Not Applicable
This disclosure relates to the field of conductive polymer electronic components and devices. In particular, it relates to resistive devices comprising a layer of thermally-sensitive resistive material, such as a conductive polymer, that is laminated between a pair of planar electrodes, wherein the device has a surface-mountable configuration.
Conductive polymer thermally-sensitive resistive devices have become commonplace on electronic circuits. These include devices that exhibit a positive temperature coefficient of resistivity (PTC) and a negative temperature coefficient of resistivity (NTC). In particular, resistive devices comprising a conductive polymer resistive material exhibiting a positive temperature coefficient of resistivity (PTC) have found widespread uses as over-current protection devices or “self-resettable fuses,” due to their ability to undergo a rapid and drastic (at least three or four orders of magnitude) increase in resistance in response to an over-current situation.
It is a common design goal for electronic components to reduce the surface area or “footprint” that they occupy on a circuit board, so that circuit boards can be made as small as possible, and so that component density on a circuit board of a specific area can be increased. One way of achieving a compact geometry, while also achieving economies in manufacturing costs, is to configure the components to be “surface-mountable” on a circuit board. A surface-mountable component is flush-mounted on conductive terminal pads on the board, without the need for sockets or through-board pins.
Various surface-mountable configurations have been devised for conductive polymer thermal-resistive devices, particularly PTC devices. There are several design criteria in making surface-mountable conductive polymer PTC devices, besides the criterion of having a small footprint. For example, the design of the devices must lend itself to low manufacturing costs. Furthermore, the design must provide for integrity of the connections between the metallic elements (electrodes and terminals) and the non-metallic (polymer) element(s). In many cases, the design is a compromise among these various criteria.
One problem with surface-mountable conductive polymer devices is that the metal elements tend to impose a physical constraint on the thermal expansion of the polymeric element(s) when they experience an over-current situation. Conductive polymer PTC elements are typically formed from an organic polymer, such as polyethylene, into which is mixed conductive particles, such as carbon black or metallic particles. The conductivity (or, conversely, the resistivity) of the composition is determined, in substantial part, by the average spacing between the conductive particles. The drastic and sudden increase in resistivity of a conductive polymer element in a PTC device upon experiencing an over-current condition is due to a thermally-induced expansion of the polymer element, which increases the average spacing between the conductive particles within the polymeric material. To the extent that the metallic elements of such a device impose physical constraints on the expansion of the conductive polymer element(s), the functionality of the device may be impaired, especially after repeated over-current “trippings.” For example, “repeatability” (the characteristic of the device to exhibit substantially the same operational parameters) may degrade over a multitude of duty cycles (over-current tripping and subsequent resetting upon removal of the overvoltage), due to a kind of stress-induced “hysteresis” effect.
In particular, typical prior art conductive polymer PTC devices tend to exhibit poor resistance stability as a function of the number of duty cycles. This means that the normal (non-over-current condition) resistance in many prior art conductive polymer PTC devices tends to increase markedly after as few as 40-50 duty cycles. Furthermore, to the extent that the metal elements allow at least some degree of polymeric expansion, the metal elements are subject to mechanical stresses that may compromise the physical integrity of the device over repeated duty cycles.
Thus, there has been a long-felt, but as yet unsatisfied, need for a surface-mountable conductive polymer resistive device, particularly a PTC device, that is economical to manufacture, that has a small circuit board footprint, and that allows adequate thermal expansion of the polymer element without subjecting the metal elements to undue stress.
In one embodiment, a surface-mountable conductive polymer electronic device comprises at least one active layer of a conductive polymer material; an upper electrode abutting an upper surface of the active layer; a lower electrode abutting a lower surface of the active layer; an upper insulation layer abutting an upper surface of the upper electrode; a lower insulation layer abutting a lower surface of the lower electrode; first and second terminals abutting a lower surface of the lower insulation layer; a first cross-conductor adjacent a first end of the device; and a second cross-conductor adjacent a second, opposite, end of the device. The first cross-conductor connects the lower electrode and the first terminal, and a portion of the upper insulation layer separates the first cross-conductor from the upper electrode. The second cross-conductor connects the upper electrode and the second terminal, and a portion of the lower insulation layer separates the second cross-conductor from the lower electrode.
In another embodiment, a surface-mountable conductive polymer electronic device comprises at least a first active layer of a conductive polymer material; a first electrode abutting an upper surface of the first active layer; a second electrode abutting a lower surface of the first active layer; an upper insulation layer abutting an upper surface of the first electrode; at least a second active layer of a conductive polymer material positioned beneath the first active layer; a third electrode abutting an upper surface of the second active layer; a fourth electrode abutting a lower surface of the second active layer; a lower insulation layer abutting a lower surface of the fourth electrode; an intermediate insulation layer sandwiched between and abutting the second and third electrodes; first and second terminals abutting a lower surface of the lower insulation layer; a first cross-conductor adjacent a first end of the device; and a second cross-conductor adjacent a second, opposite, end of the device. The first cross-conductor connects the second and third electrodes and the first terminal. A portion of the upper insulation layer separates the first cross-conductor from the first electrode, and a portion of the lower insulation layer separates the first cross-conductor from the fourth electrode. The second cross-conductor connects the first and fourth electrodes and the second terminal. Portions of the intermediate insulation layer separate the second cross-conductor from the second and third electrodes.
In a further embodiment, a surface-mountable conductive polymer electronic device comprises at least a first active layer of a conductive polymer material; a first electrode abutting an upper surface of the first active layer; a second electrode abutting a lower surface of the first active layer; an upper insulation layer abutting an upper surface of the first electrode; at least a second active layer of a conductive polymer material positioned beneath the first active layer; a third electrode abutting an upper surface of the second active layer; a fourth electrode abutting a lower surface of the second active layer; a lower insulation layer abutting a lower surface of the fourth electrode; an intermediate insulation layer sandwiched between and abutting the second and third electrodes; first and second terminals abutting a lower surface of the lower insulation layer; a first cross-conductor adjacent a first end of the device; and a second cross-conductor adjacent a second, opposite, end of the device. The first cross-conductor connects the second and fourth electrodes and the first terminal. A portion of the upper insulation layer separates the first cross-conductor from the first electrode, and a portion of the intermediate insulation layer separates the first cross-conductor from the third electrode. The second cross-conductor connects the first and third electrodes and the second terminal. A portion of the lower insulation layer separates the second cross-conductor from the fourth electrode, and a portion of the intermediate insulation layer separates the second cross-conductor from the second electrode.
In still another embodiment, a surface-mountable conductive polymer electronic device comprises at least a first active layer of a conductive polymer material; a first electrode abutting an upper surface of the first active layer; a second electrode abutting a lower surface of the first active layer; an upper insulation layer abutting an upper surface of the first electrode; at least a second active layer of a conductive polymer material positioned beneath the first active layer; a third electrode abutting an upper surface of the second active layer; a fourth electrode abutting a lower surface of the second active layer; a first intermediate insulation layer sandwiched between and abutting the second and third electrodes; at least a third active layer of a conductive polymer material positioned beneath the second active layer; a fifth electrode abutting an upper surface of the second active layer; a sixth electrode abutting a lower surface of the second active layer; a second intermediate insulation layer sandwiched between and abutting the fourth and fifth electrodes; a lower insulation layer abutting a lower surface of the sixth electrode; first and second terminals abutting a lower surface of the lower insulation layer; a first cross-conductor adjacent a first end of the device; and a second cross-conductor adjacent a second, opposite, end of the device. The first cross-conductor connects the second, third and sixth electrodes and the first terminal. A portion of the upper insulation layer separates the first cross-conductor from the first electrode, and portions of the second intermediate insulation layer separate the first cross-conductor from the fourth and fifth electrodes. The second cross-conductor connects the first, fourth and fifth electrodes and the second terminal, and portions of the first intermediate insulation layer separate the second cross-conductor from the second and third electrodes.
In a still further embodiment, a surface-mountable conductive polymer electronic device comprises a conductive polymer active layer laminated between an upper electrode and a lower electrode; an upper insulation layer applied on the upper electrode and a lower insulation layer applied on the lower electrode; first and second planar conductive terminals formed on the lower insulation layer; a first cross-conductor connecting the lower electrode and the first terminal, and separated from the upper electrode by a portion of the upper insulation layer; and a second cross-conductor connecting the upper electrode and the second terminal, and separated from the lower electrode by a portion of the lower insulation layer. The invention also encompasses a multi-active layer device that comprises two or more single active layer devices, as defined above, arranged in a vertically-stacked configuration and electrically connected in parallel.
In another aspect of this disclosure, a first embodiment of a method of producing a surface-mountable conductive polymer electronic device comprises the steps of: providing a conductive polymer substrate; laminating the polymer substrate between upper and lower metal layers; masking and etching the upper and lower metal layers to form, respectively, upper and lower electrodes; forming upper and lower insulation layers on the upper and lower electrodes, respectively; applying upper and lower metallization layers to the upper and lower insulation layers, respectively; forming through-hole vias in the device to provide for cross-conductors; plating the upper metallization layer, the lower metallization layer and the vias to form the cross-conductors; masking the vias and masking and etching the lower metallization layer to form first and second planar, surface-mount terminal pads; plating exposed metal areas of the device; and singulating the device from a laminated structure along grid lines.
Another embodiment of a method of producing a surface-mountable conductive polymer electronic device comprises the steps of: providing a conductive polymer substrate; laminating the polymer substrate between upper and lower metal layers; masking and etching the upper and lower metal layers to form, respectively, upper and lower electrodes; forming upper and lower insulation layers on the upper and lower electrodes, respectively; applying upper and lower metallization layers to the upper and lower insulation layers, respectively; forming through-hole vias in the device to provide for cross-conductors; plating the upper metallization layer, the lower metallization layer and the vias to form the cross-conductors; photo-resist masking portions of the lower metallization layer, leaving unmasked portions of the lower metallization layer, photo-resist masking all of the upper metallization layer, and leaving the plated vias unmasked; electroplate depositing an over-plate layer or layers on the unmasked portions of the lower metallization layer and on the vias; removing the photo-resist masking from the masked portions of the lower metallization layer and the upper metallization layer; etching through the previously masked portions on the lower metallization layer to the lower insulation layer to form first and second planar, surface-mount terminal pads, and etching through the upper metallization layer; and singulating the device from a laminated structure along grid lines.
Another embodiment of a method of producing a surface-mountable conductive polymer electronic device comprises the steps of: providing a conductive polymer substrate; laminating the polymer substrate between upper and lower metal layers; masking and etching the upper and lower metal layers to form, respectively, upper and lower electrodes; forming upper and lower insulation layers on the upper and lower electrodes, respectively; applying upper and lower metallization layers to the upper and lower insulation layers, respectively; forming through-hole vias in the device to provide for cross-conductors; plating the upper metallization layer, the lower metallization layer and the vias to form the cross-conductors; photo-resist masking portions of the lower metallization layer, leaving unmasked portions of the lower metallization layer, photo-resist masking portions of the upper metallization layer, leaving unmasked portions of the upper metallization layer, and leaving the vias unmasked; electroplate depositing an over-plate layer or layers on the unmasked portions of the lower metallization layer, on the unmasked portions of the upper metallization layer, and on the vias; removing the photo-resist masking from the masked portions of the lower metallization layer and the upper metallization layer; etching through the previously masked portions on the lower metallization layer to the lower insulation layer to form first and second planar, surface-mount terminal pads, and etching through the previously masked portions on the upper metallization layer to the upper insulation layer to form an anchor pad; and singulating the device from a laminated structure along grid lines.
