EP1471595A1 - Resonant cavity device converting a transversal dimensional variation, induced by a temperature variation, into a longitudinal dimensional variation - Google Patents

Abstract

The device has a wave guide body with a side wall (1) extending in a longitudinal direction and delimiting a resonant cavity (CR) with two opposite end walls (2, 3). An end wall has a thermal expansion coefficient lower than a thermal expansion coefficient of the side wall. The end wall has an internal face connected to an assembly with a plate (6) having a thermal expansion coefficient lower than the coefficient of sidewall. The assembly has an intermediate unit (7) with a thermal coefficient higher than the coefficient of the plate. The unit (7) has an end part connected to the plate and another end part connected to an internal face of the end wall.

Description

The invention relates to the field of resonant cavity devices.

Certain resonant cavity (s) devices consist of a waveguide body having a side wall extending along a longitudinal direction and delimiting at least one resonant cavity with two opposite end walls.

In order to limit the weight of these devices in applications on board, particularly in the aeronautics field, it is particularly advantageous to manufacture them out of aluminum.

As those skilled in the art know, when these devices are coupled to equipment such as multiplexers (for example of the “Omux” type), they are frequently subjected to temperature variations. It is especially the case when the strength of the signals they receive increases strongly. But, this is also the case in so-called “out of band” operation, that is to say when the signals they receive have a frequency slightly outside the frequency band in which they are supposed function. Therefore, when the resonant cavity is delimited by aluminum walls (with a high coefficient of thermal expansion), it is subject, in the presence of temperature variations, to variations dimensional which induce a frequency shift of its band of frequency.

In order to remedy this drawback, several solutions have been proposed.

A first solution consists in using an aluminum device, and to interrupt its operation when its temperature exceeds a threshold fixed. This eliminates the need to oversize the multiplexer so that it supports out of band operation. But, this requires coupling the resonant cavity device to a thermal control device.

A second solution also consists in using a device in aluminum, and to equip it with a heat dissipation device, such as example of braids. However, this solution turns out to be unsuitable when the resonant cavity device must withstand both high levels of high power and interface temperatures. In addition, this solution leads to overweight.

A third solution consists in using a device whose walls are made of a material with a very low coefficient thermal expansion over a wide temperature range, such as the INVAR (nickel-steel alloy). But, if these materials have a interesting coefficient of thermal expansion, they generally do not offer low weight and / or low cost and / or good thermal conductivity. In addition, resonant cavity devices made entirely of INVAR have reached their limits in the face of power surges and temperatures current interface (this results from the fact that the expansion coefficient INVAR (or CTE) is not zero).

A fourth solution is to use an aluminum device, and to adapt at least one of its end walls. This is particularly the case of the devices described in documents US 6,002,310 and EP 1187247. More specifically, the device described in document US 6,002,310 includes an end wall fitted with a first INVAR wall, the part of which central has been thinned, and a second aluminum wall, shaped domed, secured to the thick peripheral edge of the first wall end. When a temperature variation occurs, the second wall bulging expands in its central part which increases its bulging and forces the first INVAR wall to flex, thus amplifying the phenomenon bulging. The device described in document EP 1187247 proposes a substantially equivalent solution. Catching up on variations dimensions of the devices described in these two documents are limited in amplitude, which limits the Omux power and interface temperature to which they are coupled.

No known device therefore provides complete satisfaction.

The invention therefore aims to improve the situation.

To this end, it offers a device with a resonant cavity, comprising a waveguide body comprising a side wall, which extends along a longitudinal direction (perpendicular to a transverse plane), presenting a first coefficient of thermal expansion and delimiting a resonant cavity with first and second opposite end walls and substantially contained in transverse plans.

This device is characterized by the fact that its first wall end has a second coefficient of thermal expansion strictly lower than the first coefficient and includes an internal face secured to a first assembly comprising at least one main transverse plate, having a third coefficient of thermal expansion, strictly lower than the first, and of dimensions, in the transverse plane, substantially equal, by lower values, to those of the cavity, and an element intermediate with a fourth coefficient of thermal expansion strictly higher than the third, with an end part fixedly secured to the main plate and arranged, when a temperature variation, to transform its dimensional variations in the transverse plane in a dimensional variation according to the direction longitudinal, which induces a longitudinal translation of the main plate to inside the cavity.

