TW201827756A - Modular composite microwave heating system with separable cavity capable of flexibly increasing or decreasing the number of modules in the production line based on the actual requirement, and individual modules can be separated to be proceeded with independent measurements - Google Patents

Abstract

The present invention provides a modular heating system with conduction and microwave mixing effect, which has a microwave resonant cavity capable of being separated into an upper part and a lower part and capable of accommodating an object to be heated. A microwave half cavity of the upper part has a microwave feeding device capable of guiding the microwave into the cavity. The lower part is a conduction half cavity capable of being heated by a conventional heat source. The combination of the upper part and the lower part constitutes the microwave resonant cavity. The object to be heated is placed in a sealed box and then placed in the microwave resonant cavity. The microwave guided by the microwave feeding device can heat the object to be heated. The sealed box can resist the pressure of outward expansion of the object to be heated due to heating. The combined microwave resonant cavity is of an independent and modular structure, thus the number of modules in the production line can be flexibly increased or decreased based on the actual requirement. In the production process, individual modules can be separated from the production line to be proceeded with independent measurements so as to control the production quality and constitute a closed-loop production control.

Description

Cavity detachable modular composite microwave heating system

The invention relates to the processing of a heated object, in particular to a composite microwave heating system in which a cavity can be separated and modularized.

Heating is a basic food and industrial processing method. According to its principle, there are contact heating (fire, electric heating tube, ceramic heating), microwave heating and induction (electromagnetic) heating, etc. Contact heating is a traditional heating method, and the temperature of the heated material starts from the outside. Rising, and gradually conduction to the inside, the required heating time is longer; microwave is a kind of electromagnetic wave, the microwave of specific frequency can make the molecules of the heated object (such as water) resonate and start to heat rapidly from the inside, then the microwave acts on the heat The intensity distribution of the material will change due to the interaction of different microwave power generators, resonant cavity and heated objects, which may cause uneven heating of local locations.

In order to increase the heating uniformity of microwaves and to continuously produce or sterilize, many patents use hot fluids (hot water, hot air) as auxiliary heating medium (US7119313B2, US4962298), the heated materials are pre-filled in the sealed box, and then the sealed box The microwave chamber filled with the high-pressure fluid is placed in the microwave chamber filled with the high-pressure fluid, and the heated object in the sealed box is heated by the microwave and the coated fluid. When the temperature of the heated substance in the sealed box rises, the external expansion pressure is generated due to the expansion of the internal steam and the volume. , the seal box may be damaged, so the microwave cavity must be pressurized to offset the pressure inside the chamber and the expansion pressure outside the sealed box. However, there is no expansion pressure in the sealed box at the initial stage of heating, and the excessive cavity pressure will make the seal not yet heated. The box collapses, but the cavity pressure is too small to resist the expansion pressure after the sealing box is heated, and the sealed box is leaked. It can be seen that the operating temperature and pressure of such a system affect each other. The design creates significant limitations, while such systems require a large microwave cavity that must withstand the high pressure of the fluid, sealed Appropriate decompression and decompression procedures are required to enter and exit the cavity. It is not possible to leave the cavity for temperature measurement and monitoring. When heated, the heated object is immersed in high-pressure hot water or hot steam and exposed to microwave electromagnetic sputum. Conventional instruments and methods detect changes in temperature and quality of heated materials, so that the process is difficult to adjust and lacks flexibility. In addition, hot water and hot steam during operation of such systems are liable to cause waste heat pollution and power loss.

The contact heating condition is that the heated object must be in close contact with the heat source, and the heat energy can be transmitted to the heated object, and the microwave heating requires a proper resonant cavity for accommodating the heated object, so that the microwave can be used to heat the object in the cavity. Heating, although many patents have been combined with the above two heating methods (US4900884, US 6864468 B2, US5548101, US5177333), but the cavity is a fixed structure, the contact heating method is only placed under normal pressure on the heating plate Or there is no special arrangement in the pan to keep the heat attached to the heat source.