Another embodiment of a method of producing a surface-mountable conductive polymer electronic device, comprises the steps of laminating a conductive polymer substrate between upper and lower metal foil layers; removing a portion of the upper and lower foil layers to form upper and lower electrodes; applying an upper and a lower insulation layer on the upper and lower electrodes, respectively, applying a bottom metallization layer on the bottom insulation layer; forming an array of through-hole vias; plating the vias so as to form a first cross-conductor connecting the upper electrode to the bottom metallization layer and a second cross-conductor connecting the lower electrode to the bottom metallization layer; and removing part of the bottom metallization layer to form a pair of surface mount terminals, each connected to one of the upper and lower electrodes by one of the cross-conductors and isolated by a portion of one of the insulation layers from the other of the upper and lower electrodes.
b, and 17C are a top plan view, a cross-sectional view, and a bottom plan view, respectively, of a dual active layer conductive polymer device in accordance with the eighth embodiment of the present invention;
b, and 19C are a top plan view, a cross-sectional view, and a bottom plan view, respectively, of a dual active layer conductive polymer device in accordance with the ninth embodiment of the present invention;
As used herein, the terms “invention” and “present invention” are to be understood as encompassing the invention described herein in its various embodiments and aspects, as well as any equivalents that may suggest themselves to those skilled in the pertinent arts.
The various embodiments of the present invention are made with one or more laminated sheet structures, of the type shown in
The metal layers 12, 14 are preferably made of conductive metal foil, and more preferably a nickel-plated copper foil that is nodularized (by conventional techniques) on the surface that is placed against the polymeric layer. In a specific example embodiment, the metal layers 12, 14 are of nodularized nickel-plated copper foil having a thickness of about 18 microns. The lamination may be performed by any suitable lamination process known in the art, an example of which is described in International Patent Publication No. WO 97/06660, the disclosure of which is incorporated herein by reference.
As an alternative to laminating a layer of polymeric material between upper and lower foil sheets, it may be advantageous, for certain applications, to metallize directly the upper and lower surfaces of a sheet of polymeric material. The metallization may be accomplished by a metal plating process, vapor deposition, screen-printing, or any other suitable process that may suggest itself to those skilled in the pertinent arts. The preferred embodiments of the present invention, however, use the laminated structure described above, and the ensuing description will be based on the use of the lamination process.
As will be described below, the upper and lower metal layers 12, 14 are photo-resist masked and etched to form electrodes (not shown in
As will be explained in detail below, an array of through-hole vias (not shown in
The laminated sheet structure 10 is typically sized to provide a matrix comprising a multitude of electronic devices. Thus, as shown in
The devices described below are advantageously mass-produced while interconnected in a matrix provided by a single laminated sheet structure 10 (for a single active layer device), or in a matrix formed by the lamination of two or more sheet structures into a multi-layer laminated structure (for a device having two or more active layers). The matrix is then singulated (e.g., along the lines 26) to form individual devices. The discussion below will be set forth with reference to the illustration of a single device, but it is to be understood that the process steps described below are performed on a matrix of such devices while they are interconnected in such a matrix. Thus, each step is performed simultaneously at a plurality of pre-defined locations on the matrix. As a final step in the manufacturing processes described below, the individual devices are separated from the matrix (singulated) by cutting, breaking, or dicing the matrix along the singulation lines 26, or along a grid of separation lines defined by the singulation apparatus (if the singulation lines are not pre-formed).
An upper insulation layer 42, which may be of prepreg, an insulative polymer, or an epoxy, is applied to the exposed surface of the upper electrode 34, and a lower insulation layer 44, of similar material, is applied to the exposed surface of the lower electrode 36. The upper insulation layer 42 fills the upper isolation area 38, while the lower insulation layer 44 fills the lower isolation area 40. A bottom metallization layer, preferably a metal foil, (such as, for example, a copper foil) is applied to the exposed surface of the lower insulation layer. First and second surface mount terminals 46, 48, will be formed from the bottom metallization layer, as will be described below. Similarly, a top metallization layer, preferably a metal foil (such as, for example, a copper foil), may optionally be applied to the upper insulation layer 42 to form identification indicia 50, as also described below. The top metallization layer (if present) and the upper insulation layer 42 may be pre-formed and applied as a laminate, or they may be applied separately in sequence. Likewise, the bottom metallization layer and the bottom insulation layer 44 may be applied either together as a pre-formed laminate, or separately in sequence. In either case, the result is a laminated structure comprising a single active polymer layer 32, an upper electrode 34, a lower electrode 36, a top insulation layer 42, a bottom insulation layer 44, a bottom metallization layer, and (optionally) a top metallization layer.
A first through-hole via 52 is formed through the entire thickness of the above-described laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 54 is similarly (and, preferably, simultaneously) formed through the entire thickness of the laminated structure at each of the second plurality of via locations. Thus, each device 30 has a first through-hole via 52 at a first end, and a second through-hole via 54 at the opposite end. At this point, the top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 52, 54 are plated with one or more layers of conductive metal, thereby forming a first set of electrically conductive interconnections or “cross-conductors” 56 within each of the first set of vias 52, and a second set of cross-conductors 58 within each of the second set of vias 54. The metallization may be by any suitable process, and in a preferred embodiment, comprises at least an electroplated copper layer. Each of the first set of cross-conductors 56 establishes physical and electrical contact with the lower electrode 36, and the bottom metallization layer, and, if present, the top metallization layer, while being electrically isolated from the upper electrode 34 by the upper isolation area 38. Similarly, each of the second set of cross-conductors 58 establishes physical and electrical contact with the upper electrode 34 and the top and bottom metallization layers, while being electrically isolated from the lower electrode 36 by the lower isolation area 40.
The bottom metallization layer is formed into first and second planar surface-mount terminals 46, 48 by removing the central portion of the bottom metallization layer by any conventional technique, preferably by photo-resist masking and etching. This process leaves a planar metallized first surface-mount terminal 46 and a planar metallized second surface-mount terminal 48 on the bottom surface of the device 30, separated from each other by an exposed portion of the lower insulation layer 44. The first terminal 46 is in electrical contact with the lower electrode 36 through the first cross-conductor 56, while the second terminal 48 is in electrical contact with the upper electrode 34 through the second cross-conductor 58. If a top metallization layer has been applied, as mentioned above, the photo-resist masking and etching process may be employed to remove all of the top metallization layer except for those portions that represent the indicia 50. The exposed metal areas, particularly the terminals 46, 48 and the cross-conductors 56, 58 (and the indicia 50, if present), may advantageously be over-plated with one or more solderable metal layers, such as, for example, electroless-plated nickel followed by immersion-plated gold (a process known as Electroless Nickel/Immersion Gold plating, or “ENIG” plating). Alternatively, a single electroless-plated layer of tin may be applied.
Alternatively, as will be discussed below, the over-plating with solderable metals may be performed immediately after the copper-plating, and before the formation of the surface-mount terminals (and the optional indicia). In that case, the over-plating is preferably electroplated nickel followed by electroplated gold or tin. Alternatively, only an electroplated layer of tin may be applied.
A top insulation layer 82, which may be of prepreg, an insulative polymer, or an epoxy, is applied to the exposed surface of the first electrode 74a, and a bottom insulation layer 84, of similar material, is applied to the exposed surface of the fourth electrode 74d. The top insulation layer 82 fills the upper isolation area 76a, while the bottom insulation layer 84 fills the lower isolation area 76b. A bottom metallization layer, preferably a copper foil, is applied to the exposed surface of the bottom insulation layer to form first and second surface mount terminals or terminal pads 86, 88, as will be described below. Similarly, a top metallization layer, preferably a copper foil, may optionally be applied to the top insulation layer 82 to form identification indicia 90, as also described below. The top metallization layer (if present) and the top insulation layer 82 may be pre-formed and applied as a laminate, or they may be applied separately in sequence. Likewise, the bottom metallization layer and the bottom insulation layer 84 may be applied either together as a pre-formed laminate, or separately in sequence. In either case, the result is a multiple active layer laminated structure comprising first and second active polymer layers 72a, 72b, a first or upper electrode 74a, intermediate second and third electrodes 74b, 74c, a fourth or lower electrode 74d, an intermediate insulation layer 80, a top insulation layer 82, a bottom insulation layer 84, a bottom metallization layer, and (optionally) a top metallization layer.
A first through-hole via 92 is formed through the entire thickness of the above-described multiple active layer laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 94 is similarly (and, preferably, simultaneously) formed through the entire thickness of the structure at each of the second plurality of via locations. Thus, each device 70 has a first through-hole via 92 at a first end, and a second through-hole via 94 at the opposite end. At this point, the top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 92, 94 are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 96 within each of the first set of vias 92, and a second set of cross-conductors 98 within each of the second set of vias 94. Each of the first set of cross-conductors 96 establishes physical and electrical contact with the second and third (intermediate) electrodes 74b, 74c and the top and bottom metallization layers, while being electrically isolated from the first (upper) electrode 74a by the upper isolation area 76a, and from the fourth (lower) electrode by the lower isolation layer 76b. Similarly, each of the second set of cross-conductors 98 establishes physical and electrical contact with the first (upper) electrode 74a and the fourth (lower) electrode 74d and the top and bottom metallization layers, while being electrically isolated from the second and third (intermediate) electrodes 74b, 74c by the intermediate isolation areas 78a, 78b.
The bottom metallization layer is formed into first and second terminals or terminal pads 86, 88 by removing the central portion of the bottom metallization layer by any conventional technique, preferably by photo-resist masking and etching. This process leaves a planar metallized first surface-mount terminal 86 and a planar metallized second surface-mount terminal 88 on the bottom surface device 70, separated from each other by an exposed portion of the bottom insulation layer 84. The first terminal 86 is in electrical contact with the second and third (intermediate) electrodes 74b, 74c through the first cross-conductor 96, while the second terminal 88 is in electrical contact with the first (upper) electrode 74a and the fourth (lower) electrode 74d through the second cross-conductor 98. If a top metallization layer has been applied, as mentioned above, the masking and photo-etching process may be employed to remove all of the top metallization layer except for those portions that represent the indicia 90. The exposed metal areas, particularly the terminals 86, 88 and the cross-conductors 96, 98 (and the optional indicia 90, if present), may advantageously be over-plated with one or more solderable metal layers, such as, for example, nickel and gold ENIG plating, or just electroless tin plating. Alternatively, as mentioned above, the overplating can be performed immediately after the copper plating with electroplated nickel followed by electroplated gold or tin, or just electroplated tin.
