US3718883A

US3718883A - Electrical components with flexible terminal means

Info

Publication number: US3718883A
Application number: US00198552A
Authority: US
Inventors: A Berman; G Gerber
Original assignee: Vishay Intertechnology Inc
Current assignee: Vishay Intertechnology Inc
Priority date: 1971-10-15
Filing date: 1971-10-15
Publication date: 1973-02-27
Anticipated expiration: 1990-02-27

Abstract

Improved means of attaching electrical connectors to miniaturized electrical components are disclosed. Flexible leads separately attached to the front of an electrical component are attached at their opposite ends to more rigid electrical connectors on the reverse side of the electrical component. The electrical connectors and the electrical component are preferably bonded together for improved stability. The resulting electrical component is typically surrounded with at least one protective covering.

Description

United States Patent 1 1 Berman et al.

[ 51 Feb. 27, 1973 ELECTRICAL COMPONENTS WITH FLEXIBLE TERMINAL MEANS Inventors: Abraham Berman, Tel Aviv, Israel; George V. Gerber, Chester Springs,

Assignee: Vishay Intertechnology, 1nc., Malvern, Pa.

Filed: Oct. 15, 1971 Appl. No.: 198,552

US. Cl. ..338/322, 29/619, 336/192, 338/262, 338/313 Int. Cl. ..H0lc 1/14 Field of Search ..336/192; 338/262, 308, 322, 338/313, 332; 317/101 CC; 29/619, 627, 628

[56] References Cited UNITED STATES PATENTS 2,896,188 7/1959 Kearney ..3l7/1'0l CC 3,466,381 9/1969 Boehmke ..336/192 X Primary Examiner-13. A. Goldberg Attorney-Thomas M. Ferrill, Jr. et al.

[57] ABSTRACT 12 Claims, 13 Drawing Figures I PATENTEDFEBZHSYS SHEET 10F 2 I 2 2 nlu lllll P M II R Ill]. A

H M m UHHIHHHI PRIOR ART PRIOR ART PRIOR ART PRIOR ART INVENTORS. ABRAHAM BERMAN GEORGE V. GERBER ATTORNEY PATEVNTEDFEBZYIEIH SHEET 2 BF 2 Pi .6A

. INVENTORS.

ABRAHAM BERMAN BY GEORGE V. GERBER ATTORNEY.

ELECTRICAL COMPONENTS WITH FLEXIBLE TERMINAL MEANS.

FIELD OF INVENTION The present invention, relates to miniaturizedelectrical components andv the method;v of connecting somewhat rigid electrical connectorsto -suchele,ctrical components. More particularly, the presentinvention relates to an improved. method 1 of making electrical connections with athinfllm resistor;

BACKGROUND OF THE INVENTION- In recent years there has.been a. tendency to;.construct precision electrical components in extremely; small'sizes. Precision resistors, for-example, are; now constructed .by causing apredeterminedpattem of ,thin

metallic film tobe supported onathinsubstrate, Such.

resistors have distinct: advantages, over wire woundresistors with respect toreliability, economy, sizeand.

long term electrical and'mechanical stability.

The reduction in thesize of. electrical,components, however, has-causedproblems to arise, in connection.

with the attachment of electrical leads to such-com.- ponents. For example, the sizeof a typical thin fllmresistor-rchip is in the order of A inchzbyM II'ICI'IgBI'IdftI'IO area for attaching each electrical lead is; normally; less.-

than about 1/16 inch square. Despite-thissmallareafor attachment, the electrical. leadsmustbe so-fi'rmly con:

nected to the electricalcomponent; thatnormalstressv will notcause the electrical connections tobebroken.

Thus, as the size; of electrical; components has;

decreased the problems associated with-.the;attachment of electrical connections, have: tended to, increase, thereby losing some of the adyantagessoughtby.theat:

tempted miniaturization.v Attachment problems. have; also caused a fairly high percentageomanufactured;-. finished" componentsto be rejectedbyqualitycontrol;'

SUMMARYOF'IIHE; INVENTION An object ofthe present invention is to. provide, an: improvedthin film resistor.

Another. object of the: present invention is-to provide;

' improved means for attaching electrical connectorsto any electrical component, such as a thin. film resistor; chip.

A further. object offthe present invention is. to pro videv a thin film resistorwith electrical leads: bonded. to, such resistor in a manner, which will substantially prevent separation of the. electrical connection between, the leadsand resistor: under the; application of normal handling stress.

