Voltage-protected semiconductor bridge igniter elements

Information

  • Patent Grant
  • 6199484
  • Patent Number
    6,199,484
  • Date Filed
    Tuesday, June 15, 1999
    25 years ago
  • Date Issued
    Tuesday, March 13, 2001
    23 years ago
Abstract
A semiconductor bridge igniter device (10) having integral voltage anti-fuse protection provides an electric circuit including a first firing leg and, optionally, a monitor leg. The first firing leg includes a first semiconductor bridge having semiconductor pads (14a, 14b) separated and connected by a bridge (14c) and having metallized lands (16a, 16b) disposed over the pads (14a, 14b) so that an electrical potential applied across the metallized lands (16a, 16b) will cause sufficient current to flow through the firing leg of the electric circuit to release energy at the bridge (14c). A dielectric layer (15) is interposed within the first firing leg and has a breakdown voltage equal to a selected threshold voltage (Vth) and therefore provides protection against the device functioning at voltages below the threshold voltage (Vth). A continuity monitor leg of the electric circuit is comprised of either a fusible link (34) or a resistor (36) disposed in parallel to the first firing leg. A second firing leg may be provided which includes a second semiconductor bridge formed similar to the first semiconductor bridge although being mounted to receive a reverse polarity voltage from that of the first semiconductor bridge in order to reduce variations in firing voltage. A capacitor may be employed in parallel with the first firing leg in order to, e.g., reduce the effects of static electricity.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention is concerned with voltage-protected semiconductor bridge igniter elements, such elements having integral high voltage protection and, optionally, integral continuity testing capability.




2. Related Art




Semiconductor bridge (“SCB”) elements, means to electrically connect them for the purpose of electrical activation, and the use of such devices as igniters to initiate explosives, are well-known in the art. Presently, both the SCB of U.S. Pat. No. 4,708,060, to Bickes, Jr. et al, issued Nov. 24, 1987, and the tungsten bridge SCB of U.S. Pat. No. 4,976,200, to Benson et al, issued Dec. 11, 1990, are manufactured with large metallized pads for electrical contact to the active area of the bridge. The disclosure of U.S. Pat. No. 4,708,060 and U.S. Pat. No. 4,976,200 is incorporated herein. The SCB chip generally is mechanically bonded to an attachment surface of a header or other element of an electro-explosive device (“EED”). Proper functioning of the SCB in a detonator requires intimate contact with an energetic material such as an explosive or pyrotechnic material, and thus demands an upright position for the chip; that is, the chip cannot be assembled with its active area positioned against the attachment surface, but its active area must face towards and contact the energetic material so that the active area is free to interact with the energetic material, i.e., to impart energy thereto to initiate the energetic material.




Voltage protection for SCB elements is a highly desirable safety attribute used to prevent accidental functioning of explosive devices in the presence of stray voltage. For example, electromagnetic wave energy and, in particular, the radio frequency spectrum thereof, may induce stray voltages in SCB elements. Accordingly, use of SCB elements shipboard and on oil rigs and other places where various high power radio equipment may be utilized requires, e.g., that high voltage protection be provided in order to prevent unintended initiation of the SCB. In general, high voltage protection prevents voltages below a threshold voltage (“V


th


”) from inducing current flow through the SCB. However, for voltages above V


th


, a current will flow through the SCB with sufficient amplitude to fiction the SCB and thereby generate a plasma that will initiate an explosive load placed in intimate contact with the SCB or serve some other desired fiction. Therefore, V


th


is defined as the voltage that has to be exceeded before the SCB can be functioned. Such threshold voltages are generally in the range of from about 10 V to about 1000 V. It is known to provide high voltage protection for SCBs by various means; for example, spark gaps, near-intrinsic semiconductor films or substrates, and semiconductor diodes.




Spark gaps consist of a pair of encapsulated electrodes packaged in a gas or vacuum environment that are separated by a specific distance or “gap”. The gap, in general, determines the breakdown or threshold voltage of the device. The “gap” must be accurately and consistently controlled during the assembly process to reduce the variability range of the threshold voltage. Such a highly controlled encapsulation and electrode spacing process is quite expensive. Another drawback of this spark gap approach is that the continuity of the SCB is not easy to monitor unless a voltage greater than the spark gap breakdown voltage is applied for a very short period of time. This situation of course causes an unsafe condition of flowing high current through the SCB.




Near-intrinsic semiconductor films or substrates may also be used for voltage protection. A near-intrinsic semiconductor can be designed to have a particular volume and a particular resistance value selected so that, upon the application of voltages in excess of V


th


, enough heat will be generated to create additional carriers that will lower the resistance of the device and eventually cause current flow. Such current flow is a consequence of the negative differential resistance that intrinsic semiconductors typically exhibit. Near-intrinsic semiconductor films require very low doping levels which are difficult to control because they depend mainly on two processes: i) thermal effects such as thermal diffusion and/or thermal annealing after, for example, ion implantation and, ii) high controllability in the impurity level during the in situ growth of the semiconductor film. In addition to the difficulty of controlling a low doping level, both the impedance and the size of the near-intrinsic element must be properly designed to permit the available energy to be rapidly delivered to heat and vaporize the film to create the plasma that will set off the explosive load.




Semiconductor diodes have been used to prevent current flow caused by applied voltages below the characteristic breakdown or threshold voltage that occur at the diode's junction when biased in the reverse mode. However, this protection is lost when the diode is biased in the forward mode, therefore making the diode-protected SCB a polarized device. To alleviate this polarization problem, back-to-back diodes may be used in series with the SCB to provide protection for the SCB in both polarities. However, a major drawback of this approach is the low doping level required for high breakdown voltages for a single diode and the need for different wafers (substrates) for different breakdown voltages. For example, a diode with 500 V breakdown voltage requires a substrate doping concentration of less than 10


15


per cm


3


, which is impractical because of the difficulty of controlling such low concentrations of dopants. A solution which avoids the necessity for low doping levels is to use multiple low-voltage diodes interconnected in series with the SCB and in a back-to-back configuration. This, of course, results in a more elaborate design and use of a larger chip area. Another drawback of this back-to-back diode approach is that the continuity of the SCB is not easy to monitor unless a voltage greater than the diode breakdown voltage is applied for a very short period of time. This situation, of course, causes an unsafe condition of flowing high current through the SCB. There is, therefore, in addition to a need for an improved structure to provide high voltage protection for SCBs and the like, a need for an improved structure to enable continuity monitoring of the SCB device at various points during its manufacturing process and just prior to its use.




SUMMARY OF THE INVENTION




Generally, the present invention provides a semiconductor bridge (SCB) igniter element having integral high voltage protection and, optionally, DC current continuity monitoring capability. Such integral high voltage protection is achieved by interposing a dielectric material within the semiconductor bridge igniter element as a controllable anti-fuse. An anti-fuse is provided by a dielectric material which, upon the application of a sufficiently large voltage, i.e., the threshold voltage (V


th


), will break down to form a link through the dielectric material. As stated in


A Novel Double-Metal Structure for Voltage


-


Programmable Links


by Simon S. Cohen et al, in IEEE Electron Device Letters, Vol. 13, No. 9, September 1992, p. 488, the breakdown process of the dielectric material proceeds in three steps. First, the insulator is stressed by the applied field. Next, a filament forms in the insulation when sufficient current is available and, finally, the filament grows by a combination of Joule heating and chemical reactions for which a much larger current is required. The final state of the ruptured dielectric layer and filament formation is a low impedance link connecting the high voltage source with an element on the other side of the dielectric, in this case with the SCB igniter element. A fusible link or resistor is optionally connected in parallel to the dielectric anti-fuse SCB igniter to provide a continuity monitor leg of the circuit.