There are many disclosed technologies for applying microwaves to a mechanism for continuous heating (US 2009/0230124 A1, US 2012/0103976 A1), although the mechanism feeds microwaves into several heating spaces, the heated objects can continuously enter and exit the heating mechanism, but The cavity itself is fixed, the heated object is not sealed in advance, and the implementation of conduction heating is not considered.

Based on the above description, the existing microwave heating system has the following technical features: 1. The resonant cavity of the fixed structure cannot be modularized. Second, if the auxiliary heating medium is not used, the sealed box is not tightly attached to the conduction heating. Source, reduce heat transfer efficiency, third, the use of auxiliary heating medium requires the use of pressurized cavity, while the cavity pressure, heating temperature and the pressure of the sealed box are mutually affected, limiting the processing conditions, fourth, the system design is difficult in the microwave environment The temperature change of the heated object is measured, and the relationship between the temperature and the time of the heated object during the heating process cannot be adjusted accordingly, so that many specific heating processes, such as cooking or sterilization of food, cannot be satisfied.

The main object of the present invention is to provide a cavity-separable and modular composite microwave heating system which is operated at normal pressure without additional steam or water, and the cavity is a module. The design can be separated up and down, so it can flexibly adjust the power and time of heating, heat preservation and cooling, and can instantly detect the quality of the heated material to meet various heating process requirements.

The invention comprises a microwave half cavity, a conductive half cavity, a conduction heating unit, a microwave heating unit and a sealed box, wherein the conduction heating unit provides a contact heating source, the microwave heating unit provides a microwave, the sealing The box is filled with the heated object, and the microwave half cavity and the conductive half cavity can be combined up and down to form a sealed microwave resonant cavity, and the heated object to be processed is sealed in the sealed box and then placed into the microwave cavity. The microwave half-cavity has a microwave feeding device (such as a waveguide), and the microwave generated by the microwave heating unit can be fed into the microwave resonant cavity, so that the microwave heats the heated object in the sealed box. The conductive half cavity has a microwave permeable conductive half cavity upper cover for pressing the sealing box against the conductive half cavity, so that the sealing box is in close contact with the inner wall thereof, and the conducting half cavity is thermally conductive Made of a good material, the heating of the conductive heating unit can be accepted, and the heat can thermally heat the heat in the sealed box, and the heat vapor or volume expansion of the heated material due to heating will cause the sealed box to be produced. Extended pressure, and the semi-conductive cover and the conductive cavity half of the cavity has sufficient mechanical strength to resist structural deformation of the seal of the cartridge, to avoid leakage.

The system of the invention can separately or simultaneously use microwave and traditional heating method to heat the heated object, and the microwave heating can rapidly heat up the heated object in the sealed box and generate volume expansion to adhere to the conductive half cavity, so The conduction heating efficiency is greatly improved, so that the conduction heating unit can effectively heat the heated object, and the means for resisting the expansion pressure of the sealed box is different from the conventional high pressure water or water vapor, etc., so that the design is normal pressure, and The pressing design does not apply pressure to the sealed box when it is not heated and expanded, so that the unheated sealing box is not deformed, and the pressing strength is derived from the mechanical structure, and the pressing strength can be increased, so that the sealing can be greatly increased. Increase the temperature of the heating to meet the needs of sterilization or other heating processes.

The conductive half cavity is combined with the microwave half cavity to form a microwave heating resonant cavity during the process, and when separated, the conductive half cavity exits the microwave environment together with the sealed box, so that the general device detects the heat in the sealed box. The quality of the object, such as temperature, color, etc., dynamically monitors, records, and adjusts the heating process. Since the conductive half cavity and the microwave half cavity are separable modular designs, the subsequent, thermal, and cooling can be flexibly arranged. Wait for the process to meet the processing needs.

