DE1614591B1 - STACKED CAPACITOR THAT CAN BE ADJUSTED TO A DESIRED SETPOINT OF ITS CAPACITY - Google Patents

Description

The invention relates to a stack capacitor, which can be adjusted to a desired value of its capacity. Stacked capacitors in the sense of the present invention consist of stacked Layers of dielectric. Material, especially made of ceramic, and between the Layers located, serving as capacitor layers metal layers, in particular made of palladium, the alternately from layer to layer on different sides of the stack out of this and there are electrically interconnected with one another, e.g. by means of metal layers made of conductive silver. Electric with each other Interconnected layers of the same potential represent the capacitor coatings. It is possible to connect to the Interconnection surface of these layers also to attach an external power supply, z. B. to solder to connect the stacked capacitors to other electrical components. The stack capacitors can also be pluggable, whereby additional external power supply lines are not required.

Stack capacitors of the type described are known (US Pat. No. 3,235,939). With these Stacked capacitors are difficult to achieve a desired capacitance in that the size of the capacitor plates is usually predetermined, so that the capacitance, among others Conditions depending on the sum of the opposing surface parts of the metallic layer is. With sufficient care it can be established that the desired size of the capacitance co-determining surface of the opposing metal layer portions is achieved; however, this is the one you want The capacitance value of the stacked capacitor is still not with sufficient certainty to achieve, because - as is well known - also affects the thickness of the dielectrically effective Layers the capacity. Especially with stacked capacitors with extremely thin ceramic dielectric Layers, production-related fluctuations in the layer thickness usually have an effect considerable and hardly influenceable scatter of the capacitance of the capacitor of up to 20%. A Adjustment is possible by grinding.

In the US Pat. No. 2,526,704 a capacitor arrangement is described which - also in a stacked design - Contains the dielectrically effective layers arranged, with between these layers several metal assignments are also arranged in a comb design. For capacity adjustment the connection points of the comb are separated, so that only from a higher to a lower Capacity can be adjusted. A similar suggestion is in British Patent 558,693 described.

The present invention is based on the object Specify ways and means by which these manufacturing-related variations in the final capacitance of the capacitor can be compensated can.

To solve this problem, a capacity can be adjusted to a desired target value Stacked capacitor consisting of a monolithic monolith that is firmly joined by heat treatment Block of stacked layers of ceramic dielectric material and between the layers located, serving as capacitor coatings, consists of metal layers that alternate from layer to layer on opposite sides of the block out of this and there are electrically connected to one another by means of metal supports; this capacitor is according to the invention characterized in that within the block between dielectric layers at least one Leveling coating is provided in the form of at least one additional metal layer that is attached to the block one of the side free of the metal supports serving to interconnect the main coverings is led out, and that the leveling coating by means of further metal supports electrically conductive with one of the metal layers used to interconnect the main coverings is connected, either capacitively effective or capacitively ineffective.

The capacitance Z, which can be switched on by the compensation coating, preferably corresponds approximately to the difference between the nominal capacitance C of the capacitor and the minimum, production-related raw capacitance R.

It is also advantageous if the leveling layer is divided into several equal parts and the sum of the capacitance Z _T that can be switched on by the partial layers corresponds approximately to the difference between the nominal capacitance C and the minimum raw capacitance R. The up a distribution of the matching pad into several equal parts' allows the gradual switching of the partial capacitances.

With a symmetrical tolerance, the lowest connectable capacitance Z _m with respect to the nominal capacitance C is advantageously twice the permissible

Deviation!) (Calculated in%), i.e. Z _m = - ^ C.

IuU

In order to be able to switch on the partial coverings in the simplest possible way, it is proposed that a Group of the individual parts of the leveling covering arranged between two dielectric layers and is led to one of the adjustment interconnection pages, while the other group of the individual parts of the Leveling coating arranged between two other dielectric layers and to the opposite one Alignment interconnection page is performed.

In this way it is achieved that the adjustment interconnection pages of the stacking block regardless of the height of the given position in the block of the leveling covering with the metal covering, in particular made of conductive silver over burn-in silver tincture. This additional metal overlay only needs the length of the block after the correct distance from the Main interconnection side to be observed.

