 500 ° C. or more, preferably 600 ° C. to 900 ° C. by electromagnetic induction. The desired temperature in the region can be exothermed. If the heat generation / heat storage material 101 is a mass obtained by solidifying an electromagnetic induction heat generation material (material) in a granular form by sintering, the heating efficiency of the non-heating medium W by the heat generation / heat storage material 101 is improved. Can do.
The electromagnetic induction heating device E of the present invention hardly dissipates useless heat, and does not waste heat generated from both the first heating element 1 and the second heating element 2 due to electromagnetic induction, so that the non-heating medium W can be used. Can be used for heating.
Further, in the electromagnetic induction heating device E of the present invention, the excitation coil 202 of the second heating element 2 to which the alternating power is applied is covered, and the excitation coil 202 is prevented from being exposed to the non-heating medium W. As a result, it is possible to reduce, for example, damage (corrosion and disconnection) of the exciting coil 202 and increase reliability.
According to the electromagnetic induction liquid heating apparatus E of the present invention, as described above, most of the heat generated by the excitation coil 202 of the second heating element 2 and the electromagnetic induction heating of the first heating element 1 is not heated. Since it is used for heating W, the ripening apparatus has extremely high thermal efficiency and can prevent the exciting coil 202 from being damaged as much as possible.
Further, for example, if the cylindrical body 100 of the first heating element 1 and the inner body 200 and outer body 201 of the second heating element 2 are made of a nonmagnetic metal (alloy), the electromagnetic induction heat generation performance is not deteriorated. Has the advantage of preventing rust.

Another example of the electromagnetic induction heating device E of the present invention will be described with reference to FIG.
The electromagnetic induction heating device E shown in FIG. 3 is substantially the same as the electromagnetic induction heating device E shown in FIGS. 1 and 2 except that a third flow path is provided.
The electromagnetic induction liquid heating apparatus E shown in FIG. 3 includes an inner first heating element 1 and a second heating element 2 located outside the first heating element 1 as shown in FIG. In this respect, the electromagnetic induction heating device E shown in FIGS. 1 and 2 is almost the same, but the flow path of the non-heating medium W in the electromagnetic induction heating device E is the electromagnetic induction shown in FIGS. Unlike the induction heating device E, the electromagnetic induction liquid heating device E shown in FIG. 3 has two flow paths, a first flow path F1 and a second flow path F2, outside the second heating element 2. A third flow path F3 is provided between the first heating element 1 and the second heating element 2.
Since the electromagnetic induction heating device E shown in FIG. 3 and the electromagnetic induction heating device E shown in FIGS. 1 and 2 are substantially the same, detailed description thereof will be omitted. For example, the heat generating / heat storage material 101 is formed inside the metal cylinder 100, and the metal cylinder 100 constituting the inner first heating element 1 is, for example, a non-magnetic system. The heat-generating / heat-storage material 101 is made of a metal (alloy) or the like, and the heat-generating / heat-storage material 101 can generate heat to a desired temperature in a high temperature range of 500 ° C. or higher, preferably 600 ° C. to 900 ° C. by electromagnetic induction. In addition, a heat-generating / heat-storing material that can store heat and can heat the non-heating medium W in the first flow path F1 by heat storage is used, for example, metal, carbon, etc. Can be composed of magnetic material, concrete For example, a material obtained by solidifying a kneaded product of metal particles and a solid material (glass, ceramic, cement, etc.) or a material obtained by cutting a metal wire or a metal waste material and solidifying with a solid material similar to the above. As the heat generation / heat storage material 101, a material solidified by sintering is preferable in that the heat generation / heat storage function is excellent, and the heat generation / heat storage material 101 is a solidified lump, as shown in the figure. A large number of metal cylinders 100 are filled.

