EP1852934A1 - Coated microwave connection and cooking apparatus containing it - Google Patents

Abstract

Cooking appliance comprises cooking chamber, technical chamber separated from cooking chamber by cooking chamber wall(s) (10), and a microwave plug connector (100). The microwave plug connector comprises emitter (102) and receiver unit (101). The emitter unit is connected to a microwave source for feeding in microwaves with a wavelength (lambda ). The emitter unit is arranged in technical chamber. The emitter unit comprises a metallic conductor (12, 13) in connection with a metallic lambda /4 structure. The receiver unit comprises metallic conductor(s) connected with metallic lambda /4 structure. Cooking appliance comprises cooking chamber, a technical chamber separated from the cooking chamber by cooking chamber wall(s), and a microwave plug connector. The microwave plug connector comprises emitter unit and a receiver unit. The emitter unit is connected to a microwave source for feeding in microwaves with a wavelength (lambda ). The emitter unit is arranged in the technical chamber. The emitter unit comprises a metallic conductor in connection with a metallic lambda /4 structure. The receiver unit is connected to the emitter unit for the transmission of microwaves. The receiver unit is arranged in the cooking chamber. The receiver unit comprises metallic conductor(s) in connection with a metallic lambda /4 structure. The two lambda /4 structures can be connected on top of one another and together, separably. A dielectric is arranged in region(s) between the emitter unit and the receiver unit. The dielectric is provided as a dielectric coating of part(s) of one lambda /4 structures which serves as a metallic substrate in a region where there is a connection of the lambda /4 structures by plugging them on top of one another and together. The dielectric coating is connected elastically to the metallic substrate. The dielectric coating is porous. The dielectric coating is sealed with a mineral melt for stabilization at least in some areas. The dielectric coating comprises ceramic material, preferably aluminum oxide. The dielectric coating completely fills the intermediate space between the lambda /4 structures.

Description

The present invention relates to a microwave connector, comprising a transmitter unit and a receiver unit, wherein the transmitter unit is connected to a microwave source for feeding in microwaves of wavelength λ, the receiver unit for transmitting the microwaves is connected to the transmitter unit and at least partially between the transmitter unit and the receiver unit a dielectric is arranged, and a cooking appliance with a cooking chamber, one of them via at least one cooking chamber wall separate technical space and a microwave connector according to the invention.

A cooking appliance with a microwave generating device is, for example, in the non-prepublished EP 05026912.5 described. Thereafter, a coaxial or strip conductor for transporting microwaves in an accessory can be integrated within a cooking chamber and provided with a contact and / or coupling device in order to be connectable to a microwave generating device arranged outside the cooking chamber. The contact and / or coupling device can be electrically and / or magnetically shielded, vapor-tight and / or stable up to a temperature of at least 250 ° and comprise a plug connection. Further details of this connector are not described.

The US 5,977,841 discloses a generic non-contact microwave connector for transmitting radio frequency energy through a hull with the interposition of a dielectric layer. In this case, two coaxial plug parts are used, in which a respective dielectric material is arranged between the respective inner and outer conductors and between the two plug parts. The dielectric material is intended to prevent the metal of the connector parts from corrosion by salt water or the growth of marine life. The impedance of the known microwave plug-in connection is set by the thickness of the dielectric layer (s) in such a way that a transmission of the microwaves with a wave position λ with as little loss as possible can take place. As a preferred material for each dielectric layer Teflon is called. It is also from the US 5,977,841 Known to exploit λ / 4 effects to avoid reflections, for example, by arranging a parallel capacitor at a distance of λ / 4 from the dielectric between the two connector parts, in the respective coaxial line.

A disadvantage of these known microwave plug-in connections that they neither the temperatures and temperature changes in a cooking chamber nor the mechanical stresses that such a compound is exposed in the daily operation of a large and commercial kitchen grown. The high temperatures in the oven, which can exceed 300 ° C in the short term, destroy organic dielectrics such as Teflon. The high thermal loads caused, for example, by the fact that a cold liquid can hit the hot microwave plug connection or just the cooking chamber is heated with high energy input cause due to the different thermal expansion of metal and the dielectric mechanical stress and ultimately the destruction of microwave connector. Another problem that arises from the high and rapidly changing temperatures in the oven, is the change in the geometric conditions in the microwave connector by thermal expansion. The resulting deviations from an optimal λ / 4 geometry result in an increase in the impedance and thus in losses in the energy transmission through the microwave connector.

