SE520207C2 - Tuning assembly for dielectric resonator in a cavity, has support element with a tubular sleeve and radial outer support to clamp one resonator body and sleeve allowing movement of second resonator - Google Patents

Abstract

The tuning assembly uses a first support element with a tubular sleeve (33) and a radially outer support to clamp one of the two resonator bodies (21) axially between the sleeve and the outer support. A second support includes a shaft radially journalled by bearings in the sleeve and in a region located axially inside the mounting wall and carrying at its end a second of the two resonator bodies. Independent claims describe a tuning assembly and a filter.

Description

Filters comprising a plurality of adjacent cavities, each having a dielectric resonator and a plastic resonator support. The resonator support is mounted in only one mounting wall.

Thus, in contrast to many similar support structures, this support structure is not guided or stored in the opposite wall of the housing. A tuning device of the latter type is described in WO98756062 (Allgon AB).

In an embodiment shown in Figures 8-10, in the first-mentioned document WO97 / 02617, the electric resonator comprises two cylindrical resonator bodies in the form of circumferential annular elements, a stationary and a movable, both elements of which are made of ceramic material. with low losses and high electricity constant. The first, stationary resonator body is mounted on a plastic support in the form of a cylindrical sleeve with a plurality of elongate recesses and openings which make the support structure somewhat flexible. At the inner end, which is placed inside the cavity, the sleeve is cut out to form a plurality of spaced apart retaining elements or arms projecting from a shoulder. When mounting the first stationary resonator body on the plastic support, it is pushed with its central axial hole on the diverging arms.

When the first, stationary resonator body reaches a position where it abuts against the shoulder of the plastic support, the arms snap radially outwards and engage with inclined abutment surfaces against the upper or inner surface of the cylindrical resonator body, so that the latter is held with clamping action between the inclined abutment surfaces and the shoulder . In this way, the first resonator body will be held stationary by the plastic support.

The second resonator body, on the other hand, is attached to an adjusting shaft which is mounted so as to extend through the mounting opening and axially within the supporting 235485e.dOC; 01-12-12 10 15 20: '25 30 520 207 cylindrical sleeve. The adjusting shaft is threaded at its axially outer portion and is rotatable so that it performs a linear movement relative to the plastic support and the first, stationary resonator body. The rotational movement can be effected by means of a knurled outer head on the shaft, or automatically by means of a stepper motor. The adjustment can thus be performed with such a movement of the adjustment shaft and a concomitant displacement of the second resonator body relative to the first resonator body.

However, the plastic material of the support structure, which is necessarily somewhat flexible to enable the desired snap-fit of the first resonator body, will inevitably make the mounting of the first resonator body somewhat resilient and not very precise in the fixed position. Furthermore, the adjusting shaft, which extends freely inside the support sleeve, will adjust itself with a small angle of inclination relative to the support sleeve, so that the second resonator body will be inclined relative to the first resonator body.

Consequently, the mounting of the first resonator body on the support structure is not very accurate, and the setting can only be made approximate. Thus, at a given rotational movement of the setting axis, the relative positions of the first and second resonator bodies may vary slightly, resulting in a corresponding change in the resonant frequency.

SUMMARY OF THE INVENTION Against this background, the main object of the invention is to provide a tuning device which is more precise in the tuning process so that a given adjusting movement results in a predetermined, accurate resonant frequency. 23548se.doc; 01-12-12 10 15 20 25 30 520 207? “Ïï? ¥ @ å = íï Another object is to provide a tuning device which is easy to manufacture and assemble.

A further object is to provide a construction of the tuning device which ensures efficient heat transfer from the dielectric resonator to the surroundings of the cavity.

The stated main object is achieved for a tuning device comprising: a mounting wall, which forms at least a part of said cavity walls and has an inside, which delimits the cavity, and an outside provided with a tuning adjusting device, a support structure, which is mounted in an opening in said mounting wall for supporting said two resonator bodies on the inside of the mounting wall, the support structure comprising two mutually displaceable support elements, each made of rigid material, namely a first support element, which comprises a tubular sleeve portion and a radially outer support member for clamping a first of said resonator bodies axially between the tubular sleeve portion and the radially outer support member, and a second support member comprising a shaft radially mounted by means of bearing means within the tubular sleeve portion, at least in an area located axially within the mounting wall, and at an end portion up carrying a second of said two resonator bodies, one of said two mutually displaceable support elements being kept stationary relative to said mounting wall, while the other of said two displaceable support elements is axially movable by means of said tuning device on the outside of the mounting wall, 23548se, doc; 01-12-12 10 15 20 fzs 30 520 2ow „{ïff * å« ï¿ <åÜ - whereby said two displaceable support elements are kept precisely set in relation to each other, and the two resonator bodies are precisely positioned in relation to each other for tuning a resonant frequency of the dielectric resonator.

