DE3138469A1 - TRIMMER CAPACITOR - Google Patents

Description

ALPS ELECTRIC CO., LTD.

1-7 Yukigaya Otsuka-Cho, Ota-Ku, Tokyo, Japan, 1M5

September 15, 1981 IG / di GVC-299

Trimmer capacitor

(Priority to Japanese Application No. 159697/80 of

November 08, 1980)

The invention relates to a trimmer capacitor, in particular for high-frequency circuits, whose cylindrical insulating material housing an arc of a circle separated by a dielectric layer Stator and rotor electrode rotatable with a rotor shaft accommodates, with electrical connections for grounding and tension.

i Such trimmer capacitors are used for electronic and elec-

tric devices being electrical components, in particular for ver | different high frequency circuits are required. They should have small dimensions, with a ceramic plate or foil being used as dielectric material in order to achieve a relatively high capacity _; ity zdärmögliehen. On the other hand, however, the ceramic film or the platelet is easily broken mechanically. Per-; ner, if the dielectric film is made thinner; In order to obtain a larger capacity, the fractional . increased risk. A well-known trimmer capacitor is after-; explained below with reference to FIG. 1, which shows a section through the capacitor.

Here, an approximately semicircular stator electrode 5, which is produced by pressing and curing a silver paste or gel, rests on a surface of the dielectric layer 4 made of ceramic material. The layer h is ^!

non-rotatable on the inner surface of the bottom of a frame-shaped Housing 1 attached, wherein the stator electrode is below the dielectric layer. An electric one

Conductor 2, which supplies the external voltage, is cast in housing 1 with a t, or attached with a press fit or by caulking,
and its one end is in contact with the stator electrode 5 and a groove If is provided inside the housing 1

is, so that the two components 2 and 5 are electrically contacting "Form connection.

-On the other hand is a rotor 6 in the form of a plate or disc,
manufactured, e.g. B. as a zinc die-cast part or the like., Arranged on the dielectric layer 4. Rotor 6 is with its rotor

shaft 7 rotatable, which the rotor 6, the dielectric layer
and the housing 1 passes through and which is connected to the grounding line 8
the lower side of the insulating housing 1 or caulked
attached in another way. The lower surface of the rotor 6 ^: is provided with a circular segment or circular electrode 6c; provided, and it is a semicircular protruding edge; part 6c present, which is in a plane with the electrode 6c '■ . By serving as a movable electrode rotor 6 is rotated, the opposed surfaces of the electrode can be \ changed 6c and the stator electrode 5 and also herewith;

the capacity. i

The dielectric layer 4 is very finely polished; both the | Rotor electrode 6c as well as the edge part 6d of the rotor 6; highly polished and sufficiently flat. On the other hand, the upper

surface of the dielectric layer 4 that of the stator electrode 5
on the other hand, with regard to the requirements for the flat training; formation less exact, depending on the thickness of the stator 'electrode 5. On the other hand, because the insulating housing 1, which is in abutment with the dielectric layer 4, is made of relatively cheap plastic in order to reduce costs,
there is shrinkage during the manufacturing process; before, and the desired flat training or the required! Surface parallelism is not accurate enough. Consequently*

the housing 1 and the dielectric layer 4 with ^counter: opposing surfaces provided, whose flat or parallel
Training is not sufficiently consistent and accurate. The FoI. ge is that the space between these components 1 and 4
not neglected in application or in series production

is permeable and the desired intimate surface contact is not guaranteed. The result is that the dielectric layer 4 is transmitted through a torsional load via the rotor 6 or is applied when the rotor shaft 7 is caulked or when adjusting the capacitance, is distorted with the consequence that the characteristic of the capacitance with respect to the rotor plate 6 is distorted or undesirably drops. Another The disadvantage is that the breaking strength of the dielectric layer 4 is indefinite over the layer is distributed away, with the result that cracks occur.

; Furthermore, there is the requirement that if trimmer capacitors with : small size and high capacity for. Provided

must be, an even thinner layer is required than that Usual layer of ceramic dielectric of 0.2-0.4 mm. : Now the ceramic is prone to breakage and is particularly weak : visible bending stress during manufacture when a thin layer is initially manufactured in series production will. Such a thin layer is therefore already a raw material

■ 20 highly susceptible to cracking. Thus, the requirement forms an intimate ! Contact between the dielectric layer 4 and the insulating Enclosure 1 to ensure a difficult problem to overcome especially when the trimmer capacitors should be small and have a high capacity, while on the other hand in the manufacturing process high efficiency, low: rejects and low costs with increased output are required.

; The invention is based on the object of specifying a trimmer capacitor: 30 'in which small dimensions and high capacity

■ are guaranteed in connection with a reliable production method and operational stability. In particular, the formation of cracks in the dielectric layer is to be avoided even in the case of thin layers; the characteristic of the capacity should be stabilized in relation to the rotor load and the occurring torsion.

