JP2015021647A - Superheated steam-generating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a superheated steam-generating device capable of regulating the temperature of the generating superheated steam in good response thereto sharply over a wide range.SOLUTION: A superheated steam-generating device comprises: a heating container made of an electrically conductive metal for storing water inside; a first induction heating coil provided along an outer circumference of the heating container for generating steam by induction-heating the heating container to heat the inside water; a magnetic absorber provided along the circumference of the induction heating coil; a heating tube provided along an outer circumference of the magnetic absorber and made by winding an electrically conductive metal tube helically, through which the steam generated from the heating container is communicated inside; and a second induction heating coil provided along an outer circumference of the heating tube for generating superheated steam by induction-heating the heating tube to heat the inside steam.

Description

  The present invention relates to a superheated steam generator in which water is heated by induction heating to generate steam, particularly superheated steam.

  A superheated steam generator by induction heating is conventionally known from Patent Document 1, Patent Document 2, and the like.

  The structure of the conventional superheated steam generator described in patent document 1 is shown in FIG.

  In FIG. 3, the superheated steam generator 100 includes a heating tube 110 configured by spirally winding a conductive hollow metal tube 111 in the vertical direction. Between each turn of the metal tube 111 of the heating tube 110 or at least between the winding start end and the winding end end of the metal tube 11 is electrically connected by the connecting member 115, and the heating tube 110 as a whole has an electrical closed circuit. It is composed. The heating tube 110 forms a fluid passage 112 in which the hollow passage of the metal tube 111 is continuous. The heating tube 110 is accommodated in a heat insulating container 119 filled with a heat insulating material 118. Both the heat insulating material 118 and the heat insulating container 119 are made of a non-magnetic and non-conductive heat-resistant material.

  An induction heating coil 120 having a cylindrical shape is disposed around the outer periphery of the heat insulating container 119 by winding a coil conductor 121 having a cooling water passage 122 in a spiral shape a required number of times. The induction heating coil 120 is connected to the induction heating coil 120 and is energized by the AC power supply 140 to generate an AC magnetic field to induction-heat the internal heating tube 110.

  Further, in order to prevent the high-frequency magnetic field generated by the induction heating coil 120 from leaking outside the induction heating coil 120, a magnetic field composed of a plurality of (here, four) ring coils 131-134. A shield coil 130 is disposed.

  Then, a water supply pipe 113 that electrically insulates from the coil conductor 121 and feeds water from the outside is connected to the start end of the cooling water passage 122 of the induction heating coil 120, and the end of the cooling water passage is similarly insulated to connect the connection pipe 126 The cooling water passage 122 of the induction heating coil 120 and the fluid passage 112 of the heating tube 110 are communicated with each other by connecting to the start end of the heating tube 110.

  Further, the ring coils 131 to 134 of the magnetic seed coil 130 closed in the shape of four rings are configured as shown in FIGS. 4 (a) and 4 (b), respectively. FIG. 4 shows a configuration of the ring coil 131 as a representative.

  The ring coil 131 is formed into a circular ring by bending a tubular conductor 131a having a hollow cooling water passage 131b therein into a circular shape and coupling both ends. The cooling water passage 131b in the conductor 131a is also a closed-loop cooling water passage because the conductor 131a is a ring. By inserting a partition piece 131c at the junction of the ring-shaped cooling water passage 131b, the cooling water passage The loop of the passage is interrupted. In the vicinity of both ends of the cooling water passage 131b of the ring coil 131, outlet pipes 131d and 131e communicating with the cooling water passage 131b are provided. The ring coils 132 to 134 have the same configuration as the ring coil 131.

  As shown in FIG. 3, the outlet pipes of the ring coils 131 to 134 are sequentially electrically insulated and cascade-connected by connecting pipes 135 to 137, so that the cooling water passages 131b to 134b in each ring coil are connected in series. Connecting.