The first and second pluralities of via locations are defined as described above. A first through-hole via 152 is formed through the entire thickness of the above-described laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 154 is similarly (and, preferably, simultaneously) formed through the entire thickness of the multi-layer structure at each of the second plurality of via locations. Thus, each device 130 has a first through-hole via 152 at a first end, and a second through-hole via 154 at the opposite end. At this point, the top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 152, 154 are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 156 within each of the first set of vias 152, and a second set of cross-conductors 158 within each of the second set of vias 154. Each of the first set of cross-conductors 156 establishes physical and electrical contact with the lower electrode 136 and the top and bottom metallization layers, while being electrically isolated from the upper electrode 134 by the upper isolation area 138. Similarly, each of the second set of cross-conductors 158 establishes physical and electrical contact with the upper electrode 134 and the top and bottom metallization layers, while being electrically isolated from the lower electrode 136 by the lower isolation area 140.
The bottom metallization layer is formed into first and second terminals 146, 148 by removing the central portion of the bottom metallization layer by any conventional technique, preferably by photo-masking and etching. This process leaves a planar metallized first surface-mount terminal 146 and a planar metallized second surface-mount terminal 148 on the bottom surface device 130, separated from each other by an exposed portion of the bottom insulation layer 144. The first terminal 146 is in electrical contact with the lower electrode 136 through the first cross-conductor 156, while the second terminal 148 is in electrical contact with the upper electrode 134 through the second cross-conductor 158. If a top metallization layer has been applied, as mentioned above, the masking and etching process may be employed to remove all of the top metallization layer except for those portions that represent the indicia 150. The exposed metal areas, particularly the terminals 146, 148 and the cross-conductors 156, 158, may advantageously be over-plated with one or more solderable metal layers, such as, for example, the nickel and gold ENIG plating, as described above, or just electroless-plated tin. Alternatively, the over-plating can be electroplated nickel and gold, electroplated nickel and tin, or just electroplated tin, performed immediately after the copper plating step.
A top insulation layer 182, which may be of prepreg, an insulative polymer, or an epoxy, is applied to the exposed surfaces of the first electrode 174a and the upper residual foil area 177a, and a bottom insulation layer 184, of similar material, is applied to the exposed surfaces of the fourth electrode 174d and the lower residual foil area 177b. The top insulation layer 182 fills the upper isolation area 176a, while the bottom insulation layer 184 fills the lower isolation area 176b. A bottom metallization layer, preferably a copper foil, is applied to the exposed surface of the bottom insulation layer to form first and second surface mount terminals 186, 188, as will be described below. Similarly, a top metallization layer, preferably a copper foil, may optionally be applied to the top insulation layer 182 to form identification indicia 190, as also described below. The top metallization layer (if present) and the top insulation layer 182 may be pre-formed and applied as a laminate, or they may be applied separately in sequence. Likewise, the bottom metallization layer and the bottom insulation layer 184 may be applied either together as a pre-formed laminate, or separately in sequence. In either case, the result is a multiple active layer laminated structure comprising first and second active polymer layers 172a, 172b, a first or upper electrode 174a, intermediate second and third electrodes 174b, 174c, a fourth or lower electrode 174d, an intermediate insulation layer 180, a top insulation layer 182, a bottom insulation layer 184, a bottom metallization layer, and (optionally) a top metallization layer.
A first through-hole via 192 is formed through the entire thickness of the above-described multiple active layer laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 194 is similarly (and, preferably, simultaneously) formed through the entire thickness of the structure at each of the second plurality of via locations. Thus, each device 170 has a first through-hole via 192 at a first end, and a second through-hole via 194 at the opposite end. At this point, the top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 192, 194 are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 196 within each of the first set of vias 192, and a second set of cross-conductors 198 within each of the second set of vias 194. Each of the first set of cross-conductors 196 establishes physical and electrical contact with the second and third (intermediate) electrodes 174b, 174c and the top and bottom metallization layers, while being electrically isolated from the first (upper) electrode 174a by the upper isolation area 176a, and from the fourth (lower) electrode by the lower isolation layer 176b. Similarly, each of the second set of cross-conductors 198 establishes physical and electrical contact with the first (upper) electrode 174a and the fourth (lower) electrode 174d and the top and bottom metallization layers, while being electrically isolated from the second and third (intermediate) electrodes 174b, 174c by the intermediate isolation areas 178a, 178b.
The bottom metallization layer is formed into first and second terminals 186, 188 by removing the central portion of the bottom metallization layer by any conventional technique, preferably by photo-resist masking and etching. This process leaves a planar metallized first surface-mount terminal 186 and a planar metallized second surface-mount terminal 188 on the bottom surface of the device 170, separated from each other by an exposed portion of the bottom insulation layer 184. The first terminal 186 is in electrical contact with the second and third (intermediate) electrodes 174b, 174c through the first cross-conductor 196, while the second terminal 188 is in electrical contact with the first (upper) electrode 174a and the fourth (lower) electrode 174d through the second cross-conductor 198. If a top metallization layer has been applied, as mentioned above, the masking and photo-etching process may be employed to remove all of the top metallization layer except for those portions that represent the indicia 190. The exposed metal areas, particularly the terminals 186, 188 and the cross-conductors 196, 198, (and the indicia 190, if present) may advantageously be over-plated with one or more solderable metal layers, such as, for example, the nickel and gold ENIG plating, or just electroless-plated tin, as described above. Alternatively, the over-plating may electroplated nickel and hold, electroplated nickel and tin, or just electroplated tin, performed immediately after the copper plating step.
A first through-hole via 252 is formed through the entire thickness of the above-described laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 254 is similarly (and, preferably, simultaneously) formed through the entire thickness of the laminated structure at each of the second plurality of via locations. Thus, each device 230 has a first through-hole via 252 at a first end, and a second through-hole via 254 at the opposite end. At this point, the top entrance or opening of each of the vias 252, 254 is chamfered or beveled by any suitable method or mechanism known in the art, such as, for example, a drill with a conical drill bit (not shown), to form a chamfered or beveled first entry hole 260 for the first via 252, and a similar chamfered or beveled second entry hole 262 for the second via 254. The first entry hole 260 extends through the upper insulation layer 242 and the first isolation area 238, leaving a portion of the first isolation area 238 to separate the first entry hole 260 from a first end of the upper electrode 234, while the second entry hole 262 extends through the upper insulation layer 242 to the second via 254 either adjacent to or through the opposite end of the upper electrode 234. Although it is preferred to drill the vias 252, 254 first, and then to form the chamfered or beveled entry holes 260, 262, the chamfered or beveled entry holes 260, 262 may be formed at the pre-defined via locations before the vias 252, 254 are drilled.
The top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 252, 254, including their respective entry holes 260, 262, are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 256 within each of the first set of vias 252 and first chamfered or beveled entry hole 260, and a second set of cross-conductors 258 within each of the second set of vias 254 and second chamfered or beveled entry hole 262. Each of the first set of cross-conductors 256 establishes physical and electrical contact with the lower electrode 236 and the top and bottom metallization layers, while being electrically isolated from the upper electrode 234 by the upper isolation area 238. Similarly, each of the second set of cross-conductors 258 establishes physical and electrical contact with the upper electrode 234 and the top and bottom metallization layers, while being electrically isolated from the lower electrode 236 by the lower isolation area 240. Each of the copper-plated first vias 252 provides a first cross-conductor 256 with a sloped shoulder provided by a first chamfered entry hole 260. Likewise, each of the copper-plated second vias 254 provides a second cross-conductor 258 with a sloped shoulder provided by a second chamfered entry hole 262. The sloped shoulders of the cross-conductors 256, 258 establish a more intimate and secure contact with the top insulation layer 242 than that established by a cross-conductor formed through a straight via, such as that shown in
The bottom metallization layer is formed into first and second terminals 246, 248 by removing the central portion of the bottom metallization layer by any conventional technique, preferably by photo-resist masking and etching. This process leaves a planar metallized first surface-mount terminal 246 and a planar metallized second surface-mount terminal 248 on the bottom surface device 230, separated from each other by an exposed portion of the bottom insulation layer 234. The first terminal 246 is in electrical contact with the lower electrode 236 through the first cross-conductor 256, while the second terminal 248 is in electrical contact with the upper electrode 234 through the second cross-conductor 258. If a top metallization layer has been applied, as mentioned above, the photo-resist masking and etching process may be employed to remove the entire top metallization layer except for those portions that represent the indicia 250. The exposed metal areas, particularly the terminals 246, 248 and the cross-conductors 256, 258 (and the indicia 250, if present), may advantageously be over-plated with one or more solderable metal layers, such as, for example, the nickel and gold ENIG plating, described above, or just electroless-plated tin. Alternatively, the over-plating may be electroplated nickel and gold, electroplated nickel and tin, or just electroplated tin, performed immediately after the copper plating step.
A top insulation layer 282, which may be of prepreg, an insulative polymer, or an epoxy, is applied to the exposed surface of the first electrode 274a, and a bottom insulation layer 284, of similar material, is applied to the exposed surface of the fourth electrode 274d. The top insulation layer 282 fills the upper isolation area 276a, while the bottom insulation layer 284 fills the lower isolation area 276b. A bottom metallization layer, preferably a copper foil, is applied to the exposed surface of the bottom insulation layer to form first and second surface mount terminals 286, 288, as will be described below. Similarly, a top metallization layer, preferably a copper foil, may optionally be applied to the top insulation layer 282 to form identification indicia 290, as also described below. The top metallization layer (if present) and the top insulation layer 282 may be pre-formed and applied as a laminate, or they may be applied separately in sequence. Likewise, the bottom metallization layer and the bottom insulation layer 284 may be applied either together as a pre-formed laminate, or separately in sequence. In this embodiment (as in the other multiple active layer embodiments described herein), the lamination of the first and second laminated sheet structures together with the intermediate insulative layer 280 may be performed simultaneously with one or more of the top insulating layer 282 and the top metallization layer and the bottom insulation layer 284 and the bottom metallization layer. In any case, the result is a multiple active layer laminated structure comprising first and second active polymer layers 272a, 272b, a first or upper electrode 274a, intermediate second and third electrodes 274b, 274c, a fourth or lower electrode 274d, an intermediate insulation layer 280, a top insulation layer 282, a bottom insulation layer 284, a bottom metallization layer, and (optionally) a top metallization layer.
