EP0414004A1 - Optoelectronic fuse - Google Patents

Optoelectronic fuse Download PDF

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Publication number
EP0414004A1
EP0414004A1 EP90114815A EP90114815A EP0414004A1 EP 0414004 A1 EP0414004 A1 EP 0414004A1 EP 90114815 A EP90114815 A EP 90114815A EP 90114815 A EP90114815 A EP 90114815A EP 0414004 A1 EP0414004 A1 EP 0414004A1
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EP
European Patent Office
Prior art keywords
lens
face plate
detonator
bezel
fuse
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EP90114815A
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German (de)
French (fr)
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EP0414004B1 (en
Inventor
Rainer Siebert
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Diehl Verwaltungs Stiftung
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Diehl GmbH and Co
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F42AMMUNITION; BLASTING
    • F42CAMMUNITION FUZES; ARMING OR SAFETY MEANS THEREFOR
    • F42C13/00Proximity fuzes; Fuzes for remote detonation
    • F42C13/02Proximity fuzes; Fuzes for remote detonation operated by intensity of light or similar radiation

Definitions

  • the invention relates to an optronic detonator according to the preamble of claim 1.
  • a detonator is described in U.S. Patent 4,332,468. Its function is based on the triggering of an ignition signal for the combat charge of an ammunition equipped with this detonator when, due to the trigonometric distance to a reflecting target surface, the energy emitted from the transmission channel is being reflected into the reception channel and is being controlled by an optoelectronic converter.
  • the detonator has a converging lens in front of its optical channels.
  • Bulletproof glass constructions are known (DE-PS 32 43 163); the structurally complex packaging of individual stacks of glass plates glued together, which are framed at a distance from one another, cannot be used in an optronic ignition channel for reasons of space and weight. It would also be a disadvantage, as with the technology of planar surface cementation of optical components (DE-AS 23 64 421), that such joining agents guarantee neither unchanged in view of the high pressure and temperature fluctuations during use nor in view of the long magazine strength Radiation transmission properties can offer, but would lead to an impairment of the optronic response function due to aging.
  • the raindrop safety devices for projectile piezo igniter cannot be used here, since their protective function is based on the deformability of a buffer body arranged in front of the sensor, with the buffer body being decoupled from the sensor by a solid housing base arranged between them. Such a protective measure is prohibited in the beam path of an optronic sensor.
  • the invention is based on the object of designing an optronic fuse of the generic type in such a way that it remains functional even after a long storage period and after extreme temperature changes and foreign body stresses.
  • the magnification of the focal spot compared to an ideal converging lens is accepted with a convex lens that is designed to be flat on the front, in order to store the mechanically highly stressable, rigid rigid protective pane on the flat surface without a joint connection of the opposing surfaces, as it were floating in a common hard-elastic enclosure .
  • the lens body and its protective glass can work in the direction of the common support plane and transversely to it, depending on the temperature loads and foreign body effects, without local pressure loads being transferred from the protective glass to the lens body and becoming the starting point for lens breakage zones there.
  • a simple shrink tube lens bezel (DE-PS 26 19 288), on the other hand, would not provide a sufficiently mechanically defined bezel of the lens body with the protective disk lying flat in front of it; while on the other hand an axially resilient bezel (DE-PS 34 37 228) apart from the increased design effort would also have the disadvantage that the transfer of force from the lens body away from the plan displacement possibility of the protective disk does not guarantee.
  • the protective pane consists of a material which is transparent to the radiation spectrum of the optronic converter, preferably to the near infrared spectrum, in particular from sapphire glass which is commercially available for watch glasses.
