KR102300717B1 - Microwave heating device and microwave guiding tube thereof - Google Patents

Abstract

The present invention is a microwave heating device, and has a microwave guide tube, two microwave transmission modules, and a transmission module. The microwave guide tube is formed with a wave propagation path and has at least one pair of transport openings and at least one pair of waveguide plates. The at least one pair of transport openings has two transport openings each disposed on two opposite walls of the microwave guide tube along a transport direction. At least one pair of waveguide plates is disposed within the microwave guide tube and has two waveguide plates parallel to the wave propagation path. Two microwave transmission modules are disposed at two opposite end parts of the microwave guide tube. The transmission module extends through at least one pair of transport openings along a transport direction.

Description

MICROWAVE HEATING DEVICE AND MICROWAVE GUIDING TUBE THEREOF

The present invention relates to a microwave heating device and a microwave guide tube thereof, in particular a microwave heating device capable of uniformly heating both high microwave absorbing material and low microwave absorbing material, and a microwave guide tube thereof.

Conventional microwave heating devices in the prior art can be mainly classified into the following three types. First, closed resonant cavity: The principle of closed resonant cavity is caused by microwave hot spots and cold spots of the closed resonant cavity by moving or rotating a heating object in the closed resonant cavity. It is to reduce the non-uniformity of heating for the heated object. Second, open resonant cavity: the principle is similar to closed resonant cavity, the heating object is heated by continuous flow through the standing wave hot spot of the open resonant cavity, the heating object is ionized, and the closed resonant cavity produces a light source such as a sulfur lamp or It is mainly used for disposal. Third, traveling wave heater: the principle is to heat the heating object by the traveling wave along the microwave transmission path to avoid the heating unevenness caused by the hot spot and cold spot effect of the standing wave.

Among them, the closed resonant cavity and the open resonant cavity use a standing wave to heat a heating object. However, the standing wave will form obvious hot and cold spots in the cavity and the heating object cannot be heated uniformly. In practice, this can only be applied in low-cost markets such as wood dewatering or tobacco drying.

Although the traveling wave heater does not form obvious hot spots and cold spots, when the heating object is a low microwave absorption material, the traveling wave heater can heat the heating object uniformly. However, when the heating object is a high microwave absorbing material, the microwave energy is rapidly absorbed by the heating object to be heated close to the heating source, so that the heating object far from the heating source cannot be sufficiently heated and the object to be heated cannot be heated uniformly. lead to unpredictable results. Therefore, the conventional microwave heating apparatus of the prior art needs to be improved.

In order to overcome the disadvantages of conventional microwave heating devices, the present invention provides a microwave heating device and a microwave guide tube thereof.

The main object of the present invention is to provide a microwave heating device and a microwave guide tube thereof, particularly a microwave heating device capable of uniformly heating both high microwave absorbing material and low microwave absorbing material, and a microwave guide tube thereof.

The microwave heating device according to the present invention comprises:

a microwave guide tube that forms a wave propagation path;

two microwave transmission modules respectively disposed at two opposite ends of the microwave guide tube along the wave propagation path; and

a transfer module extending through at least one pair of transfer openings along a transfer direction;

The microwave guide tube is:

at least one heating segment;

at least one pair of transfer openings, and

at least one pair of waveguide plates disposed within the at least one heating segment;

Each one of the at least one heating segment comprises:

front opening wall,

a rear opening wall disposed with a gap spaced apart from the front opening wall along the transport direction;

a top wall connected to the front opening wall and the rear opening wall; and

a bottom wall connected to the front opening wall and the rear opening wall and facing the top wall;

each one of the at least one pair of transfer openings has two transfer openings respectively formed through the front opening wall and the rear opening wall of the at least one heating segment;

Each one of the at least one waveguide plate pair comprises:

a position corresponding to the position of the at least one pair of transport openings along the wave travel path, and

and two waveguide plates respectively disposed on a top wall and a bottom wall of the at least one heating segment and extending along a wave propagation path and made of a dielectric material.

The microwave guide tube of the microwave heating device according to the present invention comprises:

at least one heating segment;

at least one pair of transfer openings, and

at least one pair of waveguide plates disposed within the at least one heating segment;

Each one of the at least one heating segment comprises:

front opening wall,

a rear opening wall disposed with a gap spaced apart from the front opening wall along the transport direction;

a top wall connected to the front opening wall and the rear opening wall; and

a bottom wall connected to the front opening wall and the rear opening wall and facing the top wall;

each one of the at least one pair of transfer openings has two transfer openings respectively formed through the front opening wall and the rear opening wall of the at least one heating segment;

Each one of the at least one waveguide plate pair comprises:

a position corresponding to the position of the at least one pair of transport openings along the wave travel path, and

and two waveguide plates respectively disposed on a top wall and a bottom wall of the at least one heating segment and extending along a wave propagation path and made of a dielectric material.

Other objects, advantages and novel features of the present invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.