The present invention is therefore based on the object to further develop the generic microwave connector such that it overcomes the disadvantages of the prior art. In particular, a thermally and mechanically stable microwave plug-in connection is to be provided, which allows use in a cooking appliance in everyday kitchen operation. In addition, the microwave connector should be as simple and inexpensive as possible and minimize the susceptibility to interference with ease of use. Also, in the transmission of microwave energy through the connection, the losses should be kept as low as possible.

This object is achieved in that the transmitter unit comprises at least one metallic conductor in conjunction with a metallic λ / 4 structure, the receiver unit comprises at least one metallic conductor in conjunction with a metallic λ / 4 structure, the two λ / 4- Structures, in particular solvable, one another or can be plugged together, and the dielectric as a dielectric coating at least one Part of at least one of the λ / 4 structures, which acts as a metallic substrate, is provided in the abutting or Zusammenstecksteckungsbereich of λ / 4 structures.

It can be provided that the dielectric coating is elastically connected to the metallic substrate.

Furthermore, it can be provided that the dielectric coating is porous.

According to the invention it is also proposed that the dielectric coating is at least partially sealed with a mineral melt for stabilization.

Furthermore, it can be provided that the dielectric coating consists of a ceramic material.

It is also proposed according to the invention that the dielectric coating comprises aluminum oxide.

Furthermore, it can be provided that the dielectric coating essentially completely fills the gap between the λ / 4 structures.

According to the invention, it is proposed that the dielectric coating serves to influence the electric field between the λ / 4 structures.

Preferred embodiments of the invention are characterized in that the transmitter unit comprises a coaxial line with an inner conductor and an outer conductor, wherein the inner conductor and the outer conductor are each designed as a metallic conductor in conjunction with a λ / 4 structure, the receiver unit a coaxial line with an inner conductor and an outer conductor comprises, wherein the inner conductor and the outer conductor are each designed as a metallic conductor in conjunction with a λ / 4 structure, the λ / 4 structures of the inner conductor and / or the λ / 4 structures of the outer conductor or can be plugged together , At least one of the λ / 4 structures of the inner conductor is at least partially provided with a dielectric coating, wherein preferably the λ / 4 structure of the inner conductor of the transmitter unit is at least partially provided with a dielectric coating.

It can be provided that the outer conductor of the transmitter unit and the receiver unit are galvanically connected to each other or the λ / 4 structure of the outer conductor of the transmitter unit is at least partially provided with a dielectric coating.

The invention also proposes that each inner conductor and / or each outer conductor and / or each λ / 4 structure comprises stainless steel and / or copper and / or brass.

Furthermore, it may be proposed that at least one dielectric seal in the transmitter unit and / or the receiving unit galvanically isolate the respective inner conductor from the respective outer conductor, at least in the region of the respective λ / 4 structures.

It is proposed that the dielectric seal terminates the coaxial line of the transmitter unit watertight at least at its end remote from the microwave source, preferably with the interposition of at least one O-ring seal.

Embodiments of the invention may be characterized in that one of the inner conductors is in operative connection with a, in particular pin-like, projection, while the other inner conductor which can be plugged together has a recess adapted to said projection, wherein preferably both the projection have a λ / 4 structure and the

Recess represent a λ / 4 structure.

It can be provided that the projection is part of a contacting, which is positively and / or non-positively connected to the associated inner conductor.

The invention proposes that the dielectric seal be arranged between the contacting means and the outer conductor associated with the associated inner conductor, preferably with the interposition of at least one O-ring seal.

According to the invention can also be provided that the λ / 4 structures of the outer conductor of

Transmitter unit and the receiver unit plugged, in particular flat superimposed, are.

The invention likewise provides a cooking appliance with a cooking chamber, a technical space separated therefrom via at least one cooking chamber wall, and a microwave plug connection according to the invention, in which the transmitter unit is arranged in the cooking space and receiver unit in the cooking space.

It can be provided that the transmitter unit is mechanically, in particular releasably connected to the cooking chamber wall.

The invention again proposes that the λ / 4 structure of the outer conductor of the transmitter unit has a thread.

Finally, according to the invention can also be provided that the receiver unit of an accessory of the cooking appliance, preferably a post for a Garguttragegestell is included.

