CN1143730A - Axial flow fan for microwave oven - Google Patents

Abstract

An improved axial flow fan for a microwave oven is capable of more effectively cooling a magnetron and a high voltage transformer of the same and more effectively circulating air in the interior of the same, so that an improved microwave oven having a higher efficiency and a lower noise can be achieved, which includes five blades spaced-apart at a regular interval and formed at the outer circumferential surface of a cylindrical hub. The blades have a ratio ''fan hub diameter/fan outer diameter'' in the range of 0.28 0.35.

Description

The aerofoil fan of micro-wave oven

The present invention relates to micro-wave oven aerofoil fan (axial flow fan), it more specifically is an improved micro-wave oven aerofoil fan, it is magnetron and the high-tension transformer (bigh voltage transformer) in the cooled microwave stove more effectively, more effectively therefore the air-flow in the circulation microwave stove can improve the efficient of micro-wave oven and reduce noise.

Fig. 1 has shown conventional micro-wave oven, and it comprises a cooking cavity (cooking chamber) 2 in body of heater 1, is used to hold the food of being cooked.Rotating disk (turntable) 3 places the bottom of cooking cavity 2.Fire door 4 is hinged on the body of heater 1.

In addition, as shown in Figure 2, magnetron 5 and high-tension transformer 6 are positioned at body of heater 1 inside.

The side that conduit (duct) 7 is positioned at magnetron 5 is used for microwave guiding 2, one internal vent ports of cooking cavity (inner air discharging port) 8 that magnetron 5 produces are positioned at the one side of magnetron.

In addition, aerofoil fan 9 is positioned at the back of magnetron 5 and high-tension transformer 6, and links to each other with fan electromotor (fan motor) 10.

In addition, air inlet (air suction port) 12 opens the back side at micro-wave oven after aerofoil fan 9.

In addition, air inlet guider (suction guide) 11 is positioned at the front of aerofoil fan 9, being used for air- flow guiding magnetron 5 and 6, one outside exhaust outlets of high-tension transformer (external air discharging port) 13 that the commentaries on classics power of executing with aerofoil fan 9 produced is positioned on the precalculated position on the low surface of micro-wave oven.

Now in conjunction with the accompanying drawings, the operation to micro-wave oven that an aerofoil fan is housed describes.

When conventional micro-wave oven was switched on, the rotating disk 3 in the cooking cavity 2 began rotation, and magnetron 5 and high-tension transformer 6 are started working simultaneously, and magnetron 5 produces microwaves.

Microwave is directed to and places the food that will cook on the rotating disk 3, and rotating disk 3 rotates in cooking cavity.

At this moment, high-tension transformer will provide the high pressure of 4000V for magnetron 5.

So magnetron 5 and high-tension transformer 6 will produce a large amount of heat.In order to prevent that other parts are heated, and must reduce the temperature of magnetron 5 and high-tension transformer 6.

So aerofoil fan 9 is activated in order to the air in the external world is sent into cooking cavity by air inlet 12.

Inhaled air is used to cool off magnetron 5 and high-tension transformer 6 by air inlet guider 1 guiding magnetron 5 and high-tension transformer 6, and the smell of food is discharged.

Shown in Fig. 3 and 4, common aerofoil fan 9 comprises the blade that is positioned at four separation on column type wheel hub (hub) 21 peripheries.

An axle positioning port (axis fixing port) 23 is positioned at the middle part of wheel hub 21.

Aerofoil fan 9 is made by polythene material, and fan blade tip diameter (fan tip di-ameter) A is 108mm, and fan hub diameter (fan hub diameter) B is 30mm, and width C is 27.5mm.

In addition, (1eading edge) is 0 when leading edge, and trailing edge (trailing edge) is 1 o'clock, and maximum camber position (maximum camber position) is 0.5, and maximum camber position is divided equally by the cross section of (tip) 22c from wheel hub 2l to blade tip.

In addition, plunder angle (sweep angle) θ less than 10.

Among the figure, G represents the width of wheel hub 21, and H represents the length of wheel hub 21, and I represents the length of fan front portion, and J represents the length at fan rear portion.