Still a further object, of the present invention is: to.

According to a, preferred embodiment of the invention, the'resulting electrical componentis encased in a rubbery orplasticmaterial after the electrical connections havebeen made. If desired, the encasedelectrical component canthen be covered with a still further rubbery or plasticmaterial or be enclosed ina suitable protective container,

BRIEF DESCRIPTION OF THE DRAWINGS Otherand further objects, advantages and features of the invention will beapparent to those skilledin the-art from the following detailed description thereof, taken in conjunction; with the accompanying drawings, in which: v

FIG. 1' illustrates in highly schematic form a prior art embodiment; in which. electrical connectors are attacheddirectly, to an electrical component;

FIG. 2iillustrates. in highly schematic form a prior art embodiment in. which electrical connectors are attached directly to anelectrical component at two opposingsidesof the electrical component;

' FIG. Sillustrates inhighly schematicform a prior art embodiment in which electrical, connection, between electricahconnectors and an electrical component is accomplishedbymeansofflexible leads;

FIG; 4A. illustrates in highlyschematic form the front viewiofsapriorart embodiment in which electricalconnection,betweenrelectricalconnectors and an electrical component is accomplished by means of flexibleleads; FIG. 4B isaside view of the embodiment illustrated in FIG; 4A; and. FlG tC' isa view of the embodiment shown, in- FIGS, 4A., and 4B. encased. in a protective coating;

FIGQSA isa highly schematic drawing which illustratesthefrontview, of an embodiment in accordance with, the; present invention wherein an electrical component isattached to electrical connectors ,atthe back of? the electrical component and electrical connection between the electricalconnectors and electricalcomponent-ismadeby means of flexible electrical leads extending from the front of the electrical component to lustrates, the; apparatus of FIG. 6C encased in a still the backof theelectrical component; FIG. 5Bis a side view ofthe embodiment shown in FIG. 5A; and FIG. 5C is a, view of; the embodiment illustrated in FIGS. 5A and 5B encased inside a plastic or; rubberizedgprotective coating; and v FIGS. 6A through 6D illustrate in highly schematic, form another schematic embodiment of the present invcntion in. which; the electrical connectors extend; at

right anglesto the flexible leads, and wherein FIG. 6A isv a front;vi ew; FIG. 6B; is a back view; FIG. 6C is a view ofthe apparatus shownv in FIGS. 6A and 6B encasedin a rubber or plastic protective coating; and FIG. 6D.-il-

further plastic or rubber protective coating.

DESCRIPTIONOF THE PREFERRED EMBODIMENTS The construction of miniaturized, electrical equip? mentisillustrated by the development of high precision, resistors, which are constructed) by supporting a1thin film of a. selected metal alloy upon a substrate having known; physical properties. Themetallic film is caused to have apredeterminedpattern, such that electric current; flows along a conductingpath ofvery great length any suitable material such as a ceramic material or glass and can be of the order of V4 inch X /i inch with a thickness of about 0.04 inch. The bulk metal film applied to the substrate can be made from a suitable resistive alloy such as one of the Nichrome alloys, wherein nickel and chromium are the principal metals..

This film can be of the order of 0.0001 inch thick. Typically, the metallic film applied to the substrate is photoetched to a pattern which establishes a narrow conductive path of much greater total length than the dimensions of the face of the substrate. This photoetching operation can be carried out after the film has been bonded to the substrate or it can be carried out when the metallic film is on a thin support such as a plastic layer before the plastic layer is bonded to the substrate.

FIG. 1 illustrates one of the procedures adopted by the prior art for attaching relatively rigid electrical connectors to a resistor chip l0. Rigid electrical connectors 11 and 12 are shown bonded to contact

pads

14 and 15, respectively, by some suitable means. Because of the rigidity of electrical connectors 11 and 12, the resistor of FIG. 1, even when encased in rubber or plastic, tends to be sensitive to handling and under stress the rigid electrical connectors frequently become separated from chip thereby destroying electrical contact with the resistor.

A prior art modification of the resistors shown in FIG. 1 is illustrated in FIG. 2. In an effort to prevent breaking, rigid electrical connectors or

wires

18 and 19 are attached to the side of the resistor chip by cement and then electrically bonded to contact

pads

14 and 15. This mode of attaching rigid

electrical connectors

18 and 19 to chip 10 fails, however, to overcome the problem of breaking under stress and tends to increase the size and cost of making resistors.