The second heating element 2 located outside the first heating element 1 has, for example, a structure in which a heating element 202 is built inside covered with an inner body 200 and an outer body 201, as shown in the figure. The inner body 200 is made of, for example, a metal cylinder, for example, a non-magnetic metal (alloy), specifically, for example, non-magnetic stainless steel. Although omitted, an electric insulator is wound, an exciting coil (electric wire) 202 is wound as a heating element 202 from above the electric insulator to form a solenoid body, and the second heating element 2 is formed. An enameled wire as an example of an exciting coil (electric wire) 202 is spirally wound to form a solenoid body, the exciting coil 202 is pulled out from the solenoid body, and alternating power is applied from the lead wire 203 to the second Emits heating element 2 It is to be in.
As described above with reference to FIG. 1, in the electromagnetic induction heating device E, the lead wire 203 led out from the exciting coil 202 of the second heating element 2 is electrically connected to the power supply line, and the electromagnetic induction heating device. When an alternating power is applied to the excitation coil 202 of the second heating element 2 in E, the second heating element 2 generates heat, and the second heating element 2 and the first heating element 1 are placed in an alternating magnetic field, The first heating element 1 is heated by induction current loss and hysteresis loss due to induction heating of the second heating element 2, and the metal cylinder 100 in the first heating element 1 generates heat, and the metal heating element 1 is also made of the metal. The heat generation / heat storage material 101 inside the cylinder 100 generates heat to, for example, about 800 ° C. by heating.

The electromagnetic induction heating device E shown in FIG. 3 is also the same as the electromagnetic induction heating device E shown in FIGS. 1 and 2 of the embodiment, and the cylindrical body 100 of the inner first heating element 1 and the first heating element 1. A flow path is provided between the second heating element 2 and the inner body 200 located on the outer side, and a third flow path F3 is provided.
A first flow path F1 and a second flow path F2 are provided outside the third flow path F3 and outside the second heating element 2.
In the electromagnetic induction heating device E shown in FIG. 3, a first flow path F <b> 1 that is partitioned by, for example, providing a partition 6 between the electromagnetic induction liquid heating device main body I and the outer body 201 of the second heating element 2. And the 2nd flow path F2 is provided.

In the electromagnetic induction heating device E shown in FIG. 3, the non-heating medium W introduced from the inlet 4 of the non-heating medium W below the electromagnetic induction heating device E is, as shown in FIG. F1 is raised, sequentially the second flow path F2 is lowered, and then the third flow path F3 is raised.
As shown in FIG. 3, the non-heating medium W is not in contact with the second heating element 2 or the first heating element 1, and the first flow path F1, the second flow path F2, and then the third flow It flows in the road F3.
The non-heating medium W joins at the upper part of the first heating element 1 through the upper part of the inner body 200 of the second heating element 2 and is discharged from the outlet 5 of the non-heating medium W of the electromagnetic induction heating device E. The non-heating medium W discharged from the discharge port 5 is circulated between a heater and the like as will be described later.

As described above, the second heating element 2 has the excitation coil 202, and by applying alternating power to the excitation coil 202 of the second heating element 2, the second heating element 2 generates heat, and the Since the first heating element 1 generates heat by the electromagnetic induction effect with the first heating element 1, the non-heating medium W introduced into the second channel F2 via the first channel F1 is as described above. Furthermore, since it is heated by the second heating element 2 in the second flow path F2 and heated by the first heating element 1 and the second heating element 2 in the third flow path F3, it is extremely high. It can be heated with thermal efficiency. The heat generation / heat storage material 101 in the first heating element 1 generates heat to, for example, about 800 ° C. by heating and can store heat, so even if the non-heating medium W is circulated between the heater and the like, The non-heating medium W that has been circulated again with extremely high thermal efficiency without being cooled can be heated.
Other effects similar to those of the electromagnetic induction heating device E shown in FIGS.

