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Adjunct Missile Seeker Deployment Mechanism Concept Review University of Arizona Raytheon Missile Systems Team Members • Thomas Jefferson – Material Sciences • Ryan Moore – Mechanical Engineering • Philip Pierson – Optical Sciences • Scott Nielsen – Optical Sciences • Karl Heiman – Aerospace Engineering • David Kraemer – Electrical Engineering Outline • • • • • • Problem Statement Customer Needs Design Constraints Design Ideas Concept Selection Plan of Action Problem Statement • Design an Adjunct Seeker Deployment Mechanism (ASDM) that will deploy an Infrared (IR) seeker in the final stages of missile flight. • Mechanism must: – Minimize changes to existing airframe – Minimize the drag on the missile – Maximize the field of regard (FOR) of the seeker Customer Needs I • Mitigate new threats • Utilize existing components – Optimized for different system • Minimize changes to proven systems – Autopilot – Airframe • Identify trades and risks of proposed design • Implement a reliable design Customer Needs II • Use an existing IR Seeker • Minimize System Weight and Volume • Survive Thermal Environment – Storage – Flight • Rapid Deployment Design Space Circuit Cards Design Constraints Functional Requirements Category System Sizing IR Seeker Specifications Storage Conditions Flight Conditions Deployment Characteristics Req't # 1 2 3 4 5 6 7 8 9 10 11 12 13 14 Description Total Volume Card Volume System Weight w/o Cards IR Seeker Weight Window / Dome Field of Regard Storage Life Storage Temperature Launch Temperature Survive Flight Speed Total Flight Time Mechanical Shock Deployment Time Value <8in diameter x 4in length Half of total volume (unusable) 2 lbs One of three off the shelf components 1 lbs transparent for 3-6μm wavelengths Maintain ±35° in azimuth and elevation >10 years -65°C - 85°C -45°C - 60°C Mach 3 ~25s 40g for 2-3ms with 1/2 sine wave pulse <500ms Design Components • Deployment method – Must meet deployment time restrictions • Seeker orientation – Target must be visible until impact • Door mechanism – Affects previous design characteristics Deployment Mechanism • pivots at back of seeker • slides into cavity • directional hooks • scissor drive • lateral slide drive track system • lateral pivot arm • ramp • spring Seeker Orientation • angled to maximize to FOR • sits inside of enlarged nosecone • Normal to missile circuit cards • seeker sits inside and looks at a prism • nosecone / teardrop • external to maximize FOR • fixed seeker to series of mirrors • lateral to longitudinal axis • angled to longitudinal axis Door Mechanism • explodes • angles up w/ a foldable seal • domed cover that stores within missile depression • split door slides to sides • single door slides to side • single door slides to back • shaped door to facilitate tear drop • material that shatters with voltage or force • shot gun closure • slowly introduce into airstream to reduce shock • push up protective dome • bottom seal gasket Concept Selection Concept Pros Cons angled to maximize to FOR -Maximizes use of FOR -Does maximum FOR allow best Aero profile? sits inside of enlarged nosecone -Maximizes use of FOR -Mechanical shocks from nosecone? -Interfere with RF Patterns. -Change to current design autopilot to compensate. Normal to missile circuit cards -Minimal use of overall volume -Low motion, low deployment time -2 of 3 seekers potentially useless -Does not maximize FOR w/o additional movement seeker sits inside and looks at a prism -less shock to seeker -Difficult to maximize FOR? Seeker Orientation Ryan Karl Thomas Scott Phil Dave Total angled to maximize to FOR 1 1 1 1 1 0 5 sits inside of enlarged nosecone -1 -1 -1 -1 -1 0 -5 Normal to missile cerkit cards 0 -1 0 0 -1 0 -2 seeker sits inside and looks at a prism 0 -1 0 0 0 0 -1 nosecone / teardrop -1 -1 0 1 0 0 -1 external to maximize FOR 1 0 0 -1 0 0 0 fixed seeker to series of mirrors 0 0 -1 -1 1 0 -1 lateral to longitudinal axis 0 -1 1 1 0 0 1 angled to longitudinal axis 0 0 1 1 0 0 2 Note: This is only an example of the Selection Process Concept Selection I Slide Rail System Pros • One direction of Movement • Indexed Direction Cons • Lubrication required IR Seeker Missile Cross-section Slide Drive Track System Circuit Card Space Utilizes: Slide Drive System, Any Seeker, maximum length available Concept Selection II Pivot Arm Pros • Single Motion • Easy to Implement Torsional Spring? IR Seeker Pivot Arm Cons • Large Deceleration • Large torque for movement Circuit Card Space Missile Cross-section Utilizes: Pivot Arm, Any Seeker, Few moving parts Concept Selection III Seeker Rotation Pros • Simple control of movement Door Cut-out Pivot Axis Cons • Volume for motion • Torsional force required IR Seeker Missile Crosssection Circuit Card Space Utilizes: Seeker Rotation, Any Seeker, Few moving parts Plan of Action • Next two weeks – Flesh out design details – Trade analysis – Identify risks • Next two months – Design analysis – Finalize design Summary • Evaluated our customer’s needs • Presented rough ideas • Eliminated ideas based on customer needs • Came up with our preliminary designs Questions ?
