JP2023079369A - Cooker - Google Patents

Abstract

To provide a cooker having high microwave leakage performance.SOLUTION: A choke groove 24 comprises: a blocking wall surface nearly parallel to a bottom surface, and covering a portion of an opening part; and a folded part 26 extending nearly perpendicularly to the blocking wall surface from the blocking wall surface toward the inside of the choke groove 24. A height dimension H1 of a folded part 26A provided in the choke groove 24 in an upper side part 4p of a handle 4a of a door 4 is made lower than a height dimension H2 of a folded part 26B provided in the choke groove 24 in other sides (a lower side part 4q, a left side part, and a right side part) of the door 4.SELECTED DRAWING: Figure 8A

Description

The present invention relates to a heat cooker.

Heating devices using microwaves are widely put into practical use, such as microwave ovens. If microwaves leak to the outside from heating equipment that uses microwaves, unintended heating of objects and interference with radio wave communication will occur. The law stipulates that at a position 5 cm from the surface of the appliance, the emission must be 1 mW/cm ² or less when the door is closed, and 5 mW/cm ² or less when the door is half open (the door is opened until the microwave oven barely operates). ing.

In the conventional general microwave oven described in Patent Document 1, a choke structure is provided on the microwave oven door in order to prevent microwave leakage. This type of choke structure for preventing microwave leakage has a multi-stage structure with different choke groove widths, conductor widths, and effective dielectric constants, and has a choke groove depth smaller than 1/4 wavelength (for example, , see Patent Document 1). With this technology, the characteristic impedance in the traveling direction of the microwave that has entered the choke is set to a value that is small on the aperture side and large on the termination side. to infinity and works as a choke. Leakage waves incident vertically toward the choke grooves are shielded by the function of this choke.

JP 2015-178942 A

However, a general choke structure such as the one disclosed in Patent Document 1 has high leakage wave shielding performance against microwaves incident vertically toward the choke grooves, while leakage incident obliquely toward the choke grooves. With respect to waves, the choke structure alone cannot provide sufficient leakage wave shielding performance, and there is a problem that it is necessary to additionally provide a leakage radio wave suppression mechanism.

The present invention comprises a heating source for high-frequency heating of an object to be heated, a main body having a heating chamber in which the object to be heated is stored, and an openable and closable door provided in front of the heating chamber, The door has a choke structure formed by bending a metal plate multiple times around the perimeter of the door, and the choke structure includes a bottom surface facing the main body, side surfaces extending from both ends of the bottom surface toward the main body, and the main body. a choke groove having an opening facing the door, the choke groove being disposed along the perimeter of the door, the choke groove being substantially parallel to the bottom surface and covering a portion of the opening; and a folded portion extending from the closed wall surface toward the inside of the choke groove substantially perpendicular to the closed wall surface, and the height dimension of the folded portion provided in the choke groove on the side of the door handle. is lower than the height dimension of the folded portion provided in the choke groove on the other side of the door.

It is an external appearance perspective view when the heating cooker of this embodiment is seen from the front side. FIG. 2 is a cross-sectional view taken along the line AA of FIG. 1; It is a perspective view of the door unit of the heating cooker of this embodiment. FIG. 3 is an enlarged view of the X section of FIG. 2; 7 is a graph showing an analysis example of leak shielding performance with respect to frequency by a conventional choke groove. 7 is a graph showing an analysis example of leakage shielding performance with respect to the angle of incidence of leaky waves incident on the choke groove. FIG. 5 is an explanatory diagram showing the positional relationship between the door base and the frame portion when the incident angle of leakage waves is changed; 7 is a graph showing an analysis example of leakage shielding performance with respect to dimensional change of the folded portion of the choke groove. FIG. 4 is a schematic diagram showing upper and lower choke structures based on analysis results; FIG. 4 is a schematic diagram showing choke structures on the left side and right side based on analysis results;

EMBODIMENT OF THE INVENTION Hereinafter, the form (henceforth "embodiment") for implementing this invention is demonstrated in detail, referring drawings suitably. Note that the direction shown in FIG. 1 is used as a reference for the description.

FIG. 1 is a perspective view of the heating cooker of this embodiment when viewed from the front side. FIG. 2 is a cross-sectional view taken along line AA of FIG. Note that FIG. 1 shows a state in which a cabinet (outer frame) covering the upper surface and left and right side surfaces of the main body is removed. Moreover, FIG. 2 shows a state in which the door is closed.
As shown in FIG. 1, a heating cooker 1 has a main body 3 provided with a heating chamber 2 inside a cabinet (outer frame) for storing an object to be heated (not shown). A door 4 that opens vertically is provided in front of the heating chamber 2 .