By acting in a similar way to a "piston", the element intermediate causes the displacement of the main plate to which it is joined together, thus making it possible to compensate for the dimensional variations of the resonant cavity.

In a first embodiment, the device can include at least a second set, preferably substantially identical to the first set, and secured to the latter at its plate main. In other words, several sets can be installed in serial when the device is likely to be subject to strong variations dimensional.

In a second embodiment, the device can include a first set comprising at least two intermediate elements substantially identical and joined to each other, for example by a outer ring which has the third coefficient of thermal expansion. The intermediate element furthest from the first end wall is then secured by its end portion to the main plate. This allows also to compensate for strong dimensional variations.

Furthermore, the first set can be secured to the first end wall by its intermediate element. But, we can also provide an intermediate plate interposed between the first assembly, to which it is secured, and the first end wall, to which it is secured. In this case, the intermediate plate has the third coefficient of thermal expansion and dimensions in the transverse plane substantially equal, by lower values, to those of the cavity. This intermediate plate can itself be secured to the first wall end through a shim plate having preferably the fourth coefficient of thermal expansion and substantially equal dimensions in the transverse plane, by values lower than those of the cavity. This advantageously makes it possible to control the center frequency of the frequency band of the resonant cavity.

In addition, the side wall can be secured to the first or second end wall via at least one shim chosen.

Preferably, each intermediate element comprises a central part extended by first and second peripheral edges inclined at selected angles, on either side of a transverse plane containing the central part, by defining a peripheral groove, by “V” shaped example. Each peripheral edge can then include an end part secured to the main plate, the plate intermediate or the first end wall, opposite which it is located. In addition, each main plate and / or each plate intermediate and / or the first end wall may include a stop longitudinal device against which the end portion of the peripheral edge to which it is secured.

Also preferably, the side wall and / or the second wall end and / or each intermediate element and / or each plate of wedging is made of aluminum. Similarly, the intermediate plate and / or the first end wall and / or each block and / or each main plate can be made of an alloy of nickel and steel, of the INVAR type.

• la figure 1 illustre de façon schématique, dans une vue en coupe longitudinale, un premier exemple de réalisation d'un dispositif à cavité résonnante selon l'invention,
• la figure 2 illustre de façon schématique, dans une vue en coupe longitudinale, un deuxième exemple de réalisation d'un dispositif à cavité résonnante selon l'invention,
• la figure 3 illustre de façon schématique, dans une vue en coupe longitudinale, un troisième exemple de réalisation d'un dispositif à cavité résonnante selon l'invention, et
• la figure 4 illustre de façon schématique, dans une vue en coupe longitudinale, un quatrième exemple de réalisation d'un dispositif à cavité résonnante selon l'invention.

Other characteristics and advantages of the invention will appear on examining the detailed description below, and the attached drawings, in which:

• FIG. 1 schematically illustrates, in a longitudinal section view, a first embodiment of a device with a resonant cavity according to the invention,
• FIG. 2 schematically illustrates, in a longitudinal section view, a second embodiment of a device with a resonant cavity according to the invention,
• FIG. 3 schematically illustrates, in a longitudinal section view, a third embodiment of a device with a resonant cavity according to the invention, and
• FIG. 4 schematically illustrates, in a longitudinal section view, a fourth embodiment of a device with a resonant cavity according to the invention.

The attached drawings may not only serve to complete the invention, but also contribute to its definition, if necessary.

The object of the invention is to allow compensation for variations induced in a resonant cavity device by temperature variations.

In what follows, we will consider that the resonant cavity device equips an “Omux” type multiplexer (or “Output multiplexer”), and that is intended to filter microwave signals. For example, the device provides filtering on a 54 MHz frequency band. We also considers in what follows that the resonant cavity is of tubular shape (circular cylindrical). However, the invention is not limited to this single type of cavity. It also concerns the resonant cavities of section transverse rectangular or elliptical. In addition, in the following, the elements which bear identical references perform functions that are substantially identical.

