| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 141 | Method and system for aircraft weapon station testing | EP96301238.0 | 1996-02-23 | EP0733873A1 | 1996-09-25 | Monk, Winston R.; van Cleve, David P. |
A weapon station testing system for testing the mission readiness of an aircraft (10) having a plurality of weapon stations including a first weapon station (12a) and a second weapon station (12b) comprises a common electronics module (14) and a plurality of interchangeable mechanical fixtures (16a, 16b). A first interchangeable fixture (16a) is operative for interconnecting the common electronics module (14) with the first weapon station (12a). A second interchangeable fixture (16b) is operative for interconnecting the common electronics module (14) with the second weapon station (12b). |
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| 142 | Method and apparatus for aligning spin-stabilized self-propelled missiles | EP91304639.7 | 1991-05-22 | EP0467515B1 | 1995-02-22 | Steele, Michael F. |
| 143 | Structure de positionnement et de stabilisation d'un objet en un point donné à l'intérieur d'un repère tridimensionnel | EP93400551.3 | 1993-03-03 | EP0559560A1 | 1993-09-08 | Bousquet, Jean-Claude; Maupetit, Bernard; Auroux, Michel; Goninet, Gérard |
L'invention concerne une structure de positionnement d'un objet dans un repère tridimensionnel. Le but de l'invention est de réaliser une structure permettant d'orienter un objet dans l'espace sans déplacer son centre de gravité. Ce but est atteint à l'aide d'une structure comprenant un support (5) au moins cinq élingues (7, 9, 11, 13, 27) destinées à suspendre l'objet (1) audit support (5) et des moyens de réglage (33) de la longueur de chaque élingue. Cette structure permet plus particulièrement de positionner un engin tactique à l'intérieur d'une chambre anéchoïque. |
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| 144 | Schaltung zur Erfassung von Messwerten eines Geschosses | EP90102181.6 | 1990-02-03 | EP0382131B1 | 1991-10-30 | Müller, Jürgen |
| 145 | Prüfeinrichtung, insbesondere für den Suchkopf intelligenter Lenkmunition | EP87115654.3 | 1987-10-26 | EP0269843A3 | 1990-05-23 | Westphal, Robert, Dr.; Herrmann, Karl, Dr. |
Eine Prüfeinrichtung (11), wie sie insbesondere für Suchköpfe (13) intelligenter Lenkmunition (21) bekannt ist, soll bei verringertem apparativem Aufwand insbesondere hinsichtlich des Antennen-Arrays einen realistischeren Test des Suchkopfes (13) und seiner Signalverarbeitungseinrichtung (24) ermöglichen, was insbesondere den im Prüfbetrieb realisierbaren Scan-Winkel und die Endphasen-Bewegung bei der Zielannäherung betrifft. Dafür wird einerseits der Suchkopf (13) und andererseits der Zielsimulator (20) jeweils im Brennpunkt (14) eines quasioptischen Abbildungssystems (15) positioniert, das vorzugsweise aus zwei über Parallelstrahlen (18) gekoppelten parabolischen Hohlspiegeln (19) besteht. Nun kann der Suchkopf (13) über die gesamte Spiegelfläche und damit in einem sehr großen Raumwinkel verschwenkt werden, ohne daß die Erfassung des Zielsimulators (20) verloren geht, weil dieser im anderen Brennpunkt (14) liegt. |
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| 146 | Prüfeinrichtung, insbesondere für den Suchkopf intelligenter Lenkmunition | EP87115654.3 | 1987-10-26 | EP0269843A2 | 1988-06-08 | Westphal, Robert, Dr.; Herrmann, Karl, Dr. |
Eine Prüfeinrichtung (11), wie sie insbesondere für Suchköpfe (13) intelligenter Lenkmunition (21) bekannt ist, soll bei verringertem apparativem Aufwand insbesondere hinsichtlich des Antennen-Arrays einen realistischeren Test des Suchkopfes (13) und seiner Signalverarbeitungseinrichtung (24) ermöglichen, was insbesondere den im Prüfbetrieb realisierbaren Scan-Winkel und die Endphasen-Bewegung bei der Zielannäherung betrifft. Dafür wird einerseits der Suchkopf (13) und andererseits der Zielsimulator (20) jeweils im Brennpunkt (14) eines quasioptischen Abbildungssystems (15) positioniert, das vorzugsweise aus zwei über Parallelstrahlen (18) gekoppelten parabolischen Hohlspiegeln (19) besteht. Nun kann der Suchkopf (13) über die gesamte Spiegelfläche und damit in einem sehr großen Raumwinkel verschwenkt werden, ohne daß die Erfassung des Zielsimulators (20) verloren geht, weil dieser im anderen Brennpunkt (14) liegt. |