According to one embodiment of the invention can be arranged as a block under the terminal dielectric layers. The connectable capacity depends on the size of the leveling surface or on the Size of the respective parts of this adjustment coating.

It is different if, according to a development of the invention, the two groups of the individual parts of the leveling lining are arranged within the block. Here it is necessary to refer to the two main surfaces adjacent to both groups of the adjustment surface on the same main interconnection side lead out. In this case, the switchable capacity is twice as large as it is because of the area size of the leveling coating would be the case.

In order to reduce the area of the possible connection capacity Z in as small and as possible with a few partial coverings to be able to switch on many stages, it is useful

moderate, if the two groups of the individual parts of the adjustment coating each half f-j-j of the total

Include connectable capacitance Z, with one group consisting of surface parts of the same size, the connectable capacitance of which corresponds approximately to twice the permissible deviation D , while the other group consists of a single surface part.

In continuation of this idea, it is advantageous not to form this other group from just one surface part, but rather it should consist of at least three surface parts of different sizes, with a relatively large surface part symmetrically equal between at least two, the amount being twice the permissible deviation from the nominal capacity making up small equalization deposits is arranged. In terms of their connectable capacity, these small surface parts correspond to the minimum switch-on amount Z _m , while the large surface part comprises a multiple of these small surfaces and the same-sized parts of the other group of switch-on coverings are between the values of the small parts and that of the large part .

The invention is to be explained in more detail with reference to the drawings.

Fig. 1 shows a stacked capacitor according to the invention as section AA in Fig. 2;

F i g. 2 shows a side view according to arrow II in FIG. 1;

FIG. 3 shows another embodiment of the stacked capacitor as section BB in FIG. 4;

F i g. 4 shows a side view of this stacked capacitor according to arrow IV in Fi g. 3.

The F i g. 5, 6 and 7 and FIGS. 8, 9 and 10 schematically show stacked capacitors according to FIG Invention with differently arranged leveling partial coatings.

In the F i g. 1 and 2, 1 denotes the stacking block. Metal coverings 3 and 4, preferably made of palladium, are arranged between the dielectric layers 2 made of ceramic material, the metal coverings 3 being led to the right-hand side and being electrically interconnected there by the metal coating 5 (conductive silver); the metal coverings 4 are led out of the stack to the left and are electrically connected to one another there with the metal cover 6. The interconnection sides of the main coverings, in the F i g. 1 and 2, the coverings 3 and 4, respectively, are also referred to below in the other figures as the main wiring pages. The leveling coating 7 is arranged under the terminal dielectric layer, here denoted by 8, within the block. If the raw capacitance R reached after the production of the capacitor does not reach the desired target value, the leveling coating 7 is switched on through the metal coating 9, which runs on the leveling interconnection side, to the right main interconnection side, so that the capacitance is increased by this amount. If the nominal capacitance C is almost reached during production due to the raw capacitance R, the balancing coating 7 is connected to the left interconnection side and is therefore not capacitively effective. The case in which the raw capacitance R is greater than the target capacitance C does not occur because the arrangement of the main coverings and the thickness of the dielectric layers are planned in such a way that R is always smaller than C.

At this point the manufacturing process of the stacked capacitors should be discussed are explained in more detail according to the invention.

As is known from the technical literature, stacked capacitors are manufactured in that a certain Wise composite ceramic slip is drawn into foils, which after drying operations be provided with metal stains. By arranging these metal patches accordingly and through corresponding stacking of the metal foils results in blocks in which the metal layers alternate are led to opposite sides. The stack blocks are subjected to a burning process, see above that by sintering together a monolithic block is created. By painting the main interconnection pages the electrical capacitor is created with metal and, if necessary, burn-in of this metal. The leveling pads to be provided according to the present invention are just like the metal surfaces for the main coverings are already printed on the dried ceramic slip and arranged in the stack, but in such a way that this leveling coverings from a finished stack end on a side that is not used for the main interconnection (alignment interconnection side).

