KR20170099350A - Magnetron cooling fin and magnetron having the same - Google Patents

Abstract

The present invention provides a magnetron cooling fin unit. More specifically, the plate-shaped magnetron cooling fin has one or multiple corrugated areas on the body to enhance the cooling efficiency. According to a part of the disclosed embodiments of the present invention, processed corrugated areas are formed to widen the air contact area around through-holes having positive electrode parts of a magnetron unit passing therethrough, thereby enhancing the cooling efficiency.

Description

TECHNICAL FIELD [0001] The present invention relates to a magnetron cooling pin and a magnetron having the same,

The following embodiments relate to a magnetron cooling fin and a magnetron having the same. And more particularly, to a structure of a magnetron cooling fin and a magnetron having the magnetron cooling pin for cooling a heated magnetron by machining one or a plurality of corrugated regions around a through hole.

The magnetron generates a strong high frequency by controlling the flow of electrons by applying a magnetic field, and is used in a high frequency heating apparatus such as a microwave oven.

Heat generation due to generation of heat at a high temperature and generation of repetitive high frequencies and generation of thermal fatigue phenomenon may cause reduction in lifetime and deterioration of performance of the magnetron. For cooling the heated magnetron, a plurality of cooling fins in contact with the anode portion of the magnetron and forced cooling through the cooling fan in the electric room may be used.

It is necessary to effectively cool the anode portion which is the highest temperature in the magnetron and to improve the cooling efficiency of the cooling pin which is brought into contact with the anode portion to receive heat.

A magnetron cooling fin according to an embodiment of the present invention is a magnetron cooling fin having a through hole passing through an anode portion of a magnetron in a central region, a bending piece bent in a first direction at an edge of the through hole, And a plurality of fins extending from both sides of the main body, wherein a distance from a center point of the through hole to a center point of the elliptical region is larger than a center of the through hole Lt; / RTI >

According to an aspect of the present invention, a distance from a central point of the through hole to a center point of the elliptical area may be greater than a vertical length of the main body.

According to an aspect of the present invention, a distance from a center point of the through hole to a center point of the elliptical area may be smaller than a lateral length of the main body.

According to an aspect of the present invention, the height of the bending piece may be greater than the depth of the concave region.

According to one aspect of the present invention, the setting angle may be 25 ° or more and 65 ° or less.

According to an aspect of the present invention, the transverse length of the elliptical region may be 1.4 times or more of the longitudinal length, and 2.8 times or less.

According to an aspect of the present invention, the major axis of the elliptical region may be inclined with respect to the lateral direction of the main body.

According to an aspect of the present invention, one of the setting distance and the setting angle from the center point of the through hole to the center point of the elliptical area corresponding to the number of the elliptical areas may be changed.

According to another aspect of the present invention, there is provided a magnetron cooling fin comprising: a main body connected to a through hole passing through an anode part of a magnetron, a bent piece bent at an edge of the through hole, and a first crease area formed from a lower end of the bent piece; And a plurality of fins extending from both sides of the body, the diameter of the through-holes being smaller than the outer diameter of the first pleat region.

According to an aspect of the present invention, the height of the bending piece may be greater than the height of the first corrugated area.

According to one aspect of the present invention, the first corrugation zone has a step, and the diameter of the first corrugation zone may be larger than the diameter of the step.

According to an aspect of the present invention, the shape of the first corrugated region may be one of a circular shape and an elliptical shape.

According to an aspect of the present invention, the apparatus may further include a plurality of second corrugated regions located in corner areas of the main body.

According to one aspect of the present invention, the plurality of second pleat regions may guide the flow of air.

According to an aspect of the present invention, the shape of the second corrugated area may be a truncated pyramid shape.

According to an aspect of the present invention, the height of the second corrugated area may be smaller than the height of the bending piece.

According to another aspect of the present invention, there is provided a magnetron cooling fin having a through hole passing through an anode portion of a magnetron in a central region, a bent piece bent at an edge of the through hole, And a plurality of pins extending from both sides of the body, wherein the setting interval is smaller than one of a transverse length and a longitudinal length of the first crease area.

According to an aspect of the present invention, the setting interval may be smaller than one of a width and a length of the second corrugated area.

There can be provided a magnetron cooling fin having a first corrugated area for increasing the heat transfer area from the perimeter of the through hole to the outside air and for making the flow turbulent to cool the magnetron.

A magnetron cooling fin having one or a plurality of second corrugated regions for cooling the magnetron by delaying flow separation and turbulating the flow may be provided.

A magnetron cooling fin that cools the magnetron through the first corrugation zone and the second corrugation zone may be provided.

A magnetron cooling fin having a concave elliptical region for cooling the magnetron by increasing the heat transfer area from the perimeter of the through hole to the outside air and making the flow turbulent can be provided.

There can be provided a magnetron cooling fin having a convex elliptical region for increasing the heat transfer area from the perimeter of the through hole to the outside air and making the flow turbulent to cool the magnetron.

Without being limited thereto, according to various embodiments of the present invention, a magnetron cooling fin capable of cooling a heated magnetron through one or more corrugated regions may be provided.

1 is a schematic perspective view showing a high-frequency heating apparatus including a magnetron according to an embodiment of the present invention.
2 is a schematic cross-sectional view showing a magnetron according to an embodiment of the present invention.
3 is a schematic perspective view and a cross-sectional view illustrating a cooling fin according to an embodiment of the present invention.
4 is a detailed plan view and a cross-sectional view illustrating a cooling fin according to an embodiment of the present invention.
5 is a schematic view showing the flow velocity distribution and the temperature distribution around the cooling fin according to the embodiment of the present invention.
6 is a schematic perspective view and a cross-sectional view illustrating a cooling fin according to another embodiment of the present invention.
7 is a schematic perspective view and a cross-sectional view illustrating a cooling fin according to another embodiment of the present invention.
8 is a schematic perspective view and a cross-sectional view illustrating a cooling fin according to another embodiment of the present invention.
9 is a schematic perspective view and a cross-sectional view illustrating a cooling fin according to another embodiment of the present invention.
10 is a schematic perspective view and a cross-sectional view illustrating a cooling fin according to another embodiment of the present invention.
11 is a schematic perspective view and a cross-sectional view illustrating a cooling fin according to another embodiment of the present invention.
12 is a detailed plan view showing a cooling fin according to another embodiment of the present invention.
13 is a schematic perspective view and a cross-sectional view illustrating a cooling fin according to another embodiment of the present invention.
14 is a schematic view showing a flow velocity distribution around a cooling fin according to an embodiment of the present invention.

Hereinafter, exemplary embodiments according to the present invention will be described in detail with reference to the contents described in the accompanying drawings. Like reference numbers or designations in the various drawings indicate components or components that perform substantially the same function.

Terms including ordinals such as "first", "second", etc. may be used to describe various elements, but the elements are not limited by terms. Terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component. The term " and / or " includes any combination of a plurality of related items or any of a plurality of related items.

The terminology used herein is for the purpose of describing the embodiments only and is not intended to limit and / or to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, terms such as "comprises" or "having" are intended to specify that there are stated features, numbers, steps, operations, elements, parts or combinations thereof, and that one or more other features But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Like reference numerals in the drawings denote like elements which perform substantially the same function

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The forward direction used in the following description may refer to a direction in which the front surface 120 of the door of the microwave oven 1000 shown in FIG. 1 (refer to FIG. And the front surface may refer to a surface corresponding to the front-facing door 120. In addition, the rear may mean a direction opposite to the front of the microwave oven 1000 (e.g., the-y axis direction).