Still another example of the electromagnetic induction heating device E of the present invention will be described with reference to FIG.
The electromagnetic induction heating device E shown in FIG. 4 is provided on the inner side first heating element 1, the second heating element 2 positioned outside the first heating element 1, and the second heating element 2. The third heating element 3, the first flow path F1 provided outside the third heating element 3, the second flow path F2 provided inside the third heating element 3, and the first heating element 1 And a third flow path F3 provided between the second heat generating element 2 and the non-heating medium introduced into the first flow path F1 includes the third heat generating element 3, the second heat generating element 2, and the second heat generating element 2. By flowing through the first flow path F1, the second flow path F2, and the third flow path F3 without contacting the first heat generation element 1 and applying alternating power to the second heat generation element 2, the second heat generation element 2 generates heat, and due to the electromagnetic induction action between the first heating element 1 and the third heating element 3, the first heating element 1 and the third heating element 3 generate heat. The non-heating medium W introduced into the first flow path F1 is heated by the third heating element 3 in the first flow path F1, and then in the second flow path F2, the second heating element 2 and the third heating element 3 are heated. The heating element 3 is configured to be heated by the first heating element 1 and the second heating element 2 in the third flow path F3.
The electromagnetic induction liquid heating apparatus E shown in FIG. 4 applies the alternating power to the excitation coil 202 of the second heating element 2, thereby generating the second heating element 2 and generating the second heating element 2. An eddy current is generated not only by the inner first heating element 1 but also by the third heating element 3 outside the second heating element 2 by electromagnetic induction, and the first heating element 1 and the third heating element. 3 generate heat, the non-heating medium W introduced into the first flow path F1 is heated by the third heating element 3 in the first flow path F1, and then in the second flow path F2. Since it is heated by the second heating element 2 and the third heating element 3 and also heated by the first heating element 1 and the second heating element 2 in the third flow path F3, FIG. Compared with the electromagnetic induction heating device E shown in FIG. It can be.
4, in the electromagnetic induction heating device E shown in FIG. 4, the second heating element 2 is provided with a cavity C, and the second heating element 2 is provided by the cavity C as described above. When alternating power is applied to the first heating element 1 and the third heating element 3 on both sides of the second heating element 2, both the first heating element 1 and the third heating element 3 may generate heat and be overheated. it can.
Others are the same structure as the electromagnetic induction heating apparatus E shown in FIG.1, FIG2 and FIG.3, and since the same effect is show | played, detailed description is abbreviate | omitted.
The third heating element 3 preferably has the same configuration as the first heating element 1 and is formed, for example, by incorporating a heat generation / heat storage material 101 inside a metal cylinder 100.
The metal cylinder 100 constituting the inner first heating element 1 may be made of a diamagnetic metal such as copper or a paramagnetic metal such as aluminum, but is a nonmagnetic metal (alloy). This is preferable because there is an advantage that rust can be prevented without deteriorating the electromagnetic induction heat generation performance. Here, non-magnetic does not include ferromagnetism and means diamagnetism or paramagnetism.
The heat generation / heat storage material 101 is an electromagnetic induction type heat generation material capable of generating heat to a desired temperature in a high temperature range of 500 ° C. or more, preferably 600 ° C. to 900 ° C. by electromagnetic induction, and stores heat. In the second flow path F2, an exothermic / heat storage material that can heat the non-heating medium W by heat storage is used. For example, it can be composed of a magnetic material such as metal or carbon. Specifically, for example, a kneaded mixture of metal particles and a solid material (glass, ceramic, cement, etc.), or a metal wire wire or metal waste material is cut and solidified with a solid material similar to the above. Things. As the heat generation / heat storage material 101, a material solidified by sintering is preferable in that the heat generation / heat storage function is excellent.
The heat-generating / heat-storage material 101 is a solidified lump, and a large number of the heat-generating / heat-storing material 101 is filled in the metal cylinder 100 as illustrated.

As shown in FIG. 5, the electromagnetic induction heating device E of the present invention can be used for various heating applications such as floor heating 7, central heating 8, or fan convector 9.
The fan convector 9 warms the entire room with warm water, and can be composed of, for example, a blower, a heat exchanger, and an air filter.
You may enable it to supply cold water and warm water as needed.