Specifically, in accordance with the present invention, there is provided a semiconductor bridge igniter device having protection against functioning at voltages below a preselected threshold voltage. The igniter device defines an electric circuit and comprises the following components. A substrate is made from a non-conductive material and has a first semiconductor bridge disposed on the substrate. The first semiconductor bridge comprises a polysilicon layer disposed on the substrate which is dimensioned and configured to have first and second pads having therebetween a gap which is bridged by an initiator bridge connecting the first and second pads. The bridge is so dimensioned and configured that passage therethrough of an electric current of selected characteristics releases energy at the bridge. First and second metallized lands are disposed in electrically conducting contact with, respectively, the first and second pads to define a first firing leg of the electric circuit comprised of the first and second metallized lands, the first and second pads and the bridge. A dielectric material having a breakdown voltage equal to the threshold voltage is interposed in series in the first firing leg of the electric circuit whereby the circuit can only be closed upon application thereto of a voltage potential at least as great as the threshold voltage. A second semiconductor is connected in parallel to the first semiconductor bridge and is disposed on the substrate. The second semiconductor bridge comprises a polysilicon layer disposed on the substrate which is dimensioned and configured to have first and second pads having therebetween a gap which is bridged by an initiator bridge connecting the first and second pads. The bridge is so dimensioned and configured that passage therethrough of an electric current of selected characteristics releases energy at the bridge. First and second metallized lands are disposed in electrically conducting contact with, respectively, the first and second pads to define a second firing leg of the electric circuit comprised of the first and second metallized lands, the first and second pads and the bridge. A dielectric material having a breakdown voltage equal to the threshold voltage is interposed in series in the second firing leg of the electric circuit whereby the circuit can only be closed upon application thereto of a voltage potential at least as great as the threshold voltage. The first semiconductor bridge and the second semiconductor bridge being configured in the electric circuit such that each is connected to receive an opposite voltage polarity with respect to that which the other receives.




In another aspect of the present invention, the dielectric material of the first semiconductor bridge is a dielectric layer interposed between the polysilicon layer of the first semiconductor bridge and the first metallized land of the first semiconductor bridge.




In another aspect of the present invention, the dielectric material of the second semiconductor bridge is a dielectric layer interposed between the polysilicon layer of the second semiconductor bridge and the second metallized land of the second semiconductor bridge.




In still another aspect of the present invention, the first metallized land of the first semiconductor bridge and the first metallized land of the second semiconductor bridge combine to form one first conductive layer. Also, the second metallized land of the first semiconductor bridge and the second metallized land of the second semiconductor bridge combine to form one second conductive layer.




In yet another aspect of the present invention, the polysilicon layer may be doped.




In a further aspect of the present invention, the electric circuit may comprise a capacitor connected in parallel with the first and second firing legs.




The present invention provides, in another aspect, for the electric circuit to further comprise a continuity monitor leg comprising a fusible link connected in parallel to the first and second firing legs. The fusible link, which may comprise a thin film fusible link, is dimensioned and configured to rupture at an amperage above that of a selected monitor amperage whereby, if the monitor amperage is exceeded, the fusible link will rupture and open the monitor leg.




Yet another aspect of the present invention provides for the electric circuit to further comprise a continuity monitor leg comprising a resistor connected in parallel to the first and second firing legs. The resistor may comprise a doped segment of the polysilicon layer or of the non-conductive substrate. In any case, the resistor has a resistance value large enough to reduce the current flow through the first and second firing legs of the electric circuit (and thereby reduce the generation of heat within the chip) to a level at which the temperature of the first and second semiconductor bridge devices remain below a preselected temperature. In a related aspect of the present invention wherein the semiconductor bridge igniter device comprises an electro-explosive device and is disposed in contact with an energetic material, e.g., a primary explosive, the preselected temperature is the auto-ignition temperature of the energetic material.




In another aspect of the present invention, the resistor may comprise a doped segment of the polysilicon layer of the first semiconductor bridge or may comprise a doped segment of the substrate.




Yet a further aspect of the present invention provides that the substrate is separated into first and second substrates wherein the first semiconductor bridge is disposed on the first substrate and the second semiconductor bridge is disposed on the second substrate.




The present invention provides, in another aspect, an igniter device defining an electric circuit which comprises the following components. A substrate is made from a non-conductive material and has a first semiconductor bridge disposed on the substrate. The first semiconductor bridge comprises a polysilicon layer disposed on the substrate which is dimensioned and configured to have first and second pads having therebetween a gap which is bridged by an initiator bridge connecting the first and second pads. The bridge is so dimensioned and configured that passage therethrough of an electric current of selected characteristics releases energy at the bridge. First and second metallized lands are disposed in electrically conductive contact with, respectively, the first and second pads to define a first firing leg of the electric circuit comprised of the first and second metallized lands, the first and second pads and the bridge. A dielectric material having a breakdown voltage equal to the threshold voltage is interposed in series in the first firing leg of the electric circuit whereby the circuit can only be closed upon application thereto of a voltage potential at least as great as the threshold voltage. The electric circuit further comprises a capacitor connected in parallel to the first firing leg.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a schematic elevation view of a voltage-protected semiconductor bridge igniter device in accordance with one embodiment of the present invention;





FIG. 2

is a top plan view of the igniter device of

FIG. 1

;





FIG. 3

is a schematic elevation view of a voltage-protected semiconductor bridge igniter device in accordance with another embodiment of the present invention;





FIG. 4

is a top plan view of the igniter device of

FIG. 3

;





FIG. 5

is a schematic elevation view of a voltage-protected semiconductor bridge igniter device in accordance with yet another embodiment of the present invention;





FIG. 6

is a top plan view of the igniter device of

FIG. 5

;





FIG. 7

is a circuit diagram of a voltage-protected semiconductor bridge igniter device in accordance with one embodiment of the present invention comprising a fusible link disposed in parallel to the firing leg of the electric circuit of the device;





FIG. 8

is a circuit diagram of a voltage-protected semiconductor bridge igniter device in accordance with another embodiment of the present invention comprising a high-resistance resistor disposed in parallel to the firing leg of the electric circuit of the device;





FIG. 9

is a schematic plan view of a voltage-protected semiconductor bridge igniter device in accordance with the embodiment illustrated in FIG.


8


and including a serpentine high-resistance resistor disposed in parallel to the firing leg of the electric circuit of the device;





FIG. 10

is a schematic cross-sectional view in elevation of an electro-explosive device utilizing a voltage-protected semiconductor bridge igniter element in accordance with an embodiment of the present invention;





FIG. 11

is a schematic circuit diagram of the test set-up employed in Part B of Example 1;





FIG. 12

is a schematic circuit diagram of the test set-up employed in Part C of Example 1;





FIG. 13

is a schematic view of a voltage-protected semiconductor bridge igniter device in accordance with yet another embodiment of the present invention;





FIG. 14

is a schematic plan view of the voltage-protected semiconductor bridge igniter device of

FIG. 13

;





FIG. 15

is a cross sectional view taken along line XIV—XIV of

FIG. 14

;





FIG. 16

is a schematic diagram of a voltage-protected semiconductor bridge igniter device in accordance with still another embodiment of the present invention; and





FIG. 17

is an enlarged exploded view, partially in section, of an electro-explosive device utilizing the voltage-protected semiconductor bridge igniter device of FIG.


16


.