In another effort to eliminate breakage problems, flexible leads, such as flexible leads 22 and 23 in FIG. 3, have been utilized by the prior art. These flexible leads are bonded to contact pads 14 and of chip 10 and also to the rigid electrical connectors. In FIG. 3

flexible leads

22 and 23 are bonded to contact

pads

25 and 26, respectively. Rigid

electrical connectors

29 and 30, respectively, are also attached to contact

pads

25 and 26. The overall arrangement shown in FIG. 3 is not as rigid as that illustrated in FIGS. 1 and 2 and consequently the apparatus in FIG. 3 can be subjected to more stress without breaking the electrical contact at any point. Support problems arise, however,'inthe physical separation of

contact pads

14, 15, 25 and 26. The arrangement also necessitates a greatly enlarged case or a protective coating in order to seal the resistor in such a manner that only the end portions of rigid

electrical connectors

29 and 30 are exposed.

FIGS. 4A and 4B illustrate the front and side view, respectively, of a somewhat improved prior art resistor which utilizes flexible leads to connect chip 10 to rigid electrical connectors. As illustrated in FIGS. 4A and 4B, rigid

electrical connectors

32 and 33 extend up to and in back of chip10.'Flexible leads 36' and 37 are bonded directly to contact

pads

14 and 15 and also to rigid

electrical connectors

32 and 33, respectively. Although this arrangement is an improvement over other prior art procedures, it still did not overcome the problems which continued to plague this particular art. Breakage occurs with resistors constructed as in FIGS. 4A and 48 even when the electrical resistors are encased in a protective coating as shown in FIG. 4C. It is also hard to calibrate resistors prepared in accordance with FIGS. 4A and 43. Moreover, because of the necessity of covering all of resistor chip 10 and

flexible leads

36 and 37 with a protective coating, the size of the encased portion of the resistor has to be substantially greater than that of chip 10. As seen in FIG. 4C, when the resistor is encased in a rubber or plastic protective coating 40 elongated pant legs" 41 and 42 are required, extending down rigid

electrical connectors

32 and 33, respectively, in order to completely cover the flexible leads and particularly the point of their attachment to the rigid electrical connectors. If

pant legs

41 and 42 are too thin, too short, or irregularly shaped, a weak spot occurs in protective coating 40. As a result, when this type of procedure is employed for connecting flexible leads to rigid electrical connectors, an excess of protective coating material must be employed which increases the overall size and weight of the final resistor.

A preferred embodiment of the present invention is illustrated by FIGS. 5A to SC. As seen in FIGS. 5A and 58 one end of

flexible leads

47 and 48 is bonded to mounds. The resulting resistor is not only compact but substantially eliminates all breakage problems. Moreover, the resistor can be readily calibrated. An additional advantage is that the size of the final resistor encased in a protective coating 55 (see FIG. 5C) is kept at a minimum. In contrast to the elongated pant legs in FIG. 4C, no more than a normal amount of protective coating is required to completely encase both chip l0 and rigid

electrical connectors

50 and 52 in FIG. 5C. For clarity, flexible leads 47 and 48 have been shown as forming a loop over the top of chip 10. In actual practice flexible leads 47 and 48 are bent over the top of chip 10. Since these leads are generally made from a thin ribbon of material, the flexible leads remain flush with the surfaces of chip 10. Thus, when the completed resistor is encased in a protective coating 55 a very strong unit construction is obtained. The construction is such that movement or stress applied to rigid

electrical connectors

50 and 52 will not cause any breakage or otherwise destroy the resistor unless the rigid electrical connectors are completely ripped off the back of chip 10 against the resistance of protective coating 55 and cement 53. Until the rigid electrical connectors become unattached from the back of chip 10 no strain is placed on the flexible lead connections. This can be contrasted with the prior art embodiment illustrated in FIG. 4A where even if the rigid electrical connectors are cemented to the back of chip 10 the electrical connection through the flexible leads can be broken prior to any separation of the rigid electrical connectors and chip to.

Another preferred embodiment of the invention is illustrated in FIGS. 6A to 6D. As seen in FIGS. 6A and 6B, flexible leads 58 and 59 are bonded to contact

pads

44 and 45, respectively, and are also bonded to rigid

electrical connectors

62 and 63, respectively, on the reverse side of chip 10. As in the previous preferred embodiment, the rigid electrical connectors are cemented to the back of chip 10. However, unlike the embodiment illustrated in FIGS. 5A through 5C, the rigid electrical connectors are mounted substantially perpendicular to the flexible leads. A protective coating 65 (see FIG. 6C) is preferably used to encase the resistor in a manner similar to that illustrated in FIG. 5C. If desired, a still further protective coating, of the same or a different material, can be applied over protective coating 65. FIG. 6D illustrates the resistor of FIG. 6C further encased in a cylinder of suitable material, such as hard rubber, Bakelite, or epoxy resin.