In addition, Fig. 5 A shown 0 in the scope of 2Khz, during rotating speed 3020RPM, in " A " of Fig. 1 to the air flow condition that records.Fig. 5 B shown 0 in the scope of 2Khz, during rotating speed 3020RPM, in " B " of Fig. 1 to the air flow condition that records.Fig. 5 C shown 0 in the scope of 2Khz, during rotating speed 3020RPM, in " C " of Fig. 1 to the air flow condition that records.Fig. 5 D shown 0 in the scope of 2Khz, during rotating speed 3020RPM, in " D " of Fig. 1 to the air flow condition that records.Fig. 6 A shown 0 in the scope of 20Khz, during rotating speed 3020RPM, in " A " of Fig. 1 to the air flow condition that records.Fig. 6 B shown 0 in the scope of 20Khz, during rotating speed 3020RPM, in " B " of Fig. 1 to the air flow condition that records.Fig. 6 C shown 0 in the scope of 20Khz, during rotating speed 3020RPM, in " C " of Fig. 1 to the air flow condition that records.Fig. 6 D shown 0 in the scope of 20Khz, during rotating speed 3020RPM, in " D " of Fig. 1 to the air flow condition that records.Fig. 7 A shown 0 in the scope of 2Khz, during rotating speed 3020RPM, in " A " of Fig. 1 to the culinary art noise state that records.Fig. 7 B shown 0 in the scope of 2Khz, during rotating speed 3020RPM, in " B " of Fig. 1 to the culinary art noise state that records.Fig. 7 C shown 0 in the scope of 2Khz, during rotating speed 3020RPM, in " C " of Fig. 1 to the culinary art noise state that records.Fig. 7 D shown 0 in the scope of 2Khz, during rotating speed 3020RPM, in " D " of Fig. 1 to the culinary art noise state that records.

Yet,, plunder angle θ less than 10 ° because the maximum camber (maximumcamber) of the aerofoil fan of conventional micro-wave oven is 0.5, when cooling blast forms, the flow direction of cooling air is axial, so corresponding devices can not effectively be cooled off as magnetron and high-tension transformer.

In addition because the rotating speed of conventional aerofoil fan be 3020RPM (rev/min), so shown in Fig. 5-7, the noise level that can hear increases.

Therefore to be intended to be to propose a kind of micro-wave oven aerofoil fan to target of the present invention, and it can overcome conventional micro-wave oven with problem that fan ran into.

Another object of the present invention is intended to propose a kind of improved micro-wave oven aerofoil fan, it is magnetron and the high-tension transformer in the cooled microwave stove more effectively, more effectively therefore the air-flow in the circulation microwave stove can improve the efficient of micro-wave oven and reduce noise.

For achieving the above object, according to an aspect of the present invention, micro-wave oven comprises the equidistant blade that separates of five on the outer cylinder that takes shape in a column type wheel hub with aerofoil fan; " the fan hub diameter/fan external diameter " of blade is than being 0.28～0.35.

For achieving the above object, according to a further aspect in the invention, micro-wave oven comprises the equidistant blade that separates of five on the outer cylinder that takes shape in a column type wheel hub with aerofoil fan; " the fan hub diameter/fan external diameter " of blade is than being 0.28～0.3.

Fig. 1: the perspective view of conventional micro-wave oven.

Fig. 2 a: sectional view that shows cooling inlet air flow path in the micro-wave oven that conventional aerofoil fan is housed.

Fig. 3: the conventional micro-wave oven front view of aerofoil fan.

The enlarged drawing of Fig. 4: Fig. 3.

Fig. 5 A: 0 in the scope of 2Khz, during rotating speed 3020RPM, in " A " of Fig. 1 to the air flow condition that records (air flowing state).

Fig. 5 B: 0 in the scope of 2Khz, during rotating speed 3020RPM, in " B " of Fig. 1 to the air flow condition that records.

Fig. 5 C: 0 in the scope of 2Khz, during rotating speed 3020RPM, in " C " of Fig. 1 to the air flow condition that records.

Fig. 5 D: 0 in the scope of 2Khz, during rotating speed 3020RPM, in " D " of Fig. 1 to the air flow condition that records.

Fig. 6 A: 0 in the scope of 20Khz, during rotating speed 3020RPM, in " A " of Fig. 1 to the air flow condition that records.

Fig. 6 B: 0 in the scope of 20Khz, during rotating speed 3020RPM, in " B " of Fig. 1 to the air flow condition that records.

Fig. 6 C: 0 in the scope of 20Khz, during rotating speed 3020RPM, in " C " of Fig. 1 to the air flow condition that records.

Fig. 6 D: 0 in the scope of 20Khz, during rotating speed 3020RPM, in " D " of Fig. 1 to the air flow condition that records.