  The end (exit side end) of the fluid passage 12 of the heating pipe 110 is electrically insulated via the connection pipe 127 and connected to the outlet pipe 131d on the inlet side of the uppermost ring coil 131 of the magnetic shield coil 130. Thus, the fluid passage 112 of the heating pipe 110 is connected to the cooling water passage of the magnetic shield coil 130. A steam pipe 114 for taking out steam is connected to the outlet side outlet pipe 134e of the lowermost ring coil 134 of the shield coil 130.

  In the conventional superheated steam generator 100 configured as described above, the cooling water passage 122 of the induction heating coil 120 is provided on the inlet side of the fluid passage 112 of the heating pipe 110, and the cooling water passage of the magnetic shield coil 130 is provided on the outlet side. All the cooling water passages and fluid passages are connected in series.

  For this reason, the water supplied from the water supply pipe 113 flows in series in the order of the induction heating coil 120, the heating pipe 110, and the magnetic shield coil 130.

  In normal operation, when the induction heating coil 120 is energized by an AC power source, the induction heating coil 120 generates heat due to a current flowing through itself. Further, the magnetic shield coil 130 cancels out the magnetic field leaking from the induction heating coil 120 to the outside by the magnetic field generated by the current induced in each ring coil 131 by the AC magnetic field generated by the induction heating coil 120. Although it suppresses leakage of the magnetic field, the magnetic shield coil 130 also generates heat due to the current flowing at this time. In order to prevent the induction heating coil 120 and the magnetic shield coil 130 from being overheated by the generated heat, the cooling water is passed through the cooling water passage to cool it. The heat was released as a loss.

  However, in this conventional superheated steam generator 100, the water supplied from the water supply pipe 113 is supplied to the heating pipe 110 through the induction heating coil 120, so that it is cooled in the process of passing through the induction heating coil 120. Since the water preheated by the above is heated by the heating tube 110 to generate water vapor, the heat loss from the induction heating coil 120 can be recovered, and the thermal efficiency of the steam generator can be increased.

  Further, since the outlet at the end of the heating pipe 110 is connected to the cooling water passage of the magnetic shield coil 130 via the connection pipe 127, the water vapor generated in the heating pipe 110 passes through the cooling water passage of the magnetic shield coil 130. It can be taken out from the steam pipe 114. In the process of passing the steam generated in the heating pipe 110 through the cooling water passage of the magnetic shield coil 130, it can be reheated to the superheated steam by the heat generated by the magnetic shield coil 130. Can be generated.

JP 2011-122804 A JP 2007-178089 A

  As described above, the conventional superheated steam generator can efficiently generate superheated steam, but the magnetic shield coil 130 that reheats the steam generated in the heating tube 110 to generate superheated steam is inductively heated. Since the magnetic flux generated in the coil 120 is provided to prevent leakage to the outside, the amount of generated magnetic flux changes when the current supplied to the induction heating coil 120 is changed. Since the amount of saturated steam generated in the tube 110 and the amount of heat generated by the magnetic shield coil 130 change, the temperature of the superheated steam at the outlet can be roughly adjusted, but cannot be accurately adjusted to a high range. However, there is a problem that cannot be applied to food heating applications that require a high temperature.

  In order to eliminate such problems, an object of the present invention is to provide a superheated steam generator capable of finely adjusting the temperature of the generated superheated steam over a wide range with good response.

  In order to solve the above-mentioned problems, the present invention is composed of a conductive metal material, a heating container that stores water therein, and is disposed on the outer periphery of the heating container. A saturated steam generating section is composed of a first induction heating coil that heats and generates water vapor and a first magnetic shield disposed on the outer periphery of the induction heating coil, and generates the saturated steam in an internal fluid flow passage. A conductive metal tube through which water vapor generated in the section flows is spirally wound to form a cylindrical shape, and a heating tube disposed on the outer periphery of the first magnetic shield, and an outer periphery of the heating tube The heating pipe is induction-heated to re-heat the internal water vapor to generate superheated water vapor to form a superheated water vapor generating section.