Consequently, the frequency tuning can be done very accurately, and the relative positions of both resonator bodies are kept accurate, even if the device is disturbed by vibrations or other movements. Nevertheless, the manufacture of the tuning device and the assembly of the various parts is relatively cheap and easy to carry out in practice.

It is essential that the shaft is mounted precisely through the bearing means inside the tubular sleeve portion, at least in the area axially inside the mounting wall, so that the shaft and the tubular sleeve portion, and thus also the two displaceable support elements, are kept aligned exactly relative to each other.

In order to achieve improved stability, the radially outer support member of the first support element is preferably placed radially outside the tubular sleeve portion, for example in the form of an outer sleeve. The latter is advantageously thermally conductive for dissipating heat generated in the first resonator body to the mounting wall.

A practical way of providing an axial clamping force between the tubular sleeve portion and the radially outer support member is to mount the tubular sleeve member slidably in the mounting wall opening and to apply a resilient force outside the opening, for example by means of a spring element so that the tubular outer sleeve force on the first resonator body against the radially outer support member.

Alternatively, the radially outer support member, 23548Se.d0C; 01-12-12 10 15 20 25 30 szo zovåxi fl hïšfáfi * for example in the form of an outer sleeve, be spring-loaded to exert an axial force on the first resonator body, which is thereby held securely in a stationary position by means of the tubular sleeve portion. In such a case, the latter serves as an appropriation element. In case the support structure comprises a central sleeve portion and an outer support sleeve at a radial distance from the central tubular sleeve portion, the first resonator body will of course be held securely without allowing any tilting or tilting movements. The first resonator body thus assumes an exact, well-defined stationary position at a distance from the inside of the mounting wall in the cavity. Since the second resonator body is retained in position by the central bearing of the shaft, which serves as the adjusting shaft, inside and along the tubular sleeve portion, the first and second resonator bodies will be held exactly in position relative to each other.

In another possible embodiment, the second support element, which supports the second resonator body, is kept stationary, while the first support element, which supports the first resonator body, is axially movable relative to the mounting wall and the second support element.

Additional advantageous features are set out in the claims and will also be apparent from the following detailed description.

The invention is explained in more detail below with reference to the accompanying drawings, which illustrate some preferred embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 shows in a central cross-sectional view a cavity provided with an electric resonator and a tuning device according to a first embodiment of the invention; 23548se.doc; 01-12-12 10 15 20 §2s 520 207 äfïï%? “... MM w. W.

Fig. 2 shows in a partial cross-sectional view a tuning device according to a second embodiment of the invention; and Fig. 3 likewise shows in a partial cross-sectional view a tuning device according to a third embodiment of the invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS The device shown in Figure 1 is located in a cavity 10, which may be cylindrical or sound-like and defined by sleeve or cavity walls, including side walls 11, 12, 13, and a top wall or a lid which later serves as a mounting wall for mounting a tuning device with a support structure 30 for supporting an electric resonator 20 in the cavity. To connect the resonator 20 to a supply network or the like, inductive coupling loops 15 are arranged in the cavity 10. Depending on the application in question, other means can be used for excitation of an electromagnetic field inside the cavity with the resonator.

The dielectric resonator 20 includes a first, stationary resonator body 21, and a second, movable resonator body 22. The two resonator bodies are made of a material having low dielectric losses and have a relatively high dielectric constant, typically a ceramic material, as is well known to those skilled in the art. in this area.

In the embodiment shown, the first resonator body 21 has a cylindrical shape with a central axial hole 21a, which is likewise cylindrical. In the area of this central hole 21a, the first resonator body 21 is fixedly fixed to a tubular sleeve portion 31 with an outer cylinder surface which fits in the axial hole 21a. An axial locking therebetween provides 23548Se.dOC; 01-12-12 10 15 20 25 30 «. ~, f. is obtained by means of a washer 32, which is fitted in opposite grooves in the resonator 21 and the tubular sleeve portion 31, respectively.

The tubular sleeve portion 31 forms a part of a first support element 30 which has another part in the form of an outer sleeve element 33, the two parts 31, 33 being axially movable relative to each other in order to clamp the first resonator body 21 axially in between. In the exemplary embodiment shown, the tubular sleeve portion 31 is slidably mounted in a cylindrical opening 14a in the mounting wall and is axially loaded (upwards in the drawing) by means of a helical spring 40 of metal acting between the outside of the mounting wall 14 and a bearing washer 34 inserted in a groove on the end portion of the tubular sleeve portion 31.