A first through-hole via 292 is formed through the entire thickness of the above-described multiple active layer laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 294 is similarly (and, preferably, simultaneously) formed through the entire thickness of the structure at each of the second plurality of via locations. Thus, each device 270 has a first through-hole via 292 at a first end, and a second through-hole via 294 at the opposite end. At this point, the top entrance or opening of each of the vias 292, 294 is chamfered by a drill using a conical drill bit (not shown) to form a chamfered or beveled first entry hole 300 for the first via 292, and a similar chamfered or beveled second entry hole 302 for the second via 294. The removal of the insulating material at the openings or entries of the vias 292, 294 may be accomplished by any suitable mechanical or chemical mechanism or process that may suggest itself to those skilled in the pertinent arts. The first entry hole 300 extends through the upper insulation layer 282 and the first isolation area 276a, leaving a portion of the first isolation area 276a to separate the first entry hole 300 from a first end of the upper electrode 274a, while the second entry hole 302 extends through the upper insulation layer 282 to the second via 294 adjacent to or through the opposite end of the first or upper electrode 274a. Although it is preferred to drill the vias 292, 294 first, and then to form the chamfered or beveled entry holes 300, 302, the entry holes 300, 302 may be formed at the pre-defined via locations before the vias 292, 294 are drilled. Furthermore, in some applications, it may be advantageous to form only a singled chamfered or beveled entry hole in each device, i.e., either the first entry hole 300 or the second entry hole 302.
The top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 292, 294 and the chamfered entry holes 300, 302 are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 296 within each of the first set of vias 292, and a second set of cross-conductors 298 within each of the second set of vias 294. Each of the first set of cross-conductors 296 establishes physical and electrical contact with the second and third (intermediate) electrodes 274b, 274c and the top and bottom metallization layers, while being electrically isolated from the first (upper) electrode 274a by the upper isolation area 276a, and from the fourth (lower) electrode 274d by the lower isolation layer 276b. Similarly, each of the second set of cross-conductors 298 establishes physical and electrical contact with the first (upper) electrode 274a and the fourth (lower) electrode 274d and the top and bottom metallization layers, while being electrically isolated from the second and third (intermediate) electrodes 274b, 274c by the intermediate isolation areas 278a, 278b.
Each of the copper-plated first vias 292 provides a first cross-conductor 296 with a sloped shoulder provided by a first chamfered entry hole 300. Likewise, each of the copper-plated second vias 294 provides a second cross-conductor 298 with a sloped shoulder provided by a second chamfered entry hole 302. The sloped shoulders of the cross-conductors 296, 298 establish a more intimate and secure contact with the top insulation layer 282 than that established by a cross-conductor formed through a straight via, such as that shown in
The bottom metallization layer is formed into first and second terminals 286, 288 by removing the central portion of the bottom metallization layer by any conventional technique, preferably by photo-resist masking and etching. This process leaves a planar metallized first surface-mount terminal 286 and a planar metallized second surface-mount terminal 288 on the bottom surface of the device 270, separated from each other by an exposed portion of the bottom insulation layer 284. The first terminal 286 is in electrical contact with the second and third (intermediate) electrodes 274b, 274c through the first cross-conductor 296, while the second terminal 288 is in electrical contact with the first (upper) electrode 274a and the fourth (lower) electrode 274d through the second cross-conductor 298. If a top metallization layer has been applied, as mentioned above, the masking and photo-etching process may be employed to remove the entire top metallization layer except for those portions that represent the indicia 290. The exposed metal areas, particularly the terminals 286, 288 and the cross-conductors 296, 298 (and the indicia 290, if present), may advantageously be over-plated with one or more solderable metal layers, such as, for example, the nickel and gold ENIG plating, or just electroless-plated tin. Alternatively, the over-plating may be electroplated nickel and gold, electroplated nickel and tin, or just electroplated tin, applied immediately after the copper plating step.
A top insulation layer 342, which may be of prepreg, an insulative polymer, or an epoxy, is applied to the exposed surface of the upper electrode 334, and a bottom insulation layer 344, of similar material, is applied to the exposed surface of the lower electrode 336. The top insulation layer 342 fills the upper isolation area 338, while the bottom insulation layer 344 fills the lower isolation area 340. A bottom metallization layer, preferably a copper foil, is applied to the exposed surface of the bottom insulation layer to form first and second surface mount terminals 346, 348, as will be described below. Similarly, a top metallization layer, preferably a copper foil, is applied to the top insulation layer 342 to form first and second anchor pads 360, 362, and (optionally) identification indicia 350, as discussed below. The top metallization layer and the top insulation layer 342 may be pre-formed and applied as a laminate, or they may be applied separately in sequence. Likewise, the bottom metallization layer and the bottom insulation layer 344 may be applied either together as a pre-formed laminate, or separately in sequence. In either case, the result is a laminated structure comprising a single active polymer layer 332, an upper electrode 334, a lower electrode 336, a top insulation layer 342, a bottom insulation layer 344, a bottom metallization layer, and a top metallization layer.
A first through-hole via 352 is formed through the entire thickness of the above-described laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 354 is similarly (and, preferably, simultaneously) formed through the entire thickness of the laminated structure at each of the second plurality of via locations. Thus, each device 330 has a first through-hole via 352 at a first end, and a second through-hole via 354 at the opposite end.
At this point, the top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 352, 354 are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 356 within each of the first set of vias 352, and a second set of cross-conductors 358 within each of the second set of vias 354. A photo-resist masking and etching process is employed to form one or both of the first and second anchor pads 360, 362 and the optional indicia 350 from the top metallization layer, and to form the planar terminals 346, 348, from the bottom metallization layer. The masking and etching process may be employed either before or after the vias 352, 354 are formed and plated. Each of the first set of cross-conductors 356 establishes physical and electrical contact with the lower electrode 336 and the first terminal 346, while being electrically isolated from the upper electrode 334 by the upper isolation area 338. Each of the first cross-conductors 356 also is physically connected to a first anchor pad 360, which serves, along with the first terminal 346, as an anchor point for the first cross-conductor 356. Similarly, each of the second set of cross-conductors 358 establishes physical and electrical contact with the upper electrode 334 and the second terminal 348, while being electrically isolated from the lower electrode 336 by the lower isolation area 340. Each of the second cross-conductors 358 also is physically connected to a second anchor pad 362, which serves, along with the second terminal 348, as an anchor point for the second cross-conductor 358. The exposed metal areas, particularly the terminals 346, 348, the cross-conductors 356, 358, and, optionally, the anchor pads 360, 362, and the optional indicia 350 (if present) may advantageously be over-plated with one or more solderable metal layers, such as, for example, the nickel and gold ENIG plating, or just electroless-plated tin. Alternatively, the over-plating may be electroplated nickel and gold, electroplated nickel and tin, or just electroplated tin, applied immediately after the copper plating step.
It will be appreciated that the physical continuity of the cross-conductors 356 and 358 with the anchor pads 360, 362, respectively, provides added structural integrity to the device, while the anchor pads 360, 362 themselves, occupying relatively little surface area, do not impose a significant restraint on the thermal expansion of the polymer layer 332.
A top insulation layer 382, which may be of prepreg, an insulative polymer, or an epoxy, is applied to the exposed surface of the first electrode 374a, and a bottom insulation layer 384, of similar material, is applied to the exposed surface of the fourth electrode 374d. The top insulation layer 382 fills the upper isolation area 376a, while the bottom insulation layer 384 fills the lower isolation area 376b. A bottom metallization layer, preferably a copper foil, is applied to the exposed surface of the bottom insulation layer to form first and second surface mount terminals 386, 388, as will be described below. Similarly, a top metallization layer, preferably a copper foil, is applied to the top insulation layer 382 to form first and second anchor pads 400, 402, and (optionally) identification indicia 390, as also described below. The top metallization layer and the top insulation layer 382 may be pre-formed and applied as a laminate, or they may be applied separately in sequence. Likewise, the bottom metallization layer and the bottom insulation layer 384 may be applied either together as a pre-formed laminate, or separately in sequence. In either case, the result is a multiple active layer laminated structure comprising first and second active polymer layers 372a, 372b, a first or upper electrode 374a, intermediate second and third electrodes 374b, 374c, a fourth or lower electrode 374d, an intermediate insulation layer 380, a top insulation layer 382, a bottom insulation layer 384, a bottom metallization layer, and a top metallization layer.
A first through-hole via 392 is formed through the entire thickness of the above-described multiple active layer laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 394 is similarly (and, preferably, simultaneously) formed through the entire thickness of the structure at each of the second plurality of via locations. Thus, each device 370 has a first through-hole via 392 at a first end, and a second through-hole via 394 at the opposite end.
At this point, the top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 392, 394 are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 396 within each of the first set of vias 392, and a second set of cross-conductors 398 within each of the second set of vias 394. A photo-resist masking and etching process is employed to form one or both of the first and second anchor pads 400, 402 and the optional indicia 390 from the top metallization layer, and to form the planar terminals 386, 388, from the bottom metallization layer. The masking and etching process may be employed either before or after the vias 392, 394 are formed and plated. Each of the first set of cross-conductors 396 establishes physical and electrical contact with the second and third (intermediate) electrodes 374b, 374c and the first terminal 386, while being electrically isolated from the first (upper) electrode 374a and from the fourth (lower) electrode 374d by the upper isolation area 376a and the lower isolation area 376b, respectively. Each of the first cross-conductors 396 also is physically connected to a first anchor pad 400, which serves, along with the first terminal 386, as an anchor point for the first cross-conductor 396. Similarly, each of the second set of cross-conductors 398 establishes physical and electrical contact with the first (upper) electrode 374a, the fourth (lower) electrode 374d, and the second terminal 388, while being electrically isolated from the second and third (intermediate) electrodes 374b, 374c by the intermediate isolations area 378a, 378b. Each of the second cross-conductors 398 also is physically connected to a second anchor pad 402, which serves, along with the second terminal 388, as an anchor point for the second cross-conductor 398. The exposed metal areas, particularly the terminals 386, 388, the cross-conductors 396, 398, and optionally, the anchor pads 400, 402 and the optional indicia 390 (if present) may advantageously be over-plated with one or more solderable metal layers, such as nickel and gold ENIG plating or electroless tin plating. Alternatively, the over-plating may be electroplated nickel and gold, electroplated nickel and tin, or just electroplated tin, applied immediately after the copper plating step.
A first through-hole via 452 is formed through the entire thickness of the above-described laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 454 is similarly (and, preferably, simultaneously) formed through the entire thickness of the laminated structure at each of the second plurality of via locations. Thus, each device 430 has a first through-hole via 452 at a first end, and a second through-hole via 454 at the opposite end. At this point, the top entrance or opening of the second via 454 is chamfered or beveled by any suitable mechanism or process, such as, for example, a drill with a conical drill bit (not shown), to form a chamfered or beveled second entry hole 462 for the second via 454. The chamfered or beveled second entry hole 462 extends through the upper insulation layer 442 to the second via 454 adjacent to or through an end of the upper electrode 434. Although it is preferred to drill the vias 452, 454 first, and then to form the chamfered entry hole 462, the chamfered entry hole 462 may be formed at the pre-defined second via locations before the vias 452, 454 are drilled.