Fig. 7 A: 0 in the scope of 2Khz, during rotating speed 3020RPM, in " A " of Fig. 1 to the culinary art noise state that records (cooking noise state).

Fig. 7 B: 0 in the scope of 2Khz, during rotating speed 3020RPM, in " B " of Fig. 1 to the culinary art noise state that records.

Fig. 7 C: 0 in the scope of 2Khz, during rotating speed 3020RPM, in " C " of Fig. 1 to the culinary art noise state that records.

Fig. 7 D: 0 in the scope of 2Khz, during rotating speed 3020RPM, in " D " of Fig. 1 to the culinary art noise state that records.

Fig. 8: according to the front view of micro-wave oven in the first embodiment of the present invention with aerofoil fan.

Fig. 9: according to the enlarged drawing of Fig. 8 of the present invention.

Figure 10: demonstration is according to the X-Z plane of Fig. 9 of the maximum camber of the aerofoil fan of the first embodiment of the present invention.

Figure 11: demonstration is according to the X-Z plane of the Fig. 9 at the inclination angle of the aerofoil fan of the first embodiment of the present invention.

Figure 12: demonstration is according to the noise test of the aerofoil fan of the first embodiment of the present invention and the contrast table of prior art.

Figure 13: the schematic diagram that carries out the noise test of Figure 12 according to the present invention.

Figure 14 A: the culinary art noise figure according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention is housed, this figure when rotating speed 3020RPM, at " A " of Fig. 1 to recording.

Figure 14 B: the culinary art noise figure according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention is housed, this figure when rotating speed 3020RPM, at " B " of Fig. 1 to recording.

Figure 14 C: the culinary art noise figure according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention is housed, this figure when rotating speed 3020RPM, at " C " of Fig. 1 to recording.

Figure 14 D: the culinary art noise figure according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention is housed, this figure when rotating speed 3020RPM, at " D " of Fig. 1 to recording.

Figure 15 A: the culinary art noise figure according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention is housed, this figure when rotating speed 2400RPM, at " A " of Fig. 1 to recording.

Figure 15 B: the culinary art noise figure according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention is housed, this figure when rotating speed 2400RPM, at " B " of Fig. 1 to recording.

Figure 15 C: the culinary art noise figure according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention is housed, this figure when rotating speed 2400RPM, at " C " of Fig. 1 to recording.

Figure 15 D: the culinary art noise figure according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention is housed, this figure when rotating speed 2400RPM, at " D " of Fig. 1 to recording.

Figure 16 A: the culinary art noise figure according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention is housed, this figure when rotating speed 2350RPM, at " A " of Fig. 1 to recording.

Figure 16 B: the culinary art noise figure according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention is housed, this figure when rotating speed 2350RPM, at " B " of Fig. 1 to recording.

Figure 16 C: the culinary art noise figure according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention is housed, this figure when rotating speed 2350RPM, at " C " of Fig. 1 to recording.

Figure 16 D: the culinary art noise figure according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention is housed, this figure when rotating speed 2350RPM, at " D " of Fig. 1 to recording.

Figure 17 A: the culinary art noise figure according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention is housed, this figure when rotating speed 2145RPM, at " A " of Fig. 1 to recording.

Figure 17 B: the culinary art noise figure according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention is housed, this figure when rotating speed 2145RPM, at " B " of Fig. 1 to recording.

Figure 17 C: the culinary art noise figure according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention is housed, this figure when rotating speed 2145RPM, at " C " of Fig. 1 to recording.

Figure 17 D: the culinary art noise figure according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention is housed, this figure when rotating speed 2145RPM, at " D " of Fig. 1 to recording.

Figure 18: according to the fan data boundary table of the aerofoil fan of the first embodiment of the present invention.

Figure 19: the front view of using the aerofoil fan blade according to micro-wave oven according to the present invention.

Figure 20 A: the plane of aerofoil fan according to a second embodiment of the present invention.

Figure 20 B: the side view of aerofoil fan according to a second embodiment of the present invention.

Figure 21 A: the propeller-blade section figure that shows the maximum camber of aerofoil fan according to a second embodiment of the present invention.

Figure 21 B: the propeller-blade section figure that shows the inclination angle of aerofoil fan according to a second embodiment of the present invention.