Hot water introduced from the inlet 4 of the electromagnetic induction heating device E and discharged from the outlet 5 is sent to the pump 11 through the expansion tank 10, and the floor heating 7, the central heating 8 or the fan vector 9 It is sent to parts and facilities that require various types of heating.
The pump 11 is operated by driving a pump switch 12. In the present invention, the operation of the switch 12 can be performed in a single phase 100v.
The electromagnetic induction heating device E can be implemented with a rated voltage of a single phase of 200 v, a rated current of 25 A, and a frequency of 50/60 Hz. The power supply side of the electromagnetic induction heating device E is connected to the breaker 13, the switch 14, and the control device 15, and the control device 15 controls the heating temperature and the like of the non-heating medium W. In the electromagnetic induction heating device E, the pump switch 12 and the power supply side switch 14 can be appropriately turned on and off to operate, thereby saving power.

  As shown in FIG. 6, the electromagnetic induction heating device E of the present invention is connected to a part or facility that requires various types of hot water, such as a kitchen 16, a bath 17, and a wash surface 18. Hot water can be supplied to a site or facility that requires the hot water. In the hot water supply device X including the electromagnetic induction heating device E and a part or facility that requires various types of hot water such as the kitchen 16, the bath 17, and the wash surface 18, as illustrated, the pump 19, the tank 20, the pump 21, Hot water is supplied to parts or facilities that require various types of hot water such as the kitchen 16, the bath 17, and the wash surface 18 through the header 22 and the header 23. In the hot water supply apparatus X, a main water supply pipe or a main hot water supply pipe is branched into a plurality of branch pipes via headers 22 and 23, and these branch pipes are respectively associated with the kitchen 16, bath 17 and wash basin 18 (all of which are mixing plugs). Header-type water and hot water supply pipes that are connected to the faucets of water-circulating facilities such as

As shown in FIG. 7, a plurality of electromagnetic induction heating devices E of the present invention can be installed to perform heating and hot water supply as described above. FIG. 7 shows an example in which two electromagnetic induction heating devices E are installed to perform the heating / hot water supply as described above. However, three or more electromagnetic induction heating devices E are installed as described above. Heating and hot water supply may be performed. Even when two electromagnetic induction heating devices E are installed to perform the heating / hot water supply as described above, the floor heating 7 and the central heating 8 are passed through the expansion tank 10 and the compression pump 11 as shown in FIG. Alternatively, hot water is sent to parts or facilities that require various types of heating, such as Fancon Vector-9, or parts or equipment that require various types of hot water, such as the kitchen 16, bath 17, and wash surface 18 as shown in FIG. Is done.
Even when two electromagnetic induction heating devices E are installed, the control device 15 can control the heating temperature or the like of the non-heating medium W according to the number of the electromagnetic induction heating devices E.
In the said electromagnetic induction heating apparatus E, the water etc. according to the kind etc. of the non-heating medium W from the non-heating medium extraction part F can be suitably drained.

