JP2015041561A - Microwave heating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a maintenance-easy microwave heating device capable of heating a heated body while controlling a heating position, and that has a reduced size and weight.SOLUTION: A microwave transmission part 11 that is a portion for generating a microwave signal with which a heated body is irradiated is configured by using a semiconductor active element, and a size and weight of the entire microwave heating device 1 is drastically reduced. While changing a microwave signal level from the microwave transmission part 11 on the basis of a monitoring result by a temperature sensor 16 and/or a microwave reception level sensor 17 provided in a cavity resonator 14, a movable reflection plate 15 having a simple structure is driven to change a state of a standing wave generated in the cavity resonator 14, and a heating state including a heating position of the heated body is controlled.

Description

  Embodiments described herein relate generally to a microwave heating apparatus.

  In the microwave heating apparatus that heats the object to be heated placed in the heating furnace by irradiating the microwave, the occurrence of uneven heating temperature that is a temperature difference between different parts of the object to be heated is reduced. For example, while monitoring the temperature in the furnace in which the object to be heated is stored, the heating position of the object to be heated is controlled to reduce unevenness in the heating temperature, and the heating to the object to be heated is made uniform.

  Thus, as a method of controlling the heating position with respect to the object to be heated, for example, the opening direction of the microwave irradiation port provided in the heating furnace is mechanically controlled, and the microwave irradiation direction is controlled. A technique for controlling the heating position is disclosed. In addition, a method of controlling the heating position by providing a plurality of microwave irradiation sources and controlling the microwave output from each irradiation source is also disclosed (for example, see Patent Document 1).

JP 2009-301764 A JP 2006-140063 A

  However, it is difficult to stably control the direction of the microwave irradiation port in the heating furnace with good accuracy over a long period of time, and detailed maintenance work is also required. As a microwave generation source, for example, a magnetron or the like is frequently used. However, when a microwave generation source is configured by a magnetron, the capacity and mass of the single source are large. For this reason, when a microwave irradiation source is configured by using a plurality of magnetrons, an increase in size and weight is inevitable, and there are difficulties in maintaining and maintaining the apparatus.

  The present embodiment has been made in consideration of the above-described circumstances, and is downsized to heat the heated object while controlling the heating position in accordance with the situation in the heating furnace in which the heated object is arranged. It is another object of the present invention to provide a microwave heating device that is lightweight and easy to maintain.

  In order to achieve the above object, the microwave heating apparatus according to the first embodiment amplifies a microwave seed signal from a microwave signal source based on a control signal by a semiconductor active element to obtain a microwave signal of a predetermined level. A microwave transmission unit for output, one end connected to the microwave transmission unit, a transmission path for transmitting a microwave signal from the microwave transmission unit, a heated object as a heating furnace, and a micro wall on the wall A microwave resonator is provided, and the microwave irradiation port is connected to the other end of the transmission path so that the microwave signal is irradiated to the inside thereof, and the microwave irradiation port in the cavity resonator is provided. A movable reflector that is driven on the basis of a control signal and moves within the cavity resonator, and is provided in the middle of the transmission path. The movable reflection unit based on the detection result of the sensor, the termination unit that terminates the reflected wave propagating through the transmission path from the resonator toward the microwave transmission unit, the sensor provided in the cavity resonator, and And a control unit that generates a control signal for controlling a position of the plate and a microwave output signal level of the microwave transmission unit.

  Further, the microwave heating apparatus of the second embodiment outputs a plurality of microwave seed signals branched from the same signal source by controlling the phase and output level based on the control signal, respectively. A microwave transmission unit having a microwave signal output, and one end connected to any of the plurality of microwave signals output from the microwave transmission unit, and the plurality of microwave signals from the microwave transmission unit Each of the plurality of transmission paths for transmitting to the cavity resonator and the object to be heated as a heating furnace are accommodated, and a plurality of microwave irradiation ports are provided on a wall surface. A cavity resonator to which the other end of the transmission line is connected and irradiated with the plurality of microwave signals, and provided in the middle of each transmission line, from the cavity resonator A termination unit that terminates the reflected wave propagating in the transmission path toward the microwave transmitter unit, and a control signal that controls the phase and output level of each of the plurality of microwave signal outputs under predetermined conditions. And a control unit.

