The invention also relates to a tuning arrangement that includes such a screw that can be placed, for instance, in the centre conductor of the cavity filter or its lid, and also at some other suitable position in the chassis of the cavity filter.

DESCRIPTION OF THE BACKGROUND ART Radio base filters can be constructed and manufactured as so- called cavity filters which consist of a plurality of cavities either with a separate centre conductor in each cavity or more than one centre conductor per cavity. These filters are used, for instance, in base stations for GSM- based mobile telephony.

The filters are generally constructed with the aid of different components, such as a chassis or lid, for instance.

However, filters that are not tuned when manufactured must be adjusted subsequent to being fitted, because of the influence of tolerances on the filter components. This adjustment of the filter properties is effected by tuning the filter with respect to its resonator frequencies and the couplings between the centre conductors in the filter.

In a cavity filter, each cavity that includes a centre conductor functions as an electric oscillator circuit that can be represented by a parallel oscillator circuit that includes an inductive part L and a capacitive part C when the filter is tuned on a quarter wavelength of the received signal. The resonator frequencies of the filter are therewith determined through the inductive and capacitive parts.

The frequencies of the cavity filter are tuned by changing the length of the centre conductor and therewith the inductance, and by changing the distance from the centre conductor in the cavity to the cavity lid and also to the cavity side walls, which results in a change in capacitance.

Frequency adjustments must be made very accurately and also in a manner which will ensure that the set frequencies are maintained.

Tuning of the coupling coefficient factor between the centre conductors in the cavity filter is effected by changing their relative distances or by changing the geometry of the filter in the space between the centre conductors. This latter measure may entail providing the cavity partition walls with appropriate apertures for instance and/or providing a tuning device between said centre conductors.

Figure 1 illustrates a known method of tuning a cavity filter. The Figure is a sectioned view of a cavity filter 10 which is defined by a cavity bottom 12 and side walls 13. The cavity has provided therein a centre conductor 11 which in the illustrated case is formed integrally with the bottom 12 of the cavity and extends out therefrom. The whole of the cavity is covered by a lid or cover member 15. Tuning is

effected with the aid of a tuning plate 14 attached between the cavity walls and lid and functioning as an adjustable earth plane. The tuning plate is flexible to some extent, so that its position relative to the upper edge of the centre conductor can be changed by screwing a screw 17 through the cavity lid 15 until the correct distance is achieved between tuning plate 14 and centre conductor 11. Alternatively, tuning can be effected solely with the aid of the screw 17, the position of which in the filter lid is fixed by means of a counter nut or lock nut.

EP 0 525 378 A2 teaches a self-locking tuning screw which consists of a first part 1 that includes two threaded segments 4,5 and an intermediate plain or non-threaded segment 3, and a non-threaded or plain second part 2 intended for insertion in a microwaveguide. The first part of the screw includes a screwdriver accommodating recess that includes several edges which form slots at the non-threaded segment 3.

SUMMARY OF THE INVENTION The present invention relates to a component tuning arrangement, preferably for tuning a cavity filter.

One object of the invention is to provide a screw that can be used in a cavity filter to tune the frequency relationship of the filter and which will be self-locking when fitted in the centre conductor, the wall, or the lid of the filter.

Another object of the invention is to provide a screw which can be used in a cavity filter to tune the coupling

coefficient factor between two centre conductors in the filter and which will be self-locking when fitted in an appropriate position in the bottom of the cavity and its side-walls or lid respectively.

Still another object of the invention is to provide a tuning device which consists solely of one component in the form of a self-locking screw, thereby eliminating screw play.

These objects are achieved in accordance with the invention by means of a screw which has at least one slot extending in its axial direction and which is configured with at least one thicker part. As a result of this thicker part, the screw slot will be squeezed together as the screw is screwed-in, thereby exerting on the walls of the screw hole a force which ensures that the screw will be firmly locked in the position desired.

The inventive arrangement for tuning the frequency relationship of the filter is achieved by mounting the screw in a centre conductor, side wall or lid. Tuning of the coupling coefficient factor between two centre conductors is achieved by placing the screw between the centre conductors in the bottom of the filter, the lid or its side walls.