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| 147 | Kraftaufnehmer, insbesondere für ballistische Druckmessungen | EP81102275.5 | 1981-03-26 | EP0041599B1 | 1985-04-24 | Engeler, Paul; Sonderegger, Hans-Conrad; Wolfer, Peter |
| 148 | Prüf- und/oder Übungsgeschoss für eine Artilleriewaffe | EP83106313.6 | 1983-06-29 | EP0099025A2 | 1984-01-25 | Lipp, Herbert; Reckeweg, Horst |
Die Erfingung betrifft ein Prüf- und/oder Übungsgeschoß für eine Artilleriewaffe, das vielfach wiederverwendbar eine Funktionsüberprüfung der Ladevorrichtung bei jeder einstellbaren Rohrerhöhung sowie des gesamten Ladevorgangs ermöglichen soll. Dazu ist an den hinteren Bereich einer bis vor die Lage eines hinteren Führungsbandes verkürzten Geschoßhülse 1 ein hülsenartiges Einsatzstück 2 angesetzt, dessen Durchmesser und Länge so bemessen sind, daß Außenkonturen und Gesamtlänge des Artilleriegeschosses nach dem Ansetzen des Einsatzstückes 2 an die Geschoßhülse 1 wiederhergestellt sind, wobei das Einsatzstück 2 in Einschnitten 3 Führungsbandsegmente 4 aufnimmt, die auf einen definierten Führungsbanddurchmesser nach außen drückbar und wieder entriegelbar sind, Weiter ist am Bodenbereich 5 des Einsatzstücks 2 eine Zugstange 6, die zugleich Entriegelungsstange für die Führungsbandsegmente 4 sein kann, lösbar ansetzbar. |
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| 149 | NON-DESTRUCTIVE INSPECTION METHODS AND SYSTEMS | US15527684 | 2014-12-18 | US20180322622A1 | 2018-11-08 | Corbin Sean Glenn; Zhenyu Xue |
| A non-destructive inspection method that comprises obtaining one or more images corresponding to an X-ray, scanning electron microscope, or CT scan of an object, assigning numeric values to pixels of the images, comparing the numeric values to reference numeric values, and identifying an anomaly in the object based on the comparison. A non-destructive inspection system that comprises at least one processor, a memory in communication with the processor and storing instructions that causes the processor to obtain an image corresponding to an X-ray, scanning electron microscope, or CT scan of an object, assign numeric values to pixels of the image, compare the assigned numeric values to reference numeric values, and identify an anomaly in the object based on the comparison. | ||||||
| 150 | Flex circuit connector configuration | US15071745 | 2016-03-16 | US10109939B2 | 2018-10-23 | Neal R. Whatcott |
| An electronic system includes first and second circuit boards and a flexible circuit connector. The flexible circuit connector is configured to electrically connect the first and second circuit boards. The flexible circuit connector includes first and second connectors and a spiral portion. The first connector is configured to connect to the first circuit board. The second connector is configured to connect to the second circuit board. The spiral portion is connected between the first and second circuit boards and includes a circumferential portion that extends around the second connector. | ||||||
| 151 | Device for determining the velocity of a bullet | US14648673 | 2012-11-29 | US10107606B2 | 2018-10-23 | Mikael Sundberg; Jonas Genchel |
| A device determines velocity of a bullet. The device includes two electro-acoustic sensors arranged with a predetermined distance for determining velocity of a bullet. Each of the electro-acoustic sensors are configured to detect acoustic energy of a shock wave generated by the bullet travelling at supersonic speed from a point of fire to a target and configured to transduce the acoustic energy into an electrical signal. The device includes a processing unit configured to receive electrical signals from the electro-acoustic sensors as the bullet travels and to determine a time frame between the two second electrical signals. The velocity of the bullet can be determined based on the time frame. The device also includes a sighting unit attached to a housing of the device for aligning the electro-acoustic sensors parallel to the direction from the point of fire to the target. | ||||||
| 152 | Method and system for optically inspecting headed manufactured parts | US15636996 | 2017-06-29 | US10088431B2 | 2018-10-02 | Robert Joseph Offenborn; Christopher Michael Alexander; Gregory Martin Nygaard; Michael George Nygaard |