In the F i g. 3 and 4, the same parts as in FIGS. 1 and 2 are provided with the same reference numerals. On the metal supports 5 and 6 connecting wires 10 and 11 are attached to the external contact serve of the electrical capacitor. Instead of a leveling coating 7 according to FIGS. 1 and 2 three partial coverings 12, 13 and 14 are provided here. Since in the assumed case the difference in the raw capacity to the target capacity could already be compensated by the partial coverings 13 and 14, are these two coverings by a metal overlay 15 over the alignment interconnection side with the main interconnection metal overlay 5 electrically connected. The partial covering 12 is connected to the metal covering 6 by the metal covering 16 and therefore capacitively not effective.

In the F i g. 5, 6 and 7 are the interconnection metal supports of both the main interconnection and the alignment interconnection pages have also been omitted for the sake of a better overview. Appropriate Parts of this capacitor have the reference numerals already used in FIGS. 1 to 4 Mistake. As can be seen from FIG. 5, the leveling coating is divided into two groups, each are arranged under the terminal dielectric layers 8.

5, which shows a section through a stacked capacitor along lines V-V in FIGS. 6 and 7, shows that the top five partial coverings 17, 18, 19, 20 and 21 are of the same size and with capacitive connections the total capacity of the capacitor by an amount directly corresponding to the area of these partial amounts. The same applies to the differently sized partial coverings 22, 23, 24, 25 and 26. The partial coverings 17 to 21 and the partial coverings 22 to 26 are led out of the stack on opposite alignment interconnection sides.

F i g. 6 shows a plan view of the stacked capacitor according to FIG. 5 in the direction of arrow VI with matching part coverings shown hatched.

F i g. 7 likewise shows a plan view of the stacked capacitor according to FIG. 5, but in the direction

of the arrow VII, also shown hatched Matching part coverings.

The in the F i g. 5 to 7 shown serves as an example of one that should have a nominal capacitance of about 600OpF in practice. Due to the different thicknesses of the dielectric layers and the imprecise stacking of the main coatings, the raw capacitance R achieved after the manufacturing process is smaller than the nominal capacitance. Experience has shown that the lowest value of the raw capacitance (R _mt ") is 5100 pF. In the worst case, it must be possible to cover a range of 90OpF. If the required symmetrical tolerance is to be ± 0.25% (corresponding to ± 15pF), the connection capacitance Z of 900 pF can be connected in steps of 30 pF each, if the five equal-sized partial coatings 17 to 21 each deliver 90 pF, while the partial deposits 22, 23, 25 and 26 each result in 30 pF; the partial covering 24 is to be made so large that 330 pF can be set. The arrangement of the partial coverings 24 between the small partial coverings 22, 23, 25 and 26 in the manner shown allows the remaining partial coverings to be connected to the other main circuit side in a capacitively ineffective manner for each connection stage.

In Figs. 8, 9 and 10 there is a stacked capacitor shown, in which the adjustment partial deposits in contrast to the F i g. 5, 6 and 7 within the stack, so not terminal, are arranged. In addition, there is the further difference of this stacked capacitor in that one group of the in F i g. 9 partial coverings shown hatched from only three of the same large areas 27, 28 and 29, while the other group (shown hatched in Fig. 10) consists of two small partial coverings 30 and 31 and a large partial cover 32. Provided, that a nominal capacity of 6000 pF ± 0.62% (corresponds to ± 37.5 pF) is required and the connection capacity is a maximum of 90OpF, the three equally sized partial coverings 27 to 29 are to be selected so large that that each 150 pF can be switched on; the two small partial deposits 30 and 31 should each be 75 pF and the large partial covering 32 300 pF result.

The tolerance here is ± 0.62%.

By simple mathematical considerations it is possible to determine the number, the size and the arrangement The partial coverings are to be selected in such a way that also for other target and raw capacities and for other permissible deviations of the setpoint with the smallest number of partial coverings, the largest number of activation levels can be reached.

Such capacitors have approximately the dimensions 15 × 10 × 1 mm ³ for a capacitance of about 6000 pF and are composed of ten ceramic layers of about 100 μm thickness. The ceramic dielectric material has a dielectric constant of about 40. Because the leveling coverings are arranged within the monolithic block, they cannot be adversely affected by atmospheric influences. The assignment of the adjustment coverings to the two adjustment interconnection times and the special division into smaller partial coverings allow these partial coverings, either capacitively effective or capacitively ineffective, to be easily connected to the main assignments. The desired nominal capacitance can be achieved with tolerances that are unusually narrow for stacked capacitors, without excessive care having to be taken in the manufacture of the capacitors, the accuracy of the stacking and the thickness of the ceramic slip films. Furthermore, the arrangement of the adjustment pads ensures that parts of the adjustment pads that are not required for the adjustment can be connected capacitively ineffective with the main assignments, so that the capacitance of the stack does not change and all metal layers are nevertheless at a defined potential.