Tuning is effected by appropriate adjustment to the position of the screw head.

More specifically, the inventive arrangement is characterised by the features set forth in the accompanying claims.

One advantage afforded by the inventive tuning arrangement is that it consists of only one component. Because the tuning

screw included in the arrangement is self-locking with a constant moment of force along the full length of the screw, no counter nuts or lock nuts are required to lock the screw in its set, desired position. Neither is a tuning plate required in order to tune the filter. This results in more rational and less expensive manufacture.

Another advantage is that tuning is facilitated by virtue of the fact that the inventive tuning arrangement includes two screwdriver accommodating recess, of which one is intended for turning the screw and the other for adjusting the position of the screw subsequent to having placed the lid in position.

Another advantage resides in greater flexibility, since the tuning screw can be readily replaced with screws of other designs, for instance with respect to the head of the screw.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail with reference to preferred embodiments thereof and also with reference to the accompanying drawings.

Figure 1 shows a cavity that includes a tuning arrangement which, in turn, includes a tuning plate, wherewith tuning is effected by adjusting a screw provided in the lid.

Figure 2 illustrates a first embodiment of an inventive tuning screw.

Figure 3 illustrates a second embodiment of an inventive tuning screw.

Figure 4 is a perspective view of the upper screw segment of a tuning screw according to the preferred embodiment.

Figure 5 is a perspective view of the bottom screw segment of a tuning screw according to the preferred embodiment.

Figure 6 is a cross-sectional view of the tuning screw according to the preferred embodiment.

Figure 7 shows a cavity in a cavity filter that includes a first embodiment of the inventive tuning arrangement, wherein the tuning screw according to Figure 2 or Figure 3 for instance has been arranged in a centre conductor in a cavity filter.

Figure 8 illustrates a cavity in a cavity filter that includes an alternative embodiment of the inventive tuning arrangement, wherein the tuning screw of Figure 2 or Figure 3 for instance has been arranged in the filter lid.

Figure 9 illustrates part of a cavity filter wherein the tuning screw of Figure 2 or Figure 3 for instance is used for tuning the coupling coefficient factor between centre conductors.

DESCRIPTION OF PREFERRED EMBODIMENTS Figure 2 and 3 illustrate two possible embodiments of the inventive tuning screw. The screws 20; 30 comprise a threaded

screw body 21; 31 which includes two solid end parts 23a, 23b; 33a, 33b and a radially through-penetrating slot 22; 32 whose length corresponds almost to the full length of the screw body. In the case of the preferred embodiment, one end part 23a; 33a is formed with a collar 25; 35 that includes an appropriate type of screwdriver accommodating recess 26; 36.

A correspondingly arranged screwdriver accommodating recess is also provided at the other end 23b; 33b of the screw.

In a first embodiment, shown in Figure 2, the screw body 21 includes a part 24 that has a cross-sectional area whose extension perpendicular to the through-penetrating slot 22 is slightly greater than its corresponding extension at the end part 23b of said screw body where screwing of the screw commences.

In a second preferred embodiment, shown in Figure 3, the screw body 31 includes two parts 34a, 34b which have a cross- sectional area whose extension perpendicular to the through- penetrating slot 32 is slightly greater than the corresponding extension of the cross-sectional area of the end part 33b of the screw body where screwing of the screw commences.

The screw shall be self-locking. Accordingly, the screw is provided with at least one axially extending slot and with at least one portion that includes a cross-sectional area of greater extension perpendicular to each slot. The diameter of the screw hole therewith corresponds to the diameter of the cross-sectional area at the end part 23b; 33b where screwing of the screw commences. As the screw is screwed into the hole, the axial slot 22; 32 will be squeezed together

immediately the radial extension of that part of the screw which has entered the hole becomes larger than the diameter of the screw hole, so that the screw will be screwed-in with a certain degree of friction. The axial slot 22; 32 in the screw body provides a spring effect in the screw so that a force is able to act perpendicular to the longitudinal axis of the screw. The force obtained by this spring effect acts on the walls of the screw hole in those parts 24; 34a, 34b thereof at which the cross-sectional area of the screw body has an extension greater than the diameter of the screw hole.