  • a glass is extremely resistant to local mechanical loads and thus sets the shear force component of an impacting particle (raindrops or ice crystals) without local deflection into a micro-transverse movement of the protective pane on the flat surface of the lens; while the coaxial force component of the impact is absorbed over a large area and therefore with a minimal specific pressure load over the entire mass of the plano-convex lens.
  • an optronic detonator 13 Arranged in the head part 11 of an aircraft bomb 12 is an optronic detonator 13, which has two optical channels 15, which are arranged diametrically opposite one another with respect to the head part longitudinal axis 14 but essentially parallel to one another, the system axes 16 of which function as a triangulation detonator 13 with respect to the longitudinal axis 14 are slightly employed and thereby enclose a very acute angle (not shown in the drawing).
  • Each channel 15 has a hollow cylindrical housing 17, in the bottom plate 18 of which an optoelectronic transducer 19 is inserted, which is a radiator (for example light-emitting diode or solid-state laser) or a receiver (for example photo transistor).
  • the converter 19 is connected to an evaluation and ignition trigger circuit 20 for initiating the combat charge of the bomb 12 in a defined residual drop height after being dropped from the aircraft.
  • the tube 22 enclosed by the housing 17 is closed by a plano-convex converging lens 23, the convex surface of which points inwards (i.e. in the direction of the base plate 18) and accordingly the flat surface 25 thereof transversely to the system axis 16 towards the front opening 21.
  • a flat disk 26 lies on the flat surface 25, the surfaces lying one on top of the other preferably being ground flat.
  • the lens 23 and the disk 26 are not glued to one another, but are held together by a common tough-elastic enclosure 27 and held in the tube 22.
  • the bezel 27 allows slight displacements between lens 23 and disc 26 parallel to their adjacent surfaces; and the bezel 27 compensates for any differences in diameter between the lens 23 and the disk 26 and prevents local overstressing on the convex side 24 of the lens 23 during axial support against a hollow cylindrical lens carrier 28.
  • the face plate 26 only need not lie directly on the face surface 25 of the converging lens 23, as a filter film 29 can also be interposed in the parting plane, which is matched to the radiation spectrum of the transmitter transducer in the other channel in order to prevent extraneous light in the receiving channel 15.
  • the receiver transducer 19 that is to say to trigger the ignition only in the case of a reflection on the basis of the predetermined geometric spacing relationships.
  • any (adhesive) coatings are avoided between lens 23 and disk 26, which would lead to deterioration and deterioration of the optronic system characteristics due to aging phenomena, especially with strong temperature changes, quite apart from the manufacturing problems defined and evenly distributed material application.
  • the axial fixing of the lens 23 with the face plate 26 lying in front of it takes place by means of a screwed into the front opening 21 of the housing Threaded ring 30 with the axial interposition of a sealing ring 31 in front of the face plate 26, which is compressed as a result of axial pressure against the base plate 18 via a spacer 32 and the lens carrier 28.
  • the sealing of the tube space between the base plate 18 and the face plate 26 takes place in that silicone bonding is provided in the threaded area 33 of the threaded ring 30.
  • thermoplastically processable block copolymer is preferably used, such as is marketed by Du Pont as certain types of polyester rubber under the trade name "HYTREL”.
  • the mechanically extremely stable, in particular rigid, and only a very low temperature response protective disk 26 in front of the flat surface 25 of the lens 23 is preferably made of a sintered aluminum oxide such as corundum, which due to its appropriate additions for the radiation spectrum with which the transducer 19 works is permeable.
  • Suitable extremely hard protective disks are also commercially available, in particular as sapphire watch glasses.