The block diagram which shows the structure of the 1st Example of the microwave heating apparatus which concerns on this embodiment. The block diagram which shows the structure of the modification with respect to the microwave heating apparatus of 1st Example. The block diagram which shows the structure of the 2nd Example of the microwave heating apparatus which concerns on this embodiment. The block diagram which shows the structure of the 3rd Example of the microwave heating apparatus which concerns on this embodiment. The block diagram which shows the structure of the 4th Example of the microwave heating apparatus which concerns on this embodiment.

  Below, the best form for implementing the microwave heating device which concerns on this embodiment is demonstrated with reference to FIGS.

  FIG. 1 is a block diagram showing the configuration of a first example of the microwave heating apparatus according to this embodiment. As illustrated in FIG. 1, the microwave heating apparatus 1 includes a microwave transmission unit 11, a transmission path 12, a termination unit 13 provided in the middle of the transmission path 12, a cavity resonator 14, and the cavity resonator 14. The movable reflector 15, the temperature sensor 16, the reception level sensor 17, and the control unit 18 are provided inside.

  The microwave transmission unit 11 generates and transmits a microwave signal of a predetermined level for irradiating the object to be heated. The microwave transmission unit 11 includes a microwave signal source 111 and an amplifier 112. The microwave signal source 111 generates a seed signal of the microwave signal and sends it to the amplifier 112. The amplifier 112 is a variable gain amplifier, and amplifies the seed signal from the microwave signal source 111 to a predetermined level based on a control signal from the control unit 18, which will be described later, and outputs the amplified signal. The microwave transmission unit 11 includes the amplifier 112 and is configured by using a semiconductor active element such as a FET (Field Effect Transistor). Accordingly, for example, the microwave transmission unit 11 can be significantly reduced in size and weight as compared with a case where a conventional magnetron or the like is used, and further, the microwave heating device 1 as a whole can be reduced in size and weight. Has also contributed greatly.

  One end of the transmission line 12 is connected to a microwave signal output end of the microwave transmission unit 11, and the other end is connected to a microwave irradiation port 141 provided in a cavity resonator 14 described later. As the transmission line 12, for example, a waveguide, a coaxial cable, or the like can be applied. In the middle of the transmission line 12, a termination unit 13 including a directional coupler 131 for branching a reflected wave from the cavity resonator 14 side and a terminator 132 for terminating the branched reflected wave is provided. ing. Then, the microwave signal from the microwave transmission unit 11 is transmitted to the cavity resonator 14, and the reflected wave from the cavity resonator 14 side is terminated at the termination unit 13 provided in the middle.

  The cavity resonator 14 has, for example, a rectangular parallelepiped shape, and includes a microwave irradiation port 141 for irradiating a microwave signal in its own wall on one wall surface thereof. At the time of heating, a microwave signal transmitted from the microwave transmission unit 11 via the transmission path 12 is irradiated from the microwave irradiation port 141, and the object to be heated contained therein is heated as a heating furnace. To do.

  A movable reflector 15 that is driven based on a control signal from the control unit 18 is provided on the wall surface in the cavity resonator 14 on the side facing the wall surface on which the microwave irradiation port 141 is provided. This movable reflecting plate 15 is formed in a simple plate shape including a drive unit, and is used for controlling the heating position of the heated object. That is, during irradiation of the microwave signal, the movable reflector 15 is moved in the cavity resonator 14 and the position of the standing wave generated in the cavity resonator 14 is changed to control the heating position.

  Here, the state of the standing wave generated in the cavity resonator 14 when the microwave signal is irradiated into the cavity resonator 14 can be simulated in advance based on, for example, the shape of the cavity resonator 14. The same applies to the case where the movable reflector 15 is moved in the cavity resonator 14. Accordingly, the change of the standing wave in the cavity resonator 14 due to the change in the position of the movable reflector 15 is controlled in the present embodiment by, for example, acquiring in advance as known data and tabulating it. The part 18 is assumed to be held.

  Further, in this embodiment, two temperature sensors 16 (# 1) and 16 (# 2) and two microwave reception level sensors 17 (# 1) and 17 (# 2) are provided in the cavity resonator 14. Is arranged. The temperature sensor 16 monitors the heating state of the object to be heated and sends the result to the control unit 18. The microwave reception level sensor 17 is disposed at a predetermined position in the cavity resonator 14, monitors the reception level of the microwave signal, and similarly sends the result to the control unit 18. In the present embodiment, two types of sensors are arranged two by two, but the number of sensors can be either one of the two types, and the number is also limited to this. It is not a thing.