1 is a perspective view of a first embodiment of a microwave heating device according to the present invention;
Fig. 2 is an exploded perspective view of the microwave heating device of Fig. 1;
3 is a further enlarged exploded perspective view of the microwave heating device of FIG. 1 ;
Fig. 4 is a partial cross-sectional side view of the microwave heating device shown in Fig. 1;
Fig. 5 is an enlarged side view of the microwave heating device shown in Fig. 1;
Fig. 6 is a side view of a heating segment of a first embodiment of the microwave heating apparatus of Fig. 1;
7 is a side view of a heating segment of a second embodiment of a microwave heating device according to the present invention;
Fig. 8 is an enlarged side view of a heating segment of a second embodiment of the microwave heating apparatus of Fig. 7;
9 is a side view of a heating segment of a third embodiment of a microwave heating device according to the present invention;
Fig. 10 is a side view of a heating segment of a fourth embodiment of a microwave heating device according to the present invention;
Fig. 11 is an enlarged side view of a microwave suppression element of a first embodiment of the microwave heating apparatus of Fig. 1;
12 is an enlarged perspective view of a microwave guide tube of a fifth embodiment of the microwave heating device according to the present invention;
Fig. 13 is an exploded perspective view of a microwave guide tube of a fifth embodiment of the microwave heating device of Fig. 12;
Fig. 14 is a side view of a microwave guide tube of a fifth embodiment of the microwave heating device of Fig. 12;
Fig. 15 is a microwave electric field diagram of a microwave guide tube as shown in Fig. 5;
16 is a plot of reflection coefficient and mode conversion impedance matching frequency of microwave guide tubes in a pair of waveguide plates;
17 is a plot of penetration coefficient and mode conversion impedance matching frequency of microwave guide tubes of a pair of waveguide plates.

1 to 4, a first embodiment of the microwave heating device according to the present invention is a microwave guide tube 10, two microwave transmission modules 20, a transmission module 30, a suction module 40 and an isolation module 50 .

In a first embodiment of the invention, the microwave guide tube (10) has multiple heating segments (11) and multiple connecting segments (12). The heating segments 11 are arranged parallel to each other at spaced intervals along the transport direction D of the transmission module 30 . Each connecting segment 12 is connected to two adjacent ones of the heating segment 11 . In a first embodiment of the invention, each heating segment 11 may be a straight pipe, and each connecting segment 12 may be a curved pipe. By means of the heating segment 11 and the connecting segment 12 , the microwave guide tube 10 is formed into an S-shaped tube to have an S-shaped wave propagation path. Also, the microwave guide tube 10 may be a pipe with two open ends communicating with each other, so that the microwave guide tube 10 may have only one single tubular heating segment 11 .

이다.The two microwave transmission modules 20 are respectively connected to two opposite ends of the microwave guide tube 10 along the wave propagation path. Each of the two microwave transmission modules 20 follows the wave propagation path of the microwave guide tube 10 from one of the two opposite ends of the microwave guide tube 10 to the other of the two opposite ends of the microwave guide tube 10 . emit microwaves. When the heating object is heated in the microwave guide tube 10, even if the distance between the heating object and one of the two microwave transmission modules 20 is different, the heating of each heating object in response to one of the microwave transmission modules 20 The power is different, and the difference can be complementary to the other of the two microwave transmission modules 20, making the overall heating power for each heating object more uniform. Specifically, if the percentage of microwave energy absorbed by the heating object is defined as the efficiency of use, the maximum value of microwave energy absorbed by the heating object (P _max ) minus the minimum value along the wave travel path (P _{min )} this value divided by the average value (P _averag e) is defined as the uniformity. That is, the uniformity (%) is

am.

From the calculation results in Table 1, it can be seen that under the same usage efficiency, the use of two microwave transmission modules 20 can greatly improve the heating uniformity.

The relationship between uniformity and usage efficiency for one single microwave transmission module 20 and two microwave transmission modules 20: use efficiency of a single microwave transmission module
uniformity of two microwave transmission modules
uniformity 95% 297.03% 93.88% 85% 188.49% 41.44% 75% 137.83% 22.87% 65% 104.41% 13.33% 55% 79.43% 7.79% 45% 59.47% 4.39% 35% 42.86% 2.29% 25% 28.65% 1.02%

In the first embodiment of the present invention, each of the two microwave transmission modules 20 emits microwaves with a frequency of 2450 MHz toward the microwave guide tube 10, and the cross-sectional shape of the microwave guide tube 10 is determined in frequency. Adopts the WR340 rectangular cross section defined by the Electronics Industry Association (EIA). Although the rectangular cross-section allows the microwave to _{operate in TE 10} mode to reduce complexity, the microwave frequency emitted by each of the two microwave transmission modules 20 is not limited to 2450 MHz.

Further, in the first embodiment of the present invention, each microwave transmission module 20 includes a microwave source 21 , a circulator 22 , a directional coupler 23 and a water loader. ) (24). The microwave source 21 and the directional coupler 23 are disposed at both ends of the microwave transmission module 20, respectively. The circulator 22 is connected to the microwave source 21 and the directional coupler 23 . The water loader 24 is connected to one side of the circulator 22 . The directional coupler 23 is connected to one of the two opposite ends of the microwave guide tube 10 . The circulator 22 protects the microwave source 21 by controlling the microwave transmitted in a specific direction using a gyro-magnetic phenomenon. Directional coupler 23 is to measure the microwave power transmitted towards the microwave guide tube 10 by the microwave transmission module 20 and the microwave power transmitted towards the microwave transmission module 20 by the microwave guide tube 10 can

3, 5 and 6, each heating segment 11 of the microwave guide tube 10 has a pair of conveying openings 13, each pair of conveying openings 13 along a wave travel path. It has two conveying openings 131 extending through the two opposite end walls of the reaction segment of the heating segment 11 respectively along the conveying direction D of the transmission module 30 . is formed

In detail, referring to FIGS. 3, 5 and 6 , each heating segment 11 of the microwave guide tube 10 includes a front opening wall 111 , a rear opening wall 112 , a top wall 113 and It has a bottom wall 114 . The front opening wall 111 and the rear opening wall 112 are arranged at spaced apart intervals along the transport direction D of the transmission module 30 . The top wall 113 and the bottom wall 114 are connected to the front opening wall 111 and the rear opening wall 112 , and the top wall 113 and the bottom wall 114 face each other. The two conveying openings 131 of the conveying opening pair 13 are respectively formed through the front opening wall 111 and the rear opening wall 112 of the heating section 11 .