The invention is thus based on the surprising finding that a microwave plug connection is thermally and mechanically so stable that it can also be used in a cooking appliance for large and commercial kitchens by using a dielectric as one fixed to a metallic substrate which is connected to a (coaxial) Line is connected and has a λ / 4 structure, connected coating is provided and an at least partially galvanic isolation when connecting the (coaxial) line with another (coaxial) line for transmitting microwaves of wavelength λ is used. The further line can also be equipped with such a dielectric coating.

Particularly thermally stable, the compound according to the invention is characterized in that the coating is applied elastically and porous on the substrate. The mechanical stability of the connection can also be increased by the fact that the dielectric coating consists of a ceramic material, preferably aluminum oxide, and is advantageously also sealed with a mineral melt.

When using a microwave connector according to the invention in a cooking appliance with a cooking chamber and a technical room, also called equipment compartment, a garraumseitige receiver unit and / or a technical room side transmitter unit is provided with a dielectric coating. In addition, another dielectric may be arranged on the engineering space side relative to the fluid seal, namely between the inner and outer conductors of the transmitter unit, which galvanically separates the inner and outer conductors of the transmitter unit from one another.

The receiver and transmitter unit according to the invention are designed as parts of a retaining, releasable plug. With the help of a thread in the region of the λ / 4 structure of the outer conductor of the transmitter unit, it can be screwed tightly to a cooking chamber wall. Care must be taken that the thickness of the dielectric coating is suitable for the λ / 4 geometry of the compound.

Figur 1:

eine Längsschnittansicht einer Sendereinheit und einer Empfängereinheit einer erfindungsgemäßen Mikrowellensteckverbindung in nicht gestecktem Zustand; und

Figur 2:

eine Längsschnittansicht der Mikrowellensteckverbindung von Figur 1 in gestecktem Zustand.

Further features and advantages of the invention will become apparent from the following detailed description of a preferred embodiment of the invention with reference to schematic drawings. Showing:

FIG. 1:

a longitudinal sectional view of a transmitter unit and a receiver unit of a microwave connector according to the invention in the unplugged state; and

FIG. 2:

a longitudinal sectional view of the microwave connector of Figure 1 in the inserted state.

FIG. 1 shows a microwave plug connection 100 according to the invention for use in a cooking appliance (not shown) with cooking space walls 10 between a cooking space and a technology room, namely with a garraumseitigen plug in the form of a receiver unit 101 and a plug on the engineering room side in the form of a transmitter unit 102.

In the transmitter unit 102, microwaves of a wavelength λ from a microwave source (not shown) of the microwave plug connection 100 are fed via an incoming coaxial microwave line with outer conductor 12 and inner conductor 13. Via a contacting means 14, the microwaves are supplied from the feeding inner conductor 13 to a transmitter inner conductor 5 with λ / 4 structure, while the outer conductor 12 extends into a transmitter outer conductor with λ / 4 structure. The λ / 4 structures of the transmitter conductors 5, 9 are galvanically and spatially separated from one another by a watertight dielectric 7, with the interposition of an O-ring seal 15. This transmitter unit 102 is fixed to the cooking chamber walls with the aid of a fastening element 11 10 connected. The λ / 4 structure of the transmitter outer conductor 9 has a garraumseitige dielectric coating 8. Likewise, the λ / 4 structure of the transmitter inner conductor 5 has a dielectric coating 6.

On the transmitter unit 102, the receiver unit 101 can be plugged, which in turn has a continuing microwave inner conductor 1 and a continuing microwave outer conductor 3, which are each connected to a receiving λ / 4 structure 3 and 4 respectively.

In Figure 2, the microwave connector 100 is shown in the plugged state, wherein the receiver unit 101 both positive and non-positive, z. B. with the help of a mother, with the transmitter unit 102 may be firmly connected. The geometry of the λ / 4 structures 2, 4, 5, 9, the dielectric coatings 6, 8 and the sealing dielectric 7 are designed so that the incoming into the transmitter unit 102 microwaves can be transmitted as lossless as possible in the receiver unit 101. This is ensured by the adaptation of the geometry of the components to the wavelength of the microwave λ.

The electric and magnetic fields of the microwaves penetrate the non-conductive dielectric layers or coatings 6, 8 and thus transfer their energy from the λ / 4 structures 5, 9 of the transmitter unit 102 to the λ / 4 structures 2, 4 of the receiver unit 101. From there, the microwave energy is guided by the continuing coaxial microwave line 1, 3 further into the cooking chamber interior. Ideally, the coaxial receiver line 1, 2 in the cooking chamber also serves as a support structure of a cooking support structure (not shown), as in the non-prepublished EP 05026912.5 described. The microwave energy can then, as in the non-prepublished DE 10 2006 007 734.2 proposed to be fed with a suitable antenna structure food in the oven.