Accordingly, the tubular sleeve portion 31 is spring-loaded so as to exert an axial clamping force on the first resonator body 21 against the outer sleeve member 33 located axially between the first resonator body and the mounting wall 14 in the housing. The outer sleeve element 33 acts as an abutment and spacer element. In order to achieve good stability and to ensure well-defined fixation of the first resonator body 21, the outer sleeve portion 33 has a much larger diameter than the central sleeve portion 31 so that the circular abutment surface is located at a substantially radial distance from the circumference of the tubular sleeve portion 31.

In principle, the outer sleeve element 33 can be replaced by a number (preferably three or more) of separate spacer elements, which extend axially between the first resonator body 21, preferably in the vicinity of the latter periphery, and the inside of the mounting wall 14. Furthermore, the central tubular sleeve portion 31 be axially fixed, in which case the outer sleeve element 33 or the corresponding optionally separate 23548se.doc; Support members must be movable and mechanically loaded so that they exert an axial force on the first resonator body 21 (downwards in the drawing).

The second resonator body 22 is formed as a circular disk with a central hole 22a and is fixedly connected to the end portion of an adjusting shaft 35 which is slidably fitted within the tubular sleeve portion 31. The outer diameter of the shaft 35 is precisely dimensioned to form a bearing surface and secure providing a good fit with respect to the inner cylindrical surface of the tubular sleeve portion 31. In this way, the shaft 35 will be adjusted exactly with respect to the longitudinal axis of the tubular sleeve portion 31, regardless of its axial position. It is important that the two resonator bodies are precisely set and have no possibility of shifting during the operation of the device, which could change the precisely set resonant frequency. In order to avoid metallic fitting details, which could be heated to very high temperatures by the electromagnetic field, or an adhesive or other adhesive, which could age after long use, the second resonator body 22 is axially clamped between two concentric tube elements 36, 37, which together form the adjusting shaft 35 or the second support element.

The inner tube element 37 is slidable with sliding fit inside the outer tube element 36, and the two elements 36, 37 are axially spring-loaded by means of a metallic helical spring 38 arranged on the outer end portion of the shaft 35 outside the mounting wall 14. Thus the second resonator body is kept 22 central part, next to its central hole 22a, axially clamped between abutment surfaces on respective pipe elements 36, 37.

In use, the parts 22, 36 and 37 are held together as a unit and are axially displaceable within the stationary tube; 01-12-12 10 15 20 425 520 20? ¥ ïífïš ,? V | »,, In the shaped sleeve portion 31. In order to achieve a desired tuning of the device, this unit can be displaced axially and / or in the direction of rotation either manually or automatically.

For example, a threaded spindle on a stepper motor may engage an internal screw thread on the inside of a nut 39 attached to the upper end of the adjusting shaft 35 so that the shaft is displaced as desired, normally by a linear movement. Alternatively, the adjusting shaft can be rotated so that it causes the movable resonator body to perform an axial displacement movement by engaging the stationary resonator body by means of a helical surface, as described in Swedish patent application No. 9802191-8.

In the second embodiment shown in Figure 2, the geometric shape of the dielectric resonator is different. The first stationary resonator body 21 'has a cylindrical recess 21'b at the part facing away from the mounting wall 14, and the second, movable resonator body 22' has a smaller outer diameter, so that it is freely displaceable in the cylindrical recess 21'b. The stationary resonator body 21 'is attached to the sleeve portion 31' by means of the flange 31'a. Otherwise, the embodiment shown in Figure 2 is the same as that shown in Figure 1.

In the third embodiment, which is shown in Figure 3, the first resonator body 21 is axially movable, while the second resonator body 22 is held in a stationary position by means of the tube elements 36, 37, which are fixed by means of a rigid housing element 16 attached to the outside of the mounting wall 14. The inner tube member 37 extends through an opening 16a in the housing member 16 and is spring loaded upwardly by a helical spring 38 so as to exert a clamping force, at its inner end in the cavity, on the second resonator body or disk 22. 23548Se.d0C; 01-12-12 10 15 20 25 520 2 @? Ï? F “* Ä. . -. 1. The sleeve element 31, which holds the first, circular-cylindrical resonator body 21, is in this case directly enclosed by the radially outer support sleeve 33. The latter is slidably fitted in the opening 14a of the mounting wall 14, so that the sleeves 31, 33 are axially movable as a unit together with the resonator body 21. This unit can be displaced axially, for example by a rotational movement, during engagement with threads on the outside of the sleeve 33 and the inside of the hole 14a.

