RU2776350C1 - Heating device - Google Patents

Abstract

FIELD: heating equipment.

SUBSTANCE: heating device includes a cylindrical housing (110), a door housing (120), a module (161) for generating electromagnetic waves and a radiating antenna (150). A heating chamber (111) is formed in the cylindrical housing (110), which has an opening for loading and placement, and the heating chamber (111) is designed to accommodate the object to be processed. The door housing (120) is located on the opening for loading and placement and is designed to open and close the opening for loading and placement. The module (161) for generating electromagnetic waves is designed with the possibility of generating an electromagnetic wave signal. The radiating antenna (150) is located in a cylindrical housing (110) and is electrically connected to the electromagnetic wave generation module (161) to generate electromagnetic waves of the appropriate frequency in accordance with the electromagnetic wave signal. The radiating antenna (150) is made with the possibility of bending in the direction next to the object to be processed to exclude the influence of the edge effect on the uniformity of the distribution of electromagnetic waves in the heating chamber (111) and increase the energy density and the range of distribution of electromagnetic waves when solving the problem of cost and increasing the uniformity of the distribution of electromagnetic waves.

EFFECT: expansion of the range of heating devices.

8 cl, 11 dwg, 2 tbl

Description

The field of technology to which the invention belongs

The present invention relates to kitchen appliances, and specifically relates to a heating device using electromagnetic waves.

Background of the invention

The food freezing process preserves the quality of the food, but the frozen food must be thawed before being processed or eaten. In order to enable users to freeze and thaw food, in the prior art, food is usually thawed by an apparatus using electromagnetic waves.

The uniform temperature distribution of defrosted food products is closely related to the uniform distribution of electromagnetic waves in the heating chamber. When there is a gap between the radiating antenna and the inner walls of the heating chamber in the circumferential direction of the radiating antenna, electromagnetic waves in the heating chamber will be concentrated at the peripheral edge of the radiating antenna due to the edge effect of the radiating antenna. In the prior art, to solve this problem, the radiating antenna is configured to at least close the inner wall of the heating chamber so that the food products are thawed evenly. However, this solution not only requires a large production cost, but also cannot solve the problem that electromagnetic waves are concentrated on the peripheral edge of the antenna, causing local heating or even ignition of the antenna.

Due to comprehensive consideration in the design, a heating device with low cost and uniform distribution of electromagnetic waves is required.

Brief description of the invention

One object of the present invention is to provide a heating device using electromagnetic waves at low cost and uniform distribution of electromagnetic waves.

Specifically, the present invention describes a heating device including

a cylindrical body in which a heating chamber is formed having a loading and accommodating opening, and the heating chamber is configured to receive an object to be processed;

a door body located on the loading and placing opening and configured to open and close the loading and placing opening;

an electromagnetic wave generation module configured to generate an electromagnetic wave signal; and

a radiating antenna located in a cylindrical housing and electrically connected to the electromagnetic wave generation module for generating electromagnetic waves of the appropriate frequency in accordance with the electromagnetic wave signal, and

the radiating antenna is made with the possibility of bending in the direction next to the object to be processed in order to achieve a more uniform distribution of electromagnetic waves in the heating chamber.

Optionally, the radiating antenna includes

a central part and an edge part, the edge part being located on one side of the central part at a distance from the object to be processed and extending parallel to the central part; and

a connecting part configured to connect the central part and the edge part.

Optionally, the connecting part is configured to deviate from the peripheral edge of the central part to the inner peripheral edge of the edge part.

Optionally, the connecting part includes

a first arc segment configured to extend from the peripheral edge of the center portion in a direction adjacent to the edge portion and touch the center portion;

a straight line segment configured to touch the first arc segment; and

a second arc segment configured to connect the outer peripheral edge of the straight line segment and the inner peripheral edge of the edge portion and touch the straight line segment and the edge portion.

Optionally, the geometric centers of the central part, the connecting part and the edge part coincide with the center of the maximum cross section of the heating chamber, taken along an imaginary plane parallel to the central part.

By choice, the central part has an oblong shape; and

the direction of the length of the central part is parallel to the direction of the length of the cross section.