The transfer module 30 extends through each transfer opening pair 13 of the microwave guide tube 10 along the transfer direction D. Preferably, the transmission module 30 is a conveying belt and causes the heating object to sequentially pass through each heating segment 11 of the microwave guide tube 10 through a pair of conveying openings 13 along the conveying direction D. do. During the course of passing through each heating segment 11 of the microwave guide tube 10 , the heating object is heated by absorbing the microwave energy emitted by the microwave transmission module 20 .

In the first embodiment of the present invention, each delivery opening 131 of the microwave guide tube 10 has a midline 1311 , a top peripheral edge 1312 and a bottom peripheral edge 1313 . The top peripheral edge 1312 and the bottom peripheral edge 1313 are respectively disposed on either side of the midline 1311 . The distance between the top peripheral edge 1312 and the bottom peripheral edge 1313 is defined as the opening width of the conveying opening 131 . The opening widths of the opposite ends of each conveying opening 131 along the wave propagation path are each tapered to improve the impedance matching effect of microwaves on the wave propagation path in the microwave guide tube 10 to thereby improve the microwave guide tube 10. The heating object is heated more uniformly.

The specific shape of the opposite end of each conveying opening 131 is described as follows: The upper peripheral edge 1312 of each conveying opening 131 consists of a top main segment 61 and two upper necked segments. ) has The uppermost main segment 61 extends along the wave travel path, and the two upper neck segments are respectively connected to opposite ends of the uppermost main segment 61 along the wave travel path. The bottom peripheral edge 1313 of each conveying opening 131 has a bottom main segment 62 and two lower neck segments. A bottom main segment 62 extends along the wave travel path, and the two lower neck segments are connected to the two opposite ends of the bottom main segment 62 along the wave travel path. The upper and lower neck segments of each conveying opening 131 along the wave travel path at each end of the two opposite ends of the conveying opening 131 extend towards the midline 1311 , and the The two distal ends are connected to each other to form one of the two opposite ends of the transfer opening 131 . To further adjust the impedance matching, the shape of the upper and lower neck segments can be one of four types:

First, linear gradation: each neck segment (ie, upper neck segment and lower neck segment) is straight. That is, each upper neck segment is a first upper straight segment 63 , and each lower neck segment is a first lower straight segment 64 .

Second, a multiple-vertex structure: each neck segment (ie, an upper neck segment and a lower neck segment) has two It has more than one connected straight line segment. That is, each upper neck segment has a first upper straight segment 63A and a second upper straight segment 65A, the second upper straight segment 65A having a corresponding first upper straight segment 63A and an uppermost main segment 65A. It is located between the segments 61A. _{The angle θ 1} between the first upper straight segment 63A and the midline 1311A is greater than _{the angle θ 2} between the extension of the second upper straight segment 65A and the midline 1311A. Each lower neck segment has a first lower straight segment 64A and a second lower straight segment 66A, the second lower straight segment 66A having a corresponding first lower straight segment 64A and a bottom main segment 64A 62A). The angle between the first lower straight segment 64A and the midline 1311A is greater than the angle between the extension of the second lower straight segment 66A and the midline 1311A.

Of these, the first upper straight segment 63A is connected to the end of the second upper straight segment 65A extending towards the midline 1311A. In a second embodiment of the present invention, the length of each straight segment and the included angle with the midline 1311A are adjusted according to the theory of Chebyshev multi-section matching transformer to reduce the size of the system when using frequency and to be within the optimal range. It can be designed to achieve a match.

Third, the curvature gradient: each neck segment (ie, the upper neck segment and the lower neck segment) is an arc; For example, in a third embodiment of the invention as shown in FIG. 9 , each upper neck segment is a first upper arc segment 63B, and the first upper arc segment 63B preferably has a conveying opening ( Projecting outwardly of 131B, each lower neck segment is a first lower arc segment 64B, the first lower arc segment 64B preferably facing out of the conveying opening 131B.

Fourth, stepped structure: Each of the neck segments (ie, the upper neck segment and the lower neck segment) has a stepped shape. For example, in a fourth embodiment of the present invention as shown in FIG. 10 , each upper neck segment is an upper stepped segment 63C, and each lower neck segment is a lower stepped segment 64C. The distance between the upper stepped segment 63C and the lower stepped segment 64C is generally reduced away from the center of the transfer opening 131C. In the fourth embodiment of the present invention, each stepped segment 63C, 64C forms multiple right angles, but each stepped segment 63C, 64C may form only one right angle. The size of each staged segment 63C, 64C can be designed according to the theory of Chebyshev multi-section matching transformer to achieve the purpose of reducing the size of the system, and the optimum matching effect can be obtained within the frequency range. have.

In the above-described embodiment, the shape and position of the upper and lower neck segments of each transfer opening 131 are symmetric to each other, but not limited thereto.