The door 4 is provided with an outer glass 7 (see FIG. 2) and an inner glass 9 (see FIG. 2) that can withstand high temperatures for checking the heating state of the food (not shown). Between the outer glass 7 and the inner glass 9, an iron punching metal 8 (see FIG. 2) having a plurality of holes is provided. Further, a handle 4 a for opening and closing the door 4 is provided on the outer upper portion of the door 4 . A synthetic resin cover 17 is provided inside the door 4 to cover the choke structure 20 (see FIG. 3) provided along the outer periphery of the door 4 .

A microwave generator 5 is provided at the bottom of the main body 3 . The microwave generator 5 is composed of a magnetron for generating microwaves, a waveguide for sending microwaves to the heating chamber 2, and the like. A high frequency (microwave) is supplied from a microwave generator 5 to an object to be heated (not shown) housed in the heating chamber 2 to heat the object. The position where the microwave generator 5 is arranged is not limited to the bottom of the main body 3, and may be the top or the side.

A frame portion (heating chamber front plate) 16 made of a conductive plate is provided from the outer periphery of the heating chamber opening 15 toward the outer shell of the main body 3 . The frame portion 16 is formed in a rectangular frame shape. The frame portion 16 has an upper edge portion 16a and a lower edge portion 16b extending in the horizontal direction longer than the left edge portion 16c and the right edge portion 16d extending in the vertical direction. Further, the main body 3 is provided with a door switch 18 for detecting opening/closing of the door 4 .

As shown in FIG. 2, the door 4 is rotatably connected to the lower part of the main body 3. When the door 4 is fully closed, the outer surface of the door 4 faces forward. The inner surface of the door 4 is configured to face substantially upward (see FIG. 1). Further, the handle 4a is arranged so as to protrude forward when the door 4 is fully closed, and is arranged so as to protrude downward when the door 4 is fully opened (see FIG. 1).

FIG. 3 is a perspective view of the door unit of the heating cooker of this embodiment. 3 shows a state in which the cover 17 (see FIG. 1) covering the outer peripheral surface inside the door is removed.
As shown in FIG. 3, the door 4 has a structure in which a metal door base 4b is covered with a resin door frame 4c. The door base 4b forms the frame of the door 4, and is formed by cutting, punching, bending, drawing, or otherwise processing a plate material made of metal such as iron.

The door base 4b also includes a contact surface portion 4d that contacts the frame portion 16 (see FIG. 1), and a chalk structure portion 20 that extends vertically and horizontally from the contact surface portion 4d. Further, the door base 4b has a structure in which the contact surface portion 4d is in contact with the frame portion 16 of the main body 3. If the door base 4b and the frame portion 16 are in contact with each other without a gap, microwaves do not leak from the periphery of the door 4. . However, when the door base 4b and the frame portion 16 are heated to a high temperature by oven heating or the like, the flatness of the surface may change due to expansion of the metal. In this case, a slight gap is generated between the door base 4b and the frame portion 16, and microwaves may leak through the gap. If a gap occurs between the door base 4b and the frame portion 16, the choke structure 20 prevents microwave leakage from this gap. Further, the gap S is more likely to occur in the upper side portion 4p of the door 4 where the handle 4a is located on the opposite side of the pivot shaft g (see FIG. 2) than in the lower edge portion 4q.

The choke structure 20 is formed, for example, by bending a metal plate made of iron a plurality of times and forming a comb shape along the circumferential direction. Also, the choke structure 20 is arranged on the entire outer periphery of the door 4 on the back side. That is, the choke structure portion 20 is positioned at the upper side portion 4p, the lower side portion 4q, the left side portion 4r, and the right side portion 4s of the door 4. As shown in FIG. The handle 4a is positioned on the upper side portion 4p. Further, the door 4 is provided with a rotating shaft g (see FIG. 2) which serves as a fulcrum when the door 4 is opened and closed at the lower side portion 4q.

4 is an enlarged view of the X section in FIG. 2. FIG. Note that FIG. 4 shows a state in which the cover 17 that covers the outer peripheral surface inside the door is removed.
As shown in FIG. 4, when the door 4 is closed, the chalk structure 20 includes a bottom surface 21 (choke groove bottom surface) facing the frame portion 16 of the main body 3, and extending from both ends of the bottom surface 21 to the main body 3 (frame portion 16). side) and a choke groove 24 having an opening (choke groove opening) 23 facing the body 3 . The chalk groove 24 is formed in a concave shape in a vertical cross-sectional view so that the concave surface faces the frame portion 16 side so that the frame portion 16 and the opening 23 face each other. The choke grooves 24 are arranged periodically at regular intervals along the upper side 4p, the lower side 4q, the left side 4r, and the right side 4s.