Optionally, the length of the central part is 0.386-0.522 of the length of the cross section; and/or

the width of the central part is 0.19-0.471 of the width of the cross section; and/or

the radius of curvature of the central part is 0.2-0.4 of the width of the central part; and/or

the length of the outer end edge of the end part is 0.519-0.674 of the length of the cross section; and/or

the width of the outer end edge of the edge part is 0.38-0.62 of the width of the cross section; and/or

the radius of curvature of the outer end edge of the edge part is 0.2-0.4 of the width of the outer end edge of the edge part; and/or

the radius of the first arc segment is greater than or equal to 1/3 of the distance between the central part and the edge part in a direction perpendicular to the central part;

the internal angle between the straight line segment and the central part is 120-160°; and

the radius of the second arc segment is greater than or equal to 1/6 of the distance between the central part and the edge part in a direction perpendicular to the central part.

Optionally, the central part runs horizontally;

the central part is located at a height of 0.285-0.5 of the cylindrical body; and

the edge part is located at a height of 0.19-0.334 of the cylindrical body.

Optionally, the heating device additionally includes

antenna housing made of insulating material and configured to divide the inner region of the cylindrical housing into a compartment for an electrical appliance and a heating chamber, moreover

the radiating antenna is located in the electrical appliance compartment, and its central part is rigidly connected to the antenna body.

Optionally, the central part contains a plurality of engagement holes; and

the antenna housing respectively contains a plurality of brackets, and the plurality of brackets are configured to respectively pass through a plurality of engaging holes for engagement with the central part, moreover

each of the brackets consists of a fixing part perpendicular to the central part and having a hollow middle part, and an elastic part passing at an angle to the fixing part from the inner end edge of the fixing part to the central part.

The present invention creatively places the radiating antenna for bending in the direction near the object to be processed, which can relatively reduce the distance between the center of the radiating antenna and the receiving contact, and increase the distance between the peripheral edge of the emitting antenna and the receiving contact, thus eliminating the influence of the edge effect on uniformity. distribution of electromagnetic waves in the heating chamber and increasing the energy density and propagation range of electromagnetic waves while solving the problem of cost and increasing the uniformity of the distribution of electromagnetic waves.

In accordance with the following detailed descriptions of specific embodiments of the present invention in conjunction with the drawings, experts in the art will more clearly understand the above and other objects, advantages and features of the present invention.

Brief description of the drawings

Some specific embodiments of the present invention are described in detail below with reference to the drawings by way of example and not limitation. The same reference numbers throughout the drawings designate the same or similar elements or parts. Those skilled in the art will appreciate that these drawings are not necessarily drawn to scale. On the drawings

Fig. 1 is a schematic structural view of a heating device according to one embodiment of the present invention;

Fig. 2 is a schematic sectional view of the heating device as shown in Fig. 1, in which the electromagnetic wave generating unit and the power supply are omitted;

Fig. 3 is a schematic enlarged view of region A in Fig. 2;

4 is a schematic structural view of an appliance compartment according to one embodiment of the present invention;

Fig. 5 is a schematic enlarged view of region B in Fig. 4;

Fig. 6 is a schematic sectional view of the heating device in transverse direction and vertical direction;

Fig. 7 is a schematic sectional view of the heating device in front-to-back direction and vertical direction;

Fig. 8 is a test view of a radiating antenna in accordance with one embodiment of the present invention;

Fig. 9 is a simulation view of the distribution of electromagnetic waves measured based on Fig. 8;

10 is a test view of a radiating antenna according to a comparative example of the present invention;

Fig.11 is a simulation view of the distribution of electromagnetic waves measured based on Fig.10.

Detailed description of the invention

FIG. 1 is a schematic structural view of a heating device 100 according to one embodiment of the present invention; FIG. 2 is a schematic sectional view of a heating device 100 as shown in FIG. . As shown in FIGS. 1 and 2, the heating device 100 may include a cylindrical body 110, a door body 120, an electromagnetic wave generation module 161, a power supply 162, and a radiating antenna 150.

In the cylindrical body 110, a heating chamber 111 is formed having an opening for loading and accommodating, and the heating chamber 111 is configured to receive an object to be processed. The loading and placing opening may be provided in the front wall or top wall of the heating chamber 111 for loading and placing the object to be processed.