1 is a schematic perspective view showing a high-frequency heating apparatus including a magnetron according to an embodiment of the present invention.

1, a microwave oven (a body including a case and a door, hereinafter collectively referred to as a microwave oven) 1000, which is one of high-frequency heating apparatuses, includes a case 100, a cooking chamber 110, An electric element chamber 111, a door 120, an operation panel 130, a fan 140, a magnetron 200, and electrical elements 300 to 330. The magnetron 200 of the present invention can be employed in a high-frequency heating apparatus.

The case 100 forming the outer appearance of the high frequency heating device is divided into a cooking chamber 110 located inside the case 100 and an electric field chamber 111 located adjacent to the cooking chamber 110.

The cooking chamber 110, which is in the form of a polyhedron, may be configured so that the front surface (corresponding to the door 120, for example) is opened for the receipt of food to be cooked. The case 100 may include an opening corresponding to the cooking chamber 110 whose one side is open.

The electric field chamber 111 is distinguished from the outside, and one or a plurality of electric components for heating (or cooking) the food may be located.

The open front face of the cooking chamber 110 can be opened and closed by the door 120. The door 120 may be hinged to one side (e.g., the lower side or the side surface) of the case 100 so as to be rotatable. A handle 121 held by a user may be located outside the door 120.

On the front surface of the electric field chamber 111, an operation panel 130 for receiving user input for cooking food and displaying information (e.g., food name, operation time, etc.) corresponding to food cooking is provided. A fan 140 may be positioned to cool the various electrical components inside the electric room by sucking the outside air into the electric room 111. In addition, the fan 140 may discharge air to the outside in order to cool the inside of the electric field chamber 111 heated by various electrical products.

The electric field chamber 111 may be provided with a magnetron 200 for generating microwaves to be radiated to the cooking chamber 110. 2, a detailed description of the magnetron 200 will be given.

A driving module (for example, a high-voltage transformer 310, a high-voltage condenser 320, or a high-voltage diode 330) for operating the magnetron 200 may be disposed in the electric field chamber 111. For example, a high voltage transformer 310 receives commercial AC power (AC 110V or 220V) and outputs a voltage of about 2,000V. The voltage output from the high-voltage transformer 310 is maintained at about 4,000 V by the high-voltage capacitor 320 and the high-voltage diode 330.

The magnetron 200 can generate microwaves of 2.45 GHz using the input high voltage.

The high-voltage transformer 310 includes a core 311 made by stacking steel plates made of a material such as a silicon steel plate, permalloy, or ferrite, a primary coil 311 wound around the core 311, a primary coil 312, and a secondary coil 313. The commercial power is input at the input 314 of the primary coil 312. And a high voltage power is output through the output terminal 315 of the secondary coil 313.

The operation of the microwave oven 1000 is as follows.

The user can place the food to be cooked in the cooking chamber 110 and operate the microwave oven 1000 through the operation panel 130. [ The high voltage transformer 310 to which the commercial power is applied boosts the commercial power to about 2,000 V. The boosted power is delivered to the magnetron 200 at a high voltage of about 4,000 V by a high-voltage capacitor 320 and a high-voltage diode 330.

The hot electrons are emitted from the filament 241 heated by the power source applied to the filament 241 of the magnetron 200 through the center lead 244 and the side lead 245 of the cathode portion 240.

A group of electrons is formed by the thermoelectrons emitted in the working space 231 between the filament 241 and the plurality of vanes 233. [

A strong electric field is formed by the driving voltage applied to the anode part 230 in the action space 231. The magnetic field generated by the first magnet 221 and the second magnet 222 acts in the vertical direction through the first magnetic pole piece 234 and the second magnetic pole piece 235. [

Electrons emitted from the filament 241 to the action space 231 travel in the direction of the vane 233 in a spiral rotational motion under the influence of strong electric fields and magnetic fields. A high frequency of a resonance frequency corresponding to the rotation speed of the electron group is derived from the vane 233. [

The high frequencies derived from the plurality of vanes 233 are transmitted to the outside of the yoke 210 through the antenna lead 271 and are guided to the waveguide (not shown) through the antenna cap 274.

The magnetron 200 radiates microwaves in the 2.45 GHz band generated by the high frequency generating unit 220 to the cooking chamber 110 and cooks the food in the cooking chamber 110.

The cooking microwave oven 1000 can cool the internal temperature of the electric field chamber 111 by operating the fan 140 for cooling the high temperature magnetron 200 or the high temperature high pressure transformer 310. The magnetron 200 can be cooled through the plurality of cooling fins 280. [

2 is a schematic cross-sectional view showing a magnetron according to an embodiment of the present invention.

Referring to FIG. 2, the magnetron 200 includes a yoke 210 having a receiving space therein and a high-frequency generator 220 disposed inside the yoke 210 and generating a high frequency.

The high frequency generating unit 220 includes a first magnet 221 as an annular permanent magnet provided in an opening of a yoke 210, a second magnet 221 as an annular permanent magnet opposed to the first magnet 221, An anode unit 230 disposed between the first magnet 221 and the second magnet 222 and a cathode unit 240 disposed inside the anode unit 230 do.

The first yoke 211, the second yoke 212, the first magnet 221 and the second magnet 222 surround the anode portion 230 and the cathode portion 240 in the high frequency generating portion 220, A magnetic circuit can be formed.

The magnetron 200 includes an input unit 250 for applying power to the high frequency generating unit 220, a filter unit 260 connected to the input unit 250, a high frequency generating unit 220 for converting the high frequency generated from the high frequency generating unit 220 into a yoke 210 to the outside.

An opening 213 for passing the output portion 270 of the high frequency generating portion 220 is formed in the center region of the first yoke 211. A coupling hole 214 for connecting the input unit 250 of the high frequency generating unit 220 is formed in the center region of the second yoke 212.

In the high frequency generating part 220, a gasket 215 for preventing external leakage of electromagnetic waves generated in the yoke 210 may be located.

The first yoke 211 is connected to a waveguide (not shown) through a coupling protrusion (not shown) inserted into a coupling groove (not shown) of a waveguide tube (not shown) ). ≪ / RTI > The output unit 270 may be inserted into a guide groove (not shown) of the waveguide so as to radiate a high frequency wave into the waveguide.

A first sealing member 223 and a second sealing member 224 for sealing the inside of the anode portion 230 may be located in the high frequency generating portion 220.

The flange extending outwardly from the first sealing member 223 and the second sealing member 224 may be welded to the upper and lower portions of the anode portion 230.

A plurality of stacked cooling fins 280 (for example, three to six) for cooling the heated anode portion 230 may be positioned on the outer periphery of the anode portion 230. The plurality of cooling fins 280 can be brought into contact with the outer circumference of the high temperature anode part 230 heated by the high frequency to cool the anode part 230 through conduction heat transfer. The anode portion 230 may be cooled through natural convection heat transfer due to the temperature difference between the plurality of cooling fins 280 and the electric field chamber 111 and forced convection heat transfer through the fan 140.