The choke groove 24 has a closed wall surface 25 that is substantially parallel (parallel) to the bottom surface 21 and covers a part of the opening 23, and extends from the closed wall surface 25 toward the inside of the choke groove 24 and substantially perpendicular (perpendicular) to the closed wall surface 25. and an extending folded portion 26 . The blocking wall surface 25 has a length approximately half the distance between the one side surface 22 and the other side surface 22 . Details of the length (height) of the folded portion 26 will be described later.

In this way, the choke groove 24 is provided with the folded portion 26 to make the impedance in the vicinity of the opening 23 infinite, thereby securing leakage shielding performance. A gap S between the door 4 and the frame portion 16 forms a leakage wave path R (see a dashed arrow) from the heating chamber 2 (see FIG. 1) to the outer shell of the main body 3 . This leakage wave path R is composed of an overlapping portion 30 from the outer periphery of the heating chamber opening 15 (see FIG. 1) to the opening 23 and a section from the opening 23 to the folded portion 26 . The overlap margin 30 reduces the impedance of the entrance (opening 23) of the leakage wave path R on the heating chamber 2 (see FIG. 1) side by its section length, thereby suppressing microwave penetration into the leakage wave path R. is working to Note that the section length is the distance of the overlapping portion 30, and the longer the overlapping portion 30, the more the microwaves can be suppressed.

As described in the background art, in a heating device using microwaves, the amount of microwaves leaking to the outside does not cause unintended heating of objects or interference with radio wave communication when the door 4 is closed. (hereinafter referred to as the "door closed state") and when the door 4 is half-open (the door is barely open to start cooking) (hereinafter referred to as the "door half-open state") The law stipulates the power density of leaked radio waves.

When the door is closed, the leaked radio wave is attenuated by the overlapping portion 30, passes through the leaked wave path R and enters the choke groove 24 in the vertical direction, and is further attenuated by the choke structure 20. FIG. On the other hand, when the door is half-opened, a gap S is generated between the door 4 and the frame portion 16 formed of a conductive plate from the outer periphery of the heating chamber opening 15 (see FIG. 1) toward the outer shell of the main body, and the overlapping margin portion 30 is formed. It becomes smaller, and leakage radio wave performance deteriorates. Furthermore, since the ratio of oblique incidence to the choke groove 24 increases, the effect of suppressing leakage radio waves by the choke structure portion 20 is also reduced.

Next, an analysis example of the leakage shielding performance of the choke groove 24 will be described with reference to FIG. FIG. 5A is a graph showing an analysis example of leakage shielding performance with respect to frequency by a conventional choke groove. FIG. 5B is a graph showing an analysis example of leakage shielding performance with respect to the incident angle of leakage waves incident on the choke groove. FIG. 6 is an explanatory diagram showing the positional relationship between the door base and the frame portion when the incident angle of leaky waves is changed. In FIGS. 5A and 5B, the horizontal axis indicates frequency (GHz) and the vertical axis indicates shielding characteristics (dB).

As shown in the graph of FIG. 5A, the leakage wave shielding performance of the choke structure portion varies with frequency, and there is a frequency band in which the shielding effect can be obtained. In particular, the frequency range in which the shielding characteristic (attenuation rate) is less than -50 dB is called the bandwidth, and it is an index for judging that the wider the range, the better the leakage shielding performance.

As shown in the graph of FIG. 5B, there is a frequency band where the direction of the shielding characteristic (dB) on the vertical axis drops downward and the shielding effect is obtained. This frequency band varies greatly depending on the structure of the choke groove 24, the direction across the opening 23 of the choke groove 24, and the like. The leakage wave shielding characteristics when only the vertical component of the leakage wave enters the opening 23 is a curve drawn by a solid line with an incident angle of 90 degrees, and the frequency band where the leakage wave shielding performance is obtained and the operating frequency are almost Match. The case where the incident angle is 90° is the state shown in the upper diagram 200 of FIG. However, when a leakage wave with a shallower incident angle (see 100° shown in the middle diagram 300 of FIG. 6 or 110° shown in the lower diagram 400 of FIG. 6) including a cyclic component enters, As a result, the frequency band in which leakage shielding performance can be obtained deviates greatly from the operating frequency band. As a result, when the door is half-open, a large amount of leaked waves whose frequency band for which leak shielding performance is obtained is shifted is incident, which indicates that the choke structure 20 cannot sufficiently exhibit the effect of suppressing leaked radio waves. . Further, the frequency that deviates from the operating frequency band is larger when the incident angle is 110° shown in the lower diagram 400 of FIG. 6 than when the incident angle is 100° shown in the middle diagram 300 of FIG.

