SK103799A3 - Microwave oven - Google Patents

Abstract

A microwave oven and a method for feeding microwaves into it. The rectangularly parallelepipedal oven cavity (2) has a side wall (8) with a slight inward slope which gives an upwardly decreasing horizontal cross section. By the selection of a suitable slope the mode balance in the cavity is affected so that the best equalisation of the heating pattern is obtained.

Description

The invention described below relates to a microwave oven and to a method of supplying it with microwave power.

BACKGROUND OF THE INVENTION

Microwave ovens for domestic use are usually manufactured with a rectangular-shaped chamber. This shape results both from the requirements of ease of manufacture and from conventional views on how a microwave oven should look. Although to some extent it is possible to theoretically calculate which so-called. the resonant waveforms will propagate in a rectangular cavity, it has been found to be difficult to achieve an acceptable symmetrical temperature distribution, especially when the cavity is powered by microwave power through the side wall. For improved spatial distribution of temperature are used. microwave mixers resp. rotating bottom plate on which the heated food is placed.

In view of the above, a different cross-sectional geometry (section perpendicular to the direction of propagation and direction of microwave power transmission) other than a rectangular cross-section is also used in industrial microwave ovens. In this regard, a possible interpretation of the effect of the walls of the microwave cavity has been contemplated in analogy to the reflection of light rays, i. the possibility of optical-geometric control of microwave distribution is assumed.

An example of such a microwave configuration where "microwave reflection" is considered is given in the description of technical standard EP 0268 379 B1.

SUMMARY OF THE INVENTION

It is an object of the present invention to allow better temperature distribution in the rectangular prism cavity of a microwave oven.

It is a further object of the invention to allow such a spatial temperature distribution to be improved without the need for moving parts such as e.g. wine mixers or rotating bottom plate.

A secondary object of the invention is to propose a method which would allow a better configuration of the rectangular cavity of a rectangular cross-section with respect to the resulting thermal field distribution.

The foregoing objects of the invention are achieved by a microwave oven and by methods which exhibit the properties set forth in the claims set forth in the documents below.

SUMMARY OF THE INVENTION It has surprisingly been found that the distribution of the temperature field in the rectangular cavity of a rectangular cross-section can be favorably influenced by the geometric configuration of the cavity with a horizontal cross-section of non-constant width. The proposed cross-sectional changes will not change the general rectangular rectangular cross-sectional shape and are not comparable to embossed embossed walls, rounded edges, etc., which are usually made to accommodate rectangular rectangular cross-sectional dimensions for manufacturing reasons and to simplify production and improve the mechanical stability of the cavity.

We have found that the reflection interpretation of the optical (light) waves described above does not apply to the smaller cavities used in household microwave ovens.

Thus, the present invention is based on the understanding that the phase and amplitude of the wave propagation modes in the cavity can be advantageously varied in order to compensate for the course of the temperature field, by well-designed, relatively small vertical cross-sectional changes in the cavity. In other words, by making these cavity cross-sectional adjustments, it is possible to regulate the equilibrium of the propagation modes with respect to the magnitude of the amplitude and the phase of the propagation modes used so that a uniform temperature field is obtained.

We have found that if the cross-sectional modifications of the cavity of the present invention are relatively small and made with a small vertical gradient, then it is possible to maintain the characteristic volumetric wave modes in the cavity while achieving a change in the temperature field distribution. Changes in the temperature field distribution are experimentally observable, which makes it possible to additionally adjust the cross-sectional variations for the best possible temperature field performance.

In experimental tests, slow changes in the cross-section of the cavity have shown that it is possible to continuously monitor the induced changes in the temperature field, and this method, which is regarded as an advantageous property, provides the possibility to set very well the optimal cooking conditions in the microwave.

According to the present invention, it is advantageous to use changes in the cross-section of the cavity in the vertical direction, which means that the width of the horizontal cross-section upwards will decrease at least in the upper part of the cavity. In this case, it is advantageous if the transverse cross-section of the cavity can be achieved by means of a side wall of the cavity which has at least a partial inclination inwards.

Accordingly, according to a first aspect of the invention, a method for microwave feeding a rectangular cavity of a rectangular cross-section has been developed which, in order to homogenize the effect of microwave radiation in a cavity, affects the equilibrium of microwave propagation modes through a cavity, at least at the top horizontal dimension of the cross-section of the cavity. Accordingly, it is preferred to reduce the horizontal dimension of the cross-section of the cavity by slanting the side wall inwards, at least in the upper part of the wall. The microwave power supply is preferably provided through an aperture (slot) in the side wall of the cavity as opposed to the slanted side wall, and the microwave power supply should preferably be provided along a cross section in close proximity to the ceiling of the cavity.

As an alternative method, the microwave power may be fed through an opening in the ceiling of the cavity, in which case it is also advisable to extend it in the direction of

I parallel to the inclined side wall of the cavity.