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  • Engineering & Computer Science (AREA)
  • General Engineering & Computer Science (AREA)
  • Photometry And Measurement Of Optical Pulse Characteristics (AREA)
  • Lens Barrels (AREA)

Abstract

An optoelectronic fuse (13) having a collector lens (23) exposed to the environment in front of its optoelectronic transducer (19) is to be designed for the purpose of reducing the high risk of destruction of the lens which arises when the fuse (13) - for example in large-calibre aircraft bombs - is subjected to extreme pressure and temperature fluctuations and to the influence of foreign particles such as ice crystals or raindrops. For this purpose, the collector lens (23) is of plano-convex design and is provided on its flat, forwardly pointing surface (25) with a mechanically highly stressable and very flexurally stiff face plate (26) in a floating fashion (thus without a non-positive connection with the lens (23)), which transmits local axial stresses in a large-area fashion onto the lens body and transverse stresses onto the hard elastic common setting (27). It is preferable to use as protective face plate (26) a sapphire crystal, and as setting (27) a thin ring made from the creep-resistant and highly thermally stressable "Hytrel" polyester rubber structural material. <IMAGE>

Description

Die Erfindung betrifft einen optronischen Zünder gemäß dem Oberbe­griff des Ansprüches 1.
Ein derartiger Zünder ist in der US-PS 4 332 468 beschrieben. Seine Funktion beruht auf der Auslösung eines Zündsignales für die Gefechts­ladung einer mit diesem Zünder ausgestatteten Munition dann, wenn aufgrund der trigonometrischen Abstandsgegebenheiten zu einer re­flektierenden Zielfläche die aus dem Sendekanal abgestrahlte Energie gerade in den Empfangskanal reflektiert wird und dort einen opto­elektronischen Wandler durchsteuert. Im Interesse ausreichender Richtcharakteristik für den anzustrebenden Ansprechbereich des Zün­ders weist dieser vor seinen optischen Kanälen jeweils eine Sammel­linse auf. Diese ist zwangsläufig auch dann sehr exponiert und des­halb beschädigungsanfällig, wenn sie zur Ausblendung schräger Fremd­einstrahlung hinter die Stirnöffnung zurückversetzt ins Innere eines Gehäuserohres montiert ist. Denn bei Munitionsartikeln, die als ballistisch verschossene Projektile oder als außenbordgetragene Flugzeugbomben eine extrem hohe Geschwindigkeit gegenüber dem Um­gebungsmedium aufweisen und in kurzer Zeit sehr große Höhenunter­schiede erfahren, führen die dadurch hervorgerufenen thermischen und Staudruck-Wechselbeanspruchungen zumal dann leicht zu Beschädi­gungen der Linsen-Oberfläche, wenn Fremdkörper-Einwirkungen wie von Feuchtigkeits- oder Eispartikeln hinzu kommen. Ganz besonders gefährdet sind insofern die Linsen optronischer Flugzeugbomben, die der Umgebung in extremen Höhen mit mehrfacher Schallgeschwin­digkeit ausgesetzt werden. Eine gesprungene Sammellinse verfälscht und behindert den Strahlengang im optischen Kanal des Zünders aber derart, daß die definierte Zündauslösung in vorgegebenem Restabstand zum Ziel und damit die vorausbestimmte Wirkung der Munition nicht mehr gewährleistet ist.The invention relates to an optronic detonator according to the preamble of claim 1.
Such a detonator is described in U.S. Patent 4,332,468. Its function is based on the triggering of an ignition signal for the combat charge of an ammunition equipped with this detonator when, due to the trigonometric distance to a reflecting target surface, the energy emitted from the transmission channel is being reflected into the reception channel and is being controlled by an optoelectronic converter. In the interest of sufficient directional characteristics for the target range of the detonator, the detonator has a converging lens in front of its optical channels. This is inevitably very exposed and therefore prone to damage if it is installed behind the front opening to hide oblique external radiation into the interior of a housing tube. Because in the case of ammunition articles which, as ballistic-fired projectiles or as outboard-borne aircraft bombs, have an extremely high speed compared to the surrounding medium and experience very large differences in height within a short period of time, the thermal and dynamic pressure alternating stresses that are brought about as a result can easily damage the lens surface when Foreign body effects such as of moisture or ice particles. The lenses of optronic aircraft bombs, which are exposed to the environment at extreme heights with multiple speeds of sound, are particularly at risk. A cracked converging lens falsifies and hinders the beam path in the optical channel of the detonator in such a way that the defined triggering at a predetermined remaining distance from the target and therefore the predetermined effect of the ammunition is no longer guaranteed.

Zwar sind beschußfeste Glaskonstruktionen bekannt (DE-PS 32 43 163); die konstruktiv aufwendige Paketierung aus einzelnen miteinander verklebten Glasplatten-Stapeln, die in Distanz zueinander eingerahmt werden, ist aber aus Platz- und aus Gewichtsgründen in einem optro­nischen Zündkanal nicht einsetzbar. Nachteilig wäre darüberhinaus, wie auch bei der Technologie der Planflächen-Verkittung optischer Bauteile (DE-AS 23 64 421), daß solche Fügemittel weder in Hinblick auf die hohen Druck- und Temperaturschwankungen beim Einsatz noch in Hinblick auf die lange Magazinfestigkeit die Gewähr für unverän­derte Strahlungsdurchgangseigenschaften bieten können, sondern auf­grund von Alterungserscheinungen zu einer Beeinträchtigung der op­tronischen Ansprechfunktion führen würden.Bulletproof glass constructions are known (DE-PS 32 43 163); the structurally complex packaging of individual stacks of glass plates glued together, which are framed at a distance from one another, cannot be used in an optronic ignition channel for reasons of space and weight. It would also be a disadvantage, as with the technology of planar surface cementation of optical components (DE-AS 23 64 421), that such joining agents guarantee neither unchanged in view of the high pressure and temperature fluctuations during use nor in view of the long magazine strength Radiation transmission properties can offer, but would lead to an impairment of the optronic response function due to aging.