FIG. 7 is a graph showing an analysis example of leakage shielding performance with respect to dimensional change of the folded portion of the choke groove. FIG. 7 is a diagram showing the leakage shielding performance of the choke structure when the height dimension of the folded portion 26 provided in the choke groove 24 is +2 mm, +4 mm, and -2 mm with respect to the reference (0 mm). . The reference has a waveform with a peak near the frequency of 2.45 GHz (between 2.4 GHz and 2.5 GHz) when the door is closed.

As can be seen from the analysis results of FIG. 7, changing the height dimension of the folded portion 26 provided in the choke structure portion 20 (choke groove 24) shifts the frequency at which the shielding effect can be maximized. When the folded portion 26 is +2 mm from the reference, the waveform shifts in the direction in which the peak value of the frequency increases (to the right in FIG. 7), as indicated by the short dashed line. Also, when the folded portion 26 is +4 mm from the reference, the waveform shifts in the direction (to the right in FIG. 7) in which the frequency peak value is higher than when the frequency peak value is +2 mm, as indicated by the long dashed line. do. On the other hand, when the folded portion 26 is −2 mm from the reference, the waveform shifts in the direction in which the frequency peak value decreases (to the left in FIG. 7), as indicated by the dashed line.

From the above-described analysis results, the height of the folded portion 26 of the choke structure of the upper side portion 4p provided in the vicinity of the handle 4a of the door 4 where the ratio of leakage radio waves obliquely enters the choke groove 24 when the door is half-opened is high. By intentionally designing the dimensions to be smaller than the height dimensions of the choke-structured choke-structured folded parts 26 on the other sides (lower side 4q, left side 4r, right side 4s), leakage shielding performance when the door is half-opened is achieved. can be ensured.

FIG. 8A is a schematic diagram showing upper and lower choke structures based on analysis results. FIG. 8B is a schematic diagram showing left side and right side choke structures based on the analysis results.
As shown in FIG. 8A, the choke structure portion 20 positioned on the upper side portion 4p of the door 4 has a turn-back portion 26A (26) in the choke groove 24. As shown in FIG. In addition, the choke structure portion 20 located on the lower side portion 4q has a folded portion 26B (26) in the choke groove 24. As shown in FIG. Further, the height dimension H1 of the folded portion 26A is formed lower (shorter) than the height dimension H2 of the folded portion 26B.

As shown in FIG. 8B, the choke structure portion 20 located on the left side portion 4r of the door 4 has a turn-back portion 26C (26) in the choke groove 24. As shown in FIG. Also, the choke structure portion 20 positioned on the right side portion 4s has a choke groove 24 with a folded portion 26D (26). Moreover, the height dimension H2 of the folded portions 26C and 26D is the same as the height dimension H2 of the folded portion 26B in FIG. 8A.

Thus, the height dimension H1 of the folded portion 26A at the position (side) where the handle 4a is provided is the height of the folded portions 26B, 26C, and 26D at the position (side) where the handle 4a is not provided. Lower than dimension H2. As a result, the choke structure 20 having the folded portion 26A when the door is closed has the characteristics indicated by minus 2 mm in FIG. 2.4 to 2.5 GHz). Therefore, it is possible to suppress the leakage of microwaves when the door is in a half-open state. In this way, by suppressing the leakage of microwaves when the door is half-opened, separate parts such as electromagnetic wave absorption sheets provided at locations where electromagnetic waves leak (for example, the upper side portion) become unnecessary.

As described above, the heating cooker 1 of the present embodiment includes the microwave generator 5 for high-frequency heating of the object to be heated, the main body 3 including the heating chamber 2 in which the object to be heated is stored, and the heating chamber 2 and an openable and closable door 4 provided in front of. The door 4 has a choke structure 20 formed by bending a metal plate multiple times on the outer periphery of the door 4 . The choke structure 20 has a bottom surface 21 facing the main body 3, side surfaces 22, 22 extending from both ends of the bottom surface 21 toward the main body 3, and a choke groove 24 having an opening 23 facing the main body 3. 24 are arranged along the perimeter of the door 4 . The choke groove 24 includes a closed wall surface 25 that is substantially parallel to the bottom surface 21 and partially covers the opening 23, a folded portion 26 that extends from the closed wall surface 25 toward the inside of the choke groove 24 and is substantially perpendicular to the closed wall surface 25, have The height dimension H1 of the folded portion 26A provided in the choke groove 24 on the side (upper side 4p) of the door 4 where the handle 4a is located is set to the other sides of the door 4 (lower side 4q, left side 4r, right side 4s) ) is lower than the height dimension H2 of the folded portions 26B, 26C, and 26D provided in the choke groove 24 of ). In other words, the height dimension H1 of the folded portion 26A provided in the choke groove 24 on the upper side portion 4p on the side opposite to the lower side portion 4q where the rotation axis g of the door 4 is located is , left side portion 4r, right side portion 4s) of the choke groove 24). According to this, the heating cooker 1 with high microwave leakage performance can be provided.