According to a second aspect of the invention, a method has been proposed for influencing the temperature field distribution by varying the feeding of microwave power to a rectangular cavity, wherein changes in temperature field are achieved by slanting the side wall of the cavity inwardly at least in its upper part so that the cavity has a upwards due to the existing dimension of the lower part of this cross-section. Accordingly, it will be possible, based on the selected cavity width, to vary the change in horizontal cross-section by changing the degree or change the angle of inclination of the side wall inwards and observing the resulting changes in the temperature field. It is appreciated in the method that by making such variations in the internal inclination of the sidewall of the cavity for a variety of different cavity widths, it will be possible to determine the combination of the cavity width and the internal inclination of the sidewall of the cavity that gives the best resultant thermal field distribution.

In this connection, it has to be said that the discovered new effect of the inclined wall on the distribution of the temperature field is particularly pronounced for certain specific cavity widths.

According to a third aspect of the invention, the microwave oven consists of a rectangular cavity of rectangular cross-section and a microwave power source connected via a feeder to the cavity. The cavity has a tapering transverse dimension, at least in the upper part of the cavity, with respect to the dimension of the lower portion of its cross-section. Accordingly, in a preferred geometric configuration, the cavity will have a side wall, at least partially tapering upward, so as to guarantee the desired narrowing of the horizontal cross-section. In this case, it is advantageous for the inwardly inclined wall of the cavity to be in its upper part, the lower part of the cavity wall remaining perpendicular and preferably at least 50 mm high. The inclination of the upper part of the side wall inwards does not have to extend over the entire height of the side wall up to the ceiling of the cavity, but the side wall may comprise a short perpendicular wall section ending on the ceiling of the cavity. Although the inclined portion of the side wall should form a planar surface, other configurations are possible. The inclination of the side wall should preferably extend over the entire actual width of the wall, and it is preferred that it extends over at least half the height of the side wall.

For manufacturing reasons, the inclination of the side wall should be realized within the deep-drawn part of the side wall so that the connection with the rear wall and the front of the microwave can be realized by means of perpendicular corner connectors. In such a case, the desired wall inclination may preferably be distributed over 85% of the total depth of the cavity.

The microwave oven of the present invention has a horizontal cross-section of approximately square shape. The ratio of the "depth" and the cross-sectional width of the cavity is 85%: 120%. The following geometric arrangements have been found to be particularly advantageous for microwave ovens for household use (with the frequency of the 2450 MHz microwave source used):

1) Width of horizontal cross-section at the top of the cavity from 315 mm to 335 mm, with an optimum value of approx. 325 mm. The cross-sectional width at the bottom of the cavity is 8 mm to 15 mm larger.

2) The width of the horizontal cross-section at the top of the cavity ranges from 385 to 410 mm. The cross-sectional width at the bottom of the cavity is 8 mm to 15 mm larger.

In both cases, the cavity height will be measured from the lower plate, respectively. from the bottom of the cavity to the ceiling of the cavity in the range of 160 mm to 230 mm.

The invention provides a number of advantages:

Uniformly distributed temperature field, which basically contains no so-called. cold point;

improved right-left symmetry of the temperature field in the cavity fed through the side wall, especially in the microwave without moving parts;

widening the cavity of the microwave at the bottom;

furthermore, a 'more space efficient' microwave oven;

greater freedom of choice when designing cavity dimensions;

an additional degree of freedom in modifying the microwave configuration, and more freedom in choosing a microwave power back-up.

The invention is described in detail below by means of specific figures with reference to the accompanying drawing.

BRIEF DESCRIPTION OF THE DRAWINGS

In FIG. 1 shows a microwave oven. In FIG. 2 is a horizontal cross-section of the microwave oven. In FIG. 3 is a horizontal cross-sectional view of another embodiment of the microwave oven as in FIG. Second

DETAILED DESCRIPTION OF THE INVENTION

A particular representation of the microwave oven according to the present invention in Figs. 1 and 2 includes an outer cover 1, which is shown only by the outline, and a cavity of the oven 2, which is closed by the front door 3. The cavity 2 is formed by the horizontal bottom of the cavity 4; 5, the rear vertical wall of the cavity 6, the front vertical wall from the inside of the front door 3 and the two side walls 7 and 8. The right side wall 7 in FIGS. 1 and 2 is perpendicularly equipped with a microwave power supply unit into the cavity through a rectangular slot. shape 10, which is described in detail below. The left side wall 8 in Figs. 1 and 2 is considered inwardly, and thus an animal with a perpendicular angle of about 3 °. As a result, the cavity is a rectangular prism, with the exception of the side wall with an inclined inward angle of 8. However, this inclination is so small that it can be neglected and no geometric deviation from the rectangular prism can be considered, except for the effect of the resulting microwave characteristic.

All wall surfaces defining a rectangular cavity in this illustration are generally planar surfaces, although the inclined wall 8 connects to the ceiling of the cavity with a section of a perpendicular wall t1 of a small height.

An interesting feature of the present invention is that in the case of the cavity shown above, the horizontal cross-section tapering upward gradually, from the free width of the bottom of the cavity B1 to the ceiling width of the cavity B2. The constant depth of the cavity remains an advantageous feature.