Any conventional method of applying the protective coating or coatings to the electrical components made by the present invention can be employed. Suitable methods include dipping, painting, transfer molding, use of a fluidized bed, injection molding, etc.

The use of two or more different protective coatings applied at different stages helps prevent any fracturing resulting from differences in coefficients of thermal expansion. Moreover, the protective coatings can be specially chosen in order to obtain the most advantageous combination of properties. For example, the inner protective coating can be selected from a relatively soft silicone rubber whereas the final protective coating can be made from a relatively inflexible rubber or plastic material which has desirable insulating and sealing properties, such as hard rubber, polyesters, and epoxy resins. Other suitable protective coatings include polyurethanes. Evenwhen multiple protective coatings are applied to the electrical components prepared in accordance with the present invention, the. electrical components have a remarkable degree of compactness. For example, precision resistors have been prepared which require less than about an eighth of the board space occupied by conventional wire wound resistors.

It will be understood that, if desired, multiple chips rather than single chips can be incorporated into the same protective coating. It will also be understood that there can be more than two electrical connections present if so desired.

In order to minimize the size of electrical components reference has been made in this specification to the bonding of electrical connectors to the nonconducting surface on the back of an electrical component. It will be understood that if a somewhat elongated electrical component had one or more nonconductive surfaces adjacent to one or more conductive surfaces on the same side, that the present invention could be adapted for such a modification by bonding the electrical connectors to either side of the electrical component.

From the foregoing, it will be seen that this invention is well adapted to obtain all of the ends and objects hereinabove set forth, together with other advantages which are obvious and which are inherent to the system. Electrical components of the present invention have the advantage of being reliable, economical to construct, capable. of being made in extremely small sizes, and have excellent long term electrical and mechanical stability. The absence of sensitivity to han- 5 dling is of particularimportance. The electrical contact which is made in accordance with the attachment procedure of the present invention cannot be broken by any ordinary manipulation of the electrical connectors during the interconnection of an electrical component. Thus, a problem which has plagued the art is eliminated without any significant increase in either cost or size.

Obviously, many other modifications and variations 15 of the invention as hereinbefore set forth may be made without departing from the spirit and scope thereof.

What is claimed is: 1. The combination of an electrical component, flexible leads and relatively rigid electrical connectors 20 wherein each relatively rigid electrical connector is bonded to the back of the electrical component and separately extends beyond only one edge of said electrical component, and the flexible leads are separately connected to the front of the electrical component and 25 to the electrical connectors on the back of the electrical component the flexible leads extending over an edge of said electrical component thereby making an electrical connection between the relatively rigid electricalconnectors and the electrical component.

2. The combination as set forth in claim 1 wherein the electrical component, flexible leads and at least part of the relatively rigid electrical connectors are protected by at least one covering.

3. The combination as set forth in claim 1 wherein the electrical component is a precision resistor having a thin metallic film supported on a substrate on the front of the electrical component and the flexible leads connect the thin metallic film with the relatively rigid electrical connectors.

4. Electrical apparatus comprising:

an electrical component having an electrically conductive surface and a substantially non-conducting surface which forms at least a portion of the back of the electrically conductive surface;

at least two relatively rigid electrical connectors bonded to the substantially non-conducting surface of the electrical component, eachrelatively rigid electrical connector separately extending beyond only one edge of said substantially nonconducting surface; and

at least two flexible leads separately connected to the electrically conductive surface of the electrical component and to the electrical connectors on the substantially non-conducting surface the leads extending over an edge of said electrical component,

such that one flexible lead is connected to one electrical connector. 5. Electrical apparatus as in claim 4 protected by at 0 least one covering.