DETAILED DESCRI




PTION OF THE INVENTION AND PREFERRED EMBODIMENTS THEREOF Voltage-Protected SCB Device




In the present invention a semiconductor bridge igniter device is voltage-protected (sometimes herein referred to as “voltage-blocked”) by an anti-fuse comprising a dielectric layer (e.g., silicon dioxide) sandwiched between two highly conductive electrodes such as electrodes made of n-doped polysilicon, of low melting point metals (e.g., Al, Cu, Au, etc.), of refractory metals (e.g., W, Mo, Co, etc.) and/or a combination of two or more thereof. The dielectric layer is selected in such a way that its thickness and dielectric field strength in volts per centimeter of thickness of the dielectric layer (V/cm) will result in a sudden rupture of the dielectric layer at the desired high voltage threshold value (V


th


). For example, silicon dioxide with a dielectric strength of 10


7


V/cm and a film thickness of approximately 0.5μ will break down when a voltage of approximately 500 V is applied. The time to break down the dielectric is extremely short; that is, it is equivalent to that of the time associated with generation of a spark and is measured in microseconds or even nanoseconds. Thinner films have lower threshold voltages (V


th


) and vice-versa. Thus, the presence of a high voltage and the sudden formation of the filament in the dielectric layer having a short-circuit-like response will cause currents in excess of the required firing level for the semiconductor bridge igniter element such that the element will heat and vaporize, resulting in a plasma that sets off the explosive charge placed in proximity to the igniter. In general, the metal-insulation-metal anti-fuse concept is such that high voltage protection is offered by the dielectric layer for voltage values below the rupture or breakdown voltage of the dielectric layer which is selected to establish it as the threshold voltage (V


th


). V


th


is determined mainly by the material of which the dielectric layer is made and its thickness. Voltages at least as great as V


th


will rupture the dielectric layer, fuse the two electrodes together, and expose the semiconductor bridge igniter element to the applied high voltage with the subsequent heating and vaporization of the semiconductor bridge igniter element to function the electro-explosive device (“EED”) of which it is apart.





FIGS. 1 through 9

and


13


through


17


are schematic and are not drawn to scale; the size of certain elements are exaggerated for clarity of illustration. Identical elements of

FIGS. 1 through 6

are represented by the same element numbers and similar elements are represented by the same element numbers having a prime added thereto, e.g.,


16




a


′.

FIGS. 7 through 9

and


13


through


17


employ a separate numbering scheme.




Referring now to

FIGS. 1 and 2

, there is shown a semiconductor bridge device


10


having an electrically non-conducting substrate


12


which may comprise any suitable electrically non-conducting material. Generally, as is well-known in the art, a non-conducting substrate can be a single or multiple component material. For example, a suitable non-conducting substrate for a polycrystalline silicon semiconductor material comprises an insulating layer (e.g., silicon dioxide, silicon nitride, etc.) disposed on top of a monocrystalline silicon substrate. This provides a well-known suitable combination of materials for substrate


12


. A suitable non-conducting substrate for monocrystalline silicon semiconductor materials comprises sapphire, also a known suitable material for substrate


12


. An electrically-conducting material comprising, in the illustrated embodiment, a heavily doped polysilicon semiconductor


14


is mounted on substrate


12


by any suitable means known in the art, for example, by epitaxial growth or low pressure chemical vapor deposition techniques. As best seen in

FIG. 2

, semiconductor


14


comprises a pair of pads


14




a,




14




b


which in plan view are substantially rectangular in configuration except for the facing sides


14




a


′, and


14




b


′ thereof which are tapered towards initiator bridge


14




c.


Bridge


14




c


connects pads


14




a


and


14




b


and is seen to be of much smaller surface area and size than either of pads


14




a


,


14




b


. Bridge


14




c


is the active area of the semiconductor bridge device


10


. It is seen from

FIG. 2

that the resultant configuration of the semiconductor


14


somewhat resembles a “bow tie” configuration, with the large substantially rectangular pads


14




a


,


14




b


spaced apart from and connected to each other by the small initiator bridge


14




c


. A dielectric layer


15


is mounted on rectangular pad


14




a


of semiconductor


14


. Dielectric layer


15


is partly broken away in

FIG. 2

in order to show pad


14




a


and, in the illustrated embodiment, entirely covers the upper surface of pad


14




a


. A pair of metallized lands


16




a


and


16




b


, partly broken away in

FIG. 2

in order to partially show dielectric layer


15


and pad


14




b


, respectively, overlie dielectric layer


15


and pad


14




b


and, in the illustrated embodiment, entirely cover the upper surfaces of the same. Metallized lands


16




a


and


16




b


are substantially identical. The prior art generally teaches the use of aluminum or tungsten for the lands


16




a


and


16




b


although any suitable metal or combination of metals may be used. Electrical contacts


18




a


and


18




b


may be attached, respectively, to lands


16




a


and


16




b


thereby enabling the electrical connection of any suitable external voltage source to the SCB. Alternately, lands


16




a


and


16




b


may be directly connected to a printed circuit board or the like thereby enabling the electrical connection of any suitable external voltage source to the SCB.




In operation, the semiconductor bridge device of the present invention is electrically connected to an external voltage source that provides a voltage potential. Dielectric layer


15


acts as an insulator thereby preventing a voltage potential from being applied across initiator bridge


14




c


. As discussed above, dielectric layer


15


will break down or rupture and form an electric filament after a voltage (activation voltage) in excess of V


th


is applied across initiator bridge


14




c


for a sufficient amount of time. Once dielectric layer


15


is breached, i.e., a conductive filament is formed which extends between land


16




a


and pad


14




a


, the voltage potential applied across contacts


18




a


and


18




b


will cause current to flow through initiator bridge


14




c


. When a current of sufficient intensity is applied for a sufficient length of time, initiator bridge


14




c


erupts with the formation of a plasma, which will serve to provide a heat source for use in, e.g., initiating energetic materials packed in contact with initiator bridge


14




c.






Referring now to

FIGS. 3 and 4

, there is shown a semiconductor bridge device


10


′ of another embodiment of the present invention having an electrically non-conducting substrate


12


′. An electrically-conducting semiconductor


14


which is identical to that of semiconductor


14


of the embodiment of

FIGS. 1 and 2

and therefore is not further described, is mounted on substrate


12


′ such that a portion of substrate


12


′ is left exposed. A metallized conductive layer


20


is mounted on upper and side surfaces of rectangular pad


14




a


and extends to and along the exposed portion of substrate


12


′. A dielectric layer


15


′ is mounted on the upper surface of conductive layer


20


within region


20




a


. Region


20




a


is the portion of conductive layer


20


that is mounted directly on substrate


12


′. Dielectric layer


15


′ may extend to cover the entire upper surface of region


20




a


. A pair of metallized lands


16




a


′ and


16




b


(land


16




b


being broken away in

FIG. 4

in order to partially show rectangular pad


14




b


) overlaying dielectric layer


15


′ and pad


14




b


and, in the illustrated embodiment, entirely cover the upper surfaces of the same.




In operation, the semiconductor bridge device of

FIGS. 3 and 4

provides integral voltage protection similar to that of the device of

FIGS. 1 and 2

. Dielectric layer


15


acts as an insulator thereby preventing a voltage potential from being applied across initiator bridge


14




c


. As discussed above, dielectric layer


15


will break down or rupture and form an electric filament after a voltage in excess of V


th


is applied across semiconductor bridge device


10


for a sufficient amount of time. Once dielectric layer


15


is breached, i.e., a conductive filament is formed which extends between land


16




a


and pad


14




a


, the voltage potential applied across contacts


18




a


′ and


18




b


will cause current to flow through initiator bridge


14




c


. Specifically, the path of the current flow is through land


16




a


′, the conductive filament formed in dielectric layer


15


′, conductive layer


20


, pad


14




a


through initiator bridge


14




c


to pad


14




b


and land


16




b


. When a current of sufficient intensity is applied for a sufficient length of time, initiator bridge


14




c


erupts with the formation of a plasma, which will serve to provide a heat source for use in, e.g., initiating energetic materials packed in contact with initiator bridge


14




c.