In all three embodiments, the various sleeve elements 31, 33, 36 shall be made of a material which exhibits low dielectric losses and high thermal stability, such as quartz or alumina. In particular, the outer sleeve element 33, which is also used for heat conduction, is preferably made of alumina which exhibits high thermal conductivity. The inner tube member 37 may be made of the desired material with low losses such as quartz, alumina or PTFE.

Of course, all modifications of the embodiments shown may be made by those skilled in the art within the scope of the claims. For example, the tubular sleeve element 31 can be integrated with the first resonator body 21, 21 'so that they form a single piece. The same applies to the sleeve 36 and the second resonator body 22, 22 '.

The spring load by means of helical spring element of metal can alternatively be provided by means of a resilient o-ring made of silicone rubber or the like.

Furthermore, the mounting wall 14, or a central part thereof, can be axially displaceable in relation to the rest of the housing 11, 12, 13 in order to achieve fine adjustment. 23548se.dOC; 01-12-12

Claims (29)

520 2u7å @ ¥ ïëï 12 PATENT REQUIREMENTS A tuning device for tuning a dielectric resonator (20) in a cavity delimited by cavity walls, the dielectric resonator comprising two resonator bodies, namely a stationary resonator body (21) and a movable resonator body (22), both resonator bodies being produced of a material with low losses and high dielectric constant, the tuning device comprising: a mounting wall (14), which forms at least a part of one of said cavity walls and has an inside, which delimits the cavity, and an outside provided with a tuning adjusting device (35, 39), a support structure (30) mounted in an opening in said mounting wall for supporting said two resonator bodies on the inside of the mounting wall, the support structure comprising two mutually displaceable support elements, each of which is made of rigid material, namely a first support element, which comprises a tubular sleeve portion (31) and a radius an outer support means (33) for clamping a first of said resonator bodies axially between said tubular sleeve portion and the radially outer support member, and a second support member, comprising a shaft (35) radially mounted by bearing means within said tubular sleeve portion (31) , at least in an area located axially inside said mounting wall, and at an end portion a second (22) of said two resonator bodies, 23548se.doc; 01-12-12 10 15 20 25 30 520 zovf fi íï fl f 13 - wherein one (31,33) of said two mutually displaceable support elements is kept stationary in relation to said mounting wall, while the other (36, 37) of said two mutually displaceable support elements is axially movable by means of said tuning adjusting device on the outside of said mounting wall, - whereby said two displaceable support elements are kept precisely set relative to each other, and the two resonator bodies (21, 22) are exactly positionable relative to each other for tuning a resonant frequency of the dielectric the resonator. A tuning device according to claim 1, wherein said radially outer support member (33) is located at a radial distance from said tubular sleeve portion. Tuning device according to claim 2, wherein - said second support element (36, 37) is axially movable, - said first support element (31, 33) is kept stationary, - said tubular sleeve portion (31) is slidably mounted in said mounting wall opening and is axially spring-loaded on the outside of said mounting wall so as to exert an axial clamping force on said first resonator body against said mounting wall, and - said outer support means (33) serve as abutment and spacers for retaining said first resonator body in stationary position. A tuning device according to claim 2, wherein said radially outer support means is constituted by a cylindrical sleeve (33). The tuning device according to claim 1, wherein said radially outer support member (33) is made of a dielectric material having good thermal conductivity and is 2354BSeJ fl OC; 01-12-12 10 15 20 25 520 207 ¥ äÉÄf ¥ f | . f §, | . . . , i. 14 dimensioned to transfer heat generated in said first resonator body to said mounting wall. The tuning device of claim 1, wherein said first resonator body (21) is circular-cylindrical with a central axial hole (21a). A tuning device according to claim 6, wherein said tubular sleeve portion (31) is a separate body attached to said first resonator body (21) in said central axial hole. A tuning device according to claim 1, wherein said shaft (35) is tightly fitted within said tubular sleeve portion (31) by means of mutually abutting cylinder surfaces. A tuning device according to claim 8, wherein said abutting cylinder surfaces extend along substantially the entire axial length of said tubular sleeve portion (31). The tuning device of claim 1, wherein - said shaft (35) comprises two concentric cylindrical tubular members (36, 37) slidable one inside the other, and - said second resonator body (22) is axially clamped between said two concentric pipe elements. The tuning device of claim 1, wherein said movable resonator body is in the form of a circular disk (22), The tuning device of claim 11, wherein said stationary resonator body (21) is circular-cylindrical with substantially the same outer diameter as said circular disk (22). The tuning device of claim 1, wherein - said second