This object is achieved according to the invention by the subject matter of

Claim 1 solved. Advantageous refinements are given in the subclaims. Because now the dielectric layer, under pressure,. is arranged between the elastic ring or the disk ring and the plate-shaped rotor, the spacing between them, which previously existed regularly between the insulating material housing and the dielectric layer, is avoided. Furthermore, since the load on the rotor plate can now be absorbed by the entire outer circumferential surface of the dielectric layer, the reliability is increased that cracks do not form in the dielectric layer: this layer can thus be made thinner and a higher capacitance can be achieved. It can also be seen that the capacity characteristic, based on the load of the rotor, can be stabilized, associated with the fact that the torsion occurring during the rotation of the rotor plate is also stable; lized bww. is more even. All of these benefits can be un-! dependent on the fact that the trimmer capacitor maintains small dimensions and can be safely manufactured. . [

An embodiment of the invention is shown in the drawing. and is explained in more detail below. Show it:

"Fig. 2 a trimmer capacitor in section |

"Fig. 3 is a plan view of the insulating housing [

Fig. 4 is a perspective view of an elastic Ring / disc ring

5 shows a view from below of the dielectric,

Layer;

6 shows a view from below of the plate-shaped;

Rotor!

7 shows a section, in side view, through an an- ^j

Another embodiment of the thermal capacitor. ;

There is a frame-shaped cylindrical insulating housing 1, preferably made of synthetic resin, with a bottom la and a jacket Ib and a hole Ic through which the rotor shaft? in the middle part of the bottom la passed through - is. Fig. 3;

shows that the inner circumference of the jacket, so the circumference in the side edge, is formed with straight parts Id to the

! To keep dielectric layer 4 immovable, and there are parts: Ie in the form of circular arcs Ie to support the plate-shaped rotor 6 rotatably. There is also a groove If, which is formed on the upper side of the base la and one end of which is provided with an opening Ig which penetrates the base la, see FIG. The voltage-carrying conductor 2 is made of highly conductive sheet metal and is pressed into the opening Ig with a tight press fit, and its one end is bent to form an elastic contact part 2a. The conductor 2 can also, in addition to a press fit, by caulking, simultaneous potting with the Kunstharz.udgl. be attached. There is a disk ring 3 as an elastic body, consisting of insulating elastic material, for. B. made of silicone rubber. In the arrangement, this has a small thickness and a small width (approximately 1.5 IMn) ₇ VgI. 4, and this disk is arranged on the surface of the bottom la of the frame-shaped insulating housing 1, see FIG.

·

The dielectric layer 4 consists of a thin ceramic plate, whose both surfaces are highly polished. Like Fig. 5

: shows the plate has essentially an oval fprm and a central hole 4a so that the rotor shaft 7 can be passed through. On a surface of the dielectric layer 4, essentially semicircular, the stator electrode 5 is made by printing and curing an electrically conductive paste, containing silver particles. The dielectric layer is placed on the disk ring 3 so that the stator electrode 5 remains on the lower side. The contact part 2a of the conductor 2 is in elastic contact with the Stator electrode 5, so that the components 2 and 5 are now an electrical Have contact.

The disk-shaped rat-like rotor 6 can be made of cast zinc or the like. be made and ho b a drive slot 6a in the middle and a drive hole oil which is in communication with the slot and serves to receive the rotor shaft 7. Like Fi.j. 6th

ί;

shows the actual electrode 6c, that is rotatable electron i trode, advantageously semicircular on one half of the bottom 'surface of the plate-shaped rotor 6 is present, while _a: projecting semi-annular peripheral part 6d, the χ η one _i level to the electrode 6c is , on the outer peripheral edge of the; other half of the floor area is formed. The surface so-; probably the electrode 6c and the rim portion 6 "d is very finely polished _ä, ■

The rotor 6 is located on the dielectric layer 4 _S with the electrode 6c and the protruding edge part 6d being on the lower side of the rotor, and the rotor is made rotatable by the
Rotor shaft 7 held, which the rotor 6, the dielectric ^; Layer 4, the disk ring 3 and the insulating housing 1 through

puts.' The head Yes of the rotor shaft 7 is in abutment with the ■ bottom of the drive slot 6a, the other end 7b is outside the bottom la of the housing 1 through the highly conductive
Sheet metal existing grounding line 8 carried out and firmly chiselled. Thus, the dielectric layer 4 and the ela-

stic disc ring 3 bread-butter-like in contact j between the plate-shaped rotor 6 and the insulating housing 1. pressed, while on the other hand rotor 6 electrically connected to the ground line 8 is connected via the shaft 7.