The detailed description and technical contents of the present invention are as follows:

Please refer to FIG. 1 , FIG. 2 and FIG. 3 , which are a first embodiment of the present invention, which is a modular detachable modular composite microwave heating system for a heated object ( The heating process is performed, and the system comprises a microwave half cavity 30, a conductive half cavity 40, a conduction heating unit 20, a microwave heating unit 70 and a sealed box 10, wherein the sealed box 10 is filled with the The conductive heating unit 20 may be any one selected from the group consisting of electromagnetic heating, gas heating, infrared light tube and electric heating wire, which can heat the conductive half cavity 40, preferably electromagnetic induction heating. The conductive half-cavity body 41 of the conductive half-cavity 40 can be induced to be heated by high-frequency electromagnetic waves, and the heating power of the conductive heating unit 20 can be adjusted by a conductive heating power controller 80.

The conductive half cavity 40 includes a conductive half cavity body 41 and a conductive half cavity upper cover 42. The conductive half cavity body 41 has a conductive half cavity inner wall 411 and a conductive half cavity inner wall 411. The accommodating space 412 and the conductive half cavity outer wall 413 are made of a microwave permeable material, and the conductive half cavity upper cover 42 and the conductive half cavity body 41 have The movable locking structure enables the conductive half-chamber upper cover 42 to be repeatedly locked and opened on the conductive half-cavity body 41.

The sealing box 10 can be received in the accommodating space 412, and the conductive half-chamber upper cover 42 is pressed against the sealing box 10. When the heated object expands in volume due to heating or generates steam, the sealing box 10 will also be volume-sized. Following the expansion to adhere to the inner wall 411 of the conductive half cavity, the volume expansion pressure of the sealed casing 10 will be pressed by the mechanical strength of the conductive half cavity upper cover 42 and the conductive half cavity body 41 without damage and leakage. After that, the heating temperature can be greatly increased.

The material of the conductive half-cavity body 41 is preferably made of metal, and the material is microwave (such as 2.45 GHz, 915 MHz, etc.), which is impenetrable and is made of a good ferromagnetic metal material, and can generate vortex for high-frequency electromagnetic waves. Current and induction heating (eg 10KHz~200KHz). The conductive half cavity 40 is placed over the conductive heating unit 20 to receive a conventional heat source to heat the conductive half cavity body 41.

The microwave half cavity 30 includes a waveguide 31 and a microwave half cavity cover 32 and a microwave half cavity body 33. When the microwave half cavity cover 32 is sleeved on the conductive half cavity outer wall 413, the combination is The structure of the structure is as shown in FIG. 3, and a complete microwave resonant cavity is formed inside the microwave half-cavity body 33 and the accommodating space 412. The microwave resonant cavity houses a heat-receiving object. The sealed box 10 and the conductive half-cavity upper cover 42 are made of microwave transparent material because the conductive half-cavity upper cover 42 and the sealing box 10 are both microwave-permeable materials, so that the microwave resonant cavity can receive microwaves and be heated. For the heat contained in the sealed box 10, in order to avoid microwave leakage, the microwave half-chamber cover 32 and the conductive half-chamber outer wall 413 are arranged with a conventional microwave leakage preventing device or structure. Such as isolation metal rings or microwave damping structures.

The microwave heating unit 70 is a microwave generating device, and provides a microwave heating source, and the microwave is fed into the microwave resonant cavity via the waveguide 31. The microwave heating unit 70 has a microwave intensity adjustment function, which can dynamically adjust the microwave heating power. Timing and size.

In order to improve the uniformity of the heating process, the present invention may further comprise a rotation receiving turntable 50 carrying the rotation of the conducting half cavity 40 and a rotation motor 51 having an outer ring tooth 501, the rotation motor 51. The outer ring gear 501 is engaged by a gear 52 to drive the rotation receiving turntable 50 to rotate, thereby driving the conductive half cavity 40 to rotate, so that the sealed box 10 loaded with the heated object rotates to improve the conventional microwave. The problem of uneven heating.