Referring now to

FIGS. 5 and 6

, there is shown a semiconductor bridge device


10


″ of yet another embodiment of the present invention, having an electrically non-conducting substrate


12


′. An electrically-conducting semiconductor


14


which is identical to that of semiconductor


14


of the embodiment of

FIGS. 3 and 4

and therefore is not further described, is mounted on substrate


12


′ such that a portion of substrate


12


′ is left exposed. A metallized conductive layer


20


′ is mounted on upper and side surfaces of rectangular pad


14




a


and extends to a short section of the exposed portion of substrate


12


′. A localized n-doped silicon region


22


of substrate


12


′, located at the upper surface thereof, extends along the exposed portion of substrate


12


′, to electrically connect to conductive layer


20


′ in region


20




a


′. A dielectric layer


15


′ is mounted on the upper surface of n-doped silicon region


22


. Dielectric layer


15


′ may extend to cover the entire upper surface of region


20




a


′. A portion of both conducting layer


20


′ and pad


14




a


are partly broken away in

FIG. 6

in order to partially show n-doped silicon region


22


. A pair of metallized lands


16




a


′ and


16




b


(land


16




b


being partly broken away in

FIG. 6

in order to partially show rectangular pad


14




b


), overlie dielectric layer


15


′ and pad


14




b


and, in the illustrated embodiment, entirely cover the upper surfaces of the same.




The semiconductor bridge device of

FIGS. 5 and 6

provides integral voltage protection and operates in a manner which is similar to that of the semiconductor bridge devices of

FIGS. 3 and 4

. Once dielectric layer


15


is breached, i.e., a conductive filament is formed which extends between land


16




a


and pad


14




a


, the electric potential applied across contacts


18




a


′ and


18




b


will cause current to flow through initiator bridge


14




c


. Specifically, the path of the current flow is through land


16




a


′, the conductive filament formed in dielectric layer


15


′, the n-doped silicon region


22


, conductive layer


20


, pad


14




a


through initiator bridge


14




c


to pad


14




b


and land


16




b


. When a current of sufficient intensity is applied for a sufficient length of time, initiator bridge


14




c


erupts with the formation of a plasma, which will serve to provide a heat source for use in, e.g., initiating energetic materials packed in contact with initiator bridge


14




c.






The above-described embodiments, which show placement of the anti-fuse on one of the polysilicon, the metallized layer, or the silicon substrate, are just some of the possible voltage-protected semiconductor bridge igniter structures that can be used for the purpose of optimizing the anti-fuse electrical characteristics. Selection of the layer of the structure on which the anti-fuse is disposed may affect some potential reliability issues related to, for example, micro-roughness on the polysilicon surface.




Voltage-Protected SCB With Continuity Check




As noted above, it is desirable to be able to monitor continuity of the SCB device at various points in its manufacturing cycle, as well as just prior to use. For example, continuity monitoring is desirable after the SCB device is deployed in the field as part of an electro-explosive device (“EED”), i.e., an initiator for explosive charges, and before the EED is connected to a firing leg. The anti-fuse structure described above, without continuity-monitoring structure, would admit of continuity monitoring only with a high-frequency signal which, by its nature, will not propagate very far through standard two-wire lead-ins typically used in EED systems, especially for wire lengths exceeding a few feet. Hence, a high-frequency continuity check is impractical for most applications and a continuity check by use of a direct current (DC) electrical signal is preferred, and, in most cases, is the only feasible way.




The present invention provides two different approaches for a safe and effective DC continuity check for the high voltage-protected SCB device of the present invention. One is a fusible link, the other is a high-value resistor, and either one is placed in parallel to the firing leg of the SCB device.




Fusible Link Continuity Check Structure




One configuration which will facilitate a DC continuity check of an SCB device is a fusible link placed in parallel to the firing leg of the SCB device. A fusible link is typically a low-power, low-resistance metalization layer deposited on the device, such as a thin trace of aluminum. By employing the fusible link, the firing leg continuity can be tested without current flow through the firing leg of the SCB device. The aluminum trace is designed to be ruptured and thereby cause an open circuit by a low amplitude DC monitor energy level. Hence, the amplitude of the DC monitor current must be maintained below the level at which the fusible link will rupture and the voltage must be maintained below the activation voltage, i.e., the voltage at which the SCB device will be initiated. The fusible link can be placed either on the back side of the SCB device (chip) or, more easily, on the top surface of the SCB device. The fusible link may be covered with a SiO


2


passivation layer, if necessary, as in cases where the SCB device is used as part of an EED and is in contact with an energetic material such as a primary explosive, e.g., lead azide, lead styphnate, or the like. The passivation layer prevents any energetic material which is in contact with the fusible link from being initiated by either the low-amplitude monitor current or a higher amplitude current, i.e., the link activation current, which fuses the fusible link.




An electrical circuit schematic is shown in

FIG. 7

wherein a voltage-protected semiconductor bridge device


24


is comprised of a semiconductor bridge device


26


connected in series with a dielectric anti-fuse


28


. It will be appreciated that voltage-protected semiconductor bridge device


24


can be comprised of any of the embodiments illustrated in

FIGS. 1-6

or any other embodiment which places anti-fuse device


28


in series within the firing leg of the electrical circuit of the device. In

FIG. 7

, the firing leg is defined by the path ABEF which includes electrical connectors


30


,


32


across which a source of electrical energy is connected. A continuity monitor leg ACDF is connected in parallel to the firing leg and includes a fusible link


34


. The fusible link


34


is preferably a thin trace of metal, preferably aluminum, disposed on the substrate of semiconductor bridge device


26


.




The significant characteristic of fusible link


34


is its fusing current level, I


fo


, which is defined as the minimum amount of current needed to fuse open the element. Current levels below I


fo


can be used for a continuity test, where minimal heat is generated within the element. Current levels equal to or higher than I


fo


are considered fusing currents.




I


fo


for a fusible link is determined by several design parameters, some of which are: the metal of which the fusible link is made which determines the electrical resistivity (ρ


f


) to control the element's resistance R


f





f


L


f


/Ac


f


); the melting point (T


m


) to define the amount of heat needed to fuse the element; and the thermal conductivity of metal upon melting (K


m


). Typical metals are aluminum (Al), gold (Au), copper (Cu), chrome (Cr).




The substrate on which the fusible link is deposited controls the rate of heat transfer away from the fusible link. Typical materials are silicon (Si), quartz (SiO


2


), glass and sapphire (Al


2


O


3


).




The physical dimensions of the fusible link, i.e., length (L


f


), width (W


f


), thickness (Th


f


), which define the element's cross section Ac


f


(W


f


×Th


f


) for current flow, surface area As


f


(L


f


×W


f


) for heat conduction into the substrate, and volume V


f


(L


f


×W


f


×Th


f


) for total energy requirements.




The fusible link can be designed to fuse open for a small current amplitude, such as 0.1-0.5 amps. When the monitor voltage is applied, the current-limited monitor current flows through the fusible link, because the other leg of the circuit is effectively blocked by the capacitive effect of the anti-fuse layer and is therefore protected to the desired voltage, typically several hundred volts. Hence, a simple DC continuity check can be used to assess the continuity of the electrical connection to the SCB chip.




During operation, as the voltage is increased to the firing voltage, the fusible link is ruptured when the current increases beyond its activation current, thereby eliminating the continuity monitor leg of the circuit. The SCB firing leg then fires normally when the anti-fuse reaches its activation voltage.




Fusible links or fuses can be made as stand-alone (straight or coiled) wires or foils, and as thin films on substrates such as substrates


12


or


12


′ of the embodiments illustrated in

FIGS. 1-6

. Stand-alone wires and foils require thick and, therefore, bulky materials whose length is typically measured in centimeters and with a cross-sectional area of about 100 square mils. Despite their large size as compared to thin films, they are fragile and have to be contained in glass or plastic enclosures.