We first refer to Figure 1 to describe a first mode for producing a resonant cavity device according to the invention.

The resonant cavity device D includes a waveguide body having a side wall 1, which extends in a longitudinal direction OX and delimits a resonant cavity CR with first 2 and second 3 opposite end walls and substantially contained in planes transverse (perpendicular to the direction OX and parallel to the direction OY).

The resonant cavity CR here being of circular cylindrical shape, the side wall 1 therefore defines a circular cylinder while the first 2 and second 3 end walls are disc-shaped.

The side wall 1 has a first coefficient of expansion thermal (CTE1). It is for example made of aluminum. The first one end wall 2 has a second coefficient of thermal expansion (CTE2) strictly lower than the first coefficient CTE1, and preferably close to zero. It is for example made of INVAR (alloy nickel-steel). Finally, the second end wall 3 presents the first coefficient of thermal expansion (CTE1). It is for example carried out in aluminum.

The side wall 1 has at each of its two opposite ends a transverse edge allowing its attachment to the first 2 and second 3 end walls, for example via a bolt 4.

In this example, the second end wall 3 has a opening 5 allowing both input and extraction of signals microwave frequencies to be filtered. Of course, access to the resonant cavity CR could be provided on the side wall 1.

The device according to the invention D also comprises at least one first set E1 comprising, on the one hand, a main plate transverse 6, having a third coefficient of thermal expansion CTE3, strictly lower than the first CTE1, and of dimensions in the plane transverse substantially equal, by lower values, to those of the cavity resonant CR, and on the other hand, an intermediate element 7 having a fourth coefficient of thermal expansion CTE4, strictly greater than third CTE3, comprising a first end portion 8 secured fixed to the main plate 6 and a second end portion 9 fixedly fixed to an internal face (oriented towards the inside of the cavity CR) of the first end wall 2.

The resonant cavity CR here being of circular cylindrical shape, the main plate 6 is in the shape of a disc of diameter L.

Preferably, the first CTE1 and fourth CTE4 coefficients thermal expansion are identical. For example, the intermediate element 7 is made of aluminum. Likewise, the second CTE2 and third CTE3 thermal expansion coefficients are preferably identical. Through example, the main plate 6 is made of INVAR.

The intermediate element 7 has a longitudinal extension h and is specifically arranged to transform its variations dimensional ΔL (expansion) in the transverse plane, induced by a temperature variation, in a dimensional variation Δh depending on the OX longitudinal direction.

Due to the attachment of the intermediate element 7 to the plate main 6, the dimensional variation Δh in the longitudinal direction OX causes the longitudinal translation of the main plate 6 inside of the resonant cavity CR. In other words, the greater the variation dimension ΔL of the intermediate element 7 is large, the more its variation dimensional Δh is important and therefore more the amplitude of the translation longitudinal of the main plate 6 is large. This allows to control the dimensional variations of the resonant cavity CR, so that its central operating frequency remains appreciably constant over a selected temperature range.

We can roughly define an equivalent of coefficient of thermal expansion CTE _eq for the set E1 by the following formula: CTE eq = CTE4 + (L / h) * CTE4

This formula shows that the compensation is all the more more efficient than the L / h ratio is large.

In the example illustrated in Figure 1, the intermediate element 7 has a central part 10 extended by first 11 and second 12 peripheral edges (here circular) inclined at angles chosen on either side and on the other side of a transverse plane containing the central part 10, defining a peripheral throat.

The angles are preferably identical. They are chosen in depending on the amplitude of the desired translation. For example, each angle is a few tens of degrees, typically 20 ° to 45 °.

The peripheral groove has for example a section in the form of "V". But, it can also be in the shape of a crescent moon, or "U" open, and the like.

The peripheral edges 11 and 12 are each terminated by one of the transverse end portions 8, 9, respectively secured to the plate main 6 and at the first end wall 2.

Furthermore, in order to strongly constrain the intermediate element 7 to transform its dimensional variations ΔL into dimensional variations Δh, the main plate 6 and the first end wall 2 have preferably each a circular longitudinal peripheral stop 13 against which the end portion 8 or 9 of the peripheral edge 11 rests or 12 to which it is attached.