The actual implementation of the system of the present invention is shown in FIG. 4, wherein the microwave heating unit 70, the microwave half cavity 30, the conduction heating unit 20, the conduction heating power controller 80, the rotation receiving turntable 50 and the rotation motor 51 is a group of a composite heating module 60. In this embodiment, a plurality of the composite heating modules 60 are arranged in a ring shape on a rotating device 61. The rotating device 61 can be a turntable or a circular configuration. a conveyor belt, the heat-filled material is loaded into the sealed box 10 and then placed and locked in the conductive half-cavity 40, and the conductive half-cavity 40 filled with the sealed box 10 is sequentially accessed from one side to the corresponding one. The composite heating module 60 is combined with the microwave half cavity 30 to form the microwave resonant cavity. The microwave heating unit 70 and the conduction heating power control can be appropriately controlled during the forward rotation of the composite heating module 60. The output power of the device 80 is heated to heat the heated object. After the heating process is completed, the conductive half cavity 40 can be removed from the composite heating module 60 by the other side, and the conductive half is removed. Cavity 40 is no longer In the wave environment, the measurement system is not affected by microwave interference or the like, so that it is easy to measure the necessary quality (such as temperature, color, etc.) of the heated object, and in addition, the conductive half cavity of the sealed box 10 is loaded. The body 40 can be heated, insulated or cooled as needed, and the production line can be flexibly adjusted according to the needs of the heated materials and the process to meet the industrial processing requirements, such as cooking or sterilization of food.

As described above, the advantages of the present invention are as follows, as compared to conventional techniques:

1. Higher heating temperature: Since the sealed box is mechanically pressed against the conductive half cavity, it can withstand higher expansion pressure, which means that the heated object can be heated to a higher temperature.

2. High-efficiency conduction heating: Conventional technology, if high-pressure hot water or hot steam is not used as an auxiliary heat source, its conduction heating efficiency is not good, and the present invention can directly act on the sealed box by microwave in the initial stage of heating. The heat-receiving material, after the volume of the sealed box expands and adheres to the inner wall of the conducting half-cavity, the heat power of the conductive heating unit acting on the body of the conducting half-cavity can be more efficiently transmitted to the heated object.

3. The atmospheric pressure chamber is constructed and operated at a low cost: unlike the conventional high pressure chamber design of hot water or hot steam assisted heating medium, the present invention can operate at a higher heating temperature but only requires the use of a normal pressure chamber. Body, no waste heat loss and other issues, system construction and operating costs can be significantly reduced.

4. Modular cavity design, flexible arrangement of production line: For the conventional fixed cavity microwave heating system, it is necessary to change the volume of the cavity to change the capacity of the production line. Therefore, the microwave resonance distribution and parameters must be redesigned. However, the composite heating module of the present invention has a modular design, and each module is an independent cavity, and does not affect each other, so the number can be appropriately increased or decreased according to the needs of the production line without affecting the microwave cavity of the system. Body design.

5. Suitable for continuous production, without batch operation: Due to the design of the rotary disc production line of the invention, the conductive half-cavity filled with the sealed box can be continuously fed in and out for continuous production, and it is not necessary to enter and exit the cavity in batches.

6. During the process, the heated objects can be separated from the microwave environment for quality measurement: most of the electronic measuring instruments and components are easily burned or unable to move due to microwave interference, so it is difficult to use the general instrument for the quality of the heated objects in the microwave cavity. According to the measurement, the system can easily and repeatedly enter and exit the composite heating module due to the conductive half cavity filled with the sealed box, so the heating process can be arranged into a plurality of segments, and the conductive half cavity of the sealed box is filled between each segment. The body has been separated from the microwave cavity, so that the quality characteristics of the heated object can be measured using general instruments and components, and the heating power of the subsequent segments can be adjusted to ensure the final processing quality of the heated object.

7. It can be combined with microwave heating and conduction heating. The conventional microwave heating method is easy to produce the temperature difference of the cold hot spot. However, the conventional conduction heating has no cold hot spot temperature problem, but the heating efficiency is poor and the heating time is long. The invention can appropriately adjust the use timing of microwave heating and conduction heating according to the characteristics of the heat receiving material.