The coatings 6, 8 of the λ / 4 structures 5, 9 of the transmitter unit 102 can be produced by means of chemical vapor deposition (CVD) or by means of the deposition of a plasma in the form of a porous ceramic (for example aluminum oxide). Such a coating technique is for example in the US 2005/0260411 A1 described. The thus applied dielectric coatings 6, 8 are characterized by a high mechanical hardness and by a high chemical resistance, which corresponds to that of the metallic parts of the microwave connector 100 of z. As copper, iron, brass or stainless steel far exceeds. The application of the porous ceramic layer by means of CVD or plasma techniques achieves a mechanically extremely stable connection of the dielectric ceramic to the metallic substrate, which also has elastic properties. Such elastic connection withstands even the mechanical stresses in the everyday large kitchen operation. Thus, the microwave connector according to the invention can be inserted very often and without much care and pulled apart again. In addition, an operation of the cooking appliance with chemically aggressive substances at high temperatures is possible by the ceramic coating, without the metal of the microwave connector is chemically decomposed. Due to the porous elastic connection with the metallic substrate is further at high heat fluxes by the microwave connector according to the invention, as they are unavoidable when used in cooking appliances and in which heat and cool the substrate and the coating at different speeds or part of the mechanical forces caused by different thermal expansion coefficients of the two materials added. The coatings will thus not flake off the metallic substrate even at high thermal loads.

In a further embodiment according to the invention, the coatings may be coated with a mineral melt which fills the cavities of the porous ceramic and thus an additional stabilization of the dielectric layer is used without disturbing the dielectric properties.

In a further possible embodiment of the invention, both the λ / 4 structures 5, 9 of the transmitter unit 102, and the λ / 4 structures 2, 4 of the receiver unit 101 are provided with a dielectric coating. Alternatively, only the λ / 4 structures of the receiver unit 101 may be coated. In any case, care must be taken that the coatings do not give rise to excessive deviations from the optimum λ / 4 geometry of the microwave connector 100 according to the invention.

The features of the invention disclosed in the foregoing description, in the claims and in the drawings may be essential both individually and in any combination for the realization of the invention in its various embodiments.

LIST OF REFERENCE NUMBERS

1

Continuous microwave inner conductor

2

Lambda quarter structure, receiver inner conductor

3

Continuous microwave outer conductor

4

Lambda quarter structure, receiver outer conductor

5

Lambda quarter structure, transmitter inner conductor

6

dielectric coating of the inner conductor

7

sealing dielectric

8th

Dielectric coating of the outer conductor

9

Lambda quarter structure, sender outer conductor

10

cooking chamber

11

fastener

12

feeding microwave outer conductor

13

feeding microwave inner conductor

14

positive or non-positive contact means

15

poetry

100

Microwave connector

101

Receiver unit / garraumseitiger plug

102

Transmitter unit / technical room side connector

Claims (21)