The anode portion 230 includes an anode cylinder 232 surrounded by a plurality of cooling fins 280 and forming a working space 231 in the central region, a center 200a of the working space 231, A magnetic field generated by a plurality of vane 233, first magnet 221 and second magnet 222 arranged radially with respect to the first magnet 221 acting as a reference And a first pole piece 234 and a second pole piece 235 which are respectively installed at the upper and lower portions of the anode cylinder 232 so as to be concentrated in the space 231.

The outer end of the plate-like (for example, polygonal) vane 233 may be fixed to the inner surface of the anode cylinder 232 and the inner end may be fixed by a plurality of strap rings 236 and 237. The strap rings 236 and 237 may have different sizes (e.g., diameters). Each stimulating piece 234, 235 may be in the form of a funnel.

The tip end 233a of the vane 233 which is not fixed to the inner surface of the anode cylinder 232 is disposed in the same inscribed circle extending along the center 200a.

The cathode part 240 separated from each vane 233 is composed of a coiled filament 241 disposed at the center of the inscribed circle of the vane 233 and installed in the central region of the action space 231, A first end hat 242, a second end hat 243, and a filament 241, which are coupled to the upper and lower ends of the first end hat 242, respectively, A center lead 244 having a lower end extending downwardly through the second endhats 243 and a side lead 245 coupled to the periphery of the second endhats 243. The center lead 244 extends through the second endhats 243,

Both ends of the filament 241 are mounted to the first end hat 242 and the second end hat 243, respectively. The first endhats 242 and the second endhats 243 can suppress electron escape from the working space 231. [

The center lead 244 and the side lid 245 connected to an external power source can apply power to the filament 241. The lower portions of the center lead 244 and the side lid 245 are surrounded and fixed by the first insulator 246.

When power is applied to the center lead 244 and the side lead 245, the filament 241 emits thermos-electrons in the direction of the vane 233.

The center lead 244 and the side lead 245 protrude out of the yoke 210 through a relay plate 247 and are connected to the input terminal 251.

The input unit 250 includes a pair of input terminals 251 connected to the center lead 244 and the side lead 245, respectively. The input unit 250 may further include a plug (not shown) connected to the pair of input terminals 251.

The filter unit 260 connected to the input unit 250 includes a plurality of filters 261 and 262 that are choke coils. The filter unit 260 includes a filter box 260a coupled to the second yoke 212 to cover the connection hole 214 to prevent leakage of electromagnetic waves generated from the anode cylinder 232 through the connection hole 214, . A high-pressure condenser (not shown) is formed through the filter box 260a.

The output portion 270 located above the first magnetic pole piece 234 emits a microwave. One end of the output unit 270 is connected to one of the plurality of vanes 233 at one end to radiate a high frequency to the outside of the yoke 210. The other end of the output unit 270 is connected to the outside through the opening 213 And includes an extended antenna lead 271.

The output unit 270 includes a second insulator 272 bonded to the first sealing member 223 and penetrating the antenna lead 271 therein, a second insulator 272 coupled to the second insulator 272, and an antenna lead 271 A vent tube 273 penetrating through the exhaust pipe 273, and an antenna cab 274 covering the exhaust pipe 273. The antenna lead 271 extends through the first magnetic pole piece 234 and extends in the output portion 270 and its tip is fixed to the exhaust pipe 273. [ The second insulator 272 is bonded to the first sealing member 232 and to the opposite side of the first magnetic pole piece 234 connected to the first sealing member 232.

The second insulator 272 is coupled to the opening of the yoke at one side and the exhaust pipe 273 is bonded to the opposite side of the second insulator.

3 is a schematic perspective view and a cross-sectional view illustrating a cooling fin according to an embodiment of the present invention.

4 is a detailed plan view and a cross-sectional view illustrating a cooling fin according to an embodiment of the present invention.

3 and 4, the cooling fin 280 which is in contact with the outer periphery of the anode part 230 and cools the heated anode part 230 is plate-shaped. The cooling fin 280 is divided into a body 281 of a central region and a plurality of fins 282 (for example, 282a to 282f) of a multi-stage formed by bending both sides of the body 281.

The material of the cooling fin 280 may include aluminum or an aluminum alloy. For example, A1050, A1406, A1100, A1199, A2014, A2024 or A2219. The material of the cooling fin 280 may include not only aluminum but also a light metal (for example, magnesium or the like) capable of cooling the magnetron 200 or a light metal alloy.

The cooling fin 280 may be formed through a press process (e.g., including shearing, deep drawing, bending, forging, extrusion, or stamping). The cooling fin 280 may be formed by a plurality of pressing operations.

A through hole 280a is formed in the central region of the main body 281 so as to penetrate the anode portion 230. The body 281 has a first diameter (e.g., 39.8 mm, changeable, d ₃ ) and is bent along the edge of the aperture 280a in one direction (e.g., in the -z direction, A first corrugate 281a connecting the lower end of the bending piece 281a and the body 281 with a fin collar 281a and a second diameter (for example, 49.9 mm, changeable, d ₁ ) area 281b. The first corrugated area 281b may be referred to as a ring-shaped corrugated area. The first corrugated area 281b may be elliptical. In addition, the diameter of the first corrugated area 281b can be defined as a ring shape to an outer diameter.

The bent piece 281a can contact the outer periphery of the anode portion 230. [ The height of the bent pieces (281a) (h ₁₎ may be 3.6 ㎜. For example, the height (h ₁₎ of the bending piece (281a) is not less than 2.1 can be not more than 5.0 ㎜.

In the preferred embodiment, the contact area of the bent piece bent part (281a) of the cooling pin 280 that contacts the outer periphery of the anode unit 230, in response to the height (h ₁₎ the increase in (281a) can be increased have. Contact area of the bending piece (281a), the height (h ₁₎ increasing the cooling pin 280 in response to (e.g., the main body 281 relative to the floor of a) contacting the outer periphery of the anode 230 of the increased . Further, the larger the height (h ₁₎ of the bending piece (281a) can be increased cooling efficiency of cooling pin 280.

The first corrugated area 281b is connected from the first position where the lower edge of the bent piece 281a meets the first corrugated area 281b to the second position where the first corrugated area 281b meets the flat part of the main body 281 . The diameter d ₃ of the first position can be substantially similar (for example, less than ± 0.8 mm) to the transverse length (for example, the x-axis direction) of the main body 281. The diameter d ₁ of the second position may be equal to or smaller than the transverse length (e.g., x-axis direction) of the main body 281.

The height (h ₃₎ of the first pleated region (281b) may be lower than the height (h ₁₎ of the bending piece (281a). The height of the bent pieces (281a), the height (h ₁₎ with the first pleated region (281b) in height overall height of the main body 281, the sum of (h ₃₎ (h ₂₎ of the first crease area (281b) of (h ₃ ). For example, the total height h ₂ of the main body 281 may be 1.5 to 3.5 times the height h ₃ of the first wrinkle area 281b.

A first corrugated area 281b connected from the first position where the lower edge of the bent piece 281a meets the first corrugated area 281b to the second position where the first corrugated area 281b meets the flat part of the main body 281, Section may be an arc shape.