As can be seen in particular from FIGS. 1 and 3, the main coverings only extend on one side, namely the interconnection side, to the edge of the stack, while on the other three sides an intermediate surface remains free between the edge of the cover and the edge of the stack, which after the formation of the monolithic block serves as an isolation section. If the adjustment of the capacitance were to be carried out by grinding, this edge strip, which is used for insulation, would be removed, so that extremely short and therefore sensitive insulation sections are exposed between the main coverings. The proposed by the invention method to achieve narrow tolerances stacked capacitors the edge strips are fully maintained, so that the main surfaces \ are sufficiently well insulated from each other.

Claims (9)

Patent claims: 1. Stacked capacitor, which can be adjusted to a desired setpoint of its capacitance, consisting from a monolithic block of stacked one on top of the other, firmly joined together by heat treatment Layers of ceramic dielectric material and located between the layers as capacitor coatings serving metal layers that alternate from layer to layer on opposite sides of the block led out of this and electrically interconnected there by means of metal supports are, characterized in that within the block (1) between dielectric Layers (2) at least one leveling coating (7, 12, 13, 14, 17 to 31) in the form of at least an additional metal layer is provided (from the block (1) to one of the interconnection the main coverings (3, 4) serving metal supports (5, 6) free side is led out, and that the leveling coating by means of further metal supports (9,15,16) with one of the for interconnection the main coverings (3, 4) serving metal support (5, 6) is electrically connected, namely either capacitively effective or capacitively ineffective. 2. Stacked capacitor according to claim 1, characterized in that the capacitance Z which can be switched on by the leveling coating corresponds approximately to the difference between the nominal capacitance C and the minimum raw capacitance R. 3. Stack capacitor according to claim 1 or 2, characterized in that the leveling coating is divided into several equal parts and the sum of the capacitance Z ₇ which can be switched on by the partial coatings - corresponds approximately to the difference between the nominal capacitance C and the minimum raw capacitance jR. 4. Stacked capacitor according to one of claims 1 to 3, characterized in that at symmetrical dead dance the lowest connectable capacitance Z _1n in relation to the nominal capacitance C twice the permissible symmetrical disconnection 2 D
deviation D (calculated in%) is: Z _m = y ^ y C. 5. Stacked capacitor according to one of claims 1 to 4, characterized in that a Group of the individual parts of the leveling covering arranged between two dielectric layers and is led to one of the synchronization interconnection pages, while the other group of the individual Parts of the leveling coating arranged between two other dielectric layers and to the opposite one Alignment interconnection page is performed. 6. Stacked capacitor according to claim 5, characterized in that the two groups of Parts of the leveling coating each under the terminal dielectric layers (8) of the block (1) are arranged (Fig. 5 to 7). 7. Stacked capacitor according to claim 5, characterized in that the two groups of the individual Parts of the leveling cover are arranged within the block (1), and each to two main surfaces (4) adjacent to the two groups on the same main interconnection side are led out (Fig. 8). 8. Stacked capacitor according to claim 6 or 7, characterized in that the two groups of the individual parts of the adjustment coating each half (^ J of the total connectable capacity Z include and that one group consists of equal parts of the surface, while the other group consists of a single surface part. 9. stacked capacitor according to claim 6 or 7, characterized in that the two groups of the individual parts of the adjustment coating depending on the Half ( -) of the total connectable capacitance Z include, with one group consisting of at least three equal-sized surface parts (17 to 21 or 27 to 29) and the other group consisting of at least three different-sized surface parts and a very large one in this second group Partial coating (26 or 32) is arranged symmetrically between at least two identical small partial coatings (22 to 25 or 30 and 31) which make up twice the amount of the permissible symmetrical deviation. 1 sheet of drawings 109 553/241