Abstract: A fluid pressure sensor particularly useful for measuring pressure up to approximately 2000 psi has a hexport (12, 112, 212, 312) formed with a stop surface (26, 326) in a bottom wall (18) circumscribing a fluid pressure inlet (16). A pressure sensing module (22) is received on the stop surface and a distal end (40) of a wall (20, 120, 320) of the hexport is crimped to lock the pressure sensing module onto the stop surface with the stop surface limiting the amount of compression of an O-ring (30) disposed contiguous to and inboard of the stop surface. In one embodiment the crimp is placed directly on a metal ring (38) attached to a plastic connector (32) which in turn transfers the crimping force to the pressure sensing module. In other embodiments (FIGS. 2, 3) the crimp is placed directly in the pressure sensing module to form a subassembly.

Abstract: A first embodiment of a condition responsive capacitive transducer, such as an accelerometer (1), is shown in which an electrically conductive sensor element (14) is sandwiched between upper (10) and lower (12) electrically insulative planar substrates and mounted in sealed, spaced apart relation by patterns (16) of adhesive containing spacing elements. A second embodiment (100) includes a signal conditioning capacitor having plate portions (114r, 120b and 114s, 120c) on either side of a condition responsive capacitor to minimize errors caused by translational movement of the sensor element (114) relative to the substrates (110, 112). Circuit conditioning electronics (124) is shown mounted directly on one of the substrates (110) and the sensor is mountable directly on a circuit board. A third embodiment (200) shows differential capacitors (224, 226, 228, 230, 232, 234) for minimizing errors due to misalignment of the movable element (114) with respect to the fixed supports (210, 212).

Abstract: A method of constructing a printed circuit board module and the module which comprises providing a substrate core having a first aperture extending therethrough and a pair of printed circuit boards, each board having at least one electrically conductive layer, secured to the substrate core and having a second aperture therethrough aligned with the first aperture. An electrically conductive member having an electrically insulating member is disposed around the electrically conductive member. The electrically conductive member having an electrically insulating member disposed therearound is positioned so that the electrically insulating member is disposed in the first aperture and the electrically conductive member extends into the second aperture of each of the printed circuit boards. The printed circuit boards are secured to the substrate core to lock the electrically insulating member in the first aperture.

Abstract: A housing member (100, 100', 100", 100'") used to interface with a coupling of a fluid pressure source and to house a pressure sensing assembly is shown having a metallic tubular sidewall with a cylindrical first portion (102), a non-cylindrical second portion (108, 108') and intermediate third portion (112, 112',112") with a plastic body member (114, 114', 114") disposed, as by insert molding, within the tubular sidewall. The plastic body member has a base wall portion (116) extending across the sidewall at the intermediate, third portion (112) and has an elongated portion (120, 120') with a threaded bore. The second portion of the sidewall extends along a longitudinal axis at least as far as the elongated portion of the plastic body member. In one embodiment a metallic insert (152) forms a continuation of the molded plastic thread and in another embodiment inwardly extending groove (160) of second portion (108') of the tubular sidewall reinforces the molded plastic thread.

Abstract: A socket (2, 52) for attachment to a printed substrate (10, 60), has a central aperture therethrough. A connective part (3, 53) including a flexible insulative sheet (8, 58) is provided to cover the aperture and act as an electrically connective interface between an electrical part (31, 81) mounted in the socket and the printed substrate. The flexible sheet (8, 58) has a first contact means (5, 55) associated with a first surface of the flexible sheet for electrically connecting with leads (32, 82) of the electrical part and a second contact means (6, 56) associated with a second surface of the flexible sheet for electrically connecting with the printed substrate. An electroconductive member (7, 57) provides electrical connection between the first and second contact means. Such a socket is especially useful for testing electrical parts with high clock speeds and a large number of leads.

Abstract: First and second electronic devices interconnected by a nonconductive nanoporous film, the film having metal-filled pores extending through the thickness of the film, such that each of the devices is contacted by the metal in at least several pores, the film having other pores that remain unfilled, in order to enhance the compressibility of the film.