The surface area of the arc-shaped first corrugated area 281b is larger than the area of the imaginary first corrugated area 281b projected onto the flat plate of the body 281 (e.g., the area at the second position- The area at the location). For example, the surface area of the first corrugated area 281b may be 1.57 times the area of the first corrugated area 281b that is virtual at the first location. Also, the surface area of the first corrugated area 281b may be 1.1 to 2.0 times the area of the first corrugated area 281b which is virtual at the first position.

In an embodiment of the present invention, the cooling efficiency of the cooling fin 280 can be increased by the first corrugated area 281b that is machined to increase the area (or surface area) in contact with the air. In addition, the cooling efficiency of the cooling fin 280 can be increased corresponding to an increase in the area (or surface area) of the first corrugated area 281b in contact with air.

The first corrugated area 281b may have a step (e.g., a plurality of arc shapes or a step shape). A first crease area if (281b) is having a step, the diameter of the step (d ₂₎ is a value between the diameter (d ₁₎ having a diameter (d ₃₎ and a first pleated region (281b) of the bending piece (281a) (For example, 46.9 mm, changeable).

In an embodiment of the present invention, the first corrugation region 281b may facilitate turbulent flow.

The body 281 may further include a second corrugated area 281c in a plurality of corner areas (e.g., between the body 281 and the pin 282). The second corrugated area 281c may be referred to as a bank type corrugated area. A plurality of second pleat regions 281c may guide the flow stream. The velocity of the flow flow can be accelerated in the direction of the fan 140 by the plurality of second corrugated regions 281c.

The plurality of second corrugation areas 281c ₁ to 281c ₄ may be spaced apart from the first corrugated area 281b by a set interval (for example, ₁₁ to ₄₃ ). The setting interval (for example, ₁₁ to ₄₃ ) may be 1.5 mm or more and 8.0 mm or less. Set interval (e. G., L ₁₁ to l ₄₃₎ is greater than the height ((h ₃₎ of the first pleated region (281b) (or long). In addition, the set interval (e. G., L ₁₁ to l ₄₃ May be larger or smaller than the total height (h ₂ ) of the main body 281.

One facing the second pleated regions (281c ₁₎ and the set interval of one wrinkle area (281b) ₍₁₁ l to ₁₃ l) may be the same or different from each other. Each interval may be a position ( ₁₂ or ₁₃ ) or a concave position ( ₁₁ ) projecting from the one second wrinkle area 281c ₁ toward the first wrinkle area 281b. For example, l ₁₁ may be 3.7 mm, l ₁₂ may be 3.82 mm, and l ₁₃ may be 4.85 mm. The above-described setting interval is not limited to the one second wrinkle area 281c ₁ but the remaining second wrinkle area 281c ₂ 281c ₄ ) (for example, the positional difference of the second corrugated region), redundant description is omitted.

In the embodiment of the present invention, the outside air in contact with the heated anode portion 230 can be accelerated through the set interval and moved in the direction of the fan 140.

The plurality of second corrugated regions 281c ₁ to 281c ₄ can be machined by a compressive load in the edge area of the main body 281. The areas of the bottom surface (imaginary) and the projecting top surface may be different from each other in the second corrugation areas 281c ₁ to 281c ₄ . For example, the second pleat regions 281c ₁ through 281c ₄ may be similar to the frustum of pyramid shape. The corners connecting the vertexes of the bottom surface (virtual) of the second corrugated regions 281c ₁ to 281c ₄ may be curved or parabolic.

The transverse length x ₁ of one second corrugated area 281c ₄ may be 49% or less of the transverse length x of the body 281. For example, the transverse length x ₁ of one second corrugated area 281c ₄ may be 40% or less of the transverse length x of the body 281. The sum of the lateral lengths (x ₁ and x ₂ ) of the plurality of second wrinkle regions 281c ₄ and 281c ₂ may be 83% or less of the lateral length x of the main body 281. For example, the sum of the transverse lengths (x ₁ and x ₂ ) of the plurality of second corrugated regions 281c ₄ and 281c ₂ may be 78% or less of the transverse length x of the body 281.

The vertical length y ₁ of one second wrinkle area 281c ₄ may be 44% or less of the vertical length y of the main body 281. For example, the vertical length y ₁ of one second wrinkle area 281c ₄ may be 40% or less of the vertical length y of the main body 281. The sum of the transverse lengths (y ₁ and y ₂ ) of the plurality of second corrugated regions 281c ₄ and 281c ₃ may be equal to or less than 91% of the transverse length y of the main body 281. For example, the sum of the transverse lengths (y ₁ and y ₂ ) of the plurality of second corrugated regions 281c ₄ and 281c ₃ may be equal to or less than 87% of the transverse length y of the body 281.

The above-mentioned transverse length and length are not limited to one second ridged area 281c ₄ but the remaining second ridged area 281c ₁ To 281c ₃ ) (for example, the positional difference of the second corrugated region), redundant description is omitted.

Referring to FIG. 4A, the plurality of second pleat regions 281c ₁ to 281c ₄ may have a height h ₄ . The body 281 may be formed in a convex or concave shape by the height h ₄ of the second corrugated regions 281c ₁ to 281c ₄ . The plurality of second pleat regions 281c ₁ to 281c ₄ can be machined by a compressive load to have a height h ₄ . The height h ₄ of the second wrinkle regions 281c ₁ to 281c ₄ may be 0.9 or more and 4.0 mm or less.

A second pleated regions (281c ₁ to 281c ₄₎ has a height (h ₄₎ may be less than the height (h _1), or, the total height (h ₂₎ of the main body 281 of the bent section (281a). Further, the region may be two folds (281c ₁ to 281c ₄₎ the height (h ₄₎ is a second crease region (281c ₁ to 281c ₄₎ is smaller than at least one of the width and height of the.

In an embodiment of the present invention, the set intervals (for example, ₁₁ 1 to ₄₃ ) may be smaller than the width (x ₁ ) of the second corrugated area 281c ₁ , which is one of the plurality of second corrugated areas. The setting intervals (for example, ₁₁ to ₄₃ ) may be smaller than the width (x ₁ ) of the remaining second wrinkle areas 281c ₂ to 281c ₄ .

The setting interval (for example, ₁₁ to ₄₃ ) may be smaller than the vertical length (y1) of the second wrinkle area 281c1 which is one of the plurality of second wrinkle areas. In addition, at set intervals (e.g., ₁₁ l to ₄₃ l) it may be smaller than the height (y1) of the other second creases area (281c to 281c _{2, 4).}

In an embodiment of the present invention, the second pleat region 281c may facilitate turbulent flow. Further, the cooling efficiency of the cooling fin 280 can be improved by the second corrugated area 281c.

In another embodiment of the present invention, the body 281 of the cooling fin 280 may be embodied as a through hole 280a, a bent piece 281a and a second corrugated area 281c. The main body 281 of the cooling fin 280 has a lower end of the bent piece 281a bent in one direction (for example, in the -z direction, changeable during manufacture) along the edge of the through hole 280a, It can be implemented to be connected without the corrugated area 281b.

In another embodiment of the present invention, in the case of the body 281 of the cooling fin 280 implemented without the first corrugated area 281b, the second corrugated area 281c may be referred to as the first corrugated area.