  The control unit 18 includes a control signal for controlling the output level of the microwave signal output from the microwave transmission unit 11 based on the monitoring results from the temperature sensor 16 and the microwave reception level sensor 17, and the cavity resonator. The control signal for driving the movable reflecting plate 15 provided in 14 is generated, and the object to be heated contained in the cavity resonator 14 is controlled to be in a desired heating state.

  Next, the operation in the case where the object to be heated is heated using the microwave heating apparatus 1 of the present embodiment configured as described above, particularly the operation for controlling the heating position of the object to be heated will be described. .

  First, various control signals for initial setting are generated by the control unit 18 based on setting conditions necessary for heating the object to be heated accommodated in the cavity resonator 14 to a desired state, It is sent to each part in the device. Among these various control signals, the control signal for the amplifier 112 in the microwave transmission unit 11 corresponding to the setting of the microwave signal level irradiated to the object to be heated and the heating position of the object to be heated are controlled. A control signal for the movable reflector 15 is included.

  Next, a microwave signal is irradiated into the cavity resonator 14, and monitoring results from the temperature sensor 16 and the microwave reception level sensor 17 provided in the cavity resonator 14 are sequentially sent to the control unit 18 over time. The The control unit 18 repeats generation of the control signal based on the detection results of these sensors.

  That is, the temperature sensor 16 monitors the heating state of the object to be heated, and the control unit 18 sets the movable reflector 15 based on the detection result so that the object to be heated is heated to a desired state. The temperature is controlled by controlling the heating position by controlling the driving and the level of the microwave signal output from the microwave transmitter 11. Further, since the state of the standing wave generated in the cavity resonator 14 is known as described above, the detection result of the microwave reception level sensor 17 arranged at a predetermined position in the cavity resonator 14. The control unit 18 controls the microwave signal level output from the movable reflector 15 and the microwave transmission unit 11 so that the desired level of the microwave signal is irradiated to the desired position of the heated object. To do.

  The heating position can be controlled by using either the temperature sensor 16 or the microwave reception level sensor 17 as described above. In this embodiment, these two types of sensors are combined. Yes. In this way, by using the detection results from the two types of sensors, the heating state of the object to be heated and the state of the standing wave in the cavity resonator 14 are combined in accordance with the state in the cavity resonator 14. Fine control is possible, and the microwave signal levels from the movable reflector 15 and the microwave transmission unit 11 are more finely controlled, thereby enabling more stable and reliable control of the heating position.

  As described above, in this embodiment, when the object to be heated is irradiated with a microwave signal and heated, the microwave transmitter 11 which is a part that generates the microwave signal is used as a semiconductor active element. Is configured. As a result, for example, the microwave transmission unit 11 is significantly reduced in size and weight as compared with a case where a conventional magnetron or the like is used, and the entire microwave heating apparatus 1 can be reduced in size and weight. .

  Moreover, based on the monitoring result by the temperature sensor 16 and / or the microwave reception level sensor 17 provided in the cavity resonator 14, the microwave signal level from the microwave transmission part 11 is changed, and movable reflection of a simple structure is carried out. The state of the standing wave generated in the cavity resonator 14 is changed by driving the plate 15 to control the heating state including the heating position of the object to be heated. This makes it possible to obtain a microwave heating apparatus that can easily heat the object to be heated while controlling the heating position in accordance with the situation inside the cavity resonator as a heating furnace, and that can be easily maintained.

(Modification 1)
FIG. 2 is a block diagram showing a configuration of a modification of the microwave heating apparatus of the first embodiment described above. In the microwave heating apparatus 2 of this modification, two movable reflectors 15 (# 1) and 15 (# 2) are provided in the cavity resonator 14. That is, in the same manner as in the first embodiment, in addition to the movable reflector 15 (# 1) provided on the wall surface facing the microwave irradiation port 141, the movable reflector 15 (# 2) is also provided on the upper wall surface of the cavity resonator 14. ). Then, as in the first embodiment, these two movable reflectors 15 (# 1) and 15 (# 2) are driven to change the standing wave generated in the cavity resonator 14 in the vertical and horizontal directions. The heating state of the object to be heated is controlled by changing.