3 , 5 and 6 , which is a first embodiment of the present invention, the microwave guide tube 10 further has multiple waveguide plate pairs 14 each disposed in a heating segment 11 . That is, each pair of transport openings 13 is provided with a corresponding pair of waveguide plates 14 . The position of each pair of waveguides 14 on the wave travel path corresponds to the position of the transport opening pair 13 in the same heating segment 11 on the wave travel path. Each waveguide plate pair 14 has two waveguide plates 141 , which are respectively connected to each one top wall 113 and a bottom wall 114 of the heating segment 11 and follow the wave propagation path. extend Each waveguide plate 141 is made of a dielectric material, preferably made of alumina ceramic, but is not limited thereto. Each waveguide plate 141 may also be made of aluminum nitride ceramic, which has better thermal conductivity than alumina ceramic or boron nitride ceramic. The waveguide plate pair 14 modulates the wave propagation mode of microwave in the microwave guide tube 10, changing from the original basic mode TE10 to a specific higher-order mode, and has the following effects:

First, when the microwave absorption property of the heating object is strong, the waveguide plate pair 14 can still heat the heating object uniformly.

Second, when a metal object appears in a conventional microwave guide tube, the microwave in the conventional microwave guide tube will be fully reflected back to the incident end by the metal object. That is, the impedance fails, and conventional microwave guide tubes cannot heat heating objects containing metal. However, even if the heating object in the microwave guide tube 10 of the present invention is mixed with the metal, the microwave can still bypass the metal object as usual to uniformly heat the heating object.

By providing the waveguide plate pair 14, the present invention can expand the range of materials that can be heated by the present invention by treating a heating object containing a metal and a material having strong microwave absorption properties. Accordingly, the present invention provides that conventional microwave heating devices such as wet circuit boards, various electronic products containing metal components, semiconductor wafers containing metals, solar cell wafers containing metal wires, and wet clothing with metal fittings can be heated. It is possible to heat a heating object having an impossible high unit cost, which can increase the value of the present invention.

In an embodiment of the present invention, the positions of the waveguide plate pair 14 and the transport opening pair 13 correspond to each other. Specifically, the center of gravity of each waveguide plate 141 and the shape center of each conveying opening 131 in each heating segment 11 are located in the same plane, but are not limited thereto. As long as the position of the waveguide plate 141 is substantially the same as the position of the transfer opening 131, the waveguide plate 141 can adjust the impedance matching of the microwave guide tube 10, and the heating object is the microwave guide tube ( When passing through 10), it can be heated uniformly.

이다. 극초단파의 진행 방향을 따라서, 단위 거리 내에서 재료가 흡수하는 에너지의 양은

이며, 여기서 P_O는 초기 입사 에너지이고, α는 감쇠 계수이고, α의 값은 재료의 유전체 상수 및 유전체 손실뿐만 아니라 진행 파동의 주파수와 사용 모드에 의해 결정된다.Specifically, in the traveling wave heating method, the magnitude of microwave energy in the heating object along the traveling direction is

am. Along the direction of travel of the microwave, the amount of energy absorbed by a material within a unit distance is

, Where P _O is the initial incident energy, α is a damping coefficient, the value of α is, as well as dielectric constant and dielectric loss of the material determined by the frequency and mode of use of the proceeding wave.

5, 15 and 16, by using a waveguide plate pair 14 made of a dielectric material in the microwave guide tube 10, the waveguide plate pair 14 converts the wave propagation mode into the original fundamental mode (TE _10). ) to a higher-order parallel electric field in TE mode. In the parallel electric field mode, the direction of the microwave electric field is parallel to the transport direction (D). Specifically, the wave propagation mode between the two waveguide plates 141 of the waveguide plate pair 14 _{is completely converted from the fundamental mode TE 10} to the TE mode as shown in FIG. 15 . The relationship between the reflection (S11) parameter (ie reflection coefficient) and the frequency corresponding to the impedance matching is shown in Fig. 16, where the horizontal coordinate unit is Ghz and the vertical coordinate unit is dB. In addition, referring to FIG. 17 , the relationship between the penetration (S21) parameter (ie, penetration coefficient) and the frequency corresponding to the impedance mode conversion from _{the basic mode (TE 10 ) to the TE mode of FIG. 15 in the entire frequency band} 0 dB.

The advantage of converting the traveling wave mode from the original fundamental mode (TE ₁₀ ) to the parallel electric field mode is the adjustable damping coefficient. Therefore, even if the microwave absorption characteristic of the heating object is strong, the waveguide plate pair 14 can uniformly heat the heating object. The problem is solved that conventional microwave heating devices can only heat the front edge of both ends of the heating object. In addition, the parallel electric field mode allows the microwave to bypass the metal object, so that even if the heating object is mixed with the metal object, the microwave can still bypass the metal object and uniformly heat the heating object as usual.

Further, in an embodiment of the present invention, the thickness of the two opposing ends of each waveguide plate 141 is gradually reduced toward the center away from the waveguide plate 141 to further improve impedance matching. In order to further adjust the impedance matching, the thickness reduction type of the two opposite ends of the waveguide plate 141 is also the same as the thickness reduction type of the two opposite ends of the conveying opening 131, as described above, and has four types includes:

First, linear gradation: the specific shape of the two opposing ends of each waveguide plate 141 is shown in FIG. 6 . The waveguide plate 141 has two sides, an abutting surface 71 , a main surface 72 and two first inclined surfaces 73 . The abutment surface 71 is disposed on one of the two sides of the waveguide plate 141 that is connected to the microwave guide tube 10 and extends along the wave propagation path. The major face 72 is disposed on the other of the two sides of the waveguide plate 141 along the wave travel path and has a length shorter than the length of the abutting face 71 along the wave path. The two first inclined surfaces 73 are respectively connected to the two sides of the main surface 72 and respectively extend to the two sides of the abutting surface 71 to follow the wave propagation path of the two opposite sides of the waveguide plate 141 . form the end. In the first embodiment of the present invention, the shape of the waveguide plate 141 is an isosceles trapezoid when viewed in the transport direction D. As shown in FIG.