In another embodiment of the present invention, the body 281 of the cooling fin 280 implemented without the first corrugated area 281b may be a cooling fin 280 that is an embodiment of the present invention (e.g., as shown in FIGS. 3 and 4) (For example, the presence or absence of the first corrugated area) of the main body 281 of the first housing part 280 except for the first corrugated area 281b. Therefore, redundant description may be omitted.

In another embodiment of the present invention, the body 281 of the cooling fin 280 implemented without the first corrugation area 281b may be cooled (as shown in FIGS. 6-8) (For example, the presence or absence of the first wrinkle region) of the main body 281 of the pin 280 except for the first wrinkle region 281b. Therefore, redundant description may be omitted.

The plurality of fins 282a through 282c, 282d through 282f are spaced apart (for example, between 0.5 and 2.5 mm, d _f ).

The spacing of the plurality of pins 282a and 282b may be the same as or different from the spacing of the plurality of pins 282b and 282c. The spacing of the plurality of pins 282d and 282e may be the same or different from the spacing of the plurality of pins 282e and 282f. The distance between the plurality of fins 282a to 282c located on one side may be the same as or different from the distance between the plurality of fins 282d to 282f located on the other side.

The distance d _f between the plurality of fins 282a to 282c and 282d to 282f can be determined in consideration of the cooling efficiency of the cooling fin or the difficulty of machining.

The plurality of pins 282a, 282c, 282d and 282f may be folded in an angle (alpha 1, for example, 52 to 58 degrees) set in one direction (e.g. Further, the plurality of pins 282b and 282d may be folded at an angle (? 2, for example, 43 to 49 degrees) set in one direction (for example, in the -z axis direction) The magnitude of the yoke 210 of the magnetron 200 and the cooling efficiency of the cooling fin 280 may be at least the same as the angle formed between the plurality of pins 282a to 282f described above and the z axis It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

The ends of the plurality of pins 282a to 282c extending from the main body 281 may be hooked.

5 is a schematic view showing the flow velocity distribution and the temperature distribution around the cooling fin according to the embodiment of the present invention.

5 is a flow distribution around the cooling fin 280 and a temperature distribution around the cooling fin 280. FIG.

5 (a), the heat of the heated anode part 230 is conduction heat transferred to the cooling fin 280 and is naturally cooled through ambient air or forcedly cooled by rotation of the fan 140 . Referring to the experimental data, the flow rate can be from 0 to 3.5 kPa.

The air around the anode part 230 passing through the through hole 280a of the cooling fin 280 may collide with the anode part 230 by the rotation of the fan 140 to form a jet flow. The flow of the flow may stop or turbulence may occur behind the anode portion 230 based on the flow direction of the flow. The above phenomenon is referred to as a flow separation phenomenon. An area (for example, a dead-zone) in which the flow of the flow is stopped by the flow separation phenomenon is formed.

If a dead zone occurs, the flow of the flow is disturbed, noise may be generated, or cooling efficiency of the cooling fin 280 may be lowered. The flow separation starting point is increased in the downstream direction of the flow direction, so that the cooling efficiency of the cooling fin 280 is increased.

In an embodiment of the present invention, the turbulence of the flow can be promoted by at least one of the first corrugation area 281b and the second corrugation area 281c of the cooling fin 280.

According to an embodiment of the present invention, the flow separation of the cooling fin 280 may occur at a point 26 ° relative to the center 200a of the anode portion 230 in the flow direction. For example, the starting point of the flow separation may occur at 22 to 30 degrees from the center 200a of the anode portion 230 in the flow direction.

The flow separation start point of the cooling fin 280 having the first corrugation area 281b is greater than the flow separation start point of the conventional cooling fin (not shown) without the first corrugation area 281b, As shown in FIG. The flow separation start point of the cooling fin 280 having the second corrugated area 281c may occur in the downstream direction of the flow direction than the flow separation start point of the conventional cooling fin (not shown) without the second corrugated area 281c . The starting point of the flow separation of the cooling fins 280 through the combination of the first corrugated area 281b and the second corrugated area 281c is the same as that of the conventional one without the first corrugated area 281b and the second corrugated area 281c May occur in the downstream direction of the flow direction than the flow separation start point of the cooling fin (not shown).

5 (b), the heat of the heated anode part 230 is conduction heat transferred to the cooling fin 280 and is naturally cooled through ambient air or forcedly cooled by rotation of the fan 140 . Referring to the experimental data, the flow temperature between the anode portion 230 and the cooling fin 280 may be between 85 and 150 ° C.

The air around the anode portion 230 passing through the through hole 280a of the cooling fan 280 may collide with the anode portion 230 by the rotation of the fan 140 to form a jet flow. The temperature of the dead zone formed behind the anode part 230 with respect to the flow direction of the flow is higher than the temperature outside the dead zone.

The flow separation starting point increases in the downstream direction of the flow direction to increase the cooling efficiency of the cooling fin 280 (for example, the temperature is low).

The temperature of the cooling fin 230 heated by the flow separation of the cooling fin 280 generated at the point 26 ° relative to the center 200a of the anode portion 230 in the flow direction is .

The flow separation start point of the cooling fin 280 having the first corrugated area 281b is greater than the flow separation start point of the conventional cooling fin (not shown) without the first corrugated area 281b in the flow direction The cooling efficiency of the cooling fin 280 can be increased.

The flow separation start point of the cooling fin 280 having the second corrugated area 281c is generated in the downstream direction of the flow direction than the flow separation start point of the conventional cooling fin (not shown) without the second corrugated area 281c, The cooling efficiency of the pin 280 can be increased. The flow separation start point of the cooling fins 280 through the combination of the first corrugated area 281b and the second corrugated area 281c is not limited to the existing one without the first corrugated area 281b and the second corrugated area 281c Can be generated in the downstream direction of the flow direction than the flow separation start point of the cooling fin (not shown), so that the cooling efficiency of the cooling fin 280 can be increased.

In the embodiment of the present invention, the cooling efficiency of the second corrugated area 281c may be better than that of the first corrugated area 281b.

The cooling fins 280 stacked on the magnetron 200 due to the increase in the cooling efficiency of the cooling fins 280 by at least one of the first corrugated area 281b and the second corrugated area 281c in the embodiment of the present invention, Can be reduced.

The number (for example, five) of the cooling fins 280 having the first corrugated area 281b is equal to the number of the conventional cooling fins (not shown) having no first corrugated area 281b ). The number (for example, five) of the cooling fins 280 having the second corrugated area 281c is equal to the number of the conventional cooling fins (not shown) having no second corrugated area 281c ). The number (for example, 4 to 5) of the cooling fins 280 through the combination of the first corrugated area 281b and the second corrugated area 281c is set to be larger than the number of the first corrugated area 281b and the second May be less than the number of conventional cooling fins (not shown) (e.g., six) without corrugation area 281c.

The cooling fins 280 stacked on the magnetron 200 due to the increase in the cooling efficiency of the cooling fins 280 by at least one of the first corrugated area 281b and the second corrugated area 281c in the embodiment of the present invention, Can be reduced.