Aber auch die Regentropfen-Sicherheitseinrichtungen für Ge­schoß-Piezozünder (GB-PS 1 533 726) sind hier nicht einsetzbar, da ihre Schutzfunktion auf der Verformbarkeit eines vor dem Sensor angeordneten Pufferkörpers beruht, mit Entkopplung des Pufferkörpers vom Sensor durch einen dazwischen angeordneten massiven Gehäuseboden. Eine derartige Schutzmaßnahme verbietet sich im Strahlengang eines optronischen Sensors.However, the raindrop safety devices for projectile piezo igniter (GB-PS 1 533 726) cannot be used here, since their protective function is based on the deformability of a buffer body arranged in front of the sensor, with the buffer body being decoupled from the sensor by a solid housing base arranged between them. Such a protective measure is prohibited in the beam path of an optronic sensor.

In Erkenntnis dieser Gegebenheiten liegt der Erfindung die Aufgabe zugrunde, einen optronischen Zünder gattungsgemäßer Art derart auszu­legen, daß er auch nach langer Lagerzeit und nach extremen Tempe­raturwechsel- und Fremdkörper-Beanspruchungen funktionstüchtig bleibt.In recognition of these circumstances, the invention is based on the object of designing an optronic fuse of the generic type in such a way that it remains functional even after a long storage period and after extreme temperature changes and foreign body stresses.

Diese Aufgabe ist erfindungsgemäß im wesentlichen dadurch gelöst, daß, der optronische Zünder gattungsgemäßer Art gemäß dem Kennzeich­nungsteil des Ansprüches 1 ausgelegt ist.This object is essentially achieved in that the optronic igniter of the generic type is designed according to the characterizing part of claim 1.

Nach dieser Lösung wird die gegenüber einer idealen Sammellinse eintretende Vergrößerung des Brennfleckes mit einer frontseitig plan ausgebildeten Konvexlinse in Kauf genommen, um auf der Plan­fläche die mechanisch hoch beanspruchbare, biegesteife Schutzscheibe ohne Fügeverbindung der einander gegenüberliegenden Flächen, gewis­sermaßen schwimmend in einer gemeinsamen hartelastischen Einfassung zu lagern. Dadurch können der Linsenkörper und sein Schutzglas je nach den Temperaturbeanspruchungen und Fremdkörpereinwirkungen in Richtung der gemeinsamen Auflageebene und quer dazu arbeiten, ohne daß lokale Druckbeanspruchungen vom Schutzglas auf den Linsenkörper übertragen werden und dort zum Ausgangspunkt von Linsenbruchzonen werden.According to this solution, the magnification of the focal spot compared to an ideal converging lens is accepted with a convex lens that is designed to be flat on the front, in order to store the mechanically highly stressable, rigid rigid protective pane on the flat surface without a joint connection of the opposing surfaces, as it were floating in a common hard-elastic enclosure . As a result, the lens body and its protective glass can work in the direction of the common support plane and transversely to it, depending on the temperature loads and foreign body effects, without local pressure loads being transferred from the protective glass to the lens body and becoming the starting point for lens breakage zones there.

Eine einfache Schrumpfschlauch-Linseneinfassung (DE-PS 26 19 288) würde dagegen nicht eine ausreichend mechanisch-definierte Einfas­sung des Linsenkörpers mit davor planaufliegender Schutzscheibe erbringen; während andererseits eine axial nachgiebige Einfassung (DE-PS 34 37 228) abgesehen vom erhöhten konstruktiven Aufwand auch den Nachteil hätte, die der Kraftüberleitung vom Linsenkörper fort dienende Planverschiebungsmöglichkeit der Schutscheibe nicht zu gewährleisten.A simple shrink tube lens bezel (DE-PS 26 19 288), on the other hand, would not provide a sufficiently mechanically defined bezel of the lens body with the protective disk lying flat in front of it; while on the other hand an axially resilient bezel (DE-PS 34 37 228) apart from the increased design effort would also have the disadvantage that the transfer of force from the lens body away from the plan displacement possibility of the protective disk does not guarantee.