The top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 452, 454, including the chamfered entry hole 462, are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 456 within each of the first set of vias 452, and a second set of cross-conductors 458 within each of the second set of vias 454 and their associated chamfered second entry holes 462. A photo-resist masking and etching process is employed to form the anchor pad 460 and the optional indicia 450 from the top metallization layer, and to form one or both of the planar terminals 446, 448 from the bottom metallization layer. The masking and etching process may be employed either before or after the vias 452, 454 are formed and plated. Each of the first set of cross-conductors 456 establishes physical and electrical contact with the lower electrode 436 and the first terminal 446, while being electrically isolated from the upper electrode 434 by the upper isolation area 438. Similarly, each of the second set of cross-conductors 458 establishes physical and electrical contact with the upper electrode 434 and the second terminal 448, while being electrically isolated from the lower electrode 436 by the lower isolation area 440. Thus, the first terminal 446 is in electrical contact with the lower electrode 436 through the first cross-conductor 456, while the second terminal 448 is in electrical contact with the upper electrode 434 through the second cross-conductor 458. The exposed metal areas, particularly the terminals 446, 448, the cross-conductors 456, 458, and optionally the anchor pad 460 and the optional indicia 450 (if present) may advantageously be over-plated with one or more solderable metal layers, such as, for example, nickel and gold ENIG plating, or electroless tin plating. Alternatively, the over-plating may be electroplated nickel and gold, electroplated nickel and tin, or just electroplated tin, applied immediately after the copper plating step.
The upper and lower ends of the first cross-conductor 456 are respectively anchored by their connection to the anchor pad 460 and the first terminal 446. The upper and lower ends of the second cross-conductor 458 are respectively anchored by their connection to the upper electrode 434 and the second terminal 448.
A top insulation layer 482, which may be of prepreg, an insulative polymer, or an epoxy, is applied to the exposed surface of the first electrode 474a, and a bottom insulation layer 484, of similar material, is applied to the exposed surface of the fourth electrode 474d. The top insulation layer 482 fills the upper isolation area 476a, while the bottom insulation layer 484 fills the lower isolation area 476b. A bottom metallization layer, preferably a copper foil, is applied to the exposed surface of the bottom insulation layer 484, and it is photo-resist masked and etched to form first and second surface mount terminals 486, 488 separated by an exposed area of the bottom insulation layer 484. Similarly, a top metallization layer, preferably a copper foil, is applied to the top insulation layer 482, and it is photo-resist masked and etched to form an anchor pad 500 and (optionally) identification indicia 490. The photo-resist masking and etching of the top and bottom metallization layers may be performed either before or after the vias 492, 494 are formed and plated, as described below. The top metallization layer and the top insulation layer 482 may be pre-formed and applied as a laminate, or they may be applied separately in sequence. Likewise, the bottom metallization layer and the bottom insulation layer 484 may be applied either together as a pre-formed laminate, or separately in sequence. In either case, the result is a multiple active layer laminated structure comprising first and second active polymer layers 472a, 472b, a first or upper electrode 474a, intermediate second and third electrodes 474b, 474c, a fourth or lower electrode 474d, an intermediate insulation layer 480, a top insulation layer 482, a bottom insulation layer 484, a bottom metallization layer, and a top metallization layer. The top and bottom metallization layers may be formed into the anchor pad 500, the indicia 490, and the terminals 486, 488.
A first through-hole via 492 is formed through the entire thickness of the above-described multiple active layer laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 494 is similarly (and, preferably, simultaneously) formed through the entire thickness of the structure at each of the second plurality of via locations. Thus, each device 470 has a first through-hole via 492 at a first end, and a second through-hole via 494 at the opposite end. At this point, the top entrance or opening of the second via 494 is chamfered or beveled by any suitable mechanical or chemical means, such as, for example, a drill with a conical drill bit (not shown), to form a chamfered or beveled entry hole 502 for the second via 494. The chamfered or beveled entry hole 502 extends through the top insulation layer 482 to the second via 494, either adjacent to or through an end of the first or upper electrode 474a. Although it is preferred to drill the vias 492, 494 first, and then to form the chamfered or beveled entry hole 502, the chamfered entry hole 502 may be formed at the pre-defined via locations before the second vias 492, 494 are drilled.
The top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 492, 494, including the chamfered or beveled entry hole 502 of each of the second vias 494, are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 496 within each of the first set of vias 492, and a second set of cross-conductors 498 within each of the second set of vias 494. A photo-resist masking and etching process is employed to form the anchor pad 500 and the optional indicia 490 from the top metallization layer, and to form the planar terminals 486, 488 from the bottom metallization layer. The masking and etching process may be employed either before or after the vias 492, 494 are formed and plated. Each of the first set of cross-conductors 496 establishes physical and electrical contact with the second and third (intermediate) electrodes 474b, 474c, the anchor pad 500, and the first planar terminal 486, while being electrically isolated from the first (upper) electrode 474a by the upper isolation area 476a, and from the fourth (lower) electrode 474d by the lower isolation layer 476b. Similarly, each of the second set of cross-conductors 498 establishes physical and electrical contact with the first (upper) electrode 474a, the fourth (lower) electrode 474d, and the second planar terminal 488, while being electrically isolated from the second and third (intermediate) electrodes 474b, 474c by the intermediate isolation areas 478a, 478b. The first terminal 486 is in electrical contact with the second and third (intermediate) electrodes 474b, 474c through the first cross-conductor 496, while the second terminal 488 is in electrical contact with the first (upper) electrode 474a and the fourth (lower) electrode 474d through the second cross-conductor 498.
The upper and lower ends of the first cross-conductor 496 are respectively anchored by their connection to the anchor pad 500 and the first planar terminal 486. The upper and lower ends of the second cross-conductor 498 are respectively anchored by their connection to the upper electrode 474a and the lower second terminal 488. The exposed metal areas, particularly the terminals 486, 488, the cross-conductors 496, 498, and optionally the anchor pad 500 and the optional indicia 490 (if present) may advantageously be over-plated with one or more solderable metal layers, such as, for example, nickel and gold ENIG plating, or electroless tin plating. Alternatively, the over-plating may be electroplated nickel and gold, electroplated nickel and tin, or electroplated tin, applied immediately after the copper plating step.
Specifically, the device 530 includes an arcuate upper isolation area 538 between the upper electrode 534 and a first end of the device 530, adjacent a first through-hole via 552. The device 530 also includes an arcuate lower isolation area 540 between the lower electrode 536 and the opposite end of the device 530, adjacent a second through-hole via 554. A top insulation layer 542 is formed or applied on the exposed surface of the upper electrode 534, filling in the upper isolation area 538, and a bottom insulation layer 544 is similarly formed or applied on the exposed surface of the lower electrode 536, filling in the lower isolation area 540. A bottom metallization layer, preferably a copper foil, is applied to the exposed surface of the bottom insulation layer to form first and second surface mount terminals 546, 548, as will be described below. Similarly, a top metallization layer, preferably a copper foil, is applied to the top insulation layer 542 to form an anchor pad 560 and (optionally) identification indicia 550, as also described below. The top metallization layer and the top insulation layer 542 may be pre-formed and applied as a laminate, or they may be applied separately in sequence. Likewise, the bottom metallization layer and the bottom insulation layer 544 may be applied either together as a pre-formed laminate, or separately in sequence. In either case, the result is a laminated structure comprising a single active polymer layer 532, an upper electrode 534, a lower electrode 536, a top insulation layer 542, a bottom insulation layer 544, a bottom metallization layer, and a top metallization layer.
A first through-hole via 552 is formed through the entire thickness of the above-described laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 554 is similarly (and, preferably, simultaneously) formed through the entire thickness of the laminated structure at each of the second plurality of via locations. Thus, each device 530 has a first through-hole via 552 at a first end, and a second through-hole via 554 at the opposite end. An arcuate portion of the top insulation layer 542 adjacent the second via 554 is then removed by any suitable process, such as chemical etching, plasma etching, mechanical drilling or laser drilling, to form an exposed anchor surface 564 on the upper electrode 534, the purpose of which will be discussed below. Although it is preferred to drill the vias 552, 554 first, and then to form the anchor surface 564, the anchor surface 564 may be formed at the pre-defined second via locations before the vias 552, 554 are drilled.
The top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 552, 554, as well as the anchor surface 564, are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 556 within each of the first set of vias 552, a second set of cross-conductors 558 within each of the second set of vias 554, and a plated anchor element 562 on the anchor surface 564, wherein the plated anchor element 562 is contiguous with the second cross-conductor 558. A photo-resist masking and etching process is employed to form the anchor pad 560 adjacent the first through-hole via 552 (as well as the optional indicia 550) from the top metallization layer, and to form the planar terminals 546, 548 from the bottom metallization layer. The masking and etching process may be employed either before or after the vias 552, 554 are formed and plated. Each of the first set of cross-conductors 556 establishes physical and electrical contact with the lower electrode 536 and the first terminal 546, while being electrically isolated from the upper electrode 534 by the upper isolation area 538. Similarly, each of the second set of cross-conductors 558 establishes physical and electrical contact with the upper electrode 534 and the second terminal 548, while being electrically isolated from the lower electrode 536 by the lower isolation area 540. Thus, the first terminal 546 is in electrical contact with the lower electrode 536 through the first cross-conductor 556, while the second terminal 548 is in electrical contact with the upper electrode 534 through the second cross-conductor 558. The exposed metal areas, particularly the terminals 546, 548, the cross-conductors 556, 558, the anchor pad 560, and the plated anchor element 562 (and the indicia 550, if present), may advantageously be over-plated with one or more solderable metal layers, such as, for example, nickel and gold ENIG plating ore electroless tin plating. Alternatively, the over-plating may be electroplated nickel and gold, electroplated nickel and tin, or electroplated tin, applied immediately after the copper plating step.
The upper and lower ends of the first cross-conductor 556 are respectively anchored by their connection to the anchor pad 560 and the first terminal 546. The upper end of the second cross-conductor 558 is anchored by its connection to the upper electrode 534 and to the anchor element 562, while the lower end of the second cross-conductor is anchored by its connection to the second terminal 548. The anchor element 562 provides a more intimate and secure connection and contact between the second cross-conductor 558 and the exposed anchor surface 564 on the upper electrode 534 than that established by a cross-conductor formed through a straight via, such as shown in
A top insulation layer 582, which may be of prepreg, an insulative polymer, or an epoxy, is applied to the exposed surface of the first electrode 574a, and a bottom insulation layer 584, of similar material, is applied to the exposed surface of the fourth electrode 574d. The top insulation layer 582 fills the upper isolation area 576a, while the bottom insulation layer 584 fills the lower isolation area 576b. A bottom metallization layer, preferably a copper foil, is applied to the exposed surface of the bottom insulation layer 584, and it is photo-resist masked and etched to form first and second surface mount terminals 586, 588 separated by an exposed area of the bottom insulation layer 584. Similarly, a top metallization layer, preferably a copper foil, is applied to the top insulation layer 582, and it is photo-resist masked and etched to form an anchor pad 600 and (optionally) identification indicia 590. The photo-resist masking and etching of the top and bottom metallization layers may be performed either before or after the vias 592, 594 are formed and plated, as described below. The top metallization layer and the top insulation layer 582 may be pre-formed and applied as a laminate, or they may be applied separately in sequence. Likewise, the bottom metallization layer and the bottom insulation layer 584 may be applied either together as a pre-formed laminate, or separately in sequence. In either case, the result is a multiple active layer laminated structure comprising first and second active polymer layers 572a, 572b, a first or upper electrode 574a, intermediate second and third electrodes 574b, 574c, a fourth or lower electrode 574d, an intermediate insulation layer 580, a top insulation layer 582, a bottom insulation layer 584, a bottom metallization layer, and a top metallization layer. The top metallization layer is formed into the anchor pad 600 and the optional indicia 590, and the bottom metallization layer is formed into the planar terminals 586, 588, by any conventional process, such as photo-resist masking and etching, which may be performed either before or after the formation and plating of the vias, as described below.