  Thus, in the microwave heating apparatus 2 of this modification, in addition to the same effects as those of the first embodiment, the heating position of the object to be heated can be controlled more finely. Further, a third movable reflector 15 (# 3) (not shown) can be further provided on the side wall surface of the cavity resonator 14 (the surface orthogonal to the depth direction of the paper surface of FIG. 2). When configured in this way, the state of the standing wave generated in the cavity resonator 14 can be changed in any of the three axial directions, and the heating position of the heated object can be controlled. Further densification can be achieved.

  FIG. 3 is a block diagram showing a configuration of a second example of the microwave heating apparatus according to the present embodiment. In the second embodiment, the same parts as those in the first embodiment shown in FIG. 1 are denoted by the same reference numerals, and detailed description thereof is omitted. In the following description, the number of the plurality of microwave signal outputs in the present embodiment is described as two outputs.

  As illustrated in FIG. 3, the microwave heating device 3 includes a microwave transmission unit 21 having two microwave signal outputs, and two transmissions provided corresponding to the two microwave signal outputs. The path 12 (# 1) and 12 (# 2), the termination | terminus parts 13 (# 1) and 13 (# 2) provided in the middle of these two transmission paths 12, the cavity resonator 22, and the control part 23 are comprised. Has been.

  The microwave transmission unit 21 generates and transmits a plurality of microwave signals for irradiating the object to be heated. In this embodiment, the case where the number of output of the microwave signal is 2 is illustrated. The microwave transmission unit 21 includes a microwave signal source 111 that generates a seed signal of the microwave signal, and a phase shifter that sets a passing phase of the seed signal of each microwave signal branched from the microwave signal source 111. 211, and an amplifier 112 that amplifies and outputs a signal from the phase shifter 211 to a predetermined level for two systems corresponding to two microwave signal outputs (# 1 or # 2 is set to the code of each system) Add).

  The phase shifter 211 sets the passing phase of the seed signal from the microwave signal source 111 based on a control signal from the control unit 23 described later, and sends it to the amplifier 112. Similarly, the amplifier 112 amplifies the signal from the phase shifter 211 to a predetermined level based on the control signal from the control unit 23 and outputs the amplified signal. In addition, the microwave transmission unit 21 including the amplifier 112 is configured using a semiconductor active element such as an FET. Therefore, similarly to the first embodiment, the microwave transmitter 21 can be significantly reduced in size and weight, and the entire microwave heating device 3 can be reduced in size and weight.

  The two transmission paths 12 (# 1) and 12 (# 2) are configured identically, one end of which is connected to one of the two microwave signal output ends of the microwave transmitter 21, and the other end is It is connected to one of two microwave irradiation ports 221 (# 1) and 221 (# 2) provided in a cavity resonator 22 described later. Further, in the middle, termination portions 13 (# 1) and 13 (# 2) for terminating the reflected wave from the cavity resonator side are provided, respectively, and two microwaves from the microwave transmission unit 21 are provided. A wave signal is transmitted to the cavity resonator 22, and the reflected wave from the cavity resonator 22 side is terminated at the termination portion 13 provided in the middle.

  The cavity resonator 22 has a rectangular parallelepiped shape in the present embodiment, and has two irradiation ports 221 (# 1) and 221 (# 2) for irradiating two microwave signals from the microwave transmission unit 21. Are formed on the same wall surface. At the time of heating, two microwave signals from the microwave transmission unit 21 are irradiated from these two microwave irradiation ports 221 (# 1) and 221 (# 2), and as a heating furnace, the object contained inside is heated. Heat the heating element.

  The control unit 23 generates a control signal for controlling the phase shift amount and the output level for each of the two microwave signals output from the microwave transmission unit 21, and the system of each microwave signal To the phase shifter 211 and the amplifier 112 in the microwave transmission unit 21 corresponding to the above. Then, by controlling the phase and level of these two microwave signals, the irradiation direction of the microwave signals irradiated from the two microwave irradiation ports 221 in the cavity resonator 22 is electronically controlled to be heated. Control the heating position of the body.