The thickness (e.g., 0.4 mm) of the cooling fin 280 having the first corrugation area 281b is less than the thickness of the conventional cooling fin (not shown) having no first corrugation area 281b Mm. ≪ / RTI > The thickness (e.g., 0.4 mm) of the cooling fin 280 having the second corrugated area 281c is less than the thickness of the conventional cooling fin (not shown) having no second corrugated area 281c Mm. ≪ / RTI > The thickness of the cooling fins 280 (for example, 0.25 to 0.4 mm) through the combination of the first corrugated area 281b and the second corrugated area 281c is larger than the thickness of the first corrugated area 281b and the second (For example, 0.6 mm) of the conventional cooling fin (not shown) without the corrugated area 281c.

6 is a schematic perspective view and a cross-sectional view illustrating a cooling fin according to another embodiment of the present invention.

Referring to Fig. 6, the cooling fin 280-1 of Fig. 6 is substantially similar to the cooling fin 280 of Fig. 3 (e.g., the difference is the presence or absence of a dump 281d). For example, the cooling fin 280-1 of FIG. 6 may include a second pleat region 281c of a double structure having a protrusion 281d.

The components 280a, 281a, 281b and 282 of the cooling fin 280-1 of FIG. 6 may be the same as the components 280a, 281a, 281b and 282 of the cooling fin 280 of FIG.

The cooling fin 280-1 of FIG. 6 may be formed with a projection 281d on the upper surface of the second corrugated area 281c of the cooling fin 280 of FIG. May be formed each of a plurality of projections (281d ₁ 281d to ₄₎ to a plurality of second folds region (281c ₁ to 281c _4). For example, a plurality of projections 281d ₁ may be formed on the second corrugated area 281c ₁ . And can be equally applied to the remaining second wrinkle regions 281c ₂ to 281c ₄ .

The shape of the projection 281d may be similar to or different from the shape of the second corrugated area 281c. For example, the shape of the protrusion 281d may be similar to the shape of the reduced second corrugated area 281c.

Projection (281d) may be formed only in the second folds an area corresponding to the downstream region of the flow (e.g., 281c ₁ and 281c _3).

In another embodiment of the present invention, flow turbulence by flow separation can be promoted by the second corrugation area 281c with the protrusion 281d in the cooling fin 280-1. The size of the fluidized turbulence by the second corrugated area 281c having the protrusion 281d in FIG. 6 may be larger than the size of the fluidized turbulence by the second corrugated area 281d in FIG.

7 is a schematic perspective view and a cross-sectional view illustrating a cooling fin according to another embodiment of the present invention.

Referring to Fig. 7, the cooling fin 280-2 in Fig. 7 is substantially similar to the cooling fin 280 in Fig. 3 (for example, the difference is the presence or absence of the protrusion 281e). For example, the cooling fin 280-2 in FIG. 7 may include a second corrugated area 281c having a protrusion 281e.

The components 280a, 281a, 281b and 282 of the cooling fin 280-2 of FIG. 7 may be the same as the components 280a, 281a, 281b and 282 of the cooling fin 280 of FIG.

7 may be formed with a dump 281e on the second corrugated area 281c of the cooling fin 280 of FIG. It may be formed a protrusion (281e 281e ₁ to ₄₎ to a plurality of second folds area (281c1 to 281c4). For example, one protrusion 281e ₁ may be formed on the second corrugated area 281c1. And can be equally applied to the remaining second wrinkle regions 281c ₂ to 281c ₄ .

The shape of the protrusion 281e may be similar to or different from the shape of the second corrugated area 281c. For example, the shape of the protrusion 281e may be similar to the shape of the reduced second pleat region 281c.

Protrusion (281e) may be formed only in the second folds an area corresponding to the downstream region of the flow (e.g., 281c ₁ and 281c _3).

In another embodiment of the present invention, flow turbulence by flow separation can be promoted by the second corrugation area 281c with the protrusion 281e in the cooling fin 280-2. In FIG. 7, the magnitude of the flow turbulence by the second corrugated region 281c having the protrusion 281e may be larger than the magnitude of the flow turbulence by the second corrugated region 281c of FIG.

8 is a schematic perspective view and a cross-sectional view illustrating a cooling fin according to another embodiment of the present invention.

8, the cooling fin 280-3 of FIG. 8 is substantially similar to the cooling fin 280 of FIG. 3 (e.g., the difference is the shape of the second corrugated area). For example, the cooling fin 280-3 of FIG. 8 may include a second pleat region 281f shaped like a truncated pyramid. For example, the cooling fin 280-3 of FIG. 8 may include a second corrugated area 281f similar to the shape of a triangular pyramid with at least one straight edge connecting the vertices of a floor (virtual) .

The components 280a, 281a, 281b and 282 of the cooling fin 280-3 of FIG. 8 may be the same as the components 280a 281a, 281b and 282 of the cooling fin 280 of FIG.

The cooling fins 280-3 in Fig. 8 are similar to the second wrinkle area 281c, which is similar to a truncated pyramid shape in which the corners connecting the vertexes of the bottom surface (virtual) in the cooling fin 280 of Fig. 3 are curved or parabolic .

In another embodiment of the present invention, flow turbulence by flow separation can be promoted by the second corrugated area 281f, which is similar in shape to a truncated pyramid in the cooling fin 280-3. In FIG. 8, the magnitude of the flow turbulence by the second corrugated region 281f, which is similar to the truncated pyramid, may be greater than the magnitude of the flow turbulence by the second corrugated region 281c of FIG.

9 is a schematic perspective view and a cross-sectional view illustrating a cooling fin according to another embodiment of the present invention.

9, the cooling fin 280-4 of FIG. 9 is substantially similar to the cooling fin 280 of FIG. 3 (e.g., the difference is the surface area of the first corrugated area). For example, the cooling fins 280-4 of FIG. 9 may include a first corrugation area 281b ₁ having an increased surface area. The first corrugated area 281b ₁ having an increased surface area may be elliptical, unlike the circular through hole 280a. For example, the setting interval between the first corrugation area 281b ₁ and the second corrugation area 281c having increased surface area in the cooling fin 280-4 of FIG. 9 is the same as the first corrugation area 281b ) And the second corrugated area 281c may be narrower.

The increased surface area in the cooling fin 280-4 of Figure 9 allows the first corrugated area 281f to be further extended in the downstream direction of flow than the first corrugated area 281b of the cooling fin 280 of Figure 3 have. Due to the increased surface area, the first corrugated area 281f can be equally applied in the upstream direction of flow.

The components 280a, 281a and 282 of the cooling fin 280-4 of FIG. 9 may be the same as the components 280a, 281a and 282 of the cooling fin 280 of FIG.

In another embodiment of the present invention, the flow resistance in the first pleat region 281f may be reduced by the increased surface area at the cooling fin 280-4. The magnitude of the flow resistance due to the first corrugated area 281f may be smaller than the magnitude of the flow resistance due to the first corrugated area 281b of FIG. 3 due to the increased surface area in FIG.

10 is a schematic perspective view and a cross-sectional view illustrating a cooling fin according to another embodiment of the present invention.

10, the cooling fin 280-5 of FIG. 10 is substantially similar to the cooling fin 280 of FIG. 3 (e.g., the difference is the shape of the first corrugated area). For example, the cooling fins 280-5 of FIG. 10 may include a first corrugation area 281b ₃ having a disconnection interval 281b ₂ . For example, the setting interval between the first corrugation area 281b ₃ and the second corrugation area 281c having a disconnection interval in the cooling fin 280-5 of FIG. May be the same as the setting interval between the area 281b and the second corrugated area 281c. Disconnection interval (281b ₂₎ may be extended from the imaginary extension of the bending piece (281a) (e.g., + z axis direction).