support member (36, 37) is poured stationary, and 23548se.dOC; 01-12-12 10 15 20 25 30 520 207 15 - said first support element (31, 33) is axially movable in relation to said mounting wall and said second support element. A tuning device according to claim 13, wherein said radially outer support means is an outer sleeve (33) enclosing said tubular sleeve portion and movable through said mounting wall opening (14a). A tuning device according to claim 14, wherein said outer sleeve (33) is connected to said tuning adjusting device on the outside of said mounting wall. A tuning device according to claim 14, wherein said outer sleeve (33) and said tubular sleeve portion (31) are axially clamped to said first dielectric resonator body (21) by means of a spring element (40) located on the outside of said mounting wall (14). A tuning device for tuning a dielectric resonator (20) in a cavity (10) defined by cavity walls (11-14), the dielectric resonator comprising two resonator bodies, namely a first stationary resonator body (21) and a second, movable resonator body (22). ), both resonator bodies being made of a material with low losses and a high dielectric constant, the tuning device comprising: - a mounting wall (14) forming at least a part of one of said cavity walls and having an inside defining said cavity and an outside provided with a tuning adjusting device (35, 39), - a support structure (30) mounted in an opening (14a) in said mounting wall for supporting said two resonator bodies on the inside of the mounting wall, said support structure comprising two mutually displaceable 23548se.doc; 01-12-12 10 15 20 125 520 2o7> ¶§} §¿ ,, i .. 16 support elements, each of which consists of rigid material, namely - a first support element comprising two parts (31, 33) which are arranged holding said first resonator body in a stationary position by means of an axial clamping force, one part comprising a tubular sleeve portion (31) attached to said first resonator body (21), and - a second support element comprising an adjustable shaft (35) which is attached to said second movable resonator body (22), - said adjusting shaft (35) extending axially through said mounting wall opening and being radially mounted by means of storage means inside said tubular sleeve portion (31), at least in an area located axially inside said mounting wall, so that it is axially movable by means of said tuning adjusting device on the outside of said mounting wall, whereby said two displaceable support elements (31, 33, 35) are precisely aligned relative to each other and the two resonator bodies (21, 22) are precisely positionable in relation to each other for tuning a resonant frequency of the dielectric resonator. A tuning device according to claim 17, wherein a second (33) of said two parts of said first support element comprises a support member (33) surrounding the circumference of said tubular sleeve portion (31) at a radial distance therefrom. A tuning device according to claim 18, wherein said tubular sleeve portion (31) is slidably mounted in said mounting wall opening (14a) and is spring loaded (40) on the outside of the mounting wall so as to exert said axial clamping force on said first stationary resonator wall (21) against mounting mount , and said support means (33) serves as 23548821100; Receptacle and spacer element for retaining said first resonator body (21) in said stationary position. A tuning device according to claim 18, wherein said support means is constituted by an outer cylinder sleeve (33). A tuning device according to claim 18, wherein said support means (33) is made of dielectric material with good thermal conductivity and is dimensioned to efficiently transfer heat generated in said first resonator body to said mounting wall. The tuning device of claim 17, wherein said stationary resonator body (21) is circular-cylindrical with a central axial heel (21a). A tuning device according to claim 22, wherein said tubular sleeve portion constitutes a separate body (31) fixed to said first resonator body (21) in said central axial heel (21a). A tuning device according to claim 17, wherein said adjustable shaft (35) is tightly fitted internally in said tubular sleeve portion (31) by means of mutually abutting cylinder surfaces. A tuning device according to claim 24, wherein said abutting cylinder surfaces extend along substantially the entire axial length of said tubular sleeve portion (31). The tuning device of claim 17, wherein said adjusting shaft (35) comprises two concentric, cylindrical tubular members (36, 37) slidable one inside the other, and said second resonator body (22) is axially clamped between said two concentric tubular members. 23548se.doc; 01-12-12 10 520 207 é âfäšjf 18 The tuning device of claim 17, wherein said second movable resonator body (22) is in the form of a circular disk. The tuning device of claim 27, wherein said first stationary resonator body (21) is circular-cylindrical with substantially the same outer diameter as said circular disk (22). A filter comprising a housing with walls (11-14) defining a cavity (10), a dielectric resonator (20) located in said cavity, comprising a stationary resonator body (21) and a movable resonator body (22), means for generating of a resonant electromagnetic field in said cavity and a tuning device according to any one of claims 1-28, for tuning a resonant frequency of the dielectric resonator (20). 23548Se.dOC; 01-12-12