Second, multi-apex structure: Referring to Figs. 7 and 8, which are the second embodiment of the present invention, the structure of the waveguide plate 141A having an apex structure at two ends is a waveguide plate 141 having a linear gradation at two ends. ) is substantially the same as the structure of The difference is that the waveguide plate 141A further has two second inclined surfaces 74A, each one of the second inclined surfaces 74A disposed between one of the first inclined surfaces 73A and the major surface 72A. point. The inclination of the second inclined surface 74A of each waveguide plate 141A with respect to the abutting surface 71A is smaller than the inclination of the first inclined surface 73A with respect to the abutting surface 71A. In other words, the angle between the normal line of the second inclined surface (74A) abutting normal and fit surface (71A) of (θ ₃₎ is the angle between the normal line of the first inclined surface (73A) normal to the abutment surface (71A) of (θ ₄ ) is smaller than Further, in another embodiment, multiple inclined surfaces with different inclinations may be connected between the first inclined surface 73A and the main surface 72A, so that the edge of the waveguide plate 141 of the second embodiment is formed by multiple folding points . In addition, the size of each slope can be designed according to the theory of Chebyshev multi-section matching transducer to obtain an optimal matching effect.

Third, curvature gradient: Referring to FIG. 9 which is the third embodiment of the present invention, the structure of the waveguide plate 141B having a curvature gradient at both ends is substantially the same as that of the waveguide plate 141 having a linear gradient at both ends. . The difference is that the two curved surfaces 73B are disposed at two opposite ends of the major surface 72B along the wave travel path, and the two curved surfaces 73B respectively abut from the two opposite ends of the major surface 72B. 71B to form two opposing ends of the waveguide plate 141B along the wave propagation path. Each one of the curved surfaces 73B preferably projects toward the outside of the waveguide plate 141B.

Fourth, stepped structure: Referring to FIG. 10 which is the fourth embodiment of the present invention, the structure of the waveguide plate 141C having a stepped structure at both ends is substantially the same as that of the waveguide plate 141 having a linear gray level at both ends. same. The difference is that the two stepped faces 73C are disposed at two opposite ends of the major face 72C along the wave travel path, and the two stepped faces 73C are positioned from the two opposite ends of the major face 72C. The point is that each extends to the abutment surface 71C and forms opposite ends of the waveguide plate 141C along the wave propagation path. In the fourth embodiment of the present invention, each one of the stepped faces 73C forms multiple right-angled portions, but each stepped face 73C may only form a right-angled portion. The size of each stepped face 73C can be designed to obtain an optimal matching effect according to the theory of the Chebyshev multi-section matching transformer.

1, 2 and 5, the suction module 40 communicates with the inside of the microwave guide tube 10, and is used to extract the water vapor emitted by the humid heating object after being heated. The suction module 40 has a tube assembly 41 , a heating layer 42 and a collection tank 43 . The tube assembly 41 is disposed over the microwave guide tube 10 and communicates with the interior of the microwave guide tube 10 . A heating layer 42 is disposed around the outside of the suction module 40 and disposed around the tube assembly 41 to prevent water vapor from condensing and flowing back into the microwave guide tube 10 . The collection tank 43 is connected to the tube assembly 41 on the opposite side of the microwave guide tube 10 to collect water condensed by water vapor in the microwave guide tube 10 .

1 , 5 and 11 , the isolation module 50 has two bases 51 , multiple microwave containment elements 52 and multiple isolation flanges 53 . The two bases 51 are respectively connected to the two heating segments 11 respectively at the two opposite ends of the microwave guide tube 10 along the transport direction D. Each one of the two bases 51 forms a channel 511 , which surrounds the transmission module 30 and communicates with one of the conveying openings 131 of each segment of the heating segment 11 . do. A microwave suppression element 52 is mounted to and extends from one top surface of each of the two bases 51 . Each microwave suppression element 52 is a tube, and the two ends of the microwave suppression element 52 are a closed end 521 and an open end 522, respectively. Referring to FIG. 11 , the open end 522 of the microwave suppression element protrudes from the top surface of the base of each of the two bases 51 . The closed end 521 of the microwave suppression element 52 is disposed in the channel 511 of each base of the two bases 51 . The microwave suppression element 52 may limit microwaves passing through the channel 511 and may further prevent the microwaves of the microwave guide tube 10 from leaking out from the transfer opening 131 . The microwave suppression element 52 is not limited to extending through the top surfaces of the two bases 51 , but may extend through any outer side of the two bases 51 . Referring to FIG. 3 , each one of the multiple isolation flanges 53 is connected between two adjacent segments of the heating segment 11 , and the two opposing openings of the isolation flange 53 are each connected to each other to avoid microwave leakage. connected to the transfer openings 131 of two adjacent heating segments 11 towards

12 to 14, which is the fifth embodiment of the present invention, the microwave guide tube 10D is a straight tube formed by combining two blocks 15D, and each one of the two blocks 15D The ends are each two mounting ends 16D of one of the microwave transmission modules 20 . The microwave guide tube 10D has multiple waveguide plate pairs 14D having a multiple apex structure. Each waveguide plate 141D of each waveguide plate pair 14D has a first inclined surface 73D and a second inclined surface 74D. Each conveying opening 131D has a guide annular wall 17D projecting from an outer peripheral peripheral edge of the conveying opening 131D. The guide annular wall 17D has a shielding surface 171D formed to surround the transfer opening 131D and to shield two opposite ends of the transfer opening 131D to reduce microwave leakage.