Figure 22 A: in the scope of 0-2, during rotating speed 2460RPM, in Fig. 1 " A " culinary art noise figure to the micro-wave oven according to a second embodiment of the present invention that records.

Figure 22 B: in the scope of 0-2, during rotating speed 2460RPM, in Fig. 1 " B " culinary art noise figure to the micro-wave oven according to a second embodiment of the present invention that records.

Figure 22 C: in the scope of 0-2, during rotating speed 2460RPM, in Fig. 1 " C " culinary art noise figure to the micro-wave oven according to a second embodiment of the present invention that records.

Figure 22 D: in the scope of 0-2, during rotating speed 2460RPM, in Fig. 1 " D " culinary art noise figure to the micro-wave oven according to a second embodiment of the present invention that records.

Figure 23 A: in the scope of 0-20, during rotating speed 2460RPM, in Fig. 1 " A " culinary art noise figure to the micro-wave oven according to a second embodiment of the present invention that records.

Figure 23 B: in the scope of 0-20, during rotating speed 2460RPM, in Fig. 1 " B " culinary art noise figure to the micro-wave oven according to a second embodiment of the present invention that records.

Figure 23 C: in the scope of 0-20, during rotating speed 2460RPM, in Fig. 1 " C " culinary art noise figure to the micro-wave oven according to a second embodiment of the present invention that records.

Figure 23 D: in the scope of 0-20, during rotating speed 2460RPM, in Fig. 1 " D " culinary art noise figure to the micro-wave oven according to a second embodiment of the present invention that records.

Figure 24 A: in the scope of 0-2, during rotating speed 3020RPM, in Fig. 1 " A " culinary art noise figure to the micro-wave oven according to a second embodiment of the present invention that records.

Figure 24 B: in the scope of 0-2, during rotating speed 3020RPM, in Fig. 1 " B " culinary art noise figure to the micro-wave oven according to a second embodiment of the present invention that records.

Figure 24 C: in the scope of 0-2, during rotating speed 3020RPM, in Fig. 1 " C " culinary art noise figure to the micro-wave oven according to a second embodiment of the present invention that records.

Figure 24 D: in the scope of 0-2, during rotating speed 3020RPM, in Fig. 1 " D " culinary art noise figure to the micro-wave oven according to a second embodiment of the present invention that records.

Figure 25: the fan data boundary table of aerofoil fan according to a second embodiment of the present invention.

Figure 26: according to the front view of the blade among Figure 25 of the present invention.

Fig. 8 has shown the micro-wave oven aerofoil fan according to the first embodiment of the present invention, and it comprises five equidistant blades 52 that separate that take shape on column type wheel hub 51 cylinders.

The ratio of the fan hub diameter B/ fan outer diameter A of blade 52 is 0.28-0.35.

In addition, as shown in Figure 9, the anterior length I of the fan from fan center " 0,0,0 " to maximum leading edge 52a is 15.14 ± 0.5mm along rotating shaft (Z axle).

In addition, the fan rear portion length J from fan center " 0,0,0 " to maximum trailing edge 52b is 15.14 ± 0.5mm along rotating shaft (Z axle).

In addition, the ratio of the fan hub diameter B/ fan outer diameter A of blade 52 is preferably 0.33.

The fan outer diameter A is 108 ± 1mm, and fan hub diameter B is 35.6 ± 1mm.

The angle θ of plunderring from the wheel hub to the blade tip is (0～25 °) ± 1 °, and just, it is Linear Parabolic line (lineal parabola), and as shown in figure 11, inclination angle is (43.99 °～30.99 °) ± 1 °, and has linear distribution.

As shown in figure 10, maximum camber position L is 0.45～0.5, is even distribution (even distribution) from wheel hub 51 to blade tip F.

Herein, the maximum radian from wheel hub 51 to blade tip 52c (maximum camberratio) is (5.01～11.01%) ± 0.05% than " (maximum camber M/ code length) * 100 ", is linear distribution.

In addition, be " Tt=0.75Th " (Th represents maximum ga(u)ge) at the thickness of blade tip 52c place blade 52, be linear distribution, between leading edge 52a and trailing edge 52b, thickness distribution is bielliptic(al) curve (duplicated elliptical curbed line).