Next, a heating device using the electromagnetic induction heating device E of the present invention will be described.
As shown in FIG. 8, the basic configuration of the heating device H of the present invention includes the electromagnetic induction heating device E and the heating radiator 24.
As shown in FIG. 8, in the heating device H, the electromagnetic induction heating device E and the heating radiator 24 are connected by pipes 25a and 25b, and the electromagnetic induction heating device E is connected by a pipe (outward pipe) 25a. The non-heating medium W heated by electromagnetic induction is sent to the heating radiator 24, and heating is performed by natural convection or radiation in the heating radiator 24. Next, the non-heating medium W is heated by the heating radiator 24. It is sent from the heat radiator 24 to the pipe (return pipe) 25b and returned to the electromagnetic induction heating device E again.
In the circulation path between the electromagnetic induction heating device E, the heating radiator 24, the forward pipe 25a, and the return pipe 25b, the pump devices 11a and 11b are arranged as described above, and the electromagnetic induction heating device is provided. The non-heating medium W that is circulated and heated is supplied between E and the heat radiator 24 for heating, and the heating non-heating medium W that is circulated and supplied by the heating radiator 24 The above-mentioned floor heating 7, central heating 8, or fan convector-9 can be used to heat a portion or facility 26 that requires heating.
In the heating device H, basically, the electromagnetic induction heating device E, the heating radiator 24, and the pipes 25a and 25b are sufficient. However, as shown in FIG. 11b and the inlet 4 of the non-heating medium W, and the control device 13 controls the flow rate of the non-heating medium W sent to the inlet 4 of the non-heating medium W, or the temperature of the heated non-heating medium W. It is preferable to control the current when the alternating power is applied to the exciting coil 202 in the second heating element 2 of the electromagnetic induction heating device E or the like. Further, it is preferable to provide a monitoring device 27 such as an indoor monitor or an indoor sensor to perform detection and monitoring.
Although not shown, the expansion tank 10 necessary for controlling the flow rate of the non-heating medium W shown in FIG. 5 is provided, or the air vent valve 28 necessary for venting the air from the non-heating medium W is provided. An accumulator or a reserve tank may be provided.

The heating radiator 24 can radiate a medium heated at a remote place. The heating radiator 24 radiates most of the heat by radiation and convection. Heating by natural convection using the radiator 24 for heating is also possible.
It can be used for heat insulation as well as for heating, and the heating device H of the present invention includes the case of the heat insulation. The radiator 24 for heating is warmed by the non-heating medium W supplied from the electromagnetic induction heating device E of the present invention as a heat source device.
Examples of the non-heating medium W include water, a heating medium, and an antifreeze liquid. The heat medium is a liquid or gas that transports heat. The liquid is usually water, but antifreezing liquid is preferable in consideration of heating in a cold region. When the liquid is composed of an antifreeze liquid, heating is performed satisfactorily without freezing even in heating in a cold region. In the heating device of the present invention, the first heating element 1, the second heating element 2, and the third heating element 3 are hermetically sealed and not in contact with the non-heating medium W, and the non-heating medium W is the first heating element. 1, in the first flow path F1 and the second flow path F2 that do not contact the second heat generation element 2 and the third heat generation element 3, or in the flow path of the first flow path F1, the second flow path F2, and the third flow path F3 It is configured to be suitable for the use of antifreeze liquid. The antifreeze is not particularly limited, and examples thereof include ethylene glycol, propylene glycol and the like, and rust prevention for those diluted with water containing the ethylene glycol and propylene glycol as main components. The thing etc. which added the agent etc. are mentioned. In the case of water, it can also be warmed by supplying vapor as a gas. In the electromagnetic induction heating device E of the present invention, the first heating element 1 and the second heating element 2 or the first heating element 1, the second heating element 2 and the third heating element 3 are heated, so that the extremely high thermal efficiency. The heating / heat storage material 101 in the first heating element 1 and the third heating element 3 can be heated to, for example, about 800 ° C. and can store heat. Even if it is circulated, there is an advantage that the non-heating medium W that has been circulated again with extremely high thermal efficiency without being cooled can be heated. Therefore, it is also suitable for steam heating. .
The heating radiator 24 is a device that releases heat to the outside. For example, a radiator that heats the heated liquid through the inside of a pipe or the like by heating from the fin surface or a coil with fins for heat exchange is incorporated. Included are so-called convectors that generate air convection and heat and circulate room air. A heated liquid such as warm water is supplied from one end, and the heated liquid such as warm water is cooled and discharged from the other end as the heat is released.
An example of one convector (panel convector) of the heating radiator 24 will be described with reference to FIGS. 9 and 10.
The convector 24 includes a coil 2400 with a built-in heat dissipating fin (fin) and a casing 2401 covering the coil 2400. A heated liquid such as warm water is supplied from a liquid inlet 2402 to a coil 2400 with a radiating fin (fin), and the heated liquid such as warm water cooled with the release of heat is discharged from a liquid outlet 2403.