1 and 5 , when the present invention is used, a heating object is disposed at one end of the transmission module 30 , and the transmission module 30 moves the heating object relative to the microwave guide tube 10 in the transport direction D ) to move along. The heating object moves inside the microwave guide tube 10 through the transfer opening 131 . The heating object is absorbed and heated by microwave energy in the microwave guide tube 10 . When the present invention is used to heat and dehydrate a wet heating object, the suction module 40 extracts the water vapor emitted by the heating object and stores it in the collection tank 43 .

In summary, the present invention provides a microwave transmission module 20 at each of the two opposite ends of the microwave guide tube 10 to improve the heating uniformity of the microwave high absorption material of the microwave guide tube 10, and a high unit cost can improve the heat treatment of the heated object.

While many of the features and advantages of the present invention have been set forth in the foregoing description, together with details of structure and function of the present invention, the present disclosure is illustrative only, and in particular relates to the shape, size and arrangement of parts within the principles of the present invention. Matters may be changed in detail to the full extent indicated by the broad general meaning of the terms expressed by the appended claims.

Claims (27)

A microwave heating device comprising:
a microwave guide tube that forms a wave propagation path;
two microwave transmission modules respectively disposed at two opposite ends of the microwave guide tube along the wave propagation path; and
a transfer module extending through at least one pair of transfer openings along a transfer direction;
The microwave guide tube comprises:
at least one heating segment;
at least one pair of transfer openings, and
at least one pair of waveguide plates disposed within the at least one heating segment;
Each one of said at least one heating segment comprises:
front opening wall,
a rear opening wall disposed with a gap spaced apart from the front opening wall along the transport direction;
a top wall connected to the front opening wall and the rear opening wall; and
a bottom wall connected to the front opening wall and the rear opening wall and facing the top wall;
Each one of said at least one pair of transfer openings comprises:
two conveying openings respectively formed through the front opening wall and the rear opening wall of the at least one heating segment;
top perimeter edge;
a bottom perimeter edge facing the top perimeter edge at spaced apart intervals; and
having a distance between a top perimeter edge and a bottom perimeter edge defined as the opening width of the conveying opening, wherein the opening widths at the two opposite ends of the conveying opening along the wave travel path are respectively tapered,
Each one of said at least one pair of waveguide plates comprises:
a position corresponding to the position of the at least one pair of transport openings along the wave travel path, and
having two waveguide plates respectively disposed on a top wall and a bottom wall of the at least one heating segment and extending along a wave propagation path and made of a dielectric material;
microwave heating device. The method of claim 1,
each conveying opening of the microwave guide tube has a midline, and the uppermost peripheral edge and the bottom peripheral edge of the conveying opening are respectively disposed on both sides of the midline;
The uppermost peripheral edge of each transfer opening is:
an uppermost main segment extending along the wave propagation path, and
having two first upper straight segments respectively disposed at two opposite ends of the uppermost main segment;
The bottom peripheral edge of each transfer opening is:
a bottom main segment extending along the wave travel path; and
having two first lower straight segments respectively disposed at two opposite ends of the bottom main segment;
A first upper straight segment at each one of opposite ends of the top main segment along the wave travel path extends towards the midline, and a first at each one at each one of the opposite ends of the bottom main segment along the wave travel path. the lower straight segment extending towards the midline and connected to a first upper straight segment disposed at one of the opposite ends of the uppermost main segment that is the same as the opposite end of the bottom main segment;
microwave heating device. 3. The method of claim 2,
the uppermost peripheral edge of each conveying opening has two second upper straight segments, each one of the two second upper straight segments disposed between the uppermost main segment and one of the two first upper straight segments;
the bottom peripheral edge of each conveying opening has two second lower straight segments, each one of the two second lower straight segments disposed between the bottom main segment and one of the two first lower straight segments;
the angle between the midline and one of the two first upper straight segments is greater than the angle between the midline and the extension of each segment of the two second upper straight segments;
the angle between the midline and one of the two first lower straight segments is greater than the angle between the extension and the midline of each segment of the two second lower straight segments;
microwave heating device. The method of claim 1,
each conveying opening of the microwave guide tube has a middle line, and the uppermost peripheral edge and the bottom peripheral edge of the conveying opening are respectively disposed on both sides of the intermediate line;
The top peripheral edge of each conveying opening is:
an uppermost main segment extending along the wave propagation path, and
having two first upper arc segments respectively disposed at two opposite ends of the uppermost main segment;
The edge around the bottom of each transfer opening is:
a bottom main segment extending along the wave travel path; and
having two first lower arc segments respectively disposed at two opposite ends of the bottom main segment;
A first upper arc segment at each one of opposite ends of the uppermost main segment along the wave travel path extends towards the midline, and a first lower at each one at opposite ends of the bottom main segment along the wave travel path. the straight segment extending towards the midline and connected to a first upper arc segment disposed at one of the opposite ends of the top main segment that is the same as the opposite end of the bottom main segment;
microwave heating device. The method of claim 1,
each conveying opening of the microwave guide tube has a middle line, and the uppermost peripheral edge and the bottom peripheral edge of the conveying opening are respectively disposed on both sides of the intermediate line;
The top peripheral edge of each conveying opening is:
an uppermost main segment extending along the wave propagation path; and