8. The cavity has a self-rotating function to improve the temperature uniformity: the invention is arranged with a self-rotating receiving mechanism such as a turntable, and the heating of the heated object in the microwave cavity can reduce the temperature difference caused by the microwave heating in the circumferential direction.

The present invention has been described in detail above, but the foregoing is only a preferred embodiment of the invention, and is not intended to limit the scope of the invention. That is, the equivalent changes and modifications made by the scope of the present application should remain within the scope of the patent of the present invention.

10‧‧‧ Sealing box

20‧‧‧ Conduction heating unit

30‧‧‧Microwave half cavity

31‧‧‧ Waveguide

32‧‧‧Microwave half-cavity cover

33‧‧‧Microwave half-cavity body

40‧‧‧ Conducting half cavity

41‧‧‧ Conducting half cavity body

411‧‧‧ Conducting half-body wall

412‧‧‧ accommodating space

413‧‧‧ Conducting half cavity outer wall

42‧‧‧ Conducting half-cavity upper cover

50‧‧‧Revolving take-over turntable

501‧‧‧ outer ring teeth

51‧‧‧Rotating motor

52‧‧‧ Gears

60‧‧‧Composite heating module

61‧‧‧Rotating device

70‧‧‧Microwave heating unit

80‧‧‧ Conduction heating power controller

Figure 1 is a disassembled view of the cavity structure of the present invention. Figure 2 is a schematic view showing the assembly of the system of the present invention. Fig. 3 is a perspective view showing the structure of the combination of the present invention. Figure 4 is a schematic view of continuous cycle heating of the present invention.

Claims (6)

A modular detachable modular composite microwave heating system for heating a heated object, comprising: a conductive heating unit, the conductive heating unit provides a contact heating source; and a microwave heating unit, the microwave heating The unit provides a microwave; a sealed box filled with the heated object; a conductive half-cavity comprising a conductive half-cavity body having a conductive half-cavity inner wall, and a conduction The accommodating space formed by the inner wall of the half cavity and the conductive half cavity upper cover formed by the microwave permeable material covering the accommodating space, the accommodating space for accommodating the sealing box and allowing the inner wall of the conducting half cavity, The conductive half cavity upper cover abuts the sealing box, the conductive half cavity body is away from the contact heat source from a side of the conductive half cavity upper cover, and a microwave half cavity containing a waveguide, a microwave half cavity outer cover and a microwave half cavity body, the microwave half cavity can be closely connected with the conductive half cavity to form a microwave resonant cavity, and the microwave generated by the microwave heating unit can be borrowed The waveguide feeding the microwave resonant cavity so that the microwave radiation to the heat thereof. The modular composite microwave heating system capable of separating a cavity according to claim 1, wherein the microwave half cavity system is composed of a ferromagnetic metal material. The cavity-separable modular composite microwave heating system according to claim 1, wherein the conduction heating unit is any one selected from the group consisting of electromagnetic induction, gas heating and electric heating modules. The modular composite microwave heating system with the cavity separable according to the first aspect of the patent application, further comprising an autorotation receiving turntable for carrying the rotation of the microwave resonant cavity. The modular composite microwave heating system of the detachable cavity according to claim 4, further comprising a rotation motor having an outer ring tooth, the rotation motor meshing through the gear Ring teeth. The modular composite microwave heating system capable of separating a cavity according to claim 5, wherein the heating power of the conduction heating unit is adjusted by a conduction heating power controller, the microwave heating unit, the microwave half The cavity, the conduction heating unit, the conduction heating power controller, the rotation receiving turntable and the rotation motor together form a composite heating module, and the composite heating module and the conducting half cavity have a plurality of The composite heating modules are arranged in an annular arrangement on a rotating device, and the conductive half-cavities are sequentially placed and removed on the composite heating modules.