We now refer to Figure 2 to describe a second mode for producing a resonant cavity device according to the invention.

This embodiment is a variant of the first embodiment. embodiment, described above with reference to FIG. 1, in which the first set E1 ′ does not have a single intermediate element, but two 7a and 7b.

More specifically, in this embodiment, a first element intermediate 7a is secured, on the one hand, by its peripheral edge 11 to the main plate 6, and on the other hand, by its peripheral edge 12 at the edge peripheral 11 of a second intermediate element 7b, the other edge of which peripheral 12 is secured to the internal face of the first wall end 2. Preferably, the peripheral edges 12 and 11, respectively intermediate elements 7a and 7b, are joined by a outer ring 17 which has the third coefficient of expansion thermal. For example, this ring 17 is made of INVAR.

Also preferably, the intermediate elements 7, thus mounted in series, are substantially identical. But this is not compulsory.

This embodiment compensates for large variations dimensional. Of course, the number of intermediate elements 7 constituting the first set E1 ′ may be different from two.

We now refer to Figure 3 to describe a third mode for producing a resonant cavity device according to the invention.

This embodiment includes a first set E1, substantially identical to that described above with reference to the figure 1, secured to a second set E2, also consisting of a plate main 6-2 secured to an intermediate element 7-2.

More specifically, in this embodiment, on the one hand, the edge peripheral 12 of the intermediate element 7-1 of the first set E1 is secured to an internal face of the main plate 6-2 of the second set E2, and on the other hand, the peripheral edge 12 of the intermediate element 7-2 of the second set E2 is secured to the internal face of the first wall end 2.

Preferably, and as illustrated, the main plate 6-2 also has on its internal face a second peripheral stop longitudinal circular 13 against which the end portion 9 of the peripheral edge 12 of the intermediate element 7-1.

Preferably, apart from this second stop 13, the assemblies E1 and E2, thus connected in series, are substantially identical. But this is not not mandatory.

This embodiment also makes it possible to compensate for strong dimensional variations. Of course, the number of sets mounted in series may be different from two.

We now refer to Figure 4 to describe a fourth mode for producing a resonant cavity device according to the invention.

This embodiment is a variant of the third embodiment. embodiment, described above with reference to FIG. 3, in which checks the longitudinal dimension of the resonant cavity CR using a or several shims 14 of selected thicknesses, of a shim plate 15 of selected thickness and / or of an intermediate plate of selected thickness 16.

More specifically, in this embodiment, one or more several shims 14 produced in the form of washers whose thicknesses are chosen according to the central operating frequency of the resonant cavity and the height of the sets E1 and E2 and the sum of their amplitudes of longitudinal displacement Δh. These washers 14 are for example interposed between the first end wall 2 and one of the transverse edges of the side wall 1. But, they could be placed at the other end of the resonant cavity CR, between the second wall end 3 and the other transverse edge of the side wall 1 or else level of each end.

Each wedge 14 is preferably made of a material with a very low coefficient of thermal expansion, such as the INVAR example.

A wedging plate 15 is also provided, of a firstly, to the internal face of the first wall 2, and secondly, to a face (external) of an intermediate plate 16, the internal face of which is secured to the end portion 9 of the peripheral edge 12 of the intermediate element 7-2 of the second set E2.

The timing plate 15 is preferably made of aluminum (high CTE material).

Furthermore, in order to constrain the intermediate element 7-2 to efficiently transform its transverse dimensional variations ΔL into a longitudinal dimensional variation Δh, the intermediate plate 16 is preferably substantially identical to a main plate 6, both by its dimensions only by its longitudinal peripheral stop 13 and by the material in which it is made.

In the foregoing, it was a question of a device D equipped with a single resonant cavity CR. But, we can consider coupling longitudinally head to tail two D devices to form a single device with two resonant cavities. In this case, the two cavities resonant communicate through the adapted opening 5 and at least one other opening is provided on the side wall 1 to allow entry and output of signals inside said resonant cavities.