2'3 If even the upper surface of the bottom of the insulating housing 1
because of a shrinkage phenomenon. or the like. not enough
and the bottom surface of the dielectric layer 4 ^{i is} also less flat or parallel with respect to the thickness of the stator electrode 5, the deformation now causes

of the elastic disk ring 3 produced a state at

that of the outer periphery of the dielectric layer 4 in more intimate; Contact contact with the upper surface of the insulating housing 1; beyond the disk ring 3, with the result that every smaller spacing between the dielectric layer 4

and its supporting surface disappears. It is also advantageous that I is the decrease in the values in the capacity character xstxk, in relation to
on the load occurring on the rotor 6, which would otherwise be a consequence of the
small distance between dielectric layer 4 and the

3 Π 3 8 / r 6 O

a

Insulating housing 1 is - known design - completely eliminated will. The crack resistance of the dielectric disk 4 is increased and the thickness of this layer 4, so far to 0.2 mm limited, can now be only 5j 15 mm in an advantageous manner, while maintaining the above advantages.

The embodiments of the present invention is not limited to the use of the rotor shaft 7, see. Fig. 7. Here, the elastic washer ring J> the dielectric layer 4 and a plate-shaped rotor 6 ₃ arranged in succession on the inner surface of the soil in the housing 1. Rotor 6 and dielectric layer 4 are in contact with the sandwich like bread

I t

live line 2 and the grounding line 8 pressed,

t whereby the latter conductor is connected to the insulating housing 1 by common

same potting with the synthetic resin or the like. be attached. It is a chamfered or flanged lh at the top of the

t
Housing 1 side or made on the circumference, z. B. by

bead under heat or the like; this makes rotor β, dielectric Layer 4 and elastic disk ring 3 pressed in the direction of the grounding line 8. Step in this embodiment essentially the advantages of the embodiment according to FIGS. 2-6.

<0

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Claims (4)

ALPS ELECTRIC CO., LTD. l6. September 198 I. IG / di GVC-299 Claims AT trimmer capacitor, especially for high-frequency circuits, whose cylindrical insulating material housing has a dielectric Layer separate, circular arc-shaped stator and rotatable with a rotor shaft rotor electrode accommodates, with electrical Connections for earthing and supplying the voltage, · characterized in that on the outer edge area of the dem Rotor facing surface of the bottom (la) of the insulating housing (1) an annular, made of electrically insulating material existing component, e.g. B. a disk ring (3) is arranged, so that a surface of the stator electrode (5) this Component is facing and the dielectric layer (4) is rotatably mounted relative to the insulating housing (1), and through Components (6d, 6d) the outer edge of the dielectric layer between the elastic component (3) and the rotor (6) one Is exposed to pressure. 2. Capacitor according to claim 1, characterized in that a live conductor (2) fixed to the insulating housing (1) is connected that a contact part (2a) at one end of this Head is arranged as an elastic component and against the; ; Stator electrode (5) presses in the cavity of the insulating housing (1) and also the ground line (8, 8) only partially on the insulating housing (1, 1) is attached and is also electrically connected to the rotor (6, 6). 3. Capacitor according to claim 2 with an existing metal, the rotor penetrating rotor shaft, which also penetrates the dielectric layer, the housing and a grounding line, characterized in that the shaft is the ■ elastic component, z. B. the disk ring (3), also penetrated and the head (7a) of the rotor shaft (7) at the bottom of a serve as a stop • w »β« * · u * * τ GVC-299.:::: the one in the area of the upper surface of the rotor (6)
Drive slot (6a) comes to a stop and the grounding line: (8) has at least one designed as a spring and / or disposed portion at which the lower end (7b) of the rotor shaft below the j-insulating housing attached is festgestemmt particular \, (Fig. 2), and components durch.diese (Ta) ₇ (Tb ^ (Oa), '(6b), rotor (6), dielectric layer (4) and elastic shield benring (3) are not detachably mounted on the housing (1) and the j . Outer edge of the dielectric layer (4) between the elastic see disk ring (3) and the rotor (6) tightly pressed together ι are. l 4. Capacitor according to one of the preceding claims, in particular ^: . dere claim 2, characterized in that ; that the elastic Part is present at one end of the grounding line (8, 8) ί and resiliently rests against the upper surface of the rotor (6)> (FIG. 7) and furthermore the insulating housing (1) in the upper area; at least one nose-shaped, bendable, preferably of egg i nem peripheral part .umbiegbaren component (lh), which ge j gen the spring part (8) of the grounding line (8) presses and the rotor. (6), .dielectric layer (4) and the elastic disc ^! rrrig (3) on the insulating housing (1) as well as the outer edge the dielectric layer (4) between the elastic sheet i benring (3) and the rotor (6) tightly pressed together. '■