As shown in Figure 8, the distance between the blade 52 " a～b～c～d " is " 6.2～1 0.4～8.0～21.6 "

That is to say, when wheel hub 51 is 0, blade tip 52 is 1 o'clock, the distance at wheel hub 51 places is 6.2 ± 0.5mm, interval 0～0.75th, and the Linear Parabolic line, its spacing is increased to 1 0.4 ± 0.5mm from 6.2 ± 0.5mm, interval 0.75～0.95th, the Linear Parabolic line, its spacing reduces to 8.0 ± 0.5mm from 1 0.4 ± 0.5mm, in blade tip portion interval 0.95～1.0th, and cubic parabola (cubic parabola), spacing rapidly increases to 21.6 ± 0.5mm from 8.0 ± 0.5mm.Boundary point 0.75 and 0.95 between each interval, derivative are 0 (zero), and it is made of Linear Parabolic line and cubic parabola.

In order to test noise reduction effect according to the aerofoil fan of said structure of the present invention, cooling effect to conventional aerofoil fan under the 3020RPM and the aerofoil fan of the present invention under the 2400RPM compares, simultaneously the conventional aerofoil fan of 2350RPM and the cooling effect of the aerofoil fan of the present invention under the 2145RPM are compared, the results are shown in Figure 12.

As shown in figure 12, the average noise value that is used for the conventional aerofoil fan (3020RPM) of conventional micro-wave oven is 46.06db (A), and uses the average noise value of aerofoil fan of the present invention (2400RPM) to be 41.88db (A).In addition, the average noise value that is used for the conventional aerofoil fan (2350RPM) of micro-wave oven of the present invention is 43.24db (A), and uses the average noise value of aerofoil fan of the present invention (2145RPM) to be 39.47db (A).Therefore, compared with the prior art, aerofoil fan of the present invention reduces noise 3.8%.

Figure 13 has shown the schematic diagram that carries out the test of Figure 12 according to the present invention.Among Figure 13, label 71 is represented magnetron, and 72 represent control module, and 73 represent vent locations, 75 represent the cooling segment of magnetron HVT, and 76 represent the MWO fan, and 77 represent air inlet, and 78 represent cooking cavity, 79 represent the air inlet of cooking cavity, and 79a represents exhaust outlet, and 80 represent the fire door of cooking cavity.

In addition, Figure 14 A has shown the culinary art noise that is equipped with according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention, this figure under 3020RPM, at " A " of Fig. 1 to recording; Figure 14 B has shown the culinary art noise that is equipped with according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention, this figure under 3020RPM, at " B " of Fig. 1 to recording; Figure 14 C has shown the culinary art noise that is equipped with according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention, this figure under 3020RPM, at " C " of Fig. 1 to recording; Figure 14 D has shown the culinary art noise that is equipped with according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention, this figure under 3020RPM, at " D " of Fig. 1 to recording; Figure 15 A has shown the culinary art noise that is equipped with according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention, this figure under 2400RPM, at " A " of Fig. 1 to recording; Figure 15 B has shown the culinary art noise that is equipped with according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention, this figure under 2400RPM, at " B " of Fig. 1 to recording; Figure 15 C has shown the culinary art noise that is equipped with according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention, this figure under 2400RPM, at " C " of Fig. 1 to recording; Figure 15 D has shown the culinary art noise that is equipped with according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention, this figure under 2400RPM, at " D " of Fig. 1 to recording; Figure 16 A has shown the culinary art noise that is equipped with according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention, this figure under 2350RPM, at " A " of Fig. 1 to recording; Figure 16 B has shown the culinary art noise that is equipped with according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention, this figure under 2350RPM, at " B " of Fig. 1 to recording; Figure 16 C has shown the culinary art noise that is equipped with according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention, this figure is under 2350RPM, at " C " of Fig. 1 to recording, Figure 16 D has shown the culinary art noise that is equipped with according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention, this figure under 2350RPM, at " D " of Fig. 1 to recording; Figure 17 A has shown the culinary art noise that is equipped with according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention, this figure under 2145RPM, at " A " of Fig. 1 to recording; Figure 17 B has shown the culinary art noise that is equipped with according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention, this figure under 2145RPM, at " B " of Fig. 1 to recording; Figure 17 C has shown the culinary art noise that is equipped with according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention, this figure under 2145RPM, at " C " of Fig. 1 to recording; Figure 17 D has shown the culinary art noise that is equipped with according to the micro-wave oven of the aerofoil fan of the first embodiment of the present invention, this figure under 2145RPM, at " D " of Fig. 1 to recording.