Abstract: A fluid pressure responsive electric switch (100) is shown in which first and second discrete electrical switches are controlled. A first movable support ring (122) mounts first and second snap acting discs (120a, 124a) on opposite sides thereof, the discs each having the normally concave surface facing the support ring. The first disc receives a force through a pressure to force converter (134) which is transferred through the second disc to a second movable support (126) and a third snap acting disc (128a) having a normally concave surface facing a related movable contact arm. When the system pressures exceeds a first minimum level the third disc (128a) snaps allowing a motion transfer pin to transfer a force to the movable contact arm (118a) of a compressor actuation switch (118) to energize the compressor.

Abstract: A gas fired furnace system (10) has a controller (14) controlling the supply of gas through a gas valve (12) and air for combustion by means of an induced air draft fan (28), ignition of the gas by means of ignitor (22), the delivery of heated air from a heat exchanger (20) by means of an air blower (34) in response to signals from a thermostat (42). A selected constant flow of air for combustion is provided by controlling the speed of the motor driving the induced motor fan (28) despite changes which may occur in back pressure. Induced draft fan motor parameters proportional to motor torque and motor speed are read on an ongoing basis and inputted to controller (14) which computes a desired voltage and compares that with referenced data stored in the controller memory and makes corrections to the speed of the induced draft fan motor to maintain the constant air flow.

Abstract: A socket with a main socket body 10 for use in a burn-in test of a bare chip 80 with a large number of contact connectors BP is provided with a positioning plate 42 in the top of the socket body 10. This positioning plate has a plurality of through holes 42c with contact members 48 slidingly contained therein. The through holes 42c and contact members 48 are aligned in one to one relationship to contact connections on the bare chip on one side of positioning plate 42 and a plurality of electroconductive film contacts 50 on the other side of the positioning plate 42. The film contacts are movably supported in the socket. Additionally, the film contacts 50 are electrically connected in a one-to-one relationship to socket contact 56 contained in the socket for providing electrical connection between bare chip 80 and socket 10.

Abstract: A fluid pressure responsive electric switch (10) is shown having an elongated base (12) in which first and second terminals (34, 48) are mounted by dropping them into respective slots (26, 28). The terminals are provided with tabs (38, 52) to engage with a platform (30) of the base to limit motion in one direction and are in turn engaged by a guide member (62) to prevent motion in an opposite direction. The guide member (62) has a cylindrical force transfer portion (86) aligned with the weld portion (104) of a sensor assembly (92) to transfer force without adversely affecting the calibration of the sensor assembly. Electrical leads (118, 120) have connectors (126, 128) attached to an end thereof along with cylindrical gaskets (134) which form an interference fit in bores (22, 20) of the base to provide an environmental seal at the same time electrical connection is made to the terminals.

Abstract: A snap acting thermostatic disc assembly having a thermostatic disc element (20) responsive both to current and to ambient temperature is provided with an electrical contact (22) on a face surface on the disc element at one end thereof and a weld slug (24) at an opposite end of the disc element and has a fulcrum member (28, 28', 28") on the opposite face surface of the disc element in alignment with the weld slug. The fulcrum member is arranged to move the bending location of the disc element member away from the heat affected zone of the thermostatic metal caused by welding. In a second embodiment the snap acting disc element is used as an ambient temperature responsive control member.

Abstract: First and second electronic devices interconnected by a nonconductive nanoporous film, said film having metal-filled pores extending through the thickness of the film, such that each of said devices is contacted by the metal in at least several pores, wherein said film comprises a silicone polymer.

Abstract: First and second electronic parts interconnected by a nonconductive nanoporous film having first and second parallel surfaces, said film having metal-filled pores extending through the thickness of the film, such that each of said parts is contacted by the metal in at least several pores, a number of the pores being perpendicular to the surfaces of the film, and other pores being oblique to the surfaces of the film, whereby thermal dissipation is enhanced in the plane of the film.

Abstract: First and second electronic parts interconnected by a nonconductive nanoporous film, said film having metal-filled pores extending through the thickness of the film, such that each of said devices is contacted by the metal in at least several pores, wherein said film comprises liquid crystal or rigid rod polymer films.