The rigidity of the first corrugation area 281b ₃ having the cut-off section 281b ₂ in the cooling fin 280-5 of Fig. 10 can be increased. The rigidity of the first corrugation area 281b ₃ having the cut-off section 281b ₂ in the cooling fin 280-5 of FIG. 10 is stronger than the rigidity of the first corrugate area 281b of FIG. 3 .

The components 280a, 281a and 282 of the cooling fin 280-5 of Fig. 10 may be the same as the components 280a, 281a and 282 of the cooling fin 280 of Fig.

In another embodiment of the present invention, it can be strong resistance to structural change by the heat sink (280-5), the first crease area (281b ₃₎ having a cut off section (281b ₂₎ from.

11 is a schematic perspective view and a cross-sectional view illustrating a cooling fin according to another embodiment of the present invention.

12 is a detailed plan view showing a cooling fin according to another embodiment of the present invention.

11 and 12 and Figs. 3 and 4, the cooling fins 280-6 for cooling the heated anode part 230 in contact with the outer periphery of the anode part 230 are plate-shaped. The cooling fin 280-6 has a central region main body 281-1 and a plurality of fins 282-1 formed by bending both sides of the main body 281-1, for example, 282a- 282f-1).

The material of the cooling fin 280-6 shown in Fig. 11 may be substantially similar to the material of the cooling fin 280 shown in Fig. The processing method of the cooling fin 280-6 shown in Fig. 11 may be substantially similar to the processing of the cooling fin 280 shown in Fig.

A through hole 280a through the anode part 230 is formed in the central region of the body 281-1. The main body 281-1 has a first diameter (for example, 39.8 mm, changeable, d3-1), and is arranged in one direction along the edge of the through hole 280a 1) and the bent piece 281a-1 bent in the first direction (e.g., the -z-axis direction) and the second direction opposite to the first direction (Oval-shaped corrugate or elliptical groove region, 281g) whose cross section located in the plane portion of the body 281-1 concavely in the + z-axis direction have.

The direction of the bent piece 281a-1 and the concave direction of the elliptical region 281g may be opposite directions. Further, the elliptical region 281g may be seen to be convex in the viewing direction (for example, when the cooling fin is installed in the magnetron as shown in Fig. 2).

The elliptical region 281g can delay (or suppress) the occurrence of flow separation in the flow of accelerated air. The elliptical region 281g can improve the characteristics of the air flow behind the anode portion 230. [ In addition, the elliptical region 281g can provide constant cooling performance irrespective of the direction of the incoming air flow.

The body 281-1 has a first 1-1 wrinkle region (not shown) that is substantially similar (e.g., shorter than the second diameter d1) to the first wrinkle region 281b of the body 281 in Figure 3 (Not shown). The first 1-1 corrugation zone (having a diameter of 2-1) is substantially similar to the first corrugation zone 281b in FIG. 3, and thus redundant description is omitted.

The bent piece 281a-1 can contact the outer periphery of the anode portion 230. [ Since the height of the bent piece 281a-1 is substantially similar to the height h1 of the bent piece 281a in Fig. 3, the overlapping description is omitted.

In the embodiment of the present invention, the contact area of the bent portion 281a-1 of the cooling fin 280-6, which is in contact with the outer periphery of the anode portion 230, corresponding to the increase in the height of the bent portion 281a- . The contact area of the cooling fins 280-6 contacting the outer periphery of the anode portion 230 corresponding to the height increase of the bending piece 281a-1 (for example, based on the bottom of the main body 281-1) Can be increased. Also, as the height of the bent piece 281a-1 becomes larger, the cooling efficiency of the cooling fin 280-6 can be increased.

The width (for example, long axis, l51) of the elliptical region (or concave portion, 281g) may be 5 mm. For example, the transverse length l51 may be 3.5 or more and 6.5 mm or less. The vertical length (for example, short axis, l 52) of the elliptical region (or concave portion, 281g) may be 2.5 mm. For example, the transverse length l51 may be 1.8 or more and 4.3 mm or less. In addition, the transverse length l51 of the elliptical region 281g may be 1.4 or more and 2.8 times or less than the longitudinal length 152.

The center point c1 of the elliptical region 281g with reference to the horizontal direction (e.g., the-y axis direction) (see Fig. 12 (b) (Or the second-1 diameter, d2-1) by an angle, [alpha]. The set distance may be, for example, 25 mm. The setting distance may be 24.5 or more and 25.8 mm or less.

The second-1 diameter d2-1 from the center point c0 of the through hole 280a to the center point c1 of the elliptical area 281g is substantially similar to the second diameter d1 in Fig. 3 For example, a difference of +/- 0.4 mm or less). The second-1 diameter d2-1 from the center point c0 of the through hole 280a to the center point c1 of the elliptical region 281g is set to be equal to the vertical length of the main body 281-1 Axis direction) (for example, a difference of +/- 0.8 mm or less).

The second-first diameter d2-1 may be 1.3 times the first diameter d3-1. For example, the second-1 diameter d2-1 may be 1.15 times or more and 1.39 times or less of the first-diameter diameter d3-1.

The setting angle between the center point c1 of the elliptical region 281g (see Fig. 12 (b)) and the center point c0 of the through hole 280a with respect to the horizontal direction (e.g., Angle, alpha) may be 56 [deg.]. For example, the setting angle alpha is not less than 25 DEG and not more than 65 DEG. In addition, the major axis ₅₁ of the elliptical region 281g is inclined at a set angle (or a second angle,?) In the lateral direction (e.g., the -y axis direction). The set angle [beta] may be 7 [deg.]. For example, the setting angle beta may be 5.5 deg. Or more and 9 deg. Or less.

The depth d5 of the concave elliptical region 281g may be 1 mm. For example, the depth d5 may be 0.5 or more and 1.9 mm or less.

The elliptical region 281g may be located within the fourth diameter d1-1. Some of the edges of the elliptical region 281g may be in contact with the fourth diameter d1-1. The fourth diameter d1-1 may be 1.5 times the diameter of the first diameter d3-1. For example, the fourth diameter d1-1 may be 1.4 times or more and 1.89 times or less of the first diameter d3-1.

The depth d5 of the elliptical region 281g may be smaller than the height of the bent piece 281a-1.

In the embodiment of the present invention, a plurality of elliptical regions 281g spaced from each other by a predetermined distance in the through-hole 280a guide the flow of air between the elliptical regions 281g1 and 281g3 to substantially increase the heat transfer area . The cooling efficiency of the cooling fins 280-6 can be increased by the plurality of elliptical regions 281g.

In an embodiment of the present invention, the plurality of elliptical regions 281g may facilitate turbulent flow.

In another embodiment of the present invention, the number of elliptical regions 281g may be even (e.g., 2, 6, 8, etc.) or odd (e.g., 1, 3, 5, 7). In another embodiment of the present invention, the position (e.g., set angle and set distance) of the elliptical region 281g may be changed corresponding to the number of elliptical regions 281g.

13 is a schematic perspective view and a cross-sectional view illustrating a cooling fin according to another embodiment of the present invention.