In addition, Figure 18 has shown the fan data boundary according to the aerofoil fan of the first embodiment of the present invention, and Figure 19 has shown the blade of micro-wave oven according to the present invention with aerofoil fan.

Among Figure 19, label 1,41,81,121 and 161 represent the point of coordinate system.

In addition, Figure 20 A and 20B have shown aerofoil fan according to a second embodiment of the present invention, and it comprises a wheel hub 62 and five blades 64 that take shape on wheel hub 62 cylinders with the rotating handle (not shown) that is inserted into aerofoil fan 60 middle parts.

The ratio of the hub diameter DH of aerofoil fan 60 according to a second embodiment of the present invention and fan outer diameter D T is 0.28～0.3.

At this moment, fan outer diameter D T is preferably 108 ± 1mm, and fan hub diameter DH is preferably 30.2 ± 1mm.

In addition, shown in Figure 21 B, 63 tiltangle P is that (41.96 °～28.96 °) are linear distribution from wheel hub 62 to blade tip.63 the angle θ S of plunderring is (0 °～30 °) ± 2 ° from wheel hub 62 to blade tip, is that the Linear Parabolic line distributes.

Shown in Figure 21 A, 63 maximum camber position CMP evenly distributes from wheel hub 62 to blade tip, is " 0.6-0.65 ".63 the maximum camber ratio from wheel hub 62 to blade tip (maximum camber/code length (CL) * 100) is " (3.46-9.46) ± 0.05% ", is linear.

Shown in Figure 21 B, " 0 " distance of (Z axle) is front distance VL to maximum leading edge 64a along rotating shaft from the center, and shown in Figure 20 B, " 0 " distance of (Z axle) is rear portion distance R L to maximum trailing edge 64b along rotating shaft from the center.

In this embodiment, front distance VL is 19.42 ± 0.5mm, and rear portion distance R L is 11.53 ± 0.5mm.

If the maximum ga(u)ge of blade 64 is " Th ", the thickness at blade blade tip place is " 0.75Th ".In addition, the blade thickness between wheel hub 62 and the blade tip 63 is a linear change, and the blade thickness between leading edge 64a and the trailing edge 64b is distributed as the bielliptic(al) curve.

When the position of wheel hub 62 is 0, the position of blade tip is 1 o'clock, if the spacing CB between the paddle 64 increases to have the Linear Parabolic wire shaped, then the spacing CB between wheel hub 62 and the paddle 64 is 6.7 ± 0.5mm, and in 0～0.75 interval, its spacing is 6.7 ± 0.5mm and 11.2 ± 0.5mm.In addition, in the interval of " 0.75～0.95 ", be the Linear Parabolic line, spacing in the interval of " 0.95～1.0 ", is cubic parabola between 11.2 ± 0.5mm and 9.0 ± 0.5mm, spacing is between 9.0 ± 0.5mm to 23.0 ± 0.5mm, at each section boundaries point 0.75 and 0.95, derivative is 0, and the distance C B between the blade 64 is made of Linear Parabolic line and cubic parabola.

Among the figure, HL represents hub length, and HW represents the width of blade wheel hub.

By Figure 22-24, can understand performance according to a second embodiment of the present invention better.

Figure 22 A has shown in the scope of 0-2, during rotating speed 2460RPM, in the culinary art noise of Fig. 1 " A " to the micro-wave oven according to a second embodiment of the present invention that records; Figure 22 B has shown in the scope of 0-2, during rotating speed 2460RPM, in the culinary art noise of Fig. 1 " B " to the micro-wave oven according to a second embodiment of the present invention that records; Figure 22 C has shown in the scope of 0-2, during rotating speed 2460RPM, in the culinary art noise of Fig. 1 " C " to the micro-wave oven according to a second embodiment of the present invention that records; Figure 22 D has shown in the scope of 0-2, during rotating speed 2460RPM, in the culinary art noise of Fig. 1 " D " to the micro-wave oven according to a second embodiment of the present invention that records; Figure 23 A has shown in the scope of 0-20, during rotating speed 2460RPM, in the culinary art noise of Fig. 1 " A " to the micro-wave oven according to a second embodiment of the present invention that records; Figure 23 B has shown in the scope of 0-20, during rotating speed 2460RPM, in the culinary art noise of Fig. 1 " B " to the micro-wave oven according to a second embodiment of the present invention that records; Figure 23 C has shown in the scope of 0-20, during rotating speed 2460RPM, in the culinary art noise of Fig. 1 " C " to the micro-wave oven according to a second embodiment of the present invention that records; Figure 23 D has shown in the scope of 0-20, during rotating speed 2460RPM, in the culinary art noise of Fig. 1 " D " to the micro-wave oven according to a second embodiment of the present invention that records; Figure 24 A has shown in the scope of 0-2, during rotating speed 3020RPM, in the culinary art noise of Fig. 1 " A " to the micro-wave oven according to a second embodiment of the present invention that records; Figure 24 B has shown in the scope of 0-2, during rotating speed 3020RPM, in the culinary art noise of Fig. 1 " B " to the micro-wave oven according to a second embodiment of the present invention that records; Figure 24 C has shown in the scope of 0-2, during rotating speed 3020RPM, in the culinary art noise of Fig. 1 " C " to the micro-wave oven according to a second embodiment of the present invention that records; Figure 24 D has shown in the scope of 0-2, during rotating speed 3020RPM, in the culinary art noise of Fig. 1 " D " to the micro-wave oven according to a second embodiment of the present invention that records.