6. Electrical apparatus as in claim 4 wherein the electrical component is a thin film resistor.

7. Electrical apparatus comprising:

an electrical component consisting essentially of a thin film resistor mounted on a substantially nonconducting surface which forms the back of the thin film resistor;

at least two relatively rigid electrical connectors bonded to the substantially non-conducting surface of the electrical component, each relatively rigid electrical connector separately extending beyond only one edge of said substantially nonconducting surface; and at least two flexible leads separately connected to the thin film resistor and to the relatively rigid electrical connectors, the leads extending over an edge of said electrical component such that each flexible lead is separately connected to an electrical connector on the substantially non-conducting surface. .8. The apparatus of claim 7 wherein two relatively rigid electrical connectors are present and said relatively rigid electrical connectors extend in different directions from the electrical component.

9. Electrical apparatus protected by at least one covering comprising:

at least two relatively rigid electrical connectors bonded to the substantially non-conducting surface of the electrical component, each relatively rigid electrical connector separately extending beyond only one edge of said substantially nonconducting surface; and

at least two flexible leads separately connected to the thin film resistor and to the relatively rigid electrical connectors, the leads extending over an edge of said electrical component such that each flexible lead is separately connected to an electrical connector on the substantially non-conducting surface.

10. The process for attaching electrical leads to an electrical component having as opposing surfaces an electrically conductive surface and a substantially nonl conducting surface which comprises:

bonding at least two relatively rigid electrical connectors to the substantially non-conducting surface such that each electrical connector separately extends beyond only one edge of said non-conducting surface, and

separately connecting a flexible lead to the electrically conducting surface and to each relatively rigid electrical connector on the substantially nonconducting surface the connection made by extending the leads over an edge of said electrical component.

Claims

1. The combination of an electrical component, flexible leads and relatively rigid electrical connectors wherein each relatively rigid electrical connector is bonded to the back of the electrical component and separately extends beyond only one edge of said electrical component, and the flexible leads are separately connected to the front of the electrical component and to the electrical connectors on the back of the electrical component the flexible leads extending over an edge of said electrical component thereby making an electrical connection between the relatively rigid electrical connectors and the electrical component.

4. Electrical apparatus comprising: an electrical component having an electrically conductive surface and a substantially non-conducting surface which forms at least a portion of the back of the electrically conductive surface; at least two relatively rigid electrical connectors bonded to the substantially non-conducting surface of the electrical component, each relatively rigid electrical connector separately extending beyond only one edge of said substantially non-conducting surface; and at least two flexible leads separately connected to the electrically conductive surface of the electrical component and to the electrical connectors on the substantially non-conducting surface the leads extending over an edge of said electrical component, such that one flexible lead is connected to one electrical connector.

5. Electrical apparatus as in claim 4 protected by at least one covering.

7. Electrical apparatus comprising: an electrical component consisting essentially of a thin film resistor mounted on a substantially non-conducting surface which forms the back of the thin film resistor; at least two relatively rigid electrical connectors bonded to the substantially non-conducting surface of the electrical component, each relatively rigid electrical connector separately extending beyond only one edge of said substantially non-conducting surface; and at least two flexible leads separately connected to the thin film resistor and to the relatively rigid electrical connectors, the leads extending over an edge of said electrical component such that each flexible lead is separately connected to an electrical connector on the substantially non-conducting surface.

8. The apparatus of claim 7 wherein two relatively rigid electrical connectors are present and said relatively rigid electrical connectors extend in different directions from the electrical component.

9. Electrical apparatus protected by at least one covering comprising: an electrical component consisting essentially of a thin film resistor mounted on a substantially non-conducting surface which forms the back of the thin film resistor; at least two relatively rigid electrical connectors bonded to the substantially non-conducting surface of the electrical component, each relatively rigid electrical connector separately extending beyond only one edge of said substantially non-conducting surface; and at least two flexible leads separately connected to the thin film resistor and to the relatively rigid electrical connectors, the leads extending over an edge of said electrical component such that each flexible lead is separately connected to an electrical connector on the substantially non-conducting surface.

10. The process for attaching electrical leads to an electrical component having as opposing surfaces an electrically conductive surface and a substantially non-conducting surface which comprises: bonding at least two relatively rigid electrical connectors to the substantially non-conducting surface such that each electrical connector separately extends beyond only one edge of said non-conducting surface, and separately connecting a flexible lead to the electrically conducting surface and to each relatively rigid electrical connector on the substantially non-conducting surface the connection made by extending the leads over an edge of said electrical component.

11. A process as in claim 10 which includes the step of applying a protective covering to the electrical component, each flexible lead and at least part of each relatively rigid electrical connector.

12. The process as in claim 10 wherein the electrical leads are separately connected to a thin film resistor which constitutes the electrically conducting surface of the electrical component.