  That is, the change in the irradiation direction of the microwave signal in the cavity resonator 22 with respect to the phase and level change of a plurality of (two) microwave signals to be irradiated depends on the shape of the cavity resonator 22 and the number of microwave irradiation ports 221. And based on the position thereof and the like. Therefore, in the control unit 23, the relationship between the phase and level of the microwave signal generated in advance in this way and generated in the microwave transmission unit 21 and the irradiation direction in the cavity resonator 22 is, for example, The heating position is controlled by holding it in a table as a table or the like.

  In the microwave heating apparatus 3 of the present embodiment configured as described above, when heating the object to be heated to a desired state, first, various control signals for initial setting based on heating conditions and the like. Is generated by the control unit 23 and sent to each unit in the apparatus. These various control signals include control signals for each phase shifter 211 and each amplifier 112 in the microwave transmission unit 21. Next, when generation of microwave signals is started in the microwave transmission unit 21, these microwave signals are sent to the cavity resonator 22 via the transmission path 12, and the cavity resonator 22 is transmitted from the microwave irradiation port 221. Irradiated inside.

  During this irradiation, the controller 23 puts the object to be heated into a desired heating state based on preset heating conditions and the like with respect to the microwave signal to be irradiated. A control signal for controlling the output level is continuously generated and transmitted. As a result, the irradiation direction and irradiation intensity of the microwave signal in the cavity resonator 22 are electronically controlled, so that the object to be heated is heated to a desired heating state while the heating position is controlled.

  As described above, in this embodiment, the semiconductor transmitter 21 is used as the microwave transmitter 21 that generates a plurality of microwave signals to be irradiated to the object to be heated, as in the first embodiment. It has a configuration that was. Thereby, this microwave transmission part 21 can be significantly reduced in size and weight while having a plurality of signal outputs, and the entire microwave heating device 3 can be reduced in size and weight.

  The cavity resonator 22 is provided with two (a plurality of) microwave irradiation ports 221 on one wall surface, and a microwave signal is irradiated from the microwave irradiation ports 221 into the cavity resonator 22. The irradiation direction of the microwave signal in the cavity resonator 22 is electronically controlled by controlling the phase and level of the two microwave signals to be irradiated, respectively. This makes it possible to control the heating state including the heating position of the object to be heated by an electronic method regardless of mechanical driving, etc., and to maintain the heating object while controlling the heating position. An easy microwave heating apparatus can be obtained.

  FIG. 4 is a block diagram showing a configuration of a third example of the microwave heating apparatus according to the present embodiment. In the third embodiment, the same parts as those in the first and second embodiments shown in FIGS. 1 to 3 are denoted by the same reference numerals, and detailed description thereof is omitted. The third embodiment is different from the second embodiment in that, in the third embodiment, the configuration of the second embodiment is further used as a sensor for monitoring the state in the cavity resonator. A temperature sensor is provided in the resonator, and the controller is configured to generate a control signal based on a monitoring result from the temperature sensor. In the present embodiment, the case where two temperature sensors are provided is illustrated, but the number is not limited to two. Hereinafter, only the differences will be described with reference to FIGS. 1 to 3 and the block diagram of FIG.

  As illustrated in FIG. 4, the microwave heating apparatus 4 includes a microwave transmission unit 21 having two microwave signal outputs, and two transmission paths 12 that transmit the two microwave signals to the cavity resonator 22. (# 1) and 12 (# 1), termination portions 13 (# 1) and 13 (# 2) provided in the middle of the respective transmission lines 12, and cavity resonators in which two microwave irradiation ports 221 are formed 22, two temperature sensors 16 (# 1) and (# 2) provided in the cavity resonator 22, and a control unit 31.

  The microwave transmission unit 21, the transmission path 12, the termination unit 13, and the cavity resonator 22 are configured in the same manner as in the first or second embodiment, and thus description thereof is omitted. The two temperature sensors 16 (# 1) and (# 2) are also the same as in the first embodiment, and are provided in the cavity resonator 22 to monitor the heating state of the object to be heated. Is sent to the control unit 31.

  Similarly to the second embodiment, the control unit 31 also uses the two microwaves output from the microwave transmission unit 21 so that the object to be heated in the cavity resonator 22 is in a preset desired heating state. A control signal for controlling the phase and level of the wave signal is generated and transmitted. Then, the irradiation direction of the microwave signal in the cavity resonator 22 is electronically controlled by these control signals, and the heating position of the object to be heated is controlled.