Die Schutzscheibe besteht aus einem für das Strahlungsspektrum des optronischen Wandlers, vorzugsweise für das nahe Infrarotspektrum, durchlässigem Material, insbesondere aus für Uhrgläser handelsüblichem Saphirglas. Ein solches Glas ist extrem widerstandsfähig gegen lokale mechanische Beanspruchungen und setzt somit die Querkraftkomponente eines aufprallenden Partikels (Regentropfens oder Eiskristalles) ohne lokale Durchbiegung in eine Mikro-Querbewegung der Schutzscheibe auf der Planfläche der Linse um; während die koaxiale Kraftkomponente des Einschlags großflächig und daher mit minimaler spezifischer Druckbeanspruchung von der gesamten Masse der Plankonvex-Linse groß­flächig aufgenommen wird.The protective pane consists of a material which is transparent to the radiation spectrum of the optronic converter, preferably to the near infrared spectrum, in particular from sapphire glass which is commercially available for watch glasses. Such a glass is extremely resistant to local mechanical loads and thus sets the shear force component of an impacting particle (raindrops or ice crystals) without local deflection into a micro-transverse movement of the protective pane on the flat surface of the lens; while the coaxial force component of the impact is absorbed over a large area and therefore with a minimal specific pressure load over the entire mass of the plano-convex lens.

Zusätzliche Alternativen und Weiterbildungen sowie weitere Merkmale und Vorteile der Erfindung ergeben sich aus den weiteren Ansprüchen und, auch unter Berücksichtigung der Darlegungen in der Zusammen­fassung, aus nachstehender Beschreibung eines in der Zeichnung unter Beschränkung auf das Wesentliche stark abstrahiert und nicht ganz maßstabsgerecht skizzierten bevorzugten Realisierungsbeispiels zur erfindungsgemäßen Lösung. Die einzige Figur der Zeichnung zeigt im Axial-Längsschnitt bei abgebrochener Darstellung einen optischen Kanal eines optronischen Annäherungs- oder Abstandszünders im Kopf­teil einer großkalibrigen Flugzeugbombe.Additional alternatives and further developments as well as further features and advantages of the invention emerge from the further claims and, also taking into account the explanations in the summary, from the following description of a preferred implementation example, which is highly abstracted and not fully drawn to scale, limited to the essentials solution according to the invention. The only figure in the drawing shows in axial longitudinal section with a broken-off representation an optical channel of an optronic proximity or distance fuse in the head part of a large-caliber aircraft bomb.

Im Kopfteil 11 einer Flugzeugbombe 12 ist ein optronischer Zünder 13 angeordnet, der zwei einander bezüglich der Kopfteil-Längsachse 14 diametral gegenüber aber untereinander im wesentlichen parallel angeordnete optische Kanäle 15 aufweist, deren Systemachsen 16 für die Funktion als Triangulations-Zünder 13 gegenüber der Längsachse 14 etwas angestellt sind und dadurch einen sehr spitzen Winkel ein­schließen (in der Zeichnung nicht dargestellt). Jeder Kanal 15 weist ein hohlzylindrisches Gehäuse 17 auf, in dessen Bodenplatte 18 ein optoelektronischer Wandler 19 eingesetzt ist, bei dem es sich um einen Strahler (beispielsweise Leuchtdiode oder Festkörper-Laser) bzw. um einen Empfänger (beispielsweise Fototransistor) handelt. Der Wandler 19 ist an eine Auswerte- und Zündauslöse-Schaltung 20, zum Initiieren der Gefechtsladung der Bombe 12 in definierter Rest-Fallhöhe nach dem Abwurf vom Flugzeug, angeschlossen.Arranged in the head part 11 of an aircraft bomb 12 is an optronic detonator 13, which has two optical channels 15, which are arranged diametrically opposite one another with respect to the head part longitudinal axis 14 but essentially parallel to one another, the system axes 16 of which function as a triangulation detonator 13 with respect to the longitudinal axis 14 are slightly employed and thereby enclose a very acute angle (not shown in the drawing). Each channel 15 has a hollow cylindrical housing 17, in the bottom plate 18 of which an optoelectronic transducer 19 is inserted, which is a radiator (for example light-emitting diode or solid-state laser) or a receiver (for example photo transistor). The converter 19 is connected to an evaluation and ignition trigger circuit 20 for initiating the combat charge of the bomb 12 in a defined residual drop height after being dropped from the aircraft.