12, the main body 281-1 of the cooling fin 280-6 including the through hole 280a and the elliptical area 281g has a through hole 280a and a convex elliptical area (or convex groove area) 281h, . ≪ / RTI >

Since the convex elliptical area 281h in Fig. 13 is substantially similar to the concave elliptical area 281g in Fig. 12 (for example, difference in convex and concave shapes), redundant description is omitted. The cooling efficiency of the cooling fins 280-6 by the convex elliptical region 281h of Fig. 13 is substantially similar to the cooling efficiency of the cooling fins 280-6 by the concave elliptical region 281g of Fig. 12 .

14 is a schematic diagram showing the flow velocity distribution and the temperature distribution around the cooling fin according to the embodiment of the present invention.

14 (a), the heat of the heated anode part 230 is conduction heat transferred to the cooling fin 280 and is naturally cooled through ambient air or forcedly cooled by rotation of the fan 140 . Referring to the experimental data, the flow rate may be 0-3.0 ㎧.

If the flow of air on the basis of the flow direction of the flow meets the elliptical regions 281g2 and 281g4, a part of the air flow can be led to the dead zone. Depending on the dead zone delivery, the air flow bypassed may be reduced. The flow separation may be delayed by the elliptical region 281g. The flow separation start point can be moved in the downstream direction of the flow direction by the elliptical region 281g. The cooling efficiency of the cooling fins 280-6 can be increased as the fins move in the downstream direction of the flow separation start point by the elliptical region 281g.

In an embodiment of the present invention, turbulence of the flow can be promoted by the elliptical region 281g of the cooling fin 280-6.

In the embodiment of the present invention, the flow separation start point of the cooling fin 280 having the elliptical region 281g is located downstream of the flow separation start point of the existing cooling fin (not shown) without the elliptical region 281g Lt; / RTI >

14 (b), the heat of the heated anode part 230 is conduction heat transferred to the cooling fin 280, and is naturally cooled through ambient air or forcedly cooled by rotation of the fan 140 . Referring to the experimental data, the pressure between the anode part 230 and the cooling fin 280 may be between -7 Pa and 0 Pa.

The flow separation may be delayed by the elliptical region 281g. The occurrence of excessive pressure loss at the flow separation point can be prevented by the elliptical region 281g. An excessive pressure loss may not be generated behind the elliptical region 281g by the elliptical region 281g.

An excessive pressure loss that can be caused by the elliptical region 281g can be prevented, and the cooling efficiency of the cooling fin 280-6 can be increased. The elliptical region 281g prevents an excessive pressure loss that may occur behind the elliptical region 281g and the cooling efficiency of the cooling fin 280-6 can be increased.

In the embodiment of the present invention, the number of cooling fins 280-6 stacked on the magnetron 200 can be reduced due to the increase in the cooling efficiency of the cooling fin 280 by the elliptical region 281g.

The number (for example, five) of the cooling fins 280-6 having the elliptical region 281g is the number (for example, six) of the conventional cooling fins (not shown) without the elliptical region 281g, Lt; / RTI >

In the embodiment of the present invention, the thickness of the cooling fin 280-6 stacked on the magnetron 200 can be reduced due to the increase in the cooling efficiency of the cooling fin 280-6 by the elliptical region 281g.

The thickness (for example, 0.4 mm) of the cooling fin 280-6 having the elliptical region 281g is equal to the thickness (for example, 0.6 mm) of the conventional cooling fin (not shown) without the elliptical region 281g, It may be thinner.

The increase in the cooling efficiency of the cooling fin 280-6 having the elliptical region 281g in Figs. 14A and 14B is one example, and the cooling fin 280 (Fig. 14B) having the convex region 281h in Fig. -6). ≪ / RTI >

Although the present invention has been described in detail with reference to specific embodiments thereof and the like, it is to be understood that the present invention is not limited to the above-described embodiments It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Therefore, the spirit of the present invention should not be limited to the above-described embodiments, and all of the equivalents or equivalents of the claims, as well as the claims of the following claims, belong to the scope of the present invention.

1000: Microwave oven 100: Case
110: Cooking room 111: Electric room
140: fan 200: magnetron
230: anode part 240: cathode part
280: Cooling pin 280a: Through hole
281a: Bending piece 281b: First ruff area
281c: second wrinkle area 281g: ellipse area
281h: convex region 282: pin

Claims (20)

The magnetron having a through hole passing through an anode portion of the magnetron at a central region and being spaced apart at a predetermined angle with reference to a bending piece bent in a first direction at an edge of the through hole and a center point of the through hole, A body having a plurality of elliptical regions; And
And a plurality of pins extending from both sides of the body,
Wherein a distance from a center point of the through hole to a center point of the elliptical region is greater than a radius of the through hole, The method according to claim 1,
Wherein a distance from a center point of the through hole to a center point of the elliptical region is larger than a vertical length of the main body. The method according to claim 1,
Wherein a distance from a center point of the through hole to a center point of the elliptical region is smaller than a width of the main body. The method according to claim 1,
And the height of the bending piece is larger than the depth of the concave region. The method according to claim 1,
Wherein the set angle is greater than or equal to 25 degrees and less than or equal to 65 degrees. The method according to claim 1,
Wherein the width of the elliptical region is 1.4 times or more of the longitudinal length and 2.8 times or less of the longitudinal length. The method according to claim 1,
And the major axis of the elliptical region is inclined with respect to the lateral direction of the main body. The method according to claim 1,
Wherein one of the setting distance and the setting angle from the center point of the through hole to the center point of the elliptical area is changed corresponding to the number of the elliptical areas. A main body connected to a through hole passing through an anode part of the magnetron, a bending piece bent at an edge of the through hole, and a first wrinkle area formed from a lower end of the bending piece; And
And a plurality of pins extending from both sides of the body,
Wherein the diameter of the through hole is smaller than the outer diameter of the first corrugated area. 10. The method of claim 9,
And the height of the bending piece is larger than the height of the first corrugated area. 10. The method of claim 9,
Wherein the first corrugated zone has a step and the diameter of the first corrugated zone is larger than the diameter of the step. 10. The method of claim 9,
Wherein the first corrugated area is one of a circular shape and an elliptic shape. 10. The method of claim 9,
And a plurality of second corrugated regions located in corner areas of the body. 14. The method of claim 13,
Wherein the plurality of second corrugated areas guide the flow of air. 14. The method of claim 13,
And the shape of the second corrugated region is a truncated pyramid shape. 14. The method of claim 13,
And the height of the second corrugated area is smaller than the height of the bending piece. 14. The method of claim 13,
Wherein the first corrugated area and the second corrugated area are spaced apart from each other by a predetermined interval, and the predetermined interval is different depending on the first corrugated area and the second corrugated area facing each other. 14. The method of claim 13,
And a projection on the upper surface of the second corrugated area. A main body having a through hole passing through an anode part of the magnetron in a center area, a bending part bent at an edge of the through hole, and a plurality of first wrinkle areas spaced apart from the bending part at predetermined intervals and positioned in an edge area of the main body; And
And a plurality of pins extending from both sides of the body,
Wherein the setting interval is smaller than one of a width and a length of the first corrugation area. 20. The method of claim 19,
Wherein the setting interval is smaller than one of a width and a length of the second corrugated area.

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