having two upper stepped segments each disposed at two opposite ends of the uppermost main segment;
The edge around the bottom of each transfer opening is:
a bottom main segment extending along the wave travel path; and
having two lower stepped segments each disposed at two opposite ends of the floor main segment;
The upper stepped segments at each one of opposite ends of the top main segment along the wave travel path extend towards the midline, and the lower stepped segments at each one of the opposite ends of the bottom main segment along the wave travel path. is connected to the upper stepped segment extending towards the midline and disposed at one of the opposite ends of the top main segment that is the same as the opposite end of the bottom main segment;
microwave heating device. The method of claim 1,
each one of the two waveguide plates of the at least one waveguide plate pair has two opposing ends, wherein the thickness of each one of the two opposing ends of the waveguide plate is progressively reduced;
microwave heating device. 7. The method of claim 6,
Each of the waveguide plates comprises:
both sides;
an abutment surface disposed on one of both sides of the waveguide plate connected to the microwave guide tube and extending along the wave propagation path;
a major face disposed on the other one of both sides of the waveguide plate along the wave propagation path and having a length shorter than the length of the abutting face along the wave propagation path; and
having two first sloped surfaces respectively connected to opposite sides of the major face and extending respectively to opposite sides of the abutting face to form two opposing ends of the waveguide plate along a wave propagation path;
microwave heating device. 8. The method of claim 7,
each waveguide plate has two second inclined surfaces, each one of the second inclined surfaces disposed between one of the first inclined surfaces and the major surface;
an inclination of each second inclined surface of each waveguide plate with respect to the abutting surface is less than the inclination of each first inclined surface of each waveguide plate with respect to the abutting surface;
microwave heating device. 7. The method of claim 6,
Each waveguide plate is:
both sides;
an abutment surface disposed on one of both sides of the waveguide plate connected to the microwave guide tube and extending along the wave propagation path;
a major face disposed on the other of both sides of the waveguide plate along the wave propagation path and having a length shorter than the length of the abutting face along the wave propagation path; and
having two curved surfaces each connected to both sides of the major face and extending each to both sides of the abutment face to form two opposing ends of the waveguide plate along a wave propagation path;
microwave heating device. 7. The method of claim 6,
Each waveguide plate is:
both sides;
an abutment surface disposed on one of both sides of the waveguide plate connected to the microwave guide tube and extending along the wave propagation path;
a major face disposed on the other of both sides of the waveguide plate along the wave propagation path and having a length shorter than the length of the abutting face along the wave propagation path; and
having two stepped faces each connected to both sides of the major face and extending each to both sides of the abutment face to form two opposing ends of the waveguide plate along the wave propagation path;
microwave heating device. 11. The method according to any one of claims 1 to 10,
wherein the microwave heating device has a suction module in communication with the interior of the microwave guide tube and having a heating layer disposed around the outside of the suction module;
microwave heating device. 12. The method of claim 11,
The suction module has a water collection tank,
microwave heating device. 11. The method according to any one of claims 1 to 10,
The microwave heating device has one or more isolation modules, each one of the at least one isolation module comprising:
a base connected to the microwave guide tube and surrounding the transfer module and having a channel in communication with one of the transfer openings of the microwave guide tube; and
having multiple microwave suppression elements mounted to and extending from the base, each one of the microwave suppression elements being a tube and
an open end protruding from the base; and
having a closed end disposed in the channel of the base;
microwave heating device. 11. The method according to any one of claims 1 to 10,
the direction of the microwave electric field between the two waveguide plates of the at least one waveguide plate pair is parallel to the transport direction;
microwave heating device. A microwave guide tube for a microwave heating device, comprising:
at least one heating segment;
at least one pair of transfer openings, and
at least one pair of waveguide plates disposed within the at least one heating segment;
Each one of said at least one heating segment comprises:
front opening wall,
a rear opening wall disposed with a gap spaced apart from the front opening wall along the transport direction;
a top wall connected to the front opening wall and the rear opening wall; and
a bottom wall connected to the front opening wall and the rear opening wall and facing the top wall;
Each one of said at least one pair of transfer openings comprises:
two conveying openings respectively formed through the front opening wall and the rear opening wall of the at least one heating segment;
top perimeter edge;
a bottom perimeter edge facing the top perimeter edge at spaced apart intervals; and
having a distance between a top perimeter edge and a bottom perimeter edge defined as the opening width of the conveying opening, wherein the opening widths at the two opposite ends of the conveying opening along the wave travel path are respectively tapered,
Each one of said at least one pair of waveguide plates comprises:
a position corresponding to the position of the at least one pair of transport openings along the wave travel path, and
having two waveguide plates respectively disposed on a top wall and a bottom wall of the at least one heating segment and extending along a wave propagation path and made of a dielectric material;
Microwave guide tube of microwave heating device. 16. The method of claim 15,
each conveying opening of the microwave guide tube has a midline, and the uppermost peripheral edge and the bottom peripheral edge of the conveying opening are respectively disposed on both sides of the midline;
The uppermost peripheral edge of each transfer opening is:
an uppermost main segment extending along the wave propagation path, and
having two first upper straight segments respectively disposed at two opposite ends of the uppermost main segment;
The bottom peripheral edge of each transfer opening is:
a bottom main segment extending along the wave travel path; and
having two first lower straight segments respectively disposed at two opposite ends of the bottom main segment;