  In the present invention, it is preferable to generate steam by supplying high-frequency AC power to the first and second induction heating coils.

  In the present invention, the heating container is configured to supply water from the lower part of the container and take out water vapor from the upper part, and to provide a plurality of inclined baffle plates at the upper part of the container to separate the gas and liquid of the water vapor. be able to. This baffle plate is preferably a perforated plate in which a large number of through holes are dispersedly formed.

  According to the present invention, the heating pipe of the superheated steam generating section that reheats saturated steam to generate superheated steam is configured by winding a conductive metal pipe in a solenoid shape into a cylindrical shape, thereby reducing the heating area of the steam. Since it can be enlarged, the temperature of the generated superheated steam can be controlled within a high range and with high accuracy. In addition, since the heating vessel that generates saturated steam and the heating pipe that generates superheated steam are induction-heated by separate induction heating coils, the amount of saturated steam and superheated steam temperature can be controlled with high accuracy, It can be widely used for heating foods.

It is a longitudinal cross-sectional view which shows typically the structure of the Example of the superheated steam generator of this invention. It is a fragmentary sectional view which shows the Example of the heating container used for the superheated steam generator of this invention. It is an elevational view including the partial cross section which shows the structure of the conventional superheated steam generator. The structure of the magnetic shield coil used for the conventional superheated steam generator is shown, (a) is a perspective view. (B) is a plan view.

  Embodiments of the present invention will be described with reference to the embodiments shown in the drawings.

  FIG. 1 is a longitudinal sectional view schematically showing a configuration of a superheated steam generator according to a first embodiment of the present invention.

  In FIG. 1, 1 is a superheated steam generator, which heats the water in the container 11 by induction heating the heating container 11 that stores the water W supplied from the water supply pipe 31 at a predetermined water level and the heating container 11. And a saturated water vapor generating unit 10 including a first induction heating coil 12 that generates saturated water vapor S. The heating container 11 constitutes a cylindrical container sealed with a conductive metal material, for example, stainless steel. A water supply pipe 31 that supplies water W from an external water supply source is connected to the bottom of the heating container 11, and one end of a steam pipe 32 that sends water vapor S generated inside the container is connected to the top of the heating container 11. The outer periphery of the heating container 11 is covered with a heat-insulating layer 13 made of a non-conductive heat-resistant material having high heat insulation, for example, heat-resistant cement, and heat radiation from the heating container 11 to the outside is blocked. The induction heating coil 12 is formed in a cylindrical shape by winding a coil conductor around the outer periphery of the heating container 11 in a spiral shape. The induction heating coil 12 can be configured to be cooled by the cooling fluid by using a hollow tubular conductor in which a passage for passing the cooling fluid is formed as a coil conductor.

  In order to prevent the magnetic flux generated by the induction heating coil 12 from leaking to the outside, the first magnetic shield 14 is disposed on the outer periphery of the induction heating coil 12 so as to surround it. The magnetic shield 14 is formed in a cylindrical shape with a high-resistance magnetic material such as an iron oxide sintered body (ferrite) or a laminated body of silicon steel plates so that no induced current flows.

  Further, a conductive metal tube having a hollow fluid flow passage inside, for example, a stainless steel tube, is spirally wound around the outer periphery of the first magnetic shield 14 to form a cylindrical shape. The heating tube 21 through which the gas flows is arranged. The heating tube 21 is electrically connected between each turn or at least between a winding start end and a winding end end to form one or more closed-loop electric circuits.