  In addition, the control unit 31 of the present embodiment generates control signals based on the monitoring results from the two temperature sensors 16 when generating control signals for controlling the phases and levels of the two microwave signals, respectively. Is generated. That is, based on a preset heating condition or the like, while heating the object to be heated while controlling the irradiation direction of the microwave signal in the cavity resonator 22, the temperature of the object to be heated is the temperature of the object to be heated. The heating control including the heating position of the object to be heated is performed while reflecting the monitoring result.

  As described above, also in the present embodiment, the microwave transmitter 21 is reduced in size and weight as in the second embodiment, and the monitoring result by the temperature sensor 16 in the cavity resonator 22 is also obtained. Based on the above, irradiation is performed while controlling the phase and level of each microwave signal. As a result, a microwave heating device that can be heated while controlling the heating position according to the situation inside the cavity resonator as a heating furnace, and that is reduced in size and weight and easy to maintain is obtained. Can do.

  FIG. 5 is a block diagram showing a configuration of a fourth example of the microwave heating apparatus according to the present embodiment. In the fourth embodiment, the same portions as those in the first and second embodiments shown in FIGS. 1 to 3 are denoted by the same reference numerals, and detailed description thereof is omitted. The fourth embodiment is different from the second embodiment in that, in the fourth embodiment, the configuration of the second embodiment further includes sensors for monitoring the state in the cavity resonator. A reflected wave sensor for detecting a reflected wave from the cavity resonator is provided at the terminal portion, and the controller generates a control signal based on a monitoring result from the reflected wave sensor. The third embodiment is different from the third embodiment in that the temperature sensor is provided in the cavity resonator in the third embodiment as a sensor for monitoring the state in the cavity resonator. In the example, a reflected wave sensor is provided at each end portion. Hereinafter, only the differences will be described with reference to FIGS. 1 to 4 and the block diagram of FIG.

  As illustrated in FIG. 5, the microwave heating apparatus 5 includes a microwave transmission unit 21 having two microwave signal outputs, and two transmission lines 12 that transmit the two microwave signals to the cavity resonator 22. (# 1) and 12 (# 2), respectively, termination units 41 (# 1) and 41 (# 2) provided in the middle of the transmission line 12, and cavity resonators in which two microwave irradiation ports 221 are formed 22 and a control unit 42. The microwave transmitter 21, the transmission line 12, and the cavity resonator 22 are configured in the same manner as in the first or second embodiment, and thus the description thereof is omitted.

  The two terminal portions 41 (# 1) and 41 (# 2) are provided in the middle of the transmission lines 12 (# 1) and 12 (# 2), respectively, and both are configured in the same manner, and the cavity resonator 22 is provided. A directional coupler 131 for branching the reflected wave of the microwave signal propagating through the transmission line 12 from the side, and a reflected wave sensor 411 for terminating the branched reflected wave and acquiring intensity and phase information thereof. ing. Then, the reflected wave of the microwave signal from the cavity resonator 22 side is terminated, and the intensity and phase information is acquired and sent to the control unit 42.

  Similarly to the second and third embodiments, the control unit 42 outputs 2 from the microwave transmission unit 21 so that the heated object accommodated in the cavity resonator 22 is in a desired heating state. By controlling the phase and level of each of the two microwave signals, the irradiation direction and intensity of the microwave signal in the cavity resonator 22 are electronically controlled to control the heating of the object to be heated.

  In addition, in the control unit 42 of the present embodiment, control for controlling the phase and level of the two microwave signals to be irradiated based on the monitoring result of the reflected wave from the reflected wave sensor 411 of the two terminal units 41. The signal is generated. In the cavity resonator 22, the effective relative permittivity changes when the object to be heated is heated, and the phase and intensity of the reflected wave also change accordingly. In the control unit 42, for example, the relationship between the effective relative permittivity of the heated object and the reflected wave from the cavity resonator 22 is acquired in advance and held in a table or the like in the device itself. . Then, while continuing heating while controlling the irradiation direction and intensity of the microwave signal in the cavity resonator 22, the state of the reflected wave from the cavity resonator 22 is acquired as the heating state of the object to be heated. The heating control including the heating position of the object to be heated is performed while reflecting the acquisition result in the control signal with reference to the above table.