Der Bodenplatte 18 gegenüber, jedoch gegen die Stirnöffnung 21 nach rückwärts versetzt, ist das vom Gehäuse 17 umschlossene Rohr 22 durch eine plankonvexe Sammellinse 23 verschlossen, deren konvexe Oberfläche nach innen (also in Richtung auf die Bodenplatte 18) und dementsprechend deren plane Oberfläche 25 quer zur Systemachse 16 zur Stirnöffnung 21 hin weist. Auf der planen Oberfläche 25 liegt eine Planscheibe 26, wobei die aufeinanderliegenden Flächen vorzugs­weise plangeschliffen sind. Die Linse 23 und die Scheibe 26 sind nicht miteinander verklebt, sondern durch eine gemeinsame zäh-ela­stische Einfassung 27 zusammengehalten und im Rohr 22 gehaltert. Die Einfassung 27 erlaubt geringfügige Verschiebungen zwischen Lin­se 23 und Scheibe 26 parallel zu deren einander benachbarten Ober­flächen; und durch die Einfassung 27 werden etwaige Durchmesser­unterschiede zwischen Linse 23 und Scheibe 26 ausgeglichen und lo­kale Überbeanspruchungen auf der konvexen Seite 24 der Linse 23 bei der axialen Abstützung gegen einen hohlzylindrischen Linsen­träger 28 vermieden. Die Planscheibe 26 braucht lediglich insofern nicht unmittelbar auf der Planfläche 25 der Sammellinse 23 zu liegen, als in der Trennebene noch eine Filterfolie 29 zwischengelegt sein kann, die auf das Strahlungsspektrum des Sendewandlers im anderen Kanal abgestimmt ist, um im Empfangs-Kanal 15 Fremdlicht-Anregungen des Empfänger-Wandlers 19 zu vermeiden, also nur im Falle einer Reflektion aufgrund der vorgegebenen geometrischen Abstandsverhält­nisse zur Zündauslösung zu führen. Auf jeden Fall sind aber zwischen Linse 23 und Scheibe 26 jegliche (Haft-)Beschichtungen vermieden, die aufgrund von Alterungserscheinungen, zumal bei starken Tempe­ratur-Wechselbeanspruchungen, zur Eintrübung und damit zur Beein­trächtigung der optronischen Systemcharakteristik führen würden, ganz abgesehen von den fertigungstechnischen Problemen definierter und gleichmäßig verteilter Materialaufbringung.Opposite the base plate 18, but against the front opening 21 offset backwards, the tube 22 enclosed by the housing 17 is closed by a plano-convex converging lens 23, the convex surface of which points inwards (i.e. in the direction of the base plate 18) and accordingly the flat surface 25 thereof transversely to the system axis 16 towards the front opening 21. A flat disk 26 lies on the flat surface 25, the surfaces lying one on top of the other preferably being ground flat. The lens 23 and the disk 26 are not glued to one another, but are held together by a common tough-elastic enclosure 27 and held in the tube 22. The bezel 27 allows slight displacements between lens 23 and disc 26 parallel to their adjacent surfaces; and the bezel 27 compensates for any differences in diameter between the lens 23 and the disk 26 and prevents local overstressing on the convex side 24 of the lens 23 during axial support against a hollow cylindrical lens carrier 28. The face plate 26 only need not lie directly on the face surface 25 of the converging lens 23, as a filter film 29 can also be interposed in the parting plane, which is matched to the radiation spectrum of the transmitter transducer in the other channel in order to prevent extraneous light in the receiving channel 15. To avoid suggestions of the receiver transducer 19, that is to say to trigger the ignition only in the case of a reflection on the basis of the predetermined geometric spacing relationships. In any case, any (adhesive) coatings are avoided between lens 23 and disk 26, which would lead to deterioration and deterioration of the optronic system characteristics due to aging phenomena, especially with strong temperature changes, quite apart from the manufacturing problems defined and evenly distributed material application.