The part or facility 26 that requires heating in the present invention includes a part or facility that requires various types of heating such as floor heating 7, central heating 8 or fan convector 9 as described above. Examples include floors, floors, wall surfaces, windows, and toilets. Examples of the type of heating include panel heating, which is a method of heating by radiant heat from a surface such as a floor or a wall that has been heated by passing warm water or the like.
The floor heating (floor heating) 7 of the floor heating can be performed, for example, by installing a pipe on the entire surface under the floor in the room and then covering it with a concrete layer during construction. In the floor heating 7, normally, hot water circulates under the entire floor surface of each room. Pipes, piping and wiring are buried under the floor, and the room is heated gently.
For the heating, there is an underfloor type heating device in which a heating radiator 24 is installed under the floor so as to heat the floor room and the underfloor, and the heating radiator 24 is installed under the floor as a heating means in a cold district. Then, there is one in which warm air generated by the radiator 24 is circulated to heat the upper floor room and the lower floor.

Based on FIG. 11, an example of the underfloor heating device will be described.
The radiator for heating 24 is installed under the floor 700, and the radiator for heating under floor 24 and the electromagnetic induction heating device E are connected by pipes 25a and 25b in the same manner as described above, and the electromagnetic induction heating is performed by the outward pipe 25a. The liquid W heated by electromagnetic induction by the apparatus E is sent to the heating radiator 24 so that the heating radiator 24 performs heating by natural convection or radiation, and then the liquid W is used for the heating heat dissipation. It is sent from the vessel 24 to the return pipe 25b and returned to the electromagnetic induction heating device E again.
The floor 702 that partitions the underfloor 700 and the room 701 is provided with an opening 703 through which warm air can flow into the room 701 and an opening 704 that returns the warm air to the underfloor 700. From the underfloor heating radiator 24, The radiant convection is raised from the opening 703 to warm the room, and the warmed air whose temperature has dropped is returned from the opening 704.

FIG. 12 shows an example in which the heating device is installed in a toilet.
In the said heating apparatus, the radiator 24 for heating is installed in the toilet T, The underfloor heating radiator 24 and the said electromagnetic induction heating apparatus E are connected by piping 25a, 25b like the above, and an outward pipe | tube The liquid W heated electromagnetically by 25a is sent to the heating radiator 24, and heating is performed by natural convection or radiation in the heating radiator 24, and then the liquid W is heated to the heating radiator. 24 is sent out to the return pipe 25b and returned to the electromagnetic induction heating device E again.

In the above embodiment of the present invention, the example in which the heating radiator 24 is installed and the heating is performed via the heating radiator 4 is described. However, the heating is required directly without using the heating radiator 24. The part or facility 26 may be heated.
FIG. 13 shows the embodiment, in which a panel pipe 25C is arranged on the floor 702, and the liquid W heated by the outward pipe 25a is sent from the electromagnetic induction heating device E to the panel pipe 25C. Heating is performed by natural convection or radiation of warm air, and then the liquid W is sent from the panel pipe 25C to the return pipe 25b and returned to the electromagnetic induction heating device E again.

  The present invention is not limited to the above-described embodiments, and can be modified as appropriate. ,

  Although the present invention has been described with respect to heating, the present invention may be applied to cooling and heating, and in various cases other than the above-described embodiments, for example, in order to effectively block cold air from the window, the radiator 24 for heating is installed in the window. The present invention may be applied to the case where it is also used as a device (towel warmer) for installation directly below or for drying with a towel.