| A method and system for optically inspecting parts are provided wherein the system includes a part transfer subsystem including a transfer mechanism adapted to receive and support a part at a loading station and to transfer the supported part by a split belt conveyor so that the part travels along a first path which extends from the loading station to an inspection station at which the part has a predetermined position and orientation for inspection. An illumination assembly simultaneously illuminates a plurality of exterior side surfaces of the part with a plurality of separate beams of radiation. A telecentric lens and detector assembly forms an optical image of at least a portion of each of the illuminated side surfaces of the part and detects the optical images. A processor processes the detected optical images to obtain a plurality of views of the part which are angularly spaced about the part.In an alternative embodiment the method and system for optically inspecting headed manufactured parts employ an inclined split track to cause the part to traverse an inspection station by gravity feed. The part is inspected for conformity to dimensional and visual standards and sorted under control of a processor based on images of the part obtained from occluded light and reflected light while the part is within the inspection station. | ||||||
| 153 | Disposable arrow wipe with chemical indicator | US15694824 | 2017-09-03 | US10066914B2 | 2018-09-04 | Deane Owen Elliott; Mark Rogers Davidson |
| A disposable indicator for use with an arrow or crossbow bolt comprising a substrate and a chemical indicator material capable of detecting and visually indicating chemical properties of a bodily fluid wiped from the arrow by a change in color. Chemical indicating materials may be selected to indicates a variety of bodily fluid chemical properties using pH, enzyme, or detection of other bodily compounds. The indicator provides an immediate indication of the portions of the animal's body through which the arrow or bolt passed, enabling the hunter to determine the type of shot and how best to track the wounded animal. An additional benefit is that the substrate can be used to clean the arrow or bolt in additional to providing a chemical shot indication. | ||||||
| 154 | Calibration of molded piezoelectric longitudinal charge coefficient of a pressure sensor for blasting operation | US14976521 | 2015-12-21 | US10006281B2 | 2018-06-26 | Gimtong Teowee; Bryan E. Papillon; James D. Heckelman; Chris Munroe |
| A method of calibrating a coefficient of a pressure sensor for blasting operations, including striking a first piezoelectric sensor of a first unmolded pressure sensing apparatus; determining, with an interface circuit, a first peak voltage of the first piezoelectric sensor during the striking thereof, striking a second piezoelectric sensor of a second molded pressure sensing apparatus; determining with the interface circuit, a second peak voltage of the second piezoelectric sensor during the striking thereof, and calculating a piezoelectric constant of the second piezoelectric from at least the first and second peak voltages. | ||||||
| 155 | Method and system for three dimensional imaging and analysis | US14569080 | 2014-12-12 | US09998729B2 | 2018-06-12 | Ryan Lilien; Marcus Brubaker; Pierre Duez |
| The inventive systems and methods relate to the field of matching toolmarks for firearm forensics having a retrographic sensor to provide a three dimensional representation of a surface of an object for heatmapping analyzed matching geometric features. | ||||||
| 156 | K-9 training aids made using additive manufacturing | US15596101 | 2017-05-16 | US09897419B1 | 2018-02-20 | John G. Reynolds; Matthew M. Durban; Alexander E. Gash; Michael D. Grapes; Ryan S. Kelley; Kyle T. Sullivan |
| Additive Manufacturing (AM) is used to make aids that target the training of K-9s to detect explosives. The process uses mixtures of explosives and matrices commonly used in AM. The explosives are formulated into a mixture with the matrix and printed using AM techniques and equipment. The explosive concentrations are kept less than 10% by wt. of the mixture to conform to requirements of shipping and handling. | ||||||