A first upper straight segment at each one of opposite ends of the top main segment along the wave travel path extends towards the midline, and a first at each one at each one of the opposite ends of the bottom main segment along the wave travel path. the lower straight segment extending towards the midline and connected to a first upper straight segment disposed at one of the opposite ends of the uppermost main segment that is the same as the opposite end of the bottom main segment;
Microwave guide tube of microwave heating device. 17. The method of claim 16,
the uppermost peripheral edge of each conveying opening has two second upper straight segments, each one of the two second upper straight segments disposed between the uppermost main segment and one of the two first upper straight segments;
the bottom peripheral edge of each conveying opening has two second lower straight segments, each one of the two second lower straight segments disposed between the bottom main segment and one of the two first lower straight segments;
the angle between the midline and one of the two first upper straight segments is greater than the angle between the midline and the extension of each segment of the two second upper straight segments;
the angle between the midline and one of the two first lower straight segments is greater than the angle between the extension and the midline of each segment of the two second lower straight segments;
Microwave guide tube of microwave heating device. 16. The method of claim 15,
each conveying opening of the microwave guide tube has a middle line, and the uppermost peripheral edge and the bottom peripheral edge of the conveying opening are respectively disposed on both sides of the intermediate line;
The top peripheral edge of each conveying opening is:
an uppermost main segment extending along the wave propagation path, and
having two first upper arc segments respectively disposed at two opposite ends of the uppermost main segment;
The edge around the bottom of each transfer opening is:
a bottom main segment extending along the wave travel path; and
having two first lower arc segments respectively disposed at two opposite ends of the bottom main segment;
A first upper arc segment at each one of opposite ends of the uppermost main segment along the wave travel path extends towards the midline, and a first lower at each one at opposite ends of the bottom main segment along the wave travel path. the straight segment extending towards the midline and connected to a first upper arc segment disposed at one of the opposite ends of the top main segment that is the same as the opposite end of the bottom main segment;
Microwave guide tube of microwave heating device. 16. The method of claim 15,
each conveying opening of the microwave guide tube has a midline, and the uppermost peripheral edge and the bottom peripheral edge of the conveying opening are respectively disposed on both sides of the midline;
The top peripheral edge of each conveying opening is:
an uppermost main segment extending along the wave propagation path; and
having two upper stepped segments each disposed at two opposite ends of the uppermost main segment;
The edge around the bottom of each transfer opening is:
a bottom main segment extending along the wave travel path; and
having two lower stepped segments each disposed at two opposite ends of the floor main segment;
The upper stepped segments at each one of opposite ends of the top main segment along the wave travel path extend towards the midline, and the lower stepped segments at each one of the opposite ends of the bottom main segment along the wave travel path. is connected to the upper stepped segment extending towards the midline and disposed at one of the opposite ends of the top main segment that is the same as the opposite end of the bottom main segment;
Microwave guide tube of microwave heating device. 16. The method of claim 15,
each one of the two waveguide plates of the at least one waveguide plate pair has two opposing ends, wherein the thickness of each one of the two opposing ends of the waveguide plate is progressively reduced;
Microwave guide tube of microwave heating device. 21. The method of claim 20,
Each of the waveguide plates comprises:
both sides;
an abutment surface disposed on one of both sides of the waveguide plate connected to the microwave guide tube and extending along the wave propagation path;
a major face disposed on the other of both sides of the waveguide plate along the wave propagation path and having a length shorter than the length of the abutting face along the wave propagation path; and
having two first sloped surfaces respectively connected to opposite sides of the major face and extending respectively to opposite sides of the abutting face to form two opposing ends of the waveguide plate along a wave propagation path;
Microwave guide tube of microwave heating device. 22. The method of claim 21,
each said waveguide plate has two second inclined surfaces, each one of the second inclined surfaces disposed between one of the first inclined surfaces and the major surface;
an inclination of each second inclined surface of each waveguide plate with respect to the abutting surface is less than the inclination of each first inclined surface of each waveguide plate with respect to the abutting surface;
Microwave guide tube of microwave heating device. 21. The method of claim 20,
Each waveguide plate is:
both sides;
an abutment surface disposed on one of both sides of the waveguide plate connected to the microwave guide tube and extending along the wave propagation path;
a major face disposed on the other of both sides of the waveguide plate along the wave propagation path and having a length shorter than the length of the abutting face along the wave propagation path; and
having two curved surfaces each connected to both sides of the major face and extending each to both sides of the abutment face to form two opposing ends of the waveguide plate along a wave propagation path;
Microwave guide tube of microwave heating device. 21. The method of claim 20,
Each waveguide plate is:
both sides;
an abutment surface disposed on one of both sides of the waveguide plate connected to the microwave guide tube and extending along the wave propagation path;
a major face disposed on the other of both sides of the waveguide plate along the wave propagation path and having a length shorter than the length of the abutting face along the wave propagation path; and
having two stepped faces each connected to both sides of the major face and extending each to both sides of the abutment face to form two opposing ends of the waveguide plate along the wave propagation path;
Microwave guide tube of microwave heating device. 25. The method according to any one of claims 15 to 24,
the direction of the microwave electric field between the two waveguide plates of the at least one waveguide plate pair is parallel to the transport direction;
Microwave guide tube of microwave heating device.
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