A microwave plug-in connection (100) comprising a transmitter unit (102) and a receiver unit (101), the transmitter unit (102) being connected to a microwave source for feeding in microwaves of the wavelength λ, the receiver unit (101) for transmitting the microwaves to the transmitter unit (101). 102) and between the transmitter unit (102) and the receiver unit (101) at least partially a dielectric (6, 8) is arranged, characterized in that the transmitter unit (102) at least one metallic conductor (12, 13) in conjunction with a metallic λ / 4 structure (5, 9),
the receiver unit (101) comprises at least one metallic conductor (1, 3) in conjunction with a metallic λ / 4 structure (2, 4),
the two λ / 4 structures (2, 4, 5, 9), in particular detachable, one another or can be plugged together, and
the dielectric as a dielectric coating (6, 8) of at least one part of at least one of the λ / 4-structures (5, 9), which acts as a metallic substrate, in the abutting or mating region of the λ / 4-structures (2, 4 , 5, 9). Microwave connector according to claim 1, characterized in that
the dielectric coating (6, 8) is elastically connected to the metallic substrate. Microwave connector according to claim 1 or 2, characterized in that the dielectric coating (6, 8) is porous. Microwave connector according to one of the preceding claims, characterized in that
the dielectric coating (6, 8) for stabilization is at least partially sealed with a mineral melt. Microwave connector according to one of the preceding claims, characterized in that
the dielectric coating (6, 8) consists of a ceramic material. Microwave connector according to one of the preceding claims, characterized in that
the dielectric coating (6, 8) comprises alumina. Microwave connector according to one of the preceding claims, characterized in that
the dielectric coating (6, 8) substantially completely fills the gap between the λ / 4 structures (5, 9). Microwave connector according to one of the preceding claims, characterized in that
the dielectric coating (6, 8) serves to influence the electric field between the λ / 4 structures (2, 4, 5, 9). Microwave connector according to one of the preceding claims, characterized in that
the transmitter unit (102) comprises a coaxial line having an inner conductor (13) and an outer conductor (12), wherein the inner conductor (13) and the outer conductor (12) are each in the form of a metallic conductor in conjunction with a λ / 4 structure (5, 9 ) are executed,
the receiver unit (101) comprises a coaxial line with an inner conductor (1) and an outer conductor (3), wherein the inner conductor (1) and the outer conductor (3) are each in the form of a metallic conductor in connection with a λ / 4 structure (2, 4 ) are executed,
the λ / 4 structures (2, 5) of the inner conductors (1, 13) and / or the λ / 4 structures (4, 9) of the outer conductors (9, 12) are stackable or can be plugged together, and
at least one of the λ / 4 structures (5) of the inner conductors (1, 13) is provided at least in regions with a dielectric coating (6), wherein preferably the λ / 4 structure (5) of the inner conductor (13) of the transmitter unit (102 ) is provided at least partially with a dielectric coating (6). Microwave connector according to claim 9, characterized in that
the outer conductors (3, 12) of the transmitter unit (102) and the receiver unit (101) are galvanically connected to one another or the λ / 4 structure (9) of the outer conductor (12) of Transmitter unit (102) is at least partially provided with a dielectric coating (8). Microwave connector according to claim 9 or 10, characterized in that each inner conductor (1, 13) and / or each outer conductor (3, 12) and / or each λ / 4 structure (2, 4, 5, 9) stainless steel and / or Copper and / or brass covered. Microwave connector according to one of claims 9 to 11, characterized in that
at least one dielectric seal (7) in the transmitter unit (102) and / or the receiving unit (101) electrically isolates the respective inner conductor (13) from the respective outer conductor (12) at least in the region of the respective / J4 structures (5, 9) , Microwave connector according to claim 12, characterized in that
the dielectric seal (7) terminates the coaxial line of the transmitter unit (102) in a watertight manner, at least at its end remote from the microwave source, preferably with the interposition of at least one O-ring seal (15). Microwave connector according to one of claims 9 to 13, characterized in that
one of the inner conductors (13) is in operative connection with a, in particular pin-like, projection (5), while the other inner conductor (1) which can be plugged together has a recess adapted to said projection (5), preferably both the projection and a λ / 4 Structure (5) and the recess represent a λ / 4 structure (2). Microwave connector according to claim 14, characterized in that
the projection (5) is part of a contacting means (14) which is positively and / or non-positively connected to the associated inner conductor (13). Microwave connector according to claim 15, characterized in that
the dielectric seal (7) is arranged between the contacting means (14) and the outer conductor (12) belonging to the associated inner conductor (13), preferably with the interposition of at least one O-ring seal (15). Microwave connector according to one of claims 9 to 16, characterized in that
the λ / 4 structures (4, 9) of the outer conductors (3, 12) of the transmitter unit (102) and the receiver unit (101) can be plugged onto one another, in particular can be laid flat on one another. Cooking appliance with a cooking chamber, one of them via at least one cooking chamber wall (10) separate technical room and a microwave plug connection according to one of the preceding claims, characterized in that
the transmitter unit (102) in the technical room and the receiver unit (101) are arranged in the oven. Cooking appliance according to claim 18, characterized in that
the transmitter unit (102) is mechanically, in particular releasably, connected to the cooking chamber wall (10). Cooking appliance according to claim 19, characterized in that
the λ / 4 structure (9) of the outer conductor (12) of the transmitter unit (102) has a thread. Cooking appliance according to one of claims 19 to 20, characterized in that
the receiver unit (101) of an accessory of the cooking appliance, preferably a post for a Garguttragegestell is included.

Images