On the other hand, thin film fusible links are micrometer-sized elements that are deposited on flat substrates by means of photolithography techniques such as those used in semiconductor processing. Some of the substrate types that are compatible with thin film fusible links include standard silicon wafers, glass or plastic discs, sapphire substrates, ceramics and other flat surfaces that are electrically insulating. However, fabricating fusible links on standard silicon substrates that have been previously and selectively oxidized offers the advantage of circuit integration on the same chip. The ability to integrate a fusible link and semiconductor circuit on the same chip has in itself the great advantage of reducing manufacturing cost, increasing production reliability and reproducibility, as well as protection against mechanical damage. The flexible dimensioning which photolithography offers allows one to scale the fusible element up or down to adjust its resistance while maintaining the same fusing current.




In addition, the thin film fusible link can be fabricated of almost any metal, based on technology readily available from the semiconductor industry. For example, standard photolithography techniques may be used to define the fusible link geometry and the fusible link thickness is controlled during metal deposition. In addition, the thin film fusible link metal can be deposited by various other well-known techniques including evaporation, sputtering, spraying, electroplating, chemical vapor deposition, etc.




Resistive Continuity Check




As an alternative to a fusible link, a high-value resistance can be used in parallel to the SCB anti-fuse-containing firing leg of the circuit, to act as a resistive element with which to check the circuit continuity. The resistor is preferably integrated onto the SCB substrate, although a separate discrete resistor component can be used. The resistance value is selected to be appropriate for the intended use. For example, in order for the integrated resistor to be effective in EED applications, its resistance value must be large enough (on the order of 100 kilo-ohms) to keep the current flow, and therefore power dissipation, low enough to maintain the temperature of the SCB device at all times below the auto-ignition temperature of the energetic material (e.g., primary explosive) with which it is in contact in the explosive device. The applied continuity monitor voltage must of course be below the activation voltage, i.e., the voltage at which the SCB will be initiated. The activation voltage can vary from tens of volts to hundreds of volts, depending on the design of the voltage-blocked SCB device (the SCB device in series with the anti-fuse dielectric) and the contemplated application of the device. Low power dissipation will also reduce the effect of heat on the voltage-blocking performance of the anti-fuse, because experience shows that heat tends to lower the voltage threshold of such anti-fuse devices.




A schematic electrical circuit for a voltage-protected semiconductor bridge device including a resistive continuity monitor leg ACDF is shown in

FIG. 8

which is identical to

FIG. 7

except that a resistor


36


is substituted for the fusible link


34


of the

FIG. 7

embodiment. The elements of

FIG. 8

which are identical to those

FIG. 7

are identically numbered and need not be further described except to note that, like the circuit of

FIG. 7

, the circuit of

FIG. 8

comprises a firing leg ABEF and a continuity monitor leg ACDF.




The location of the resistor can be either in the bulk silicon of the wafer or in the polysilicon layer that contains the SCB. Some of the advantages of each are discussed below. However, the preferred configuration is for the resistor to be located in the bulk silicon of the wafer. The doping of either the bulk silicon or the polysilicon can be controlled to provide a high electrical resistance per square such that a high-value resistor could be manufactured on the same chip as the SCB. One embodiment uses a serpentine design to achieve a high value of resistance. The resistor is connected to the voltage-blocked SCB by large area n+ type diffused contact pads which mitigate the creation of a non-linear component such as a Shottky diode.




A typical design layout of a voltage-blocked SCB with a high-value resistor as a continuity check is shown in

FIG. 9

wherein a semiconductor bridge device


38


is both high-voltage-protected and has a continuity monitor leg integrally formed therein. A semiconductor bridge device


38


comprises an electrically non-conducting substrate


40


which may be made of a suitable material such as silicon dioxide, silicon nitride,. etc. In a construction similar or identical to that illustrated, for example, in

FIGS. 1 and 2

, semiconductor bridge device


38


is seen in plan view to comprise a pair of metallized lands


42




a,




42




b


disposed atop pads


44




a,




44




b


of a polysilicon semiconductor, pads


44




a


and


44




b


being connected by an initiator bridge


44




c


. Pads


44




a


,


44




b


and initiator bridge


44




c


are formed of an integral, single piece of polysilicon semiconductor. Not visible in

FIG. 9

is an anti-fuse comprised of a dielectric layer, comparable to dielectric layer


15


illustrated in

FIGS. 1 and 2

, and disposed between metallized land


42




a


and pad


44




a


. Resistor contact pads


46




a


and


46




b


are electrically connected to, respectively, metallized lands


42




a


and


42




b.


Resistor contact pads


46




a


and


46




b


are connected by a metal connector layer, such as an aluminum connector, which extends as a strip or trace of metal downwardly through substrate


40


via passageways (not visible in

FIG. 9

) extending through substrate


40


to the underside thereof, also not visible in FIG.


9


. The passageway is lined with a suitable dielectric material to prevent electrical contact between the metal trace extending from the connector pads and other components of the device. The metal connector layer connects resistor contact pads


46




a,




46




b


to opposite ends of a serpentine resistor


48


formed on the underside of substrate


40


. High resistivity can be accomplished with near intrinsic silicon wafers, and a specific value can be obtained by a light concentration of doping ions to achieve the required high resistivity per square. This can also be accomplished in standard-doped wafers by counter-doping with the opposite ion (positive ions for p-type wafers and vice-versa) until the desired high resistivity is achieved. As an alternative to the illustrated structure, the resistor could also be located in the same polysilicon layer which contains the SCB device instead of in or on substrate


40


.




One of the potential advantages of placing the resistor in the polysilicon is that because of the SiO


2


isolation layer beneath the polysilicon, the resistor can be completely electrically isolated from the supporting silicon substrate. Another potential advantage of placing the resistor in the polysilicon layer is that the polysilicon is grown undoped and can more easily be doped to a low concentration of ions than can the bulk silicon of standard-doped wafers. The low doping gives rise to a high resistance per square. However, a major advantage of placing the resistor in the bulk silicon of the wafer is the superior heat transfer out of the device and into the header or other structure (e.g., see FIG.


10


and its description below) on which the SCB device is mounted, thereby minimizing heat buildup. Applying the resistor to the bulk silicon substrate is thus a preferred configuration if thermal considerations are paramount.




The semiconductor bridge igniter devices of the present invention are advantageously employed as a component of an EED. A typical EED is illustrated in

FIG. 10

by a conventional explosives igniter


50


comprised of a header


52


defining a cup-like recess


54


containing an explosive charge


56


which typically comprises a primary explosive such as lead azide or lead styphnate. Disposed at the bottom of recess


54


is a semiconductor bridge device


58


made in accordance with the present invention and comprised of metallized lands


60




a,




60




b


with igniter bridge


62


disposed therebetween and in contact with explosive charge


56


. The semiconductor bridge device is secured to the bottom of cup-like recess


54


by suitable means such as an epoxy glue


65


, and metal lands


60




a,




60




b


are connected to electrical leads


64


by respective electrical lead wires


66




a,




66




b,


each having one end wire-bonded to a respective one of metal lands


60




a,




60




b


and the other end wire-bonded to a respective one of electrical leads


64


.




EXAMPLE 1




A. Voltage blocked SCB igniter devices


38


manufactured in the configuration shown in

FIG. 9

were, for testing purposes, mounted on TO-46 headers in the manner illustrated in connection with the explosives igniter


50


of

FIG. 10

, except that energetic material (corresponding to explosive charge


56


of

FIG. 10

) was omitted. Each of the tested units


150


(

FIGS. 11 and 12

) contained an SCB igniter device


38


comprised of the following components:




a) a 0.5 μm thick silicon dioxide film as the anti-fuse element (not shown in

FIG. 9

but equivalent to dielectric layer


15


of FIG.