Die axiale Festlegung der Linse 23 mit davor aufliegender Planscheibe 26 erfolgt mittels eines in die Gehäuse-Stirnöffnung 21 eingeschraubten Gewinderinges 30 unter axialer Zwischenlage eines Dichtungsringes 31 vor der Planscheibe 26, der infolge axialen Andruckes gegen die Bodenplatte 18 über ein Distanzstück 32 und den Linsenträger 28 gestaucht wird. Im übrigen erfolgt die Abdichtung des Rohrraumes zwischen Bodenplatte 18 und Planscheibe 26 dadurch, daß eine Silikon­verklebung im Gewindebereich 33 des Gewinderings 30 vorgesehen ist.The axial fixing of the lens 23 with the face plate 26 lying in front of it takes place by means of a screwed into the front opening 21 of the housing Threaded ring 30 with the axial interposition of a sealing ring 31 in front of the face plate 26, which is compressed as a result of axial pressure against the base plate 18 via a spacer 32 and the lens carrier 28. In addition, the sealing of the tube space between the base plate 18 and the face plate 26 takes place in that silicone bonding is provided in the threaded area 33 of the threaded ring 30.

Für den Spielsitz der radial schwimmenden Halterung der Planscheibe 26 vor der Sammellinse 23 eignet sich jeder gängige elastische Hoch­leistungs-Konstruktionswerkstoff mit hoher Zähigkeit und Rückfede­rung sowie hoher Dauerstandfestigkeit über breite Temperaturspannen. Bevorzugt wird ein thermoplastisch verarbeitbares Blockcopolymer eingesetzt, wie es etwa als bestimmte Polyesterkautschuktypen unter dem Handelsnamen "HYTREL" von Du Pont vertrieben wird.Any common elastic high-performance construction material with high toughness and springback as well as high fatigue strength over wide temperature ranges is suitable for the play seat of the radially floating mounting of the face plate 26 in front of the converging lens 23. A thermoplastically processable block copolymer is preferably used, such as is marketed by Du Pont as certain types of polyester rubber under the trade name "HYTREL".

Die mechanisch äußerst stabile, insbesondere biegesteife, und nur einen sehr geringen Temperaturgang aufweisende Schutz-Scheibe 26 vor der Planfläche 25 der Linse 23 besteht vorzugsweise aus einem gesinterten Aluminiumoxid wie Korund, das aufgrund seiner entspre­chenden Beimengungen für das Strahlungsspektrum, mit dem der Wandler 19 arbeitet, durchlässig ist. Geeignete extrem harte Schutz-Schei­ben sind insbesondere auch als Saphiruhrgläser handelsüblich.The mechanically extremely stable, in particular rigid, and only a very low temperature response protective disk 26 in front of the flat surface 25 of the lens 23 is preferably made of a sintered aluminum oxide such as corundum, which due to its appropriate additions for the radiation spectrum with which the transducer 19 works is permeable. Suitable extremely hard protective disks are also commercially available, in particular as sapphire watch glasses.

Claims (7)