Shown in Figure 22-24, compare with conventional fan, the present invention has reduced discrete noise, and wide band noise reduces.

In addition, when culinary art, discrete noise increases.That is to say the micro-wave oven noise of aerofoil fan minimizing 4.8db (A) when air flows, the noise of minimizing 4.8db (A) when culinary art.

In addition according to a second embodiment of the present invention micro-wave oven has been carried out the test that heats up.

The container that a splendid attire 2000ml water is arranged in the cooking cavity, test has been carried out two hours.Under this state, the temperature of heat-generating units does not change, and detects limiting temperature.

With differential recorder HR2500E (Yokogaya) and K type thermocouple the temperature of the upper surface of the anode of magnetron and high-tension transformer is measured.

Measurement result is as shown in the table:

Micro-wave oven heats up and tests (Table I)

Table I

Fan type	Tested position	The fan revolution	????T(℃)
				Conventional fan	Magnetron	??3020	????148.2
????HVT	????96.8
		Fan of the present invention	Magnetron		??2460		????147.4
????HVT	????100.4

HVT represents high-tension transformer in the last table.

As above shown in the table, also may reach conventional temperature with lower rotating speed.

In addition, also tested the noise of micro-wave oven.

When the noise test of cooking status, be placed with the container that splendid attire 1500ml water in the cooking cavity, heated 30 minutes, in aforesaid operations, noise has reduced.When air flows the noise test, has only fan in operation.Test result is as shown in the table.

Noise of microwave oven test (Table II)

Table II

?FT	?NR	?RS	Noise level				??AV
								???A	???B??	??C	???D
			?FA	?3020	Flow	?42.13						?45.74	?44.99	?51.36	?46.06
Culinary art	?42.21	?45.31					?44.71	?50.96	?45.80
					?FP	?2460				Flow	?36.80	?40.75	?38.88	?44.75	?40.30
Culinary art	?37.67	?40.80	?40.24	?45.16			?40.97

In last table, Ft represents fan type, and Nr represents rotation speed of the fan, and AV represents mean value, and FA represents the fan of prior art, and FP represents fan of the present invention.In addition, A, B, C, D represent the direction among Figure 13.

As shown in Table II, compare with the fan of prior art, fan of the present invention has reduced noise.

Figure 25 has shown the data boundary of aerofoil fan according to a second embodiment of the present invention, and Figure 26 has shown the blade according to Figure 25 of the present invention.

As mentioned above, micro-wave oven according to the present invention passes through to change the number of blade with aerofoil fan, improve and plunder the angle, the inclination angle, the distance of maximum camber and maximum camber position and blade, the more effectively magnetron of cooled microwave stove and high-tension transformer, the air of more effective circulation microwave furnace interior, therefore improve the efficient of micro-wave oven, reduced noise.

Though optimum implementation of the present invention announces for explanation, only otherwise depart from disclosed scope and spirit of the present invention in the claim statement, the modification of technical maturing part, increase and substituting also is fine.

Claims (16)

1. a micro-wave oven comprises with aerofoil fan:

Five equidistant separation distributions of blade and taking shape on the column type wheel hub outer cylinder;

The ratio of " the fan hub diameter/fan external diameter " of above-mentioned blade is 0.28～0.35.

2. as the fan in the claim 1, its external diameter is 108 ± 1mm, and the fan hub diameter is 35.6 ± 1mm.