1


);




b) aluminum metal lands (


42




a,




42




b


of FIG.


9


);




c) a polysilicon layer (not shown in

FIG. 9

except for initiator bridge


44




c,


but equivalent to polysilicon semiconductor


14


of

FIG. 1

;


44




c


of

FIG. 9

is the equivalent of


14




c


of FIG.


1


); and




d) a 15,000 ohm resistor (serpentine resistor


48


in

FIG. 9

) connected in parallel to the voltage-blocked firing leg. The latter is provided by the metallized lands (


42




a,




42




b


of FIG.


9


), the dielectric layer (equivalent to 15 of

FIG. 1

) and the polysilicon semiconductor layer (equivalent to 14 of FIG.


1


).




The test units were electrically tested by each of a capacitive discharge (10 μF) test, a ramp-up DC voltage test, a resistance current versus step-up DC voltage test, and an AC voltage (120 volts and 60 cycles per second) test.




B. Capacitive discharge tests were conducted using a first test circuit


68


illustrated schematically in FIG.


11


and comprising a 600 volt, 10 μF capacitor


70


, a toggle switch


72


, an oscilloscope


74


and a high-voltage, direct current (DC) power supply


76


, which is variable from 0 to 400 volts. The tested unit


150


was connected into the circuit via electrical leads corresponding to electrical leads


64


of FIG.


10


. During this test, a breakdown voltage of 200±20 volts was obtained for the anti-fuse element (equivalent to dielectric layer


15


of FIG.


1


). Voltage at the capacitor was stepped up in increments of 10 volts within the range of 150 to 250 volts. In this scenario, no significant role was played by the parallel resistor continuity monitor leg since the voltage delivered to the anti-fuse was instantaneous and the resistor did not consume any significant amount of energy.




C. Ramp-up DC voltage tests were conducted by connecting the high-voltage DC power supply


76


of

FIG. 11

directly to the electrical leads of the tested unit


150


(corresponding to the electrical leads


64


of

FIG. 10

) and monitoring the results by the oscilloscope


74


. Testing showed that the voltage-protected SCB fired consistently at the 200±20 volts level for an input voltage that was manually increased at a rate of 30 volts per second or higher. This was consistent with the results obtained from the capacitive discharge test of part B. However, for voltage rates of about 15 volts per second or lower, the voltage-protected SCB showed some electrical instabilities at about 160 V that led to a premature functioning of the device at slightly lower voltages, in the range of 160 to 180 V. This is believed to be a consequence of heat generated by the parallel resistor. Heat promotes the diffusion of aluminum in the SiO


2


dielectric film, in turn reducing the effective thickness of the original 0.5 μm thick dielectric film.




D. Resistance current versus step-up DC voltage tests were conducted by connecting, as shown in

FIG. 12

, the DC high-voltage power supply


76


and an ammeter


78


in series with the tested unit


150


in a second test circuit


80


which includes the oscilloscope


74


. Continuous voltage monitoring testing was performed on the voltage-blocked SCB devices. In this test, voltage was applied in a step-up voltage mode with each voltage step lasting for 1 minute, and at voltage steps of 10 volts within the range of 60 to 160 V. The purpose of the one-minute intervals between stepping up the voltage at each voltage step was to allow for temperature stabilization of the semiconductor igniter device


38


of tested unit


150


at each voltage. Data was thus obtained on the resistance value of the parallel resistor (equivalent to resistor


36


in

FIG. 8

) of the semiconductor igniter device


38


as a fiction of the applied voltage. The overall results from this test indicated that the tested units could sustain


140


volts DC in a continuous mode for more than 12 hours without physical and/or electrical degradation of the tested units.




Electrical parameters, voltage and current of the voltage-protected SCB were monitored during this test. Hence, the resistance of the resistor (corresponding to resistor


36


of

FIG. 8

) and power were calculated as a function of applied voltage. The main electrical characteristic observed was that the parallel resistor (corresponding to resistor


36


of

FIG. 8

) changed its value from the initial 15,000 ohms at 0.5 volts to approximately a peak value of 150,000 ohms at one hundred volts, and then dropped to about 100,000 ohms at 140 volts. Power loss was less than 0.2 watt at 140 volts.




This dynamic electrical behavior of the resistor is responsible for the excellent continuity test capability and voltage protection offered by the addition of the high-impedance parallel resistor (corresponding to resistor


36


of

FIG. 8

) to the voltage-protected SCB igniter device


38


(FIG.


9


). In other words, the response of the parallel resistor to a continuously increasing stray voltage is to increase the resistance offered by the resistor due to the small amount of heat generated within the SCB chip. Of course, as will be appreciated by those skilled in the art, the larger the SCB chip size, the better its heat-dissipating capability will be.




E. In the AC voltage test, the tested units


150


were repeatedly plugged into and unplugged from a 120 volts, 60 cycles per second AC outlet connected to the equivalent of the electrical leads


64


of FIG.


10


. No physical or electrical damage to the tested units


150


was observed. The tested units were also left plugged into the AC outlet overnight without any detectable degradation.




Multiple Bridge Structure




Voltage-protected semiconductor bridge igniter devices described above which comprise a single voltage-protected semiconductor bridge device (such as device


24


of FIGS.


7


and


8


), have been found to be sensitive to voltage polarity. In particular, variations in firing levels have been observed depending upon the polarity of the voltage applied to the igniter device. One way to alleviate this sensitivity is by the introduction of a second voltage-protected semiconductor bridge device into the electric circuit to receive a reverse voltage polarity from that of the first voltage-protected semiconductor bridge device.




A schematic electrical circuit of a voltage-protected semiconductor bridge igniter device employing a multiple bridge structure and a resistive continuity monitor leg ADEH is shown generally at


200


in FIG.


13


. The circuit of

FIG. 13

comprises a pair of firing legs ABGH and ACFH and a continuity monitor leg ADEH each connected together in parallel. The monitor leg ADEH may be similar to that discussed above and, as illustrated, comprises a high-value resistor


202


, although it will be understood that a fusible link may be employed in this embodiment instead of the resistor. Circuit continuity may be checked through the resistor


202


and the resistor is preferably integrated onto the SCB substrate, although a separate discrete resistor component can be employed. The resistance value may be selected as appropriate for the intended use and the applied continuity monitor voltage must be below the activation voltage as discussed above. As with the embodiment of

FIG. 8

, the location of the resistor can be either in the bulk silicon of the wafer or in the polysilicon layer that contains the SCB.




Firing leg ABGH comprises a voltage-protected semiconductor bridge


204


and firing leg ACFH comprises a voltage-protected semiconductor bridge


204


′. Each of these voltage-protected semiconductor bridges


204


,


204


′ comprises a semiconductor bridge device


206


,


206


′ connected in series with a dielectric anti-fuse


208


,


208


′. It is seen that the semiconductor bridge device


206


and the anti-fuse


208


are connected to receive an opposite voltage polarity from that of semiconductor bridge device


206


′ and anti-fuse


208


′. It will be appreciated that voltage-protected semiconductor bridge devices


204


,


204


′ can be comprised of any of the embodiments illustrated in

FIGS. 1-9

or any other embodiment which places an anti-fuse device in series within the firing legs of the electrical circuit of the device.