The force causes the screw to be locked in the desired position to which it is set, so as to eliminate screw play.

In order to ensure stability of the screw, even when the screw is subjected to torsion as it is screwed into the hole, the screw body 21; 31 is formed with two end parts 23a, 23b; 33a, 33b.

In the preferred embodiment, the screw includes two metallic end parts which are embedded in a suitable plastic material.

These metallic parts are shown in Figures 4 and 5, whereas Figure 6 is a cross-sectional view of a tuning screw according to this preferred embodiment and including said parts. Figure 4 shows the first metallic part 40, which has the form of a collar that provides a screw head 41 and that is provided with a screwdriver accommodating recess 42. The part 40 also includes a short solid part that has two mutually parallel legs 43a, 43b. The shape of the screw head can be varied to suit the area of use of the tuning screw. Figure 5 illustrates the other metallic part 50, which comprises a shorter solid part 51 that includes a screwdriver accommodating recess 52 and two mutually parallel legs 53a, 53b. One of the legs 43b; 53b has been provided with a hole

44; 54 at each segment, so as to enable the parts to be fixed in the plastic material in manufacture and to counteract movement therebetween. In an alternative embodiment, each of the parts 40; 50 may comprise only one leg.

In the case of the tuning screw according to the preferred embodiment, the metallic end parts 63a, 63b may be disposed so that the free end-parts of the legs 64a, 64b are positioned mutually opposite each other at a given distance apart, so as to form a free space 61 between said parts, as illustrated in Figure 6. In the manufacture of the screw body, a portion of said solid parts, said legs and the space present between said parts are embedded in a plastic material 62. The slots between the legs and a slot in the space between said parts is omitted, wherewith the radially through-penetrating slot is formed in the axial direction of the screw body. The plastic body 62 is provided with a screw thread such as to form a screw body that can be screwed into a corresponding screw hole.

When mounted in a cavity filter, the inventive screw can be represented by two series-connected capacitances Cl and C2.

The capacitance Cl is obtained between the screw head and the lid of the cavity filter, whereas the capacitance C2 is obtained between the legs of the screw segment and that part of the cavity filter where the screw has been fitted. For instance, when the screw is backed-off in the screw hole to a given extent, the capacitance Cl will be increased since the distance between its active surfaces decreases. The total capacitance resulting from the series connection shall be comprised chiefly of the capacitance C1, since this capacitance is influential with respect to the resonator

frequency of the cavity. Consequently, the capacitance C2 must be considerably greater than the capacitance Cl. In order to maintain this relationship, even in the event of displacements, it is necessary for the legs 43a, 43b of the part 40 to be dimensioned with a length such that the area of the active surface in respect of C2 will be sufficiently large along the full tuning length of the screw to ensure that C2 will be greater than Cl in all positions.

A plastic material suitable for manufacture of the screw must have high temperature stability and good mechanical stability. The coefficient of linear expansion of the plastic material must correspond to the coefficient of linear expansion of the metal in its surroundings. The plastic material must also have low electric losses, so that it will not absorb a significant part of the electrical energy. A suitable plastic material in this respect is polyethyleneimide (PEI) or polyarylamide (PAA). A suitable metal must primarily have good resilience. Examples of suitable metals are tin bronze or beryllium copper. These metals can be coated with a material that is a good conductor of electricity.

The inventive tuning screw may be produced in alternative forms. In the case of a first alternative embodiment, the screw body is produced with only one metallic part. The part shown in Figure 4 is provided at one end of the screw and is partially moulded in the plastic material and preferably provided with a screwdriver accommodating recess and a collar that forms the screw head. The other end-part of the screw is formed in plastic and includes a second screwdriver

accommodating recess. The choice of material used is governed by the same criteria as that in the preferred embodiment.