The microwave unit 9 includes a magnetron 13 and a waveguide 14 connected thereto to provide microwave power to the feeder slot 10. As noted above, the feeder slot is typically an elongated rectangular shape and located at the center of the top of the side wall 7 at the side wall and ceiling joint. cavities 5.

As can be seen in FIG. 2, the microwave oven may comprise a lower plate of microwave-permeable material 16 onto which the heated food 17 is placed. If desired, the plate may be designed in a rotary design. However, it has been found that, despite the side position of the microwave feeder, the microwave oven produced as described in the present invention provides such a homogeneous temperature that the use of a rotary plate for heated foods loses its merits.

Typical geometric dimensions of a household microwave oven according to Fig. 1 and Fig. 2 are as follows: B1 = approx. 333 mm, B2 = approx. cavity depth = 370 mm.

Figure 3 is a schematic horizontal cross-section of the same type of oven as Figure 2, showing another embodiment of a microwave oven according to the present invention. The pipe in Fig. 3 differs from the pipe in Figs. 1 and 2 by the construction of the inclined side wall and the microwave power supply.

In this example, the inclined side wall 8 'in FIG. 3 has a lower portion 21 that is perpendicular and an upper inwardly inclined portion 22. The inner inclination of the side wall starts about in the middle of the side wall and the inclination angle is 6 °. The taper of the horizontal cross-section near the ceiling of the cavity is slightly greater than in the cavity space of Figs. 1 and 2, typically the distance by which the transverse dimension is tapered is 10 mm.

3, microwave power is provided through a rectangular slot 10 ' located in the center of the ceiling of the cavity 5, the longitudinal side of which is parallel to the side walls of the cavity 7 '

As will be appreciated by those skilled in the art, the present invention is not limited to the above examples, and several modifications of the invention are possible within the scope of the appended claims. E.g. the inclination of the side wall of the cavity can be divided between the two opposite side walls of the cavity.

WoiT'9 ^c

Claims (16)

A microwave oven comprising a rectangular cavity and a microwave power source for feeding microwave radiation to a cavity connected thereto, characterized in that the width of the horizontal cross-section narrows upwardly as a result of the inclined side wall inwardly at least in its upper part. Microwave oven according to claim 1, characterized in that it is characterized by a side wall which has a perpendicular section at least 50 mm high in its lower part. Microwave oven according to claim 1 or 2, characterized in that the side wall opposite the slanted side wall is provided with at least one slot opening for feeding microwave radiation from a source located above the chamber (cavity). Microwave oven according to claims 1, 2 and 3, characterized in that it is provided with a slot opening in the ceiling of the cavity for feeding the microwave radiation, the slot extending perpendicular to the vertical cross-section in which the horizontal width of the cavity decreases upwards . Microwave oven according to any one of claims 1 to 4, characterized in that the horizontal cross-section of the cavity has a depth which is in the range of 85% to 120% of the width of the cavity. Microwave oven according to any one of claims 1 to 5, characterized in that the cross-sectional width at the top of the cavity is from 315 mm to 335 mm, and the cross-sectional width at the bottom of the cavity is 8 mm to 15 mm greater. Microwave oven according to any one of claims 1 to 5, characterized in that the cross-sectional width at the top of the cavity is from 385 mm to 410 mm and that the cross-sectional width at the bottom of the cavity is 8 mm to 15 mm greater. Microwave oven according to any one of claims 6 or 7, characterized in that the cavity has a height in the range of 150 mm to 220 mm. Microwave oven according to any one of claims 2 to 8, characterized in that the inclined part of the side wall is at least 50 mm high. 10. A method of feeding microwave power to a rectangular cavity, characterized in that, in order to counteract the effect of microwaves in the cavity space, the equilibrium of the wave propagation modes is influenced by an upwardly narrowing cross-section of the cavity relative to the cross-sectional width at the bottom of the cavity. of the upper cavity. Method according to claim 10, characterized in that the decreasing horizontal width is achieved at least in the upper part of the side wall with an inward inclination. Method according to claim 11, characterized in that the microwave radiation is fed into the cavity through at least one slot located in the upper part of the side wall of the cavity opposite the inwardly inclined side wall. Method according to claim 11 or 12, characterized in that the microwave radiation is led into the cavity through an opening in the ceiling of the cavity. 14. A method affecting the course of a temperature field resulting from the introduction of microwave radiation into a rectangular cavity of a microwave oven, characterized in that the displacements of the field lines of the temperature field are achieved by sloping the side wall of the cavity, at least in its upper part so that the cavity has a horizontal cross-section tapering upward. The method according to claim 14, characterized in that, based on the selected cavity width, the width of the cross-sectional width will change by varying the angle of the inner inclination of the side wall and the resulting changes in the temperature field are observed. The method of claim 15, wherein the variations in the inclination of the side wall inwards are realized for a variety of different widths of the cavity to determine a suitable combination of the width of the sidewall and the angle of the inner inclination of the sidewall at which the best resultant temperature field is measured. .