1. Optronischer Zünder (13), insbesondere für eine großkalibrige Flugzeugbombe (12), mit einer in einem Rohr (22) vor seinem elek­trooptischen Wandler (19) gehalterten Sammellinse (23),
dadurch gekennzeichnet,
daß die Sammellinse (23) als plankonvexe Linse (23) ausgebildet ist, auf der frontseitig, vor ihrer vom Wandler (19) abgelegenen planen Oberfläche (25) eine steife Planscheibe (26) eben aufliegt, die seitlich mit der Sammellinse (23) steifelastisch-schwimmend über eine Einfassung (27) im Rohr (22) gehaltert ist.1. Optronic detonator (13), in particular for a large-caliber aircraft bomb (12), with a converging lens (23) held in a tube (22) in front of its electro-optical converter (19),
characterized,
that the converging lens (23) is designed as a plano-convex lens (23), on the front, in front of its flat surface (25) remote from the transducer (19), a rigid face plate (26) lies flat, which is laterally rigid with the converging lens (23) - Floating in a tube (22) is held over a border (27). 2. Zünder nach Anspruch 1,
dadurch gekennzeichnet,
daß zwischen der planen Oberfläche (25) der Linse (23) und der Planscheibe (26) eine Filterfolie (29) eingelegt ist.2. detonator according to claim 1,
characterized,
that a filter film (29) is inserted between the flat surface (25) of the lens (23) and the face plate (26). 3. Zünder nach Anspruch 1 oder 2,
dadurch gekennzeichnet,
daß die Einfassung (27) über einen vor der Planscheibe (26) gele­genen Dichtungsring (31) von einem Gewindering (30) gegen einen Linsenträger (28) axial angedrückt ist, der von der Linse (23) durch die Einfassung (27) distanziert ist.3. igniter according to claim 1 or 2,
characterized,
that the bezel (27) is axially pressed against a lens carrier (28) by a threaded ring (30), which is distanced from the lens (23) through the bezel (27), via a sealing ring (31) located in front of the faceplate (26) . 4. Zünder nach Anspruch 3,
dadurch gekennzeichnet,
daß der Gewindebereich (33) des Gewinderinges (30) eine Silikon­verklebung zum umgehenden Rohr-Gehäuse (17) aufweist.4. igniter according to claim 3,
characterized,
that the threaded area (33) of the threaded ring (30) has a silicone bond to the surrounding tube housing (17). 5. Zünder nach einem der vorangehenden Ansprüche,
dadurch gekennzeichnet,
daß die Einfassung (27) aus einem hartelastischen Polyesterkaut­schuk-Konstruktionswerkstoff gespritzt ist.5. igniter according to one of the preceding claims,
characterized,
that the bezel (27) is injection molded from a hard elastic polyester rubber construction material. 6. Zünder nach einem der vorangehenden Ansprüche,
dadurch gekennzeichnet,
daß die Planscheibe (26) aus einer strahlungsdurchlässigen gesin­terten Aluminiumoxidkeramik besteht.6. detonator according to one of the preceding claims,
characterized,
that the face plate (26) consists of a radiation-permeable sintered aluminum oxide ceramic. 7. Zünder nach einem der vorangehenden Ansprüche,
dadurch gekennzeichnet,
daß die Planscheibe (26) eine Saphirscheibe ist.7. detonator according to one of the preceding claims,
characterized,
that the face plate (26) is a sapphire disc.
EP90114815A 1989-08-23 1990-08-02 Optoelectronic fuse Expired - Lifetime EP0414004B1 (en)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
DE3927819 1989-08-23
DE3927819A DE3927819A1 (en) 1989-08-23 1989-08-23 OPTRONIC IGNITIONER

Publications (2)

Publication Number Publication Date
EP0414004A1 true EP0414004A1 (en) 1991-02-27
EP0414004B1 EP0414004B1 (en) 1993-10-27

Family

ID=6387694

Family Applications (1)

Application Number Title Priority Date Filing Date
EP90114815A Expired - Lifetime EP0414004B1 (en) 1989-08-23 1990-08-02 Optoelectronic fuse

Country Status (2)

Country Link
EP (1) EP0414004B1 (en)
DE (2) DE3927819A1 (en)

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EP3220177A1 (en) * 2016-03-17 2017-09-20 Rosemount Aerospace Inc. Optical component mounting for high-g applications
CN114623960A (en) * 2022-03-08 2022-06-14 深圳迈塔兰斯科技有限公司 Pressure sensor, pressure analyzer and preparation method thereof

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US7009167B2 (en) 2000-05-25 2006-03-07 Diehl Munitionssysteme Gmbh Method of adjusting an optronic fuse system
DE10025962A1 (en) * 2000-05-25 2001-12-06 Diehl Munitionssysteme Gmbh Method of adjusting an optronic ignition system
DE10031871B4 (en) * 2000-06-30 2005-02-24 Diehl Munitionssysteme Gmbh & Co. Kg Protective device in front of the sensor of an optoelectronic ignition device
DE10031870A1 (en) * 2000-06-30 2002-01-10 Diehl Munitionssysteme Gmbh Optronic ignition device for weapon system has sensor mounted adjustably in weapon system with three-point bearing containing mounting plate and adjustable, fixable bearing plate
DE10346731A1 (en) 2003-10-08 2005-05-04 Diehl Munitionssysteme Gmbh Proximity sensor arrangement

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CH709817A1 (en) * 2014-06-27 2015-12-31 Haslerrail Ag Protection device for an optical sensor device for rail vehicles.
EP3220177A1 (en) * 2016-03-17 2017-09-20 Rosemount Aerospace Inc. Optical component mounting for high-g applications
CN114623960A (en) * 2022-03-08 2022-06-14 深圳迈塔兰斯科技有限公司 Pressure sensor, pressure analyzer and preparation method thereof

Also Published As

Publication number Publication date
DE3927819C2 (en) 1991-11-28
DE3927819A1 (en) 1991-03-14
DE59003215D1 (en) 1993-12-02
EP0414004B1 (en) 1993-10-27

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