One embodiment of a voltage-blocked semiconductor bridge igniter device is shown generally at


201


in

FIGS. 14 and 15

. The voltage-blocked semiconductor bridge igniter device


201


comprises a high value serpentine resistor


202


and a pair of voltage-protected semiconductor bridge devices


204


,


204


′. The resistor


202


is supported by an electrically non-conductive substrate


210


which may be made of a suitable material such as silicon dioxide, silicon nitride, etc. The resistor


202


comprises a serpentine pattern connected between resistor contact pads


212




a


and


212




b


which are, in turn, electrically connected to, respectively, metallized lands


214




a


and


214




b


. Resistor contact pads


212




a


and


212




b


may optionally be disposed on insulating pads


216




a


and


216




b


composed of, e.g., an oxide compound. The serpentine pattern of the resistor


202


may be formed by a layer of doped semiconductor material which may be deposited and etched into the shape of a strip or trace of material along the upper surface


218


of the substrate


210


. Optionally, the resistor


202


may be located on the underside of the substrate


210


or in the polysilicon layer as discussed above with respect to the embodiment of FIG.


9


. The resistance of the resistor


202


may be varied as desired by the amount of doping as also discussed above with respect to the embodiment of FIG.


9


.




The metallized lands


214




a


and


214




b


electrically interconnect the resistor


202


with each of the voltage-protected semiconductor bridge igniter devices


204


and


204


′ in parallel. It will be understood that while the semiconductor bridge igniter devices


204


and


204


′ are disposed on a single substrate


210


, each of the semiconductor bridge igniter devices


204


and


204


′ may be mounted on separate substrates. As illustrated, the voltage-protected semiconductor bridge devices


204


and


204


′ are mounted atop an optional insulating layer


220


composed of, for example, an oxide compound.




The voltage-protected semiconductor bridge device


204


comprises pads


222




a


and


222




b


being connected by an initiator bridge


222




c,


each of which is formed of an integral, single piece of polysilicon semiconductor. An anti-fuse comprised of a dielectric layer


224


, comparable to dielectric layer


15


illustrated in

FIGS. 1 and 2

, is disposed between metallized land


214




a


and pad


222




a.


Likewise, the voltage-protected semiconductor bridge device


204


′ comprises pads


222




a


′ and


222




b


′ being connected by an initiator bridge


222




c


′, each of which is formed of an integral, single piece of polysilicon semiconductor. In order for voltage-protected semiconductor bridge device


204


′ to be electrically connected to receive opposite voltage polarity from that of voltage-protected semiconductor bridge device


204


, an anti-fuse dielectric layer


224


′, also comparable to dielectric layer


15


illustrated in

FIGS. 1 and 2

, is disposed between metallized land


214




b


and pad


222




b


′. Accordingly, it is seen that, because of the difference in location of dielectric layer


224


from that of


224


′, voltage of opposite polarity will be applied to each of the dielectric layers.




Reduction in Pin Holing




The voltage-protected semiconductor bridge igniter devices such as those described herein have been found to be susceptible under certain circumstances, such as during electrostatic discharge (ESD) testing, to incur pin holes in the anti-fuse structure. In order to prevent such pin holing, it has been found that a capacitor may be provided in parallel with a voltage-protected semiconductor bridge igniter as illustrated in the schematic electrical diagram of FIG.


16


.




The electrical circuit for a voltage-protected semiconductor bridge igniter device is illustrated generally at


300


of FIG.


16


and comprises a capacitive leg ABKL connected in parallel with a first firing leg ADIL through junctions C and J. A second firing leg AEHL and a continuity monitor leg AFGL are also connected in parallel with legs ABKL and ADIL. It will be understood that the monitor leg AFGL may be similar to that discussed above and, as illustrated, comprises a high-value resistor, although it will be appreciated that a fusible link may also be employed in this embodiment instead of the resistor. It will also be understood that the first and second firing legs ADIL and AEHL may be replaced by a single firing leg as discussed above, for example, in connection with FIG.


8


. The capacitive leg ABKL includes a capacitor


302


having a capacitance of approximately 0.15 microfarads or greater. Typically, the capacitor


302


may have a capacitance on the order of approximately 0.47 microfarads.




As illustrated in

FIG. 17

, another embodiment of an electro-explosive device is depicted and comprises a semiconductor bridge igniter device


301


, which may be similar to semiconductor bridge igniter device


201


discussed above, and a capacitor


302


. The electro-explosive device also comprises an explosives igniter


304


comprised of a header


306


, a mounting base


308


and a capacitor mounting structure


310


. The header


306


may be similar to the header


52


discussed above and defines a cup-like recess


312


containing an explosive charge


314


. Disposed at the bottom of recess


312


is the semiconductor bridge igniter device


301


which may be assembled to the header


306


in a similar manner to that discussed above with respect to FIG.


10


.




Mounting base


308


comprises a base


316


and a pair of electrically conductive electrodes


318


. The base


316


may be composed of any moldable and insulative material such as a plastic and may be connectable with a device (not shown) for energizing the electrodes


318


. It will be appreciated that the latter device may include continuity monitoring capability as desired.




The capacitor mounting structure


310


supports the capacitor


302


and comprises a housing


320


, a pair of tubular sleeves


322


and connectors


324


. The housing may be composed of the same material as the base and is moldable about the capacitor


302


, the tubular sleeves


322


and the connectors


324


. The tubular sleeves


322


and connectors


324


may be composed of a conductive material such as a metallic substance and function to electrically connect the capacitor


302


with the electrodes


318


. The capacitor


302


is comprised of plates


326


disposed about a material


328


which may be composed of a dielectric substance.




EXAMPLE 2




The electro-explosive device comprising a semiconductor bridge igniter device


301


, capacitor


302


and explosive igniter


304


as illustrated in

FIG. 17

was tested for radio frequency (RF) sensitivity in accordance with the probing test portion of MIL-STD-1576, method


2207


. This procedure involved the testing of approximately 230 electro-explosive devices to determine the RF sensitivity at ten different frequencies ranging from 1.5 MHz to 33 GHz. Electro-explosive devices were tested with continuous waveform (CW) and pulsed modulation input signals, depending on the applied frequency, and were tested in both pin-to-pin (P-P) and pin-to-case (P-C) modes. Exposure for each device during the test was five minutes.




During the RF probing tests, the detonators exhibited a high degree of RF insensitivity. Only two electro-explosive devices fired (one at 900 MHz, 10 watts (W) and one at 8.9 GHz, 13W). In one test series seven electro-explosive devices were tested at 1.5 MHz, 27W, pin-to-case, and none of the electro-explosive devices were inadvertently initiated. At another frequency, seven devices were tested at 250 MHz, 18W, pin-to-pin with no inadvertent fixing. A summary of the RF probing test results is given in the TABLE.


















TABLE











Frequency




Mode




Power (Watts)




No-Fires




Fires













1.5 MHz




P-P




10.5




7




None







(CW)




P-C




27.0




7




None







27 MHz




P-P




3.0




1




None







(CW)




P-P




8.0




1




None








P-P




9.0




3




None








P-P




12.0




1




None







27 MHz




P-C




3.4




1




None







(CW)




P-C




3.7




2




None








P-C




3.8




1




None








P-C




4.0




2




None







54 MHz




P-P




18.0




7




None







(CW)




P-C




18.0




7




None







250 MHz




P-P




18.0




7




None







(CW)




P-C




18.0




7




None







900 MHz




P-P




5.0




1




None







(CW)




P-P




8.0




1




None








P-P




10.0




5




1








P-C




10.0




7




None







2.7 GHz




P-P




10.0




7




None







(Pulsed)




P-C




10.0




7




None







5.4 GHz




P-P




10.0




7




None







(Pulsed)




P-C




10.0




7




None







8.9 GHz




P-P




5.0




1




None







(Pulsed)




P-P




13.0




6




None








P-C




13.0




6




1







16 GHz




P-P




6.0




8




None







(Pulsed)




P-C




6.0




7




None







33 GHz




P-P




5.0




1




None







(Pulsed)




P-P




6.0




6




None








P-C




5.0




4




None








P-C




6.0




3




None















While the invention has been described in detail with reference to particular embodiments thereof, it will be apparent that upon a reading and understanding of the foregoing, numerous alterations to the described embodiment will occur to those skilled in the art and it is intended to include all such alterations within the scope of the appended claims.