A first through-hole via 592 is formed through the entire thickness of the above-described multiple active layer laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 594 is similarly (and, preferably, simultaneously) formed through the entire thickness of the structure at each of the second plurality of via locations. Thus, each device 570 has a first through-hole via 592 at a first end, and a second through-hole via 594 at the opposite end. An arcuate portion of the top insulation layer 582 adjacent the second via 594 is then removed by any suitable process, such as chemical etching, plasma etching, mechanical drilling or laser drilling, to form an exposed anchor surface 604 on the upper electrode 574a, the purpose of which will be discussed below. Although it is preferred to drill the vias 592, 594 first, and then to form the anchor surface 604, the anchor surface 604 may be formed at the pre-defined second via locations before the vias 592, 594 are drilled.
The top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 592, 594, as well as the anchor surface 604, are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 596 within each of the first set of vias 592, a second set of cross-conductors 598 within each of the second set of vias 594, and a plated anchor element 602 on the anchor surface 604, wherein the plated anchor element 602 is contiguous with the second cross-conductor 598. At this point, a photo-resist masking and etching process is employed to form the anchor pad 600 adjacent the first through-hole via 592 (as well as the optional indicia 590) from the top metallization layer, and to form the planar terminal pads 586, 588 from the bottom metallization layer. The masking and etching process may be performed either before or after the vias 592, 594 are formed and plated. Each of the first set of cross-conductors 596 establishes physical and electrical contact with the second and third (intermediate) electrodes 574b, 574c, the anchor pad 600, and the first planar terminal 586, while being electrically isolated from the first (upper) electrode 574a by the upper isolation area 576a, and from the fourth (lower) electrode 574d by the lower isolation layer 576b. Similarly, each of the second set of cross-conductors 598 establishes physical and electrical contact with the first (upper) electrode 574a, the fourth (lower) electrode 574d, and the second planar terminal 588, while being electrically isolated from the second and third (intermediate) electrodes 574b, 574c by the intermediate isolation areas 578a, 578b. The first terminal 586 is in electrical contact with the second and third (intermediate) electrodes 574b, 574c through the first cross-conductor 596, while the second terminal 588 is in electrical contact with the first (upper) electrode 574a and the fourth (lower) electrode 574d through the second cross-conductor 598.
The upper and lower ends of the first cross-conductor 596 are respectively anchored by their connection to the anchor pad 600 and the first planar terminal 586. The upper end of the second cross-conductor 598 is anchored by its connection to the upper electrode 574a and to the anchor element 602, while the lower end of the second cross-conductor is anchored by its connection to the lower second terminal 588. The exposed metal areas, particularly the terminals 586, 588, the cross-conductors 596, 598, the anchor pad 600, and the plated anchor element 602 (and the indicia 590, if present), may advantageously be over-plated with one or more solderable metal layers, such as, for example, nickel and gold ENIG plating or electroless tin plating. Alternatively, the over-plating may be electroplated nickel and gold, electroplated nickel and tin, or electroplated tin, applied immediately after the copper plating step.
A top insulation layer 642, which may be of prepreg, an insulative polymer, or an epoxy, is applied to the exposed surface of the upper electrode 634, and a bottom insulation layer 644, of similar material, is applied to the exposed surface of the lower electrode 636. The top insulation layer 642 fills the upper isolation area 638, while the bottom insulation layer 644 fills the lower isolation area 640. A bottom metallization layer, preferably a copper foil, is applied to the exposed surface of the bottom insulation layer to form first and second surface mount terminals 646, 648, as will be described below. Similarly, a top metallization layer, preferably a copper foil, is applied to the top insulation layer 642 to form an anchor pad 660, and (optionally) identification indicia 650, as discussed below. The top metallization layer and the top insulation layer 642 may be pre-formed and applied as a laminate, or they may be applied separately in sequence. Likewise, the bottom metallization layer and the bottom insulation layer 644 may be applied either together as a pre-formed laminate, or separately in sequence. In either case, the result is a laminated structure comprising a single active polymer layer 632, an upper electrode 634, a lower electrode 636, a top insulation layer 642, a bottom insulation layer 644, a bottom metallization layer, and a top metallization layer.
A first through-hole via 652 is formed through the entire thickness of the above-described laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 654 is similarly (and, preferably, simultaneously) formed through the entire thickness of the laminated structure at each of the second plurality of via locations. Thus, each device 630 has a first through-hole via 652 at a first end, and a second through-hole via 654 at the opposite end.
At this point, the top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 652, 654 are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 656 within each of the first set of vias 652, and a second set of cross-conductors 658 within each of the second set of vias 654. A photo-resist masking and etching process is employed to form anchor pad 660, and the optional indicia 650 from the top metallization layer, and to form the planar terminals 646, 648, from the bottom metallization layer. The masking and etching process may be employed either before or after the vias 652, 654 are formed and plated. Each of the first set of cross-conductors 656 establishes physical and electrical contact with the lower electrode 636 and the first terminal 646, while being electrically isolated from the upper electrode 634 by the upper isolation area 638. Each of the first cross-conductors 656 also is physically connected to a first anchor pad 660, which serves, along with the first terminal 646, as an anchor point for the first cross-conductor 656. Similarly, each of the second set of cross-conductors 658 establishes physical and electrical contact with the upper electrode 634 and the second terminal 648, while being electrically isolated from the lower electrode 636 by the lower isolation area 640. The exposed metal areas, particularly the terminals 646, 648, the cross-conductors 656, 658, and optionally, the anchor pad 660 (and the optional indicia 650, if present), may advantageously be over-plated with one or more solderable metal layers, such as, for example, nickel and gold ENIG plating or electroless tin plating. Alternatively, the over-plating may be electroplated nickel and gold, electroplated nickel and tin, or electroplated tin applied immediately after the copper plating step.
A top insulation layer 682, which may be of prepreg, an insulative polymer, or an epoxy, is applied to the exposed surface of the first electrode 674a, and a bottom insulation layer 684, of similar material, is applied to the exposed surface of the fourth electrode 674d. The top insulation layer 682 fills the upper isolation area 676a, while the bottom insulation layer 684 fills the lower isolation area 676b. A bottom metallization layer, preferably a copper foil, is applied to the exposed surface of the bottom insulation layer to form first and second surface mount terminals 686, 688, as will be described below. Similarly, a top metallization layer, preferably a copper foil, is applied to the top insulation layer 682 to form an anchor pad 700 and (optionally) identification indicia 690, as also described below. The top metallization layer and the top insulation layer 682 may be pre-formed and applied as a laminate, or they may be applied separately in sequence. Likewise, the bottom metallization layer and the bottom insulation layer 684 may be applied either together as a pre-formed laminate, or separately in sequence. In either case, the result is a multiple active layer laminated structure comprising first and second active polymer layers 672a, 672b, a first or upper electrode 674a, intermediate second and third electrodes 674b, 674c, a fourth or lower electrode 674d, an intermediate insulation layer 680, a top insulation layer 682, a bottom insulation layer 684, a bottom metallization layer, and a top metallization layer.
A first through-hole via 692 is formed through the entire thickness of the above-described multiple active layer laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 694 is similarly (and, preferably, simultaneously) formed through the entire thickness of the structure at each of the second plurality of via locations. Thus, each device 670 has a first through-hole via 692 at a first end, and a second through-hole via 694 at the opposite end.
At this point, the top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 692, 694 are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 696 within each of the first set of vias 692, and a second set of cross-conductors 698 within each of the second set of vias 694. A photo-resist masking and etching process is employed to form anchor pad 700 and the optional indicia 690 from the top metallization layer, and to form the planar terminals 686, 688, from the bottom metallization layer. The masking and etching process may be employed either before or after the vias 692, 694 are formed and plated. Each of the first set of cross-conductors 696 establishes physical and electrical contact with the second and third (intermediate) electrodes 674b, 674c and the first terminal 686, while being electrically isolated from the first (upper) electrode 674a and from the fourth (lower) electrode 674d by the upper isolation area 676a and the lower isolation area 676b, respectively. The first cross-conductors 696 also is physically connected to a first anchor pad 700, which serves, along with the first terminal 686, as an anchor point for the first cross-conductor 696. Similarly, each of the second set of cross-conductors 698 establishes physical and electrical contact with the first (upper) electrode 674a, the fourth (lower) electrode 674d, and the second terminal 688, while being electrically isolated from the second and third (intermediate) electrodes 674b, 674c by the intermediate isolations area 678a, 678b. The exposed metal areas, particularly the terminals 686, 688, the cross-conductors 696, 698, and optionally, the anchor pad 700 (and the indicia 690, if present), may advantageously be over-plated with one or more solderable metal layers, such as, for example, nickel and gold ENIG plating or electroless tin plating. Alternatively, the over-plating may be electroplated nickel and gold, electroplated nickel and tin, or electroplated tin, applied immediately after the copper plating.
A top insulation layer 742, which may be of prepreg, an insulative polymer, or an epoxy, is applied to the exposed surface of the upper electrode 734, and a bottom insulation layer 744, of similar material, is applied to the exposed surface of the lower electrode 736. The top insulation layer 742 fills the upper isolation area 738, while the bottom insulation layer 744 fills the lower isolation area 740. A bottom metallization layer, preferably a copper foil, is applied to the exposed surface of the bottom insulation layer to form first and second surface mount terminals 746, 748, as will be described below. Similarly, a top metallization layer, preferably a copper foil, is applied to the top insulation layer 742 to form an anchor pad 762, and (optionally) identification indicia 750, as discussed below. The top metallization layer and the top insulation layer 742 may be pre-formed and applied as a laminate, or they may be applied separately in sequence. Likewise, the bottom metallization layer and the bottom insulation layer 744 may be applied either together as a pre-formed laminate, or separately in sequence. In either case, the result is a laminated structure comprising a single active polymer layer 732, an upper electrode 734, a lower electrode 736, a top insulation layer 742, a bottom insulation layer 744, a bottom metallization layer, and a top metallization layer.
A first through-hole via 752 is formed through the entire thickness of the above-described laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 754 is similarly (and, preferably, simultaneously) formed through the entire thickness of the laminated structure at each of the second plurality of via locations. Thus, each device 730 has a first through-hole via 752 at a first end, and a second through-hole via 754 at the opposite end.