Abstract: A condition responsive capacitive transducer, such as an accelerometer, is shown using a material system having refractory metal for the sensing element and glass material for a supporting substrate. The refractory metal is preferably tungsten, tantalum or molybdenum, and is coated with a glass seal enhancing material, such as titanium or nickel.

Abstract: A variable differential transformer system (10), both linear and rotary (L/RVDT) includes a primary coil (12) drive by a primary drive (20) having a triangle wave generator whose frequency is set by an external frequency control (R.sub.osc and C.sub.osc) which includes compensation for gain temperature error. Secondary coils (14, 16) have a common connection for balanced loading with an input stage arrangement (R7, R8, R9, R10) providing low common mode range and a way to differentiate between normal operation and coil faults detected by a fault detection network (28). Synchronous demodulation (22) extracts both magnitude and direction from the secondary coil signals. Electronic calibration (24) is shown which compensates for sensor offset and gain. Sensor offset calibration is accomplished by adding a percentage of the synchronous demodulation reference wave form to the differential secondary signal.

Abstract: The ability to achieve ultra-fast frequency settling times with good frequency resolution and high absolute accuracy over significant bandwidth at microwave frequencies ranging over three octaves. The implementation is an open-loop system requiring little or no compensation of temperature. This is accomplished by providing a frequency doubled direct digital synthesizer output to up/down convert a microwave frequency source. A special tracking filter architecture coupled to the microwave source provides the suppression of unwanted products. Fixed frequency set-on and swept bandwidths in excess of 300 MHz have been demonstrated. This is accomplished by using a direct digitally synthesized quadrature phased carrier which can be set to any frequency within a 350 MHz bandwidth to coherently up/down convert a low phase-noise microwave frequency to the sum or the difference frequency product.

Abstract: A capacitive transducer (10) which provides an output voltage in response to the application of a mechanical stimulus such as pressure or acceleration includes a signal conditioning integrated circuit (12) to which are connected a variable capacitor (C.sub.VAR), a reference capacitor (C.sub.REF), a linear correction capacitor (C.sub.LIN) as well as an integrating capacitor (C.sub.INT) and associated filtering components. The linear correction capacitor (C.sub.LIN) is used to offset a fixed parasitic charge associated with the variable capacitor. Any net error charge appearing on a detect, common node (pin 4) between the variable capacitor and the reference capacitor is cancelled out by means of an analog feedback network (22). In a modified embodiment a thermal compensation network (40) allows for correction for thermal error at a second temperature without having any affect at a first temperature.

Abstract: There are provided low profile inductor and transformer windings, and methods for fabricating the same. An elongate conductive ribbon is wound in one continuous direction on a generally hourglass shaped mandrel to form the ribbon into a double conical helix having a plurality of spaced apart coils. A sheet of dielectric material having an orifice therethrough is threaded to the midpoint of the double conical helix. The two sides of the helix are then compressed into planes such that the coils in each side lie flat and engage the adjacent side of the sheet of dielectric material. A compound inductor winding can be fabricated from a continuous conductive ribbon wound into a plurality of double conical helixes joined end-to-end. After compression, the compound winding consists of a low profile stack of spiraled windings connected in series, but constituting only one continuous ribbon having no internal connections.

Abstract: A variable differential transformer system (10), both linear and rotary (L/RVDT) includes a primary coil (12) drive by a primary drive (20) having a triangle wave generator whose frequency is set by an external frequency control (R.sub.osc and C.sub.osc) which provides compensation for gain temperature error. Secondary coils (14, 16) have a common connection for balanced loading with an input stage arrangement (R7, R8, R9, R10) providing low common mode range and a way to differentiate between normal operation and coil faults detected by a fault detection network (28). Synchronous demodulation (22) extracts both magnitude and direction from the secondary coil signals. Electronic calibration (24) compensates for sensor offset and adjust circuit gain by adding a percentage of the synchronous demodulation reference waveform to the secondary differential voltage.