Claims
  • 1. A semiconductor bridge igniter device having protection against functioning at voltages below a preselected threshold voltage, the igniter device defining an electric circuit and comprising:a substrate made from a non-conductive material; and a first semiconductor bridge comprising: (a) a polysilicon layer disposed on the substrate and dimensioned and configured to have first and second pads having therebetween a gap which is bridged by an initiator bridge connecting the first and second pads, the bridge being so dimensioned and configured that passage therethrough of an electric current of selected characteristics releases energy at the bridge; (b) first and second metallized lands disposed in electrically conductive contact with, respectively, the first and second pads, to define a first firing leg of the electric circuit comprised of the first and second metallized lands, the first and second pads and the bridge; and (c) a dielectric material having a breakdown voltage equal to the threshold voltage and interposed in series in the first firing leg of the electric circuit whereby the circuit can only be closed upon application thereto of a voltage potential at least as great as the threshold voltage; a second semiconductor bridge connected in parallel to the first semiconductor bridge, the second semiconductor bridge disposed on the substrate and the second semiconductor bridge comprising: (a) a polysilicon layer disposed on the substrate and dimensioned and configured to have first and second pads having therebetween a gap which is bridged by an initiator bridge connecting the first and second pads, the bridge being so dimensioned and configured that passage therethrough of an electric current of selected characteristics releases energy at the bridge; (b) first and second metallized lands disposed in electrically conducting contact with, respectively, the first and second pads, to define a second firing leg of the electric circuit comprised of the first and second metallized lands, the first and second pads and the bridge; and (c) a dielectric material having a breakdown voltage equal to the threshold voltage and interposed in series in the second firing leg of the electric circuit whereby the circuit can only be closed upon application thereto of a voltage potential at least as great as the threshold voltage; wherein the first semiconductor bridge and the second semiconductor bridge are configured in the electric circuit such that each is connected to receive an opposite voltage polarity with respect to that which the other receives.
  • 2. The igniter device of claim 1 wherein the dielectric material of the first semiconductor bridge is a dielectric layer interposed between the polysilicon layer of the first semiconductor bridge and the first metallized land of the first semiconductor bridge.
  • 3. The igniter device of claim 2 wherein the dielectric material of the second semiconductor bridge is a dielectric layer interposed between the polysilicon layer of the second semiconductor bridge and the second metallized land of the second semiconductor bridge.
  • 4. The igniter device of claim 3 wherein the first metallized land of the first semiconductor bridge and the first metallized land of the second semiconductor bridge combine to form one first conductive layer and the second metallized land of the first semiconductor bridge and the second metallized land of the second semiconductor bridge combine to form one second conductive layer.
  • 5. The igniter device of any one of claims 1 through 4, wherein the polysilicon layer is doped.
  • 6. The igniter device of any one of claims 1 through 4, wherein the electric circuit further comprises a capacitor connected in parallel to the first and second firing legs.
  • 7. The igniter device of any one of claims 1 through 4, wherein the electric circuit further comprises a capacitor located on the substrate and connected in parallel to the first and second firing legs.
  • 8. The igniter device of any one of claims 1 through 4, wherein the electric circuit further comprises a continuity monitor leg comprising a fusible link connected in parallel to the first and second firing legs, the fusible link being dimensioned and configured to rupture at an amperage above that of a selected monitor amperage whereby, if the monitor amperage is exceeded, the fusible link will rupture and open the monitor leg.
  • 9. The igniter device of claim 8 wherein the fusible link comprises a thin film fusible link.
  • 10. The igniter device of any one of claims 1 through 4, wherein the electric circuit further comprises a continuity monitor leg comprising a resistor connected in parallel to the first and second firing legs, the resistor having, at voltage levels below the preselected threshold voltage, a resistance value large enough to reduce the current flow through the first and second firing legs of the electric circuit to a level at which the temperature of the first and second semiconductor bridge devices remain below a preselected temperature.
  • 11. The igniter device of claim 10 comprising an electro-explosive device and disposed in contact with an energetic material, and wherein the preselected temperature is the auto-ignition temperature of the energetic material.
  • 12. The igniter device of claim 10 wherein the resistor comprises a doped segment of the polysilicon layer of the first semiconductor bridge.
  • 13. The igniter device of claim 10 wherein the resistor comprises a doped segment of the substrate.
  • 14. The igniter device of any one of claims 1 through 3, wherein the substrate is separated into first and second substrates wherein the first semiconductor bridge is disposed on the first substrate and the second semiconductor bridge is disposed on the second substrate.
  • 15. A semiconductor bridge igniter device having protection against functioning at voltages below a preselected threshold voltage, the igniter device defining an electric circuit and comprising:a substrate made from a non-conductive material; and a first semiconductor bridge comprising: (a) a polysilicon layer disposed on the substrate and dimensioned and configured to have first and second pads having therebetween a gap which is bridged by an initiator bridge connecting the first and second pads, the bridge being so dimensioned and configured that passage therethrough of an electric current of selected characteristics releases energy at the bridge; (b) first and second metallized lands disposed in electrically conducting contact with, respectively, the first and second pads, to define a first firing leg of the electric circuit comprised of the first and second metallized lands, the first and second pads and the bridge; and (c) a dielectric layer having a breakdown voltage equal to the threshold voltage and interposed in series between the polysilicon layer and the first metallized land in the first firing leg of the electric circuit whereby the circuit can only be closed upon application thereto of a voltage potential at least as great as the threshold voltage; wherein the electric circuit further comprises a capacitor connected in parallel to the first firing leg.
  • 16. The igniter device of claim 15 wherein the electric circuit further comprises a continuity monitor leg comprising a fusible link connected in parallel to the first firing leg, the fusible link being dimensioned and configured to rupture at an amperage above that of a selected monitor amperage whereby, if the monitor amperage is exceeded, the fusible link will rupture and open the monitor leg.
  • 17. The igniter device of claim 16 wherein the fusible link comprises a thin film fusible link.
  • 18. The igniter device of claim 15 wherein the electric circuit further comprises a continuity monitor leg comprising a resistor connected in parallel to the first firing leg, the resistor having, at voltage levels below the preselected threshold voltage, a resistance value large enough to reduce the current flow through the first firing leg of the electric circuit to a level at which the temperature of the first semiconductor bridge device remains below a preselected temperature.
  • 19. The igniter device of claim 18 comprising an electro-explosive device and disposed in contact with an energetic material, and wherein the preselected temperature is the auto-ignition temperature of the energetic material.
  • 20. The igniter device of claim 18 wherein the resistor comprises a doped segment of the polysilicon layer of the first semiconductor bridge.
  • 21. The igniter device of claim 18 wherein the resistor comprises a doped segment of the substrate.
CROSS REFERENCE TO RELATED APPLICATIONS

This application is a Continuation-in-Part of U.S. Patent application Ser. No. 08/985,926 filed Dec. 5, 1997 and entitled “Voltage-Protected Semiconductor Bridge Igniter Elements” which claims the benefit of priority of U.S. Provisional Patent application Ser. No. 60/034,015, filed Jan. 6, 1997 and entitled “High Voltage Protection For Semiconductor Bridge (SCB) Elements”.

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Provisional Applications (1)
Number Date Country
60/034015 Jan 1997 US
Continuation in Parts (1)
Number Date Country
Parent 08/985926 Dec 1997 US
Child 09/333105 US