Moreover, the heating tube 21 is configured to be enclosed by a heat insulating layer 23 formed of a non-conductive heat-resistant material having high heat insulation properties, for example, fire-resistant cement, so as to block heat radiation to the outside. A second induction heating coil 22 configured in a cylindrical shape by winding a coil conductor in a spiral shape is disposed on the outer periphery of the heating tube 21 encased by the heat insulating layer 23, and on the outside thereof, similarly to the first magnetic shield 13. A second magnetic shield 24 formed in a cylindrical shape with a high-resistance magnetic material is disposed. The heating pipe 21, the second induction heating coil 22, and the second magnetic shield 24 constitute the superheated steam generator 20. Similarly to the first induction heating coil 12, the second induction heating coil 22 uses a hollow tubular conductor in which a cooling fluid passage is formed as the coil conductor and is cooled by the cooling fluid. The other end of the steam pipe 32 whose one end is in communication with the top of the heating vessel 11 of the steam generation unit 10 is connected to the winding end of the lower end of the steam heating pipe 21 in the superheated steam generation unit 20. Thereby, the heating container 11 and the heating pipe 21 are communicated with each other by the steam pipe 32. A steam take-out pipe 33 for taking out superheated steam to the outside is coupled to the end of the upper end of the heating pipe 21.

  The operation of the superheated steam generator 1 of the present invention configured as described above will be described.

  After the water W supplied from the external water supply source through the water supply pipe 31 is stored in the heating container 11 to a predetermined water level, the first and second induction heating coils 12 and 22 can be controlled independently of high frequency. For example, high frequency power of about 10 to 30 kHz is supplied from an AC power source. By supplying high-frequency power in this way, high-frequency AC magnetic fields are generated from the induction heating coils 12 and 22, respectively.

  Due to the high-frequency magnetic field generated by the first induction heating coil 12, an induction current flows through the container wall of the heating container 11 formed of a cylindrical container, and the container wall generates heat due to Joule heat generated by the induction current. The water W stored in the heating container 11 that generates heat due to Joule heat is heated to generate saturated water vapor (water vapor containing water) S, which is stored in the upper space of the heating container. As a result, the pressure in the heating container 11 is increased, so that the saturated steam S stored in the container 11 is sent to the heating pipe 21 through the steam pipe 32. The amount of water vapor sent from the heating container 11 to the heating tube 21 can be adjusted by controlling the high frequency power supplied to the first induction heating coil 12.

  Magnetic flux that leaks to the outside due to the high-frequency magnetic field generated by the first induction heating coil 12 for induction heating of the heating container 11 is absorbed by the cylindrical magnetic shield 14 provided on the outer periphery of the first induction heating coil 12. In addition, since leakage to the outside is prevented, the magnetic field generated by the first induction heating coil 11 does not affect the heating tube 21 arranged on the outside thereof.

  An induction current is generated in the heating tube 21 by the high-frequency magnetic field generated by the second induction heating coil 22. Due to this induced current, the heating tube 21 generates Joule heat to generate heat, and in the process in which the steam S supplied from the heating vessel 11 flows through the flow path in the tube, this heat is reheated to generate superheated steam SH. Is done. The superheated steam SH generated in the heating pipe 21 is taken out from the steam take-out pipe 33 and supplied to a load that uses steam.

  The magnetic flux leaking to the outside due to the magnetic field generated by the second induction heating coil 22 is absorbed by the cylindrical magnetic shield 24 arranged on the outer periphery of the coil 22 and is prevented from leaking to the outside. Can be deterred. Moreover, since leakage to the first induction heating coil 11 side is blocked by the first magnetic shield 13, the magnetic field generated by the second induction heating coil 22 affects the heating container 11 and the first induction heating coil 12. Is also suppressed.

  The high-frequency AC power supplied to the second induction heating coil 22 can be controlled independently without being influenced by the high-frequency AC power supplied to the first induction heating coil 12, so that the second induction heating coil 22 is controlled. The temperature of the superheated steam SH generated by controlling the high-frequency power supplied to can be freely adjusted. In the present invention, in particular, the heating tube 21 is formed in a cylindrical shape by winding a conductive metal tube many times in a spiral shape, so that the heating area of the heating tube 21 with respect to water vapor flowing through the inside is expanded. As a result, the heating efficiency increases, the temperature of the superheated steam responds to the control of the high-frequency power supplied to the induction heating coil 21 at a high speed, and the temperature of the superheated steam is accurately adjusted to any temperature within the range of 100 to 300 ° C. can do.