The door body 120 can be mounted together with the cylindrical body 110 in an appropriate manner such as sliding rail connection, hinge connection, etc., and is configured to open and close the loading and placement opening. In the depicted embodiment, the heating device 100 also includes a drawer 140 for supporting an object to be processed, a front end plate of the drawer 140 is rigidly connected to the door body 120, and two transverse side plates of the drawer are movably connected to the cylindrical body 110 using sliding guides.

The power supply unit 162 may be electrically connected to the electromagnetic wave generation unit 161 to supply electric power to the electromagnetic wave generation unit 161 so that the electromagnetic wave generation unit 161 generates electromagnetic wave signals. The radiating antenna 150 may be located in the cylindrical body 110 and electrically connected to the electromagnetic wave generation module 161 to generate electromagnetic waves of appropriate frequencies in accordance with the electromagnetic wave signals to heat the object to be processed in the cylindrical body 110.

When the loading and stowage opening is formed in the front wall of the cylindrical body 110, the radiating antenna 150 may be located on the top side, the bottom side, two sides, or the rear side of the cylindrical body 110. When the loading and stowage opening is formed in the top wall of the cylindrical body 110 , the radiating antenna 150 may be located on the peripheral side or underside of the cylindrical body 110. Preferably, the radiating antenna 150 is located on the underside of the cylindrical body 110 to prevent damage to the antenna due to an excessively tall object to be processed in the drawer 140, and the antenna may be closed with drawer 140.

Below, the technical solution of the present invention is described in detail by using the radiating antenna 150 located at the bottom of the cylindrical body 110 as an example.

In some embodiments, the cylindrical housing 110 may be made of metals for use as a receiving contact for receiving electromagnetic waves generated by the radiating antenna 150. In some other embodiments, the receiving contact plate may be located on the top wall of the cylindrical housing 110 for receiving electromagnetic waves, generated by the radiating antenna 150.

4 is a schematic structural view of an appliance compartment 112 in accordance with one embodiment of the present invention. As shown in FIG. 4, the radiating antenna 150 can be configured to bend upward to relatively reduce the distance between the center of the radiating antenna 150 and the top wall of the cylindrical body 110 and increase the distance between the peripheral edge of the radiating antenna 150 and the top wall of the cylindrical body 110, thus , eliminating the influence of the edge effect on the uniformity of the distribution of electromagnetic waves in the heating chamber 111 and increasing the energy density and the range of propagation of electromagnetic waves while increasing the uniformity of the distribution of electromagnetic waves.

It is well known to those skilled in the art that the edge effect means that the magnetic field strength at the peripheral edge of the antenna is much higher than the magnetic field strength at the center of the antenna.

Specifically, the radiating antenna 150 may include a central part 150a, an edge part 150c, and a connecting part 150b for connecting the central part 150a and the edge part 150c. The central portion 150a may extend in a horizontal direction. The edge part 150c may be located under the central part 150a and run parallel to the central part 150a. The connecting part 150b may be configured to extend from the peripheral edge of the central part 150a to the inner peripheral edge of the edge part 150c to further improve the uniformity of the distribution of electromagnetic waves in the heating chamber 111.

In some embodiments, connecting portion 150b may include a first arc segment, a straight line segment, and a second arc segment that are connected in series from a peripheral edge of center portion 150a to an inner edge of edge portion 150c, wherein the first arc segment may be configured to touch the center part 150a, the straight line segment may be configured to touch the first arc segment, and the second arc segment may be configured to touch the straight line segment and the edge portion 150c to prevent the generation of an edge effect at sharp corners and further improve the uniformity of the distribution of electromagnetic waves in the heating chamber 111.

In some embodiments, the geometric centers of the central part 150a, the connecting part 150b and the edge part 150c coincide with the center of the maximum cross section of the heating chamber 111, taken along an imaginary plane passing horizontally, to provide a more uniform distribution of electromagnetic waves in the heating chamber 111.

In some embodiments, the implementation of the heating chamber 111 may be in the form of a rectangle. Adaptively, the center portion 150a may be oblong in shape, and the length direction of the center portion 150a may be parallel to the length direction of the aforementioned cross-section, so that the electromagnetic waves in the heating chamber 111 are more evenly distributed.