In a second alternative embodiment, the screw is manufactured entirely from metal. However, in the case of this embodiment effective galvanic contact is required between the screw body and the body into which the screw shall be fitted. The screw is made, for instance, from tin bronze or beryllium copper and is silver plated in order to obtain a low resistance at the transition between screw and screw hole, and also to provide good conductivity.

Figures 7 and 8 show the inventive tuning screw when used in two alternative arrangements for tuning the frequency relationship of the cavity filter.

Figure 7 shows a cavity in a cavity filter including a centre conductor 71 in which the inventive tuning screw has been fitted. The cavity is defined by a cavity bottom 72 and side walls 73. In this embodiment, the centre conductor 71 is formed directly from the cavity bottom 72 and is an integral part of said bottom. The centre conductor includes a through- penetrating bore which is partially threaded so that the screw can be screwed thereinto. The entire cavity is covered by a lid 74. The tuning arrangement is implemented by the tuning screw 75 screwed into the centre conductor 71. As described above, the tuning screw 75 is comprised of a screw body that includes at least one radially through-penetrating slot and at least one part that has a larger cross-sectional surface area of greater extension perpendicular to the slot than other parts of the screw. The tuning screw 75 is preferably provided at one end with a collar 751 formed as a

screw head, and at least the other end 752 of the screw is provided with a screwdriver accommodating recess. Since the screw is self-locking, it can be affixed in a stable fashion in any chosen position in the centre conductor 71, when screwing in the screw. The distance between the screw head 751 and the lid 74 is decisive with respect to tuning components, said distance determining the resonator frequency of the cavity. This distance is varied by varying the extent to which the screw enters the centre conductor. When the screw 75 has two screwdriver accommodating recess, the recess on the screw head 751 is preferably used to screw the screw into the centre conductor 71, while the other recess at the other end 752 of the screw body is conveniently used to finely adjust the position of the screw when the lid 74 has been placed on the cavity.

The inventive tuning screw may alternative be disposed in the cavity lid. This alternative embodiment is shown in Figure 8.

The cavity is defined by a cavity bottom 82 and side walls 83. Arranged in the cavity is a centre conductor 81 which has been formed directly from the cavity bottom 82 in the case of this embodiment. The tuning screw 85 has the same design as the screw described above with reference to Figure 7. The tuning screw 85 is inserted into a threaded hole in the lid 84, which shall be constructed to ensure that the tuning screw 85 will be stably fastened. A decisive tuning factor is the distance between the screw head 851 located in the cavity and the upper surface of the centre conductor, this distance determining the resonator frequency of the cavity. The distance can be varied by varying the depth of penetration of the screw in the lid. When the tuning screw 85 has two screwdriver accommodating recess, the recess on the screw

head 851 is preferably used to screw the screw into the lid 84, whereas the other recess on the other end 852 of said screw body can be used conveniently to finely adjust the position of the screw when the lid 84 has been placed on the cavity.

Figure 9 illustrates the inventive tuning screw 95a, 95b when used to tune the coupling coefficient factor between two centre guides in the cavity filter. The illustrated part of the cavity Figure comprises three cavities, wherein two centre guides 91a, 91b have been arranged in one and the same cavity and each of a further two centre guides 91c, 91d has been arranged in a respective cavity. The coupling coefficient factor between two centre guides is determined in a first stage by their relative distance and position and can be varied, for instance, through suitable recesses or cut- outs in the cavity partition walls 93a, 93b. The coupling coefficient factor can then be tuned by means of the inventive tuning arrangement, which is comprised of a tuning screw 95a, 95b as described above with reference to Figure 7 and arranged in the space between two centre conductors. The tuning screw 95a for tuning the coupling coefficient factor between the centre guides 91b, 91c is placed in the recess in the wall 93a present between the centre conductors. The inventive tuning arrangement can be arranged advantageously in cavities that include more than one centre conductor where the coupling coefficient factor cannot be varied by mechanical treatment of the partition walls. In this case, the tuning screw 95b is placed between the centre conductors 91a, 91b on the bottom of the filter.

It will be understood that the invention is not restricted to the aforedescribed and illustrated embodiments thereof, and that modifications can be made within the scope of the accompanying Claims.