In addition, the present invention is not limited to the above-described embodiment, and includes various modifications. For example, in the present embodiment, the vertically opening door 4 having the handle 4a on the upper side 4p has been described as an example, but it can be applied to a horizontally opening door having the handle on the left side 4r or the right side 4s. good too. In the case of a door having a handle on the right side 4s, the turning shaft is on the left side 4r. is lower than the height dimension of the folded portion 26 provided in the choke groove 24 on the other sides (upper side 4p, lower side 4q, left side 4r). Even with such a configuration, it is possible to provide the cooking device 1 with high microwave leakage performance.

Also, the gap between the door 4 and the main body 3 increases from one side where the rotary shaft g is located toward the other side. Therefore, the height dimension of the folded portions 26C and 26D provided in the choke groove 24 of the left side portion 4r and the right side portion 4s of the door 4 which are perpendicular to the lower side portion 4q where the rotation axis g is located is Gradually lower from one side to the other. That is, the height dimension of the turn-up portions 26C and 26D of the choke groove 24 located on the side with the rotation axis g is maximized, and the turn-up portions 26C and 26D of the choke groove 24 located on the side opposite to the rotation axis g are increased. The height dimension of is the shortest. According to this, the leakage of microwaves when the door is half-opened can be suppressed more effectively than when the height dimensions of the folded portions 26C and 26D are all the same.

1 heating cooker 2 heating chamber 3 main body 4 door 4a handle 4p upper side (side with handle)
4q lower side (other side)
4r left side (other side)
4s right side (other side)
5 Microwave generator (heating source)
20 Chalk structure 21 Bottom surface 22 Side surface 23 Opening 24 Choke groove 25 Blocking wall surface 26, 26A, 26B, 26C, 26D Folding part g Rotation axis H1 height dimension of folded part)
H2 height dimension (height dimension of the folded part provided in the choke groove on the other side of the door)
R Leakage path S Clearance

Claims (3)

a heating source for high-frequency heating of an object to be heated;
a main body having a heating chamber in which the object to be heated is stored;
A door that can be opened and closed provided in front of the heating chamber,
The door has a choke structure formed by bending a metal plate multiple times on the outer circumference of the door,
The choke structure has a bottom surface facing the main body, side surfaces extending from both ends of the bottom surface toward the main body, and a choke groove having an opening facing the main body, and the choke groove extends along the outer periphery of the door. placed along the
The choke groove has a closed wall surface that is substantially parallel to the bottom surface and covers a part of the opening, and a folded portion extending from the closed wall surface toward the inside of the choke groove and substantially perpendicular to the closed wall surface. ,
The height dimension of the folded portion provided in the chalk groove on the side of the door handle is made lower than the height dimension of the folded portion provided in the chalk groove on the other side of the door. Heating cooker. a heating source for high-frequency heating of an object to be heated;
a main body having a heating chamber in which the object to be heated is stored;
A door that can be opened and closed provided in front of the heating chamber,
The door has a choke structure formed by bending a metal plate multiple times on the outer circumference of the door,
The choke structure has a bottom surface facing the main body, side surfaces extending from both ends of the bottom surface toward the main body, and a choke groove having an opening facing the main body, and the choke groove extends along the outer circumference of the door. placed along the
The choke groove has a closed wall surface that is substantially parallel to the bottom surface and covers a part of the opening, and a folded portion extending from the closed wall surface toward the inside of the choke groove and substantially perpendicular to the closed wall surface. ,
The height dimension of the folded portion provided in the choke groove on the side opposite to the side on which the rotation axis of the door is located is the height of the folded portion provided in the choke groove on the other side of the door. A heating cooker characterized by being lower than the height dimension. In the heating cooker according to claim 2,
The height dimension of the folded portion provided in the choke groove on the side perpendicular to the rotation axis of the door is gradually lowered from one side of the rotation axis toward the other side. heating cooker.

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