In some embodiments, the length w _{1 of} the central portion 150a may be 0.386-0.522 (such as 0.386, 0.45, or 0.522) the length W of the aforementioned cross section. The width d _{1 of} the central portion 150a may be 0.19-0.471 (such as 0.19, 0.2, 0.375 or 0.471) of the width D of the above cross-section. The radius of curvature of the central portion 150a may be 0.2-0.4 (such as 0.2, 0.33, or 0.4) of the width d _{1 of} the central portion 150a. The length w _{2 of} the outer end edge of the edge portion 150c may be 0.519-0.674 (such as 0.519, 0.6 or 0.674) of the length W of the above cross-section. The width d _{2 of} the outer end edge of the edge portion 150c may be 0.38-0.62 (such as 0.38, 0.5 or 0.62) of the width D of the above cross-section. The radius of curvature of the outer end edge of the edge portion 150c may be 0.2-0.4 (such as 0.2, 0.33 or 0.4) of the width d _{2 of} the outer end edge of the edge portion 150c. The radius r _{1 of} the first arc segment may be greater than or equal to 1/3 of the distance (h ₁ -h ₂ ) between the central part 150a and the edge part 150c in the vertical direction, for example, may be 1/3, 2/5 or 1/2 of the distance between the central part 150a and the edge part 150c in the vertical direction. The internal angle α between the straight line segment and the central portion 150a may be 120-160°, such as 120°, 140° or 160°. The radius r _{2 of} the second arc segment may be greater than or equal to 1/6 of the distance (h ₁ -h ₂ ) between the central portion 150a and the edge portion 150c, for example, may be 1/6, 1/5, 1/3 or 1/2 the distance between the central part 150a and the edge part 150c in the vertical direction. In the present invention, by limiting each size of the radiating antenna 150 in the horizontal direction, the cost can be saved, and at the same time, the electromagnetic waves in the heating chamber 111 can have a relatively large propagation area in the horizontal direction.

The central portion 150a may be located at a height (h1/H) of 0.285-0.5 (such as 0.285, 0.292, 0.33, 0.4, or 0.5) of the cylindrical body 110. The edge portion 150c may be located at a height ( h ₂ /H) 0.19-0.334 (such as 0.19, 0.195, 0.2, 0.25 or 0.334) of the cylindrical body 110. In the present invention, by limiting the installation height of the radiating antenna 150 in the vertical direction, the volume of the heating chamber 111 may be relatively large, and at the same time, the electromagnetic waves in the heating chamber 111 may have a relatively high energy density.

For a further understanding of the present invention, the preferred embodiments of the present invention are described below in conjunction with more specific embodiments.

8 is a test view of a radiating antenna in accordance with one embodiment of the present invention. As shown in FIG. 8, the radiating antenna is a radiating antenna according to one embodiment of the present invention, and the parameters of the radiating antenna are w ₁ =154 mm, d ₁ =86 mm, w ₂ =205 mm, d ₂ =115 mm, r ₁ =10 mm, α=130°, r ₂ =5 mm, h ₁ =50 mm, h ₂ =34 mm; the radius of curvature of the central part 150a is 28 mm; and the radius of curvature of the outer end edge of the edge portion 150c is 38 mm.

10 is a test view of a radiating antenna according to a comparative example of the present invention. As shown in Fig. 8, the radiating antenna is a flat plate antenna, and the antenna has an oblong shape with a length of 205 mm, a width of 115 mm, a curvature radius of 38 mm, and a distance of 50 mm between the antenna and the bottom wall.

Test Description: The radiating antenna in the embodiment of Fig. 8 and the radiating antenna in the comparative example of Fig. 10 are respectively located in a cylindrical housing (W=342 mm, D=230 mm, H=171 mm) for simulation experiments.

Fig. 9 is a simulation view of the distribution of electromagnetic waves measured in Fig. 8. Fig. 11 is a simulation view of the distribution of electromagnetic waves measured in Fig. 10. In order to clearly compare the difference in electromagnetic wave distribution between the embodiment and the comparative example, both the simulation view in Fig. 9 and the simulation view in Fig. 11 are set as follows: when the magnetic field strength at any spatial point in the cylindrical body is greater than the strength value ( the strength value is the difference between the magnetic field strength at the center of the antenna in the embodiment of Fig. 8 and the magnetic field strength at the center of the antenna in the comparative example of Fig. 10), the spatial point is shown as having electromagnetic waves.