At this point, the top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 752, 754 are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 756 within each of the first set of vias 752, and a second set of cross-conductors 758 within each of the second set of vias 754. A photo-resist masking and etching process is employed to form the anchor pad 762, and the optional indicia 750 from the top metallization layer, and to form the planar terminals 746, 748, from the bottom metallization layer. The masking and etching process may be employed either before or after the vias 752, 754 are formed and plated. Each of the first set of cross-conductors 756 establishes physical and electrical contact with the lower electrode 736 and the first terminal 746, while being electrically isolated from the upper electrode 734 by the upper isolation area 738. Each of the first cross-conductors 756 also is physically connected to the anchor pad 762, which serves, along with the first terminal 746, as an anchor point for the first cross-conductor 756. Similarly, each of the second set of cross-conductors 758 establishes physical and electrical contact with the upper electrode 734 and the second terminal 748, while being electrically isolated from the lower electrode 736 by the lower isolation area 740. The exposed metal areas, particularly the terminals 746, 748, the cross-conductors 756, 758, and optionally, the anchor pad 762 (and the indicia 750, if present), may advantageously be over-plated with one or more additional metal layers, such as, for example, nickel and gold ENIG plating or electroless tin plating. Alternatively, the over-plating may be electroplated nickel and gold, electroplated nickel and tin, or electroplated tin, applied immediately after the copper plating step.
A top insulation layer 782, which may be of prepreg, an insulative polymer, or an epoxy, is applied to the exposed surface of the first electrode 774a, and a bottom insulation layer 784, of similar material, is applied to the exposed surface of the fourth electrode 774d. The top insulation layer 782 fills the upper isolation area 776a, while the bottom insulation layer 784 fills the lower isolation area 776b. A bottom metallization layer, preferably a copper foil, is applied to the exposed surface of the bottom insulation layer to form first and second surface mount terminals 786, 788, as will be described below. Similarly, a top metallization layer, preferably a copper foil, is applied to the top insulation layer 782 to form an anchor pad 802 and (optionally) identification indicia 790, as also described below. The top metallization layer and the top insulation layer 782 may be pre-formed and applied as a laminate, or they may be applied separately in sequence. Likewise, the bottom metallization layer and the bottom insulation layer 784 may be applied either together as a pre-formed laminate, or separately in sequence. In either case, the result is a multiple active layer laminated structure comprising first and second active polymer layers 772a, 772b, a first or upper electrode 774a, intermediate second and third electrodes 774b, 774c, a fourth or lower electrode 774d, an intermediate insulation layer 780, a top insulation layer 782, a bottom insulation layer 784, a bottom metallization layer, and a top metallization layer.
A first through-hole via 792 is formed through the entire thickness of the above-described multiple active layer laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 794 is similarly (and, preferably, simultaneously) formed through the entire thickness of the structure at each of the second plurality of via locations. Thus, each device 770 has a first through-hole via 792 at a first end, and a second through-hole via 794 at the opposite end.
At this point, the top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 792, 794 are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 796 within each of the first set of vias 792, and a second set of cross-conductors 798 within each of the second set of vias 794. A photo-resist masking and etching process is employed to form anchor pad 802 and the optional indicia 790 from the top metallization layer, and to form the planar terminals 786, 788, from the bottom metallization layer. The masking and etching process may be employed either before or after the vias 792, 794 are formed and plated. Each of the first set of cross-conductors 796 establishes physical and electrical contact with the second and third (intermediate) electrodes 774b, 774c and the first terminal 786, while being electrically isolated from the first (upper) electrode 774a and from the fourth (lower) electrode 774d by the upper isolation area 776a and the lower isolation area 776b, respectively. Similarly, each of the second set of cross-conductors 798 establishes physical and electrical contact with the first (upper) electrode 774a, the fourth (lower) electrode 774d, and the second terminal 788, while being electrically isolated from the second and third (intermediate) electrodes 774b, 774c by the intermediate isolations area 778a, 778b. The second cross-conductors 798 also is physically connected to an anchor pad 802, which serves, along with the second terminal 788, as an anchor point for the second cross-conductor 796. The exposed metal areas, particularly the terminals 786, 788, the cross-conductors 796, 798, and optionally, the anchor pad 802 (and the indicia 790, if present), may advantageously be over-plated with one or more solderable metal layers, such as, for example, nickel and gold ENIG plating or electroless tin plating. Alternatively, the over-plating may be electroplated nickel and gold, electroplated nickel and tin, or electroplated tin, applied immediately after the copper plating step.
A first through-hole via 852 is formed through the entire thickness of the above-described laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 854 is similarly (and, preferably, simultaneously) formed through the entire thickness of the laminated structure at each of the second plurality of via locations. Thus, each device 830 has a first through-hole via 852 at a first end, and a second through-hole via 854 at the opposite end. At this point, the top entrance or opening of the first via 852 is chamfered or beveled by any suitable mechanism or process, such as, for example, a drill with a conical drill bit (not shown), to form a chamfered or beveled entry hole 860 for the first via 852. Although it is preferred to drill the vias 852, 854 first, and then to form the chamfered entry hole 860, the chamfered entry hole 860 may be formed at the pre-defined first via locations before the vias 852, 854 are drilled. The entry hole 860 extends through the upper insulation layer 842 and the upper isolation area 838.
The top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 852, 854, including the chamfered entry 860, are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 856 within each of the first set of vias 852, and a second set of cross-conductors 858 within each of the second set of vias 854. A photo-resist masking and etching process is employed to form the anchor pad 862 and the optional indicia 850 from the top metallization layer, and to form one or both of the planar terminals 846, 848 from the bottom metallization layer. The masking and etching process may be employed either before or after the vias 852, 854 are formed and plated. Each of the first set of cross-conductors 856 establishes physical and electrical contact with the lower electrode 836 and the first terminal 846, while being electrically isolated from the upper electrode 834 by the upper isolation area 838. Similarly, each of the second set of cross-conductors 858 establishes physical and electrical contact with anchor pad 862, the upper electrode 834 and the second terminal 848, while being electrically isolated from the lower electrode 836 by the lower isolation area 840. Thus, the first terminal 846 is in electrical contact with the lower electrode 836 through the first cross-conductor 856, while the second terminal 848 is in electrical contact with the upper electrode 834 through the second cross-conductor 858. The exposed metal areas, particularly the terminals 846, 848 and the cross-conductors 856, 858, the anchor pad 862, and optionally, the indicia 850 (if present) may advantageously be over-plated with one or more solderable metal layers, such as, for example, nickel and gold ENIG plating or electroless tin plating. Alternatively, the over-plating may be electroplated nickel and gold, electroplated nickel and tin, or electroplated tin, applied immediately after the copper plating step.
The upper and lower ends of the second cross-conductor 858 are respectively anchored by their connection to the anchor pad 862 and the second terminal 848. The upper and lower ends of the first cross-conductor 856 are respectively anchored by their connection to the chamfered via entry hole 860 and the first terminal 846.
A top insulation layer 882, which may be of prepreg, an insulative polymer, or an epoxy, is applied to the exposed surface of the first electrode 874a, and a bottom insulation layer 884, of similar material, is applied to the exposed surface of the fourth electrode 874d. The top insulation layer 882 fills the upper isolation area 876a, while the bottom insulation layer 884 fills the lower isolation area 876b. A bottom metallization layer, preferably a copper foil, is applied to the exposed surface of the bottom insulation layer 884, and it is photo-masked and etched to form first and second surface mount terminals 886, 888 separated by an exposed area of the bottom insulation layer 884. Similarly, a top metallization layer, preferably a copper foil, is applied to the top insulation layer 882, and it is photo-masked and etched to form an anchor pad 902 and (optionally) identification indicia 890. The photo-resist masking and etching of the top and bottom metallization layers may be performed either before or after the vias 892, 894 are formed and plated, as described below. The top metallization layer and the top insulation layer 882 may be pre-formed and applied as a laminate, or they may be applied separately in sequence. Likewise, the bottom metallization layer and the bottom insulation layer 884 may be applied either together as a pre-formed laminate, or separately in sequence. In either case, the result is a multiple active layer laminated structure comprising first and second active polymer layers 872a, 872b, a first or upper electrode 874a, intermediate second and third electrodes 874b, 874c, a fourth or lower electrode 874d, an intermediate insulation layer 880, a top insulation layer 882, a bottom insulation layer 884, a bottom metallization layer, and a top metallization layer. The top and bottom metallization layers may be formed into the anchor pad 902, the indicia 890, and the terminals 886, 888.
A first through-hole via 892 is formed through the entire thickness of the above-described multiple active layer laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 894 is similarly (and, preferably, simultaneously) formed through the entire thickness of the structure at each of the second plurality of via locations. Thus, each device 870 has a first through-hole via 892 at a first end, and a second through-hole via 894 at the opposite end. At this point, the top entrance or opening of the first via 892 is chamfered by any suitable mechanical or chemical means, such as, for example, a drill with a conical drill bit (not shown), to form a chamfered or beveled entry hole 900 for the first via 892. Although it is preferred to drill the vias 892, 894 first, and then to form the chamfered entry hole 900, the chamfered entry hole 900 may be formed at the pre-defined via locations before the second vias 892, 894 are drilled. The entry hole 900 extends through the upper insulation layer 842 and the upper isolation area 876a.
The top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 892, 894, including the chamfered entry hole 900 of each of the first vias 892, are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 896 within each of the first set of vias 892, and a second set of cross-conductors 898 within each of the second set of vias 894. A photo-resist masking and etching process is employed to form the anchor pad 902 and the optional indicia 890 from the top metallization layer, and to form the planar terminals 886, 888 from the bottom metallization layer. The masking and etching process may be employed either before or after the vias 892, 894 are formed and plated. Each of the first set of cross-conductors 896 establishes physical and electrical contact with the second and third (intermediate) electrodes 874b, 874c and the first planar terminal 886, while being electrically isolated from the first (upper) electrode 874a by the upper isolation area 876a, and from the fourth (lower) electrode 874d by the lower isolation layer 876b. Similarly, each of the second set of cross-conductors 898 establishes physical and electrical contact with the first (upper) electrode 874a, the fourth (lower) electrode 874d, the anchor pad 902 and the second planar terminal 888, while being electrically isolated from the second and third (intermediate) electrodes 874b, 874c by the intermediate isolation areas 878a, 878b. The first terminal 886 is in electrical contact with the second and third (intermediate) electrodes 874b, 874c through the first cross-conductor 896, while the second terminal 888 is in electrical contact with the first (upper) electrode 874a and the fourth (lower) electrode 874d through the second cross-conductor 898.
The upper and lower ends of the first cross-conductor 896 are respectively anchored by their connection to the chamfered entry hole 900 and the first planar terminal 886. The upper and lower ends of the second cross-conductor 898 are respectively anchored by their connection to the anchor pad 902 and the lower second terminal 888. The exposed metal areas, particularly the terminals 886, 888, the cross-conductors 896, 898, and the anchor pad 902 (and the indicia 890, if present) may advantageously be over-plated with one or more solderable metal layers, such as, for example, nickel and gold ENIG plating or electroless tin plating. Alternatively, the over-plating may be electroplated nickel and gold, electroplated nickel and tin, or electroplated tin, applied immediately after the copper plating step.