The invention is not limited to the embodiments of device to resonant cavity (ies) described above, only by way of example, but it includes all the variants that a person skilled in the art will be able to envisage in the The scope of the claims below.

Claims (16)

Resonant cavity device (D), comprising a waveguide body comprising a side wall (1), extending in a longitudinal direction, having a first coefficient of thermal expansion and delimiting a resonant cavity (CR) with a first (2) and a second (3) opposite end walls, characterized in that said first end wall (2) has a second coefficient of thermal expansion strictly less than said first coefficient and comprises an internal face secured to a first assembly (E1) comprising at least one main plate (6), having a third coefficient of thermal expansion, strictly less than the first, and of dimensions, in a plane perpendicular to said longitudinal direction, substantially equal, by values less than those of the cavity, and an intermediate element (7) having a fourth coefficient of thermal expansion, strictly greater than the third me, comprising an end portion (8) fixedly secured to said main plate (6) and arranged, in the event of temperature variation, to transform a dimensional variation in a direction perpendicular to the longitudinal direction into a dimensional variation in said direction longitudinal inducing a longitudinal translation of said main plate (6) inside said cavity (CR). Device according to claim 1, characterized in that it comprises at least a second assembly (E2), also comprising a main plate (6-2) secured to an intermediate element (7-2) and to the intermediate element (7 -1) of said first set (E1). Device according to claim 2, characterized in that said second set (E2) is substantially identical to said first set (E1). Device according to claim 1, characterized in that said first assembly (E1 ') comprises at least two intermediate elements (7a, 7b) substantially identical and secured to one another, the intermediate element (7a) the most distant of said first end wall (2) being secured by its end portion (8) to said main plate (6). Device according to claim 4, characterized in that said intermediate elements (7a, 7b) are joined two by two by an outer ring (17) having said third coefficient of thermal expansion. Device according to one of claims 1 to 4, characterized in that said first assembly (E1, E1 ') is secured to said first end wall (2) by its intermediate element (7). Device according to one of claims 1 to 4, characterized in that it comprises an intermediate plate (16) having said third coefficient of thermal expansion, of dimensions, in a plane perpendicular to said longitudinal direction, substantially equal, by values lower than those of the resonant cavity (CR), and interposed between said first assembly (E1), to which it is secured, and said first end wall (2), to which it is secured. Device according to claim 7, characterized in that said intermediate plate (16) is secured to said first end wall (2) by means of a wedging plate (15) having said fourth coefficient of thermal expansion and of dimensions, in a plane perpendicular to said longitudinal direction, substantially equal, by lower values, to those of the resonant cavity (CR), and in that said side wall (1) is secured to said first (2) or second ( 3) end wall by means of at least one shim (14) of selected thickness. Device according to one of claims 1 to 8, characterized in that each intermediate element (7) has a central part (10) extended by a first (11) and a second (12) peripheral edges inclined at selected angles, of on either side of a plane containing said central part (10), defining a peripheral groove. Device according to claim 9, characterized in that said peripheral groove has a cross section substantially in the form of a V. Device according to one of claims 9 and 10, characterized in that each peripheral edge (11,12) has an end portion (8,9) secured to the main plate (6), intermediate plate (16) or first end wall (2) opposite which it is located. Device according to claim 11, characterized in that each main plate (6) and / or each intermediate plate (16) and / or said first end wall (2) comprises at least one longitudinal peripheral stop (13) against which s 'supports the end portion (8,9) of the peripheral edge (11,12) to which it is secured. Device according to one of claims 1 to 12, characterized in that said first and fourth coefficients of thermal expansion are identical. Device according to one of claims 1 to 13, characterized in that said second and third coefficients of thermal expansion are identical. Device according to one of claims 1 to 14, characterized in that said side wall (1) and / or said second end wall (3) and / or each intermediate element (7) and / or each shim plate ( 15) is made of aluminum. Device according to one of claims 1 to 15, characterized in that said intermediate plate (16) and / or said first end wall (2) and / or each shim (14) and / or each main plate (6) is made of an alloy of nickel and steel, in particular INVAR.

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