In Figs. 9 and 11, it can be seen that, compared with the flat plate antenna in the comparative example, the radiating antenna 150 in the embodiment of the present invention has no latent magnetic field concentration problems, and has a uniform distribution and a relatively large distribution range of electromagnetic waves.

Table 1

Table a electric field strength tests

measuring point X Y Z Electric field strength m1 15,500 66,000 401.830 2.782e+003 m2 15,500 66,000 457.700 3.059e+003 m3 110,500 66,000 401.830 3.181e+003 m4 15,500 66,000 347.700 2.829e+003 m5 -79,500 66,000 401.830 3.060e+003

table 2

Table b electric field strength test

measuring point X Y Z Electric field strength m1 15,600 66,000 401.830 1.206e+003 m2 15,500 66,000 457.700 1.813e+003 m3 110,500 66,000 401.830 1.813e+003 m4 15,500 66,000 347.700 1.446e+003 m5 -79,500 66,000 401.830 1.685e+003

Table 1 is an electric field strength test table in FIG. Table 2 is an electric field strength test table in FIG. From Tables 1 and 2, it can be seen that the radiating antenna 150 in the embodiment of the present invention has a higher electric field strength at the same spatial point of the cylindrical body than the flat plate antenna in the comparative example, that is, the energy density of electromagnetic waves at this spatial point higher, and higher heating efficiency can be obtained.

As shown in FIG. 2 and 4, the heating device 100 may further include an antenna case 130 for dividing the interior of the cylindrical body 110 into a heating chamber 111 and an electrical appliance compartment 112. The object to be processed and the radiating antenna 150 may be respectively disposed in the heating chamber 111 and the appliance compartment 112 to separate the object to be processed from the radiating antenna 150 to prevent contamination or damage to the radiating antenna 150 due to accidental touching.

In some embodiments, antenna housing 130 may be made of an insulating material such that electromagnetic waves generated by radiating antenna 150 can pass through antenna housing 130 to heat the object to be treated. In addition, the antenna body 130 may be made of an opaque material to reduce the electromagnetic loss of electromagnetic waves on the antenna body 130, thereby increasing the heating rate of the object to be treated. The above-mentioned opaque material is a translucent material or an opaque material. The opaque material may be polypropylene, polycarbonate or acrylonitrile butadiene styrene.

Antenna housing 130 may also be configured to mount a radiant antenna 150 to facilitate assembly of the heating device 100 and provide location and installation of the radiant antenna 150. Specifically, the antenna housing 130 may include a sheathing board 131 for separating the heating chamber 111 and compartment 112 for electrical appliance, and the enclosing part 132 rigidly connected to the inner wall of the cylindrical housing 110, and the central part 150a of the radiating antenna 150 can be made with the possibility of rigid connection with the sheathing board 131.

In some embodiments, the implementation of the radiating antenna 150 may be configured to engage with the body 130 of the antenna. Fig. 5 is a schematic enlarged view of region B in Fig. 4. As shown in FIG. 5, the radiating antenna 150 may include a plurality of engagement holes 151, the antenna housing 130 may respectively comprise a plurality of brackets 133, and the plurality of brackets 133 are configured to respectively pass through the plurality of engagement holes 151 to engage with the radiating antenna 150.

Specifically, each of the brackets may be composed of a fixing part perpendicular to the radiating antenna and having a hollow middle part, and an elastic part extending at an angle to the fixing part from the inner end edge to the radiating antenna.

The antenna housing 130 may further include a plurality of stiffening ribs, and the stiffening ribs are configured to connect the board 131 and the enclosure 132 to increase the structural strength of the antenna housing 130.

Fig. 3 is a schematic enlarged view of region A in Fig. 2. As shown in FIGS. 1-3, the heating device 100 may further include a signal processing, measurement, and control circuit 170. Specifically, the signal processing, measurement, and control circuit 170 may include a detection unit 171, a control unit 172, and a matching unit 173.