| 157 | Systems to measure yaw, spin and muzzle velocity of projectiles, improve fire control fidelity, and reduce shot-to-shot dispersion in both conventional and airbursting programmable projectiles | US15200023 | 2016-07-01 | US09879963B2 | 2018-01-30 | Kevin Michael Sullivan |
| Kits or sub-systems that include sensors to measure a projectile's condition at muzzle exit. The kits or sub-systems are coupled to ballistic calculators or fire control systems that calculate aiming and programming solutions to improve shot placement, reduced dispersion and improve terminal performance. Where airburst munitions are used, the projectile is programmed when reaching a programming station beyond the barrel and the projectile is programmed with a solution that adjusts the burst location based on the measured muzzle velocity. Sub-systems, processes and sub-routines optimize “post-shot” programming using certain non-linear methods that are incorporated into fire control systems and ballistic calculators. These non-linear sub-routines are useful in establishing the optimum terminal effect of such airburst projectiles. The sub-systems are used separately or are incorporated into the weapons, to reduce dispersion and improve the terminal effects of the projectiles. | ||||||
| 158 | DECELERATION HYSTERISIS MEASURING APPARATUS FOR SOFT RECOVERY SYSTEM | US15588867 | 2017-05-08 | US20180017674A1 | 2018-01-18 | Jae-Hyun CHOI; Min-Sup SONG; Jin-Eep ROH |
| A deceleration hysteresis measuring apparatus for a soft recovery system is configured to transmit an electromagnetic wave to a pressure tube of the soft recovery system and receive the electromagnetic wave reflected from a projectile moving in the pressure tube so as to measure a distance of the projectile based on signals of the transmitted and received waves. | ||||||
| 159 | FLUID MEASURING DEVICE AND MEASURING HEAD DEVICE FOR MOISTURE DETECTION, IN PARTICULAR IN CONTAINERS FOR FLUID-SENSITIVE ELECTRICAL AND/OR ELECTRONIC COMPONENTS IN ROAD VEHICLES | US15651153 | 2017-07-17 | US20180017462A1 | 2018-01-18 | Roland KUBE |
| A fluid measuring device includes a measuring head device having a measuring head with separated and electrically insulated electrodes and measuring head contacts each connected to a respective electrode. A measuring circuit includes terminal contacts each connected to a respective measuring head contact. The measuring circuit includes a current source for pulsed energizing of the measuring head connected to the terminal contacts. The measuring circuit includes an output circuit between the terminal contacts including a measuring capacitor and an evaluation circuit ascertaining state-of-charge information regarding the measuring capacitor. A supplementary circuit in the measuring head is connected to the measuring head contacts and establishes basic capacitance and resistance properties therebetween corresponding to capacitance and resistance properties between the measuring head contacts upon contact with predefined partial wetting of the electrodes by conductive fluid having predefined conductivity without the supplementary circuit. A measuring head device is also provided. | ||||||
| 160 | Systems and Methods for Forming and Operating an Ecosystem for a Conducted Electrical Weapon | US15380301 | 2016-12-15 | US20170337504A1 | 2017-11-23 | Joseph Charles Dimino, JR.; Siddharth Heroor; Michael E. Gish; Reinhard J. Gagnon; Teri Dawn Michaels |
| A system that creates an environment (e.g., ecosystem) for using, transmitting, and storing data from a CEW and other equipment. The information from a CEW includes a log maintained by the CEW. The log may include information related to the operation, maintenance, software, and deployment units used by the CEW. The information may be used alone or in combination with other information received and stored by an evidence management system for managing inventory, generating use-of-force reports, incident reports, and/or providing information related to equipment, such as a CEW, to the supplier of the equipment. Sources of information provided to an evidence management system includes equipment suppliers, CEWs, other cooperating equipment, records management systems of an agency, a dispatch system of an agency, and third parties. A CEW or other equipment may also receive information for storing in the log. | ||||||