  According to this invention, the amount of saturated steam generated and the temperature of superheated steam can be individually finely adjusted by individually controlling the power supplied to the first induction heating coil 12 and the power supplied to the second induction heating coil. it can.

  FIG. 2 shows a modification of the heating container 11 as a second embodiment of the present invention.

  In this embodiment, a plurality of baffle plates 15 are provided in the upper space of the heating container 11 serving as a storage space for the generated water vapor in order to obstruct the flow of water vapor. Each baffle plate 15 is coupled to the opposing left and right side walls of the heating container 11 with their base ends alternately shifted from each other, and the tip ends are inclined at a predetermined angle in the upward direction, and are zigzag spaced apart from each other. Arranged.

  Each baffle plate 15 is a flat plate provided with a through-hole through which water droplets flow at least at the base end, or a perforated plate in which a plurality of through-holes are distributed over the entire surface, or a net plate formed of a metal net. Can be configured.

  When a plurality of baffle plates 15 are provided in a zigzag shape in the upper space of the heating container 11 in this way, the water vapor S generated in the container 11 flows upward and hits the baffle plate 15 in the upper part of the container 21 to flow the water vapor. Is disturbed. For this reason, the flow of the water vapor S is a zigzag flow in the upper space of the heating vessel 11 as shown by the arrow in FIG. When the water vapor flow is forcibly deflected in a zigzag manner in this way, turbulent flow is generated in the water vapor flow. Are combined with each other to increase the size and weight. Moisture with increased weight falls by its own weight and is separated from water vapor. The separated water is guided to the baffle plate 15 and flows down on the baffle plate 15 to the base end side, and sequentially falls from the through hole provided in the baffle plate 15 to the lower stage, and finally returns to the stored water in the heating container 11. .

  As described above, by providing the baffle plate 15 on the upper part of the heating container 11, it is possible to separate the gas-liquid of the saturated steam generated in the heating container 11, so that the dried steam from which moisture has been separated is heated to the heating tube 21. Can be sent to. When the water vapor dried from the heating container 11 is supplied to the heating pipe 21, the reheating efficiency of the water vapor here is improved, and the superheated water vapor can be generated efficiently.

1: superheated steam generator 10: (saturated) steam generator 11: heating vessel 12: first induction heating coil 13: first heat insulation layer 14: first magnetic shield 15: baffle plate 20: superheated steam generator 21: Heating tube 22: second induction heating coil 23: second heat insulating layer 24: second magnetic shield

Claims (4)

  A heating container that is made of a conductive metal material and stores water therein, and is disposed on the outer periphery of the heating container. The first induction heating that generates water vapor by inductively heating the heating container to heat the internal water The coil and the first magnetic shield disposed on the outer periphery of the induction heating coil constitute a saturated steam generating section, and the conductivity is such that the steam generated by the saturated steam generating section flows through the internal fluid flow passage. A metal tube is wound in a spiral shape to form a cylindrical shape, a heating tube disposed on the outer periphery of the first magnetic shield, and an outer periphery of the heating tube. A superheated steam generator, comprising a superheated steam generator with a second induction heating coil that reheats steam to generate superheated steam.   The superheated steam generator according to claim 1, wherein steam is generated by supplying high-frequency AC power to each of the first and second induction heating coils.   3. The heating container according to claim 1, wherein the heating container is configured to supply water from a lower part of the container and take out water vapor from the upper part, and provided with a plurality of inclined baffle plates at the upper part of the container. A superheated steam generator.   4. The superheated steam generator according to claim 3, wherein the baffle plate is a perforated plate in which a large number of holes are dispersedly formed.

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