3. fan as claimed in claim 1, the wherein above-mentioned angle of plunderring is (0～25 °) ± 1 ° from the wheel hub of blade to blade tip, the above-mentioned angle of plunderring is the Linear Parabolic wire shaped.

4. fan as claimed in claim 1, wherein above-mentioned wheel hub from blade are (43.99 °～30.99 °) ± 1 ° to the inclination angle of blade tip, and above-mentioned inclination angle is the linear distribution shape.

5. fan as claimed in claim 1, wherein above-mentioned maximum camber position is 0.45～0.5 even distribution from the wheel hub of blade to blade tip, and above-mentioned maximum camber ratio (maximum camber/code length * 100) is the linear distribution of (5.01～11.01%) ± 0.05% to blade tip from the wheel hub of blade.

6. fan as claimed in claim 1, wherein the thickness of above-mentioned blade is Tt=0.75Th, is linear distribution (Tt represents the thickness of blade, and Th represents the maximum ga(u)ge of wheel hub), the thickness distribution between leading edge and the trailing edge is the bielliptic(al) curve.

7. fan as claimed in claim 1, wherein working as wheel hub is 0, blade tip is 1 o'clock, the distance of wheel hub is 6.2 ± 0.5mm, interval 0～0.75th, the Linear Parabolic line, its spacing is increased to 10.4 ± 0.5mm from 6.2 ± 0.5mm, interval 0.75～0.95th, the Linear Parabolic line, its spacing reduces to 8.0 ± 0.5mm from 10.4 ± 0.5mm, in blade tip portion interval 0.95～1.0th, cubic parabola, its spacing rapidly increases to 21.6 ± 0.5mm from 8.0 ± 0.5mm, the boundary point 0.75 and 0.95 between each interval, derivative is 0 (zero), and it is made of Linear Parabolic line and cubic parabola.

8. fan as claimed in claim 1, wherein the anterior length of above-mentioned aerofoil fan is 15.14 ± 0.5mm, rear portion length is 15.14 ± 0.5mm.

9. a micro-wave oven comprises with aerofoil fan:

Five equidistant separation distributions of blade and taking shape on the column type wheel hub outer cylinder;

The ratio of " the fan hub diameter/fan external diameter " of above-mentioned blade is 0.28～0.3.

10. fan as claimed in claim 9, wherein the said fans external diameter is 108 ± 0.5mm, the said fans hub diameter is 30.2 ± 0.5mm.

11. fan as claimed in claim 9, wherein above-mentioned wheel hub from blade is (0～30 °) ± 2 ° to the angle of plunderring of blade tip, and the above-mentioned angle of plunderring is the Linear Parabolic line.

12. fan as claimed in claim 9, wherein above-mentioned wheel hub from blade are (41.96 °～28.96 °) ± 1 ° to the inclination angle of blade tip, it is linear that above-mentioned inclination angle is.

13. fan as claimed in claim 9, wherein above-mentioned maximum camber position is 0.6～0.65 even distribution from the wheel hub of blade to blade tip, and above-mentioned maximum camber ratio (maximum camber/code length * 100) is the linear distribution of (3.46～9.46%) ± 0.05% to blade tip from the wheel hub of blade.

14. fan as claimed in claim 9, wherein the thickness of above-mentioned blade is the linear distribution (Tt represents the thickness of blade, and Th represents the maximum ga(u)ge of wheel hub) of Tt=0.75Th, and the thickness distribution between leading edge and the trailing edge is the bielliptic(al) curve.

15. fan as claimed in claim 9, wherein working as wheel hub is 0, blade tip is 1 o'clock, the distance of wheel hub is 6.7 ± 0.5mm, interval 0～0.75th, the Linear Parabolic line, its spacing is increased to 11.2 ± 0.5mm from 6.7 ± 0.5mm, interval 0.75～0.95th, the Linear Parabolic line, its spacing reduces to 9.0 ± 0.5mm from 11.2 ± 0.5mm, in blade tip portion interval 0.95～1.0th, cubic parabola, spacing rapidly increases to 23.0 ± 0.5mm from 9.0 ± 0.5mm, the boundary point 0.75 and 0.95 between each interval, derivative is 0 (zero), and it is made of Linear Parabolic line and cubic parabola.

16. fan as claimed in claim 9, wherein the anterior length of above-mentioned aerofoil fan is 19.42 ± 0.5mm, and rear portion length is 11.53 ± 0.5mm.

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