It is a block diagram of the electromagnetic induction heating apparatus which shows the Example of this invention. It is sectional drawing of the electromagnetic induction heating apparatus which shows the Example of this invention. It is a block diagram of the electromagnetic induction heating apparatus which shows the other Example of this invention. It is a block diagram of the electromagnetic induction heating apparatus which shows other Example of this invention. It is a block diagram which shows an example of the usage example of the electromagnetic induction heating apparatus of this invention. It is a block diagram which shows an example of the usage example of the electromagnetic induction heating apparatus which shows the other Example of this invention. It is a block diagram of the electromagnetic induction heating apparatus which shows the other Example of this invention. It is a block diagram of the heating apparatus which shows the Example of this invention. It is an external appearance block diagram of an example of the heat radiator for heating used by this invention. (A) It is sectional drawing of the radiator for heating, (B) It is a partial sectional view of the radiator for heating. It is a block diagram of the heating apparatus which shows the Example of this invention. It is a block diagram of the heating apparatus which shows the other Example of this invention. It is a block diagram of the heating apparatus which does not use the radiator for heating which shows the Example of this invention.

DESCRIPTION OF SYMBOLS 1 ... 1st heat generating body 2 ... 2nd heat generating body 3 ... 3rd heat generating body 24 ... Heating radiator 26 ... The site | part or equipment 101 which requires heating ... Heat-generation / heat storage material E ... Electromagnetic induction heating apparatus F1 ... 1st flow Path F2 ... second flow path F3 ... third flow path H ... heating device W ... non-heating medium

Claims (6)

An inner first heating element, a second heating element located outside the first heating element, a first flow path provided outside the second heating element, the first heating element and the second heating element A non-heating medium introduced into the first flow path without contacting the second heat generating element and the first heat generating element. The second heating element generates heat by flowing through two flow paths and applying alternating power to the second heating element, and the first heating element is moved by electromagnetic induction between the first heating element and the second heating element. The non-heating medium that generates heat and is introduced into the first channel is heated by the second heating element in the first channel, and the first heating element and the second heating element in the second channel. It is comprised so that it may be heated by, The electromagnetic induction heating apparatus characterized by the above-mentioned. An inner first heating element, a second heating element located outside the first heating element, a first flow path and a second flow path provided outside the second heating element, and the first heating element And a third flow path provided between the second heating element and the non-heating medium introduced into the first flow path without contacting the second heating element and the first heating element. By flowing through the first flow path, the second flow path, and the third flow path, and applying alternating power to the second heating element, the second heating element generates heat, and electromagnetic waves between the first heating element and the second heating element are generated. Due to the inductive action, the first heating element generates heat, and the non-heating medium introduced into the first flow path is heated by the second heating element in the second flow path and also into the third flow path. The electromagnetic induction heating device is configured to be heated by the first heating element and the second heating element. An inner first heating element, a second heating element located outside the first heating element, a third heating element provided outside the second heating element, and provided outside the third heating element A first flow path, a second flow path provided inside the third heating element, and a third flow path provided between the first heating element and the second heating element, The non-heating medium introduced into the first flow path flows through the first flow path, the second flow path, and the third flow path without contacting the third heat generation element, the second heat generation element, and the first heat generation element. By applying alternating power to the second heating element, the second heating element generates heat and electromagnetic induction between the first heating element and the third heating element causes the first heating element and the second heating element to generate heat. The three heating elements generate heat, and the non-heating medium introduced into the first flow path is heated by the third heating element in the first flow path. It is configured to be heated by the second heating element and the third heating element in the flow path and to be heated by the first heating element and the second heating element in the third flow path. Electromagnetic induction heating device. 4. The electromagnetic induction according to claim 1, wherein the first heating element includes a heat generation / heat storage material capable of generating heat and storing heat inside a metal cylinder. Heating device. The part which requires heating by the heating medium supplied from the electromagnetic induction heating apparatus by connecting the electromagnetic induction heating apparatus according to claim 1, 2, 3 or 4 and the part or equipment which requires heating. Or the heating apparatus using the electromagnetic induction heating apparatus characterized by heating an installation. The electromagnetic induction heating device according to claim 1, 2, 3, or 4 is connected to a part or facility that requires hot water, and hot water is supplied from the electromagnetic induction heating device to the part or facility that requires the hot water. A hot water supply apparatus using an electromagnetic induction heating device, wherein

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