The detection unit 171 may be connected in series between the electromagnetic wave generation unit 161 and the radiating antenna 150, and is configured to detect in real time specific parameters of the incident wave signals and the reflected wave signals passing through the detection unit.

The control unit 172 may be configured to obtain specific parameters from the detection unit 171 and calculate the power of the incident waves and reflected waves in accordance with the specific parameters. In the present invention, the specific parameters may be voltage values and/or current values. Alternatively, the detection unit 171 may be a power meter for directly measuring the power of incident waves and reflected waves.

The control unit 172 may further calculate the electromagnetic wave absorption rate of the object to be processed according to the power of the incident waves and the reflected waves, compare the electromagnetic wave absorption rate with the predetermined absorption threshold, and issue an adjustment command to the matching unit 173 when the electromagnetic wave absorption rate is less than the predetermined absorption threshold. The predetermined absorption threshold may be 60%-80%, such as 60%, 70%, or 80%.

The matching unit 173 may be connected in series between the electromagnetic wave generation unit 161 and the radiating antenna 150, and is configured to adjust the load resistance of the electromagnetic wave generation unit 161 in accordance with the adjustment command of the control unit 172 to improve the degree of matching between the output impedance and the load resistance of the generation unit 161 electromagnetic waves, so that when foodstuffs with different fixed characteristics (such as type, weight, and volume) are placed in the heating chamber 111 or at the time of food temperature change, relatively more electromagnetic wave energy is emitted in the heating chamber 111, thus increasing the speed heating.

In some embodiments, the implementation of the heating device 100 may be used for defrosting. The control unit 172 may also be configured to calculate the rate of change of the imaginary part of the dielectric coefficient of the object to be processed according to the power of the incident waves and reflected waves, compare the rate of change of the imaginary part with a predetermined change threshold, and send a stop command to the electromagnetic wave generation module 161 when the rate of change of the imaginary part of the dielectric coefficient of the object to be processed is greater than or equal to the predetermined change threshold, so that the electromagnetic wave generation unit 161 stops and the defrost program is terminated.

A predetermined change threshold can be obtained by testing the rate of change of the imaginary part of the dielectric coefficient of food products with different fixed characteristics at -3°C to 0°C, so that the food products have good shear strength. For example, when the object to be processed is raw beef, the predetermined change threshold may be set to 2.

The control unit 172 may also be configured to receive a user command and control the electromagnetic wave generation module 161 to start operation in accordance with the user's command, the control unit 172 being electrically connected to the power unit 162 to receive electrical power from the power unit 162 and permanently in a state of waiting.

In some embodiments, signal processing, measurement, and control circuitry 170 may be integral with a circuit board and horizontally positioned in appliance compartment 112 to provide electrical connection between radiating antenna 150 and matching module.

The antenna body 130 and the cylindrical body 110 may include heat dissipation holes 190, respectively, at positions corresponding to the matching block 173, so that heat generated by the matching block 173 during operation is removed through the heat dissipation holes 190. In some embodiments, signal processing, measurement, and control circuitry 170 may be located on the rear side of radiating antenna 150. Heat dissipation holes 190 may be formed in the rear walls of antenna housing 130 and cylindrical housing 110.

In some embodiments, the metal barrel 110 may be configured to be grounded to drain electrical charges from it, thereby improving the safety of the heating device 100.

The heating device 100 may further include a metal bracket 180. The metal bracket 180 may be configured to couple the circuit board and the barrel 110 to support the circuit board and conduct electrical charges from the circuit board through the barrel 110. In some embodiments, the metal bracket 180 may consist of two parts perpendicular to each other. The metal bracket 180 may be rigidly connected in advance to the printed circuit board and the cylindrical body 110.

In some embodiments, the electromagnetic wave generation module 161 and the power supply 162 may be located on the outside of the cylindrical housing 110. A portion of the metal bracket 180 may be located at the rear of the printed circuit board and extend vertically in the transverse direction and may contain two holes for wiring, so that the wiring terminal of the detection unit 171 (or matching unit 173) comes out of one wiring hole and is electrically connected to the electromagnetic wave generation module 161, and the wiring clip of the control unit 172 comes out of the other wiring hole and is electrically connected to the electromagnetic wave generation module 161 and block 162 power.