A top insulation layer 982, which may be of prepreg, an insulative polymer, or an epoxy, is applied to the exposed surface of the first electrode 974a, and a bottom insulation layer 984, of similar material, is applied to the exposed surface of the fourth electrode 974d. The top insulation layer 982 fills the upper isolation area 976a, while the bottom insulation layer 984 fills the lower isolation area 976b. A bottom metallization layer, preferably a copper foil, is applied to the exposed surface of the bottom insulation layer 984, and it is photo-resist masked and etched to form first and second surface mount terminals 986, 988 separated by an exposed area of the bottom insulation layer 984. Similarly, a top metallization layer, preferably a copper foil, is applied to the top insulation layer 982, and it is photo-resist masked and etched to form an anchor pad 1000 and (optionally) identification indicia 990. The photo-resist masking and etching of the top and bottom metallization layers may be performed either before or after the vias 992, 994 are formed and plated, as described below. The top metallization layer and the top insulation layer 982 may be pre-formed and applied as a laminate, or they may be applied separately in sequence. Likewise, the bottom metallization layer and the bottom insulation layer 984 may be applied either together as a pre-formed laminate, or separately in sequence. In either case, the result is a multiple active layer laminated structure comprising first and second active polymer layers 972a, 972b, a first or upper electrode 974a, intermediate second and third electrodes 974b, 974c, a fourth or lower electrode 974d, an intermediate insulation layer 980, a top insulation layer 982, a bottom insulation layer 984, a bottom metallization layer, and a top metallization layer. The top and bottom metallization layers may be formed into the anchor pad 1000, the indicia 990, and the terminals 986, 988.
A first through-hole via 992 is formed through the entire thickness of the above-described multiple active layer laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 994 is similarly (and, preferably, simultaneously) formed through the entire thickness of the structure at each of the second plurality of via locations. Thus, each device 970 has a first through-hole via 992 at a first end, and a second through-hole via 994 at the opposite end. At this point, the top entrance or opening of the second via 994 is chamfered by any suitable mechanical or chemical means, such as, for example, a drill with a conical drill bit (not shown), to form a chamfered or beveled entry hole 1002 for the second via 994. The chamfered entry hole 1002 extends to the second via 994, either adjacent to or through an end of the first or upper electrode 974a. Although it is preferred to drill the vias 992, 994 first, and then to form the chamfered entry hole 1002, the chamfered entry hole 1002 may be formed at the pre-defined via locations before the second vias 992, 994 are drilled. The entry hole 1002 extends through the upper insulation layer 982 to the second via 994, either adjacent to or through the adjacent end of the first or upper electrode 974a.
The top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 992, 994, including the chamfered entry hole 1002 of each of the second vias 994, are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 996 within each of the first set of vias 992, and a second set of cross-conductors 998 within each of the second set of vias 994. A photo-resist masking and etching process is employed to form the anchor pad 1000 and the optional indicia 990 from the top metallization layer, and to form the planar terminals 986, 988 from the bottom metallization layer. The masking and etching process may be employed either before or after the vias 992, 994 are formed and plated. Each of the first set of cross-conductors 996 establishes physical and electrical contact with the second and fourth electrodes 974b, 974d, the anchor pad 1000, and the first planar terminal 986, while being electrically isolated from the first (upper) electrode 974a by the upper isolation area 976a, and from the third (intermediate) electrode 974c by the first intermediate isolation layer 978a. Similarly, each of the second set of cross-conductors 998 establishes physical and electrical contact with the first (upper) electrode 974a, the third (intermediate) electrode 974c, and the second planar terminal 988, while being electrically isolated from the second and fourth electrodes 974b, 974d by the second intermediate isolation area 978a and the lower isolation area 976b, respectively. The first terminal 986 is in electrical contact with the second and fourth electrodes 974b, 974d through the first cross-conductor 996, while the second terminal 988 is in electrical contact with the first (upper) electrode 974a and the third electrode 974c through the second cross-conductor 998.
The upper and lower ends of the first cross-conductor 996 are respectively anchored by their connection to the anchor pad 1000 and the first planar terminal 986. The upper and lower ends of the second cross-conductor 998 are respectively anchored by their connection to the upper electrode 974a and the lower second terminal 988. The exposed metal areas, particularly the terminals 986, 988, the cross-conductors 996, 998, and the anchor pad 1000 may advantageously be over-plated with one or more solderable metal layers, such as, for example, nickel and gold ENIG plating or electroless tin plating. Alternatively, the over-plating may be electroplated nickel and gold, electroplated nickel and tin, or electroplated tin, applied immediately after the copper plating step.
A top insulation layer 1082, which may be of prepreg, an insulative polymer, or an epoxy, is applied to the exposed surface of the first electrode 1074a, and a bottom insulation layer 1084, of similar material, is applied to the exposed surface of the sixth electrode 1074f. The top insulation layer 1082 fills the upper isolation area 1076a, while the bottom insulation layer 1084 fills the lower isolation area 1076b. A bottom metallization layer, preferably a copper foil, is applied to the exposed surface of the bottom insulation layer 1084, and it is photo-resist masked and etched to form first and second surface mount terminals 1086, 1088 separated by an exposed area of the bottom insulation layer 1084. Similarly, a top metallization layer, preferably a copper foil, is applied to the top insulation layer 1082, and it is photo-resist masked and etched to form an anchor pad 1100 and (optionally) identification indicia 1090. The photo-resist masking and etching of the top and bottom metallization layers may be performed either before or after the vias 1092, 1094 are formed and plated, as described below. The top metallization layer and the top insulation layer 1082 may be pre-formed and applied as a laminate, or they may be applied separately in sequence. Likewise, the bottom metallization layer and the bottom insulation layer 1084 may be applied either together as a pre-formed laminate, or separately in sequence. In either case, the result is a multiple active layer laminated structure comprising first second and third active polymer layers 1072a, 1072b, 1072c a first or upper electrode 1074a, intermediate second, third, fourth and fifth electrodes 1074b, 1074c, 1074d, 1074e a sixth or lower electrode 1074f, intermediate insulation layers 1080a, 1080b, a top insulation layer 1082, a bottom insulation layer 1084, a bottom metallization layer, and a top metallization layer. The top and bottom metallization layers may be formed into the anchor pad 1100, the indicia 1090, and the terminals 1086, 1088.
A first through-hole via 1092 is formed through the entire thickness of the above-described multiple active layer laminated structure (e.g. by mechanical or laser drilling) at each of the first plurality of via locations, and a second through-hole via 1094 is similarly (and, preferably, simultaneously) formed through the entire thickness of the structure at each of the second plurality of via locations. Thus, each device 1070 has a first through-hole via 1092 at a first end, and a second through-hole via 1094 at the opposite end. At this point, the top entrance or opening of the second via 1094 is chamfered or beveled by any suitable mechanical or chemical means, such as, for example, a drill with a conical drill bit (not shown), to form a chamfered or beveled entry hole 1102 for the second via 1094. The chamfered entry hole 1102 extends to the second via 1094, either adjacent to or through an end of the first or upper electrode 1074a. Although it is preferred to drill the vias 1092, 1094 first, and then to form the chamfered entry hole 1102, the chamfered entry hole 1102 may be formed at the pre-defined via locations before the second vias 1092, 1094 are drilled.
The top and bottom surfaces of the structure and the inside surfaces of the through-hole vias 1092, 1094, including the chamfered entry hole 1102 of each of the second vias 1094, are plated with one or more layers of conductive metal, preferably copper, thereby forming a first set of cross-conductors 1096 within each of the first set of vias 1092, and a second set of cross-conductors 1098 within each of the second set of vias 1094. A photo-resist masking and etching process is employed to form the anchor pad 1100 and the optional indicia 1090 from the top metallization layer, and to form the planar terminals 1086, 1088 from the bottom metallization layer. The masking and etching process may be employed either before or after the vias 1092, 1094 are formed and plated. Each of the first set of cross-conductors 1096 establishes physical and electrical contact with the second, third and sixth electrodes 1074b, 1074c, 1074f the anchor pad 1100, and the first planar terminal 1086, while being electrically isolated from the first (upper) electrode 1074a by the upper isolation area 1076a, from the fourth electrode 1074d by the isolation layer 1078c and from the fifth electrode 1074e by the isolation layer 1078d. Similarly, each of the second set of cross-conductors 1098 establishes physical and electrical contact with the first (upper) electrode 1074a, fourth, and fifth electrodes 1074d, 1074e and the second planar terminal 1088, while being electrically isolated from the second and third (intermediate) electrodes 1074b, 1074c by the intermediate isolation areas 1078a, 1078b and from the sixth (lower) electrode 1074f by the isolation layer 1076b. The first terminal 1086 is in electrical contact with the second, third and sixth electrodes 1074b, 1074c, 1074f through the first cross-conductor 1096, while the second terminal 1088 is in electrical contact with the first (upper) electrode 1074a, the fourth and fifth (intermediate) electrodes 1074d, 1074e through the second cross-conductor 1098.
The upper and lower ends of the first cross-conductor 1096 are respectively anchored by their connection to the anchor pad 1100 and the first planar terminal 1086. The upper and lower ends of the second cross-conductor 1098 are respectively anchored by their connection to the upper electrode 1074a and the lower second terminal 1088. The exposed metal areas, particularly the terminals 1086, 1088, the cross-conductors 1096, 1098, and the anchor pad 1100 may advantageously be over-plated with one or more solderable metal layers, such as, for example, nickel and gold ENIG plating or electroless tin plating. Alternatively, the over-plating may be electroplated nickel and gold, electroplated nickel and tin, or electroplated tin, applied immediately after the copper plating step.
While several example embodiments of the invention have been described herein, these embodiments are not exclusive. It is therefore understood that the scope of the invention disclosed and claimed herein will encompass other embodiments, variations, and modifications as equivalent to the specific embodiments described in this specification.
The flowcharts provided herein illustrate example embodiments of the present methods. In some alternative embodiments, the steps shown in these figures may occur out of the order presented. For example, in some cases two steps shown in succession may be executed substantially concurrently, or the steps may sometimes be executed in the reverse order. Those of ordinary skill in the art will also appreciate that the scope of the present methods is defined only by the claims provided below, and therefore some embodiments may not include all of the steps shown in the provided figures.
This application is a continuation of U.S. patent application Ser. No. 12/294,675, filed on Mar. 31, 2011, which is a national phase filing, under 35 U.S.C. §371(c), of International Application No. PCT/US2007/066729, filed Apr. 16, 2007, which claims the benefit, under 35 U.S.C. §119(e), of Provisional Application No. 60/744,897, filed on Apr. 14, 2006, the disclosure of which is incorporated herein by reference.
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Number | Date | Country | |
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20140077923 A1 | Mar 2014 | US |
Number | Date | Country | |
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Number | Date | Country | |
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Parent | 12294675 | US | |
Child | 14034092 | US |