  As described above, also in the present embodiment, as in the second and third embodiments, the microwave transmitter 21 is reduced in size and weight. Further, the heating state of the object to be heated in the cavity resonator 22 is acquired from the intensity and phase information of the reflected wave at the terminal portion 41, and the phase and level of each microwave signal are controlled based on the acquisition result. However, the light is irradiated into the cavity resonator 22. Therefore, also in the fourth embodiment, the object to be heated can be heated while controlling the heating position in accordance with the situation inside the cavity resonator as a heating furnace, and the maintenance that is reduced in size and weight is easy. A microwave heating apparatus can be obtained.

  Although several embodiments have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

1, 2, 3, 4, 5 Microwave heating device 11, 21 Microwave transmission unit 12 Transmission path 13, 41 Termination unit 14, 22 Cavity resonator 15 Movable reflector 16 Temperature sensor 17 Microwave reception level sensor 18, 23 , 31, 42 Control unit 111 Microwave signal source 112 Amplifier 131 Directional coupler 132 Terminator 141, 221 Microwave irradiation port 211 Phase shifter 411 Reflected wave sensor

Claims (8)

A microwave transmission unit that amplifies a microwave signal from a microwave signal source based on a control signal by a semiconductor active element and outputs it as a microwave signal of a predetermined level;
One end is connected to the microwave transmitter, a transmission path for transmitting a microwave signal from the microwave transmitter,
A cavity resonator that accommodates an object to be heated as a heating furnace, has a microwave irradiation port on a wall surface, and is connected to the other end of the transmission path to the microwave irradiation port and is irradiated with the microwave signal When,
A movable reflector provided on a wall on a side different from the wall provided with the microwave irradiation port in the cavity, and driven in accordance with a control signal to move in the cavity;
A termination unit that is provided in the middle of the transmission path and terminates a reflected wave that propagates through the transmission path from the cavity resonator toward the microwave transmission unit,
A sensor provided in the cavity resonator;
A microwave comprising: a control unit that generates a control signal for controlling a position of the movable reflecting plate and a microwave output signal level of the microwave transmission unit based on a detection result of the sensor. Heating device.   The sensor may be one or both of a temperature sensor for monitoring a heating state of the object to be heated and a microwave reception level sensor provided at a predetermined position in the cavity resonator. Item 2. The microwave heating apparatus according to Item 1. A plurality of microwave signals branched from the same signal source, each of which is controlled based on a control signal, and outputs a microwave signal having a plurality of microwave signal outputs;
A plurality of transmission lines each having one end connected to any of the plurality of microwave signals output from the microwave transmission unit and transmitting the plurality of microwave signals from the microwave transmission unit to the cavity resonator; ,
While accommodating a to-be-heated body as a heating furnace, a wall surface is provided with a plurality of microwave irradiation ports, and the other ends of the plurality of transmission paths are connected to the plurality of microwave irradiation ports, respectively. A cavity resonator in which a microwave signal is irradiated;
A termination portion that is provided in the middle of each transmission path and terminates a reflected wave that propagates through the transmission path from the cavity resonator toward the microwave transmission section,
A microwave heating apparatus, comprising: a control unit that generates a control signal for respectively controlling a phase and an output level of the plurality of microwave signal outputs under predetermined conditions.   The microwave transmission unit includes an amplifier using a semiconductor active element whose gain is variable by the control signal in correspondence with each of the plurality of branched microwave type signals, and the amplifiers use the amplifier to The microwave heating apparatus according to claim 3, wherein each output level of the microwave signal output is controlled.   5. The microwave heating apparatus according to claim 3, wherein the cavity resonator has a rectangular parallelepiped shape, and the plurality of microwave irradiation ports are all provided on the same wall surface. 6.   Furthermore, the sensor which monitors the state in the said cavity resonator is provided, The said control part produces | generates the said control signal based on the monitoring result from this sensor, Any of Claim 3 thru | or 5 characterized by the above-mentioned. The microwave heating device according to claim 1.   The microwave heating apparatus according to claim 6, wherein the sensor is a temperature sensor provided in the cavity resonator.   The microwave heating apparatus according to claim 6, wherein the sensor is a signal sensor that detects intensity or phase of a reflected wave at a plurality of the terminal portions.

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