In some embodiments, barrel body 110 and door body 120 may respectively comprise electromagnetic shielding features such that door body 120 is conductively connected to barrel body 110 when the door body is in the closed position to prevent electromagnetic waves from leaking out.

In some embodiments, a heating device 100 may be located in a storage compartment of a refrigerator to allow users to defrost food.

However, those skilled in the art should understand that while many embodiments of the present invention have been shown and described in detail herein without departing from the spirit and scope of the present invention, many other changes or modifications that are consistent with the principles of the present invention are still can be directly determined or derived from the content disclosed in the present invention. Therefore, the scope of the present invention should be understood and considered as including all these other changes or modifications.

Claims (37)

1. Heating device, containing: a cylindrical body in which a heating chamber is formed having an opening for loading and accommodating, and the heating chamber is configured to receive an object to be processed; a door body located on the loading and placing opening and configured to open and close the loading and placing opening; an electromagnetic wave generation module configured to generate an electromagnetic wave signal; and a radiating antenna located in a cylindrical housing and electrically connected to the electromagnetic wave generation module for generating electromagnetic waves of the appropriate frequency in accordance with the electromagnetic wave signal, and the radiating antenna is made with the possibility of bending in the direction close to the object to be processed, in order to achieve a more uniform distribution of electromagnetic waves in the heating chamber, radiating antenna contains a central part and an edge part, the edge part being located on one side of the central part at a distance from the object to be processed and extending parallel to the central part; and a connecting part configured to connect the central part and the edge part, and connecting part contains: a first arc segment configured to extend from the peripheral edge of the central portion in a direction adjacent to the edge portion and touch the central portion; a straight line segment configured to touch the first arc segment; and a second arc segment configured to connect the outer peripheral edge of the straight line segment and the inner peripheral edge of the edge portion and touch the straight line segment and the edge portion. 2. The heating device according to Claim. 1, in which the connecting part is made with the possibility of deviation from the peripheral edge of the Central part to the inner peripheral edge of the edge part. 3. The heating device according to claim 1, in which the geometric centers of the central part, the connecting part and the edge part coincide with the center of the maximum cross section of the heating chamber, taken along an imaginary plane parallel to the central part. 4. The heating device according to claim. 3, in which the central part has an oblong shape; and the direction of the length of the central part is parallel to the direction of the length of the cross section. 5. Heating device according to claim 4, in which the length of the central part is 0.386-0.522 of the length of the cross section; and/or the width of the central part is 0.19-0.471 of the width of the cross section; and/or the radius of curvature of the central part is 0.2-0.4 of the width of the central part; and/or the length of the outer end edge of the edge part is 0.519-0.674 of the length of the cross section; and/or the width of the outer end edge of the edge part is 0.38-0.62 of the width of the cross section; and/or the radius of curvature of the outer end edge of the edge part is 0.2-0.4 of the width of the outer end edge of the edge part; and/or the radius of the first arc segment is greater than or equal to 1/3 of the distance between the central part and the edge part in a direction perpendicular to the central part; the internal angle between the straight line segment and the central part is 120-160°; and the radius of the second arc segment is greater than or equal to 1/6 of the distance between the central part and the edge part in a direction perpendicular to the central part. 6. Heating device according to claim 1 or 5, in which the central part runs horizontally; the central part is located at a height of 0.285-0.5 of the cylindrical body, and the edge part is located at a height of 0.19-0.334 of the cylindrical body. 7. The heating device according to claim 1, further comprising an antenna housing made of insulating material and configured to divide the inner region of the cylindrical housing into a compartment for an electrical appliance and a heating chamber, moreover the radiating antenna is located in the electrical appliance compartment, and its central part is rigidly connected to the antenna housing. 8. Heating device according to claim 7, in which the central part contains a plurality of engagement holes; and the antenna housing respectively comprises a plurality of brackets, and the plurality of brackets are configured to respectively pass through the plurality of engagement holes to engage with the central part, wherein each of the brackets consists of a fixing part perpendicular to the central part and having a hollow middle part, and an elastic part passing at an angle to the fixing part from the inner end edge of the fixing part to the central part.

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