|
Propellant Grain Cracks Detection System
Navy SBIR 2018.2 - Topic N182-111 NAVAIR - Ms. Donna Attick - [email protected] Opens: May 22, 2018 - Closes: June 20, 2018 (8:00 PM ET)
TECHNOLOGY AREA(S): Air
Platform ACQUISITION PROGRAM: PMA-201
Precision Strike Weapons OBJECTIVE: Develop a sensor
capable of detecting cracks in a propellant grain and transmitting that data
through a hermetically sealed rocket motor case. DESCRIPTION: The propellants
used in Propellant Actuated Devices (PADs) and Cartridge Actuated Devices
(CADs) can develop cracks while installed onboard an aircraft. If the device is
initiated, the cracks would result in an increase of the burning surface area
of the propellant, causing an increase in the gas production that may result in
rupture of the device. The required work will employ innovative technologies to
provide wireless through-case data transmission, in situ rocket motor health
assessment, and appropriate miniaturization for CAD/PAD applications. The
ability to detect a propellant grain crack was demonstrated in the past, but
there were limitations in capability, which prevented transition to fleet
service. The limitations of the previous designs included size (the design was
too large to fit within the available device�s envelope) and inability to
transmit information through a hermetically sealed rocket motor case. The Navy
seeks a sensor system capable of detecting the presence of cracks greater than
2mm anywhere within the propellant grain, providing an indication if cracks are
present as soon as they are detected, providing an alert (visual and/or
auditory) to maintenance personnel, and maintaining data collected for download
by engineering staff at the completion of a 10-year ordnance service life. The
sensor system should record the installation date of the unit, temperature, and
data dependent of method used for crack detection. The data should be collected
once a day and wirelessly downloaded every three months. The use of multiple
sensors may be required to ensure crack detection throughout the propellant
grain and to assure system reliability (90% reliability at 90% confidence). The
size of the sensor system should be kept to a minimum size but must not exceed
2�x 3�x 0.08� thick. The total weight of the sensor system must be as light as
possible with a maximum weight of 6 ounces. The proposer must prototype and
demonstrate the solution, before and after environmental conditioning, as
described in MIL-P-83126 [Ref 4]. Evaluation criteria will be: (1) crack
detection capability, (2) data transmission capability through a hermetically
sealed rocket case (such as the MK 109 Canopy Jettison Rocket Motor), (3)
system reliability, (4) 10-year ordnance service life, and (5) capability of
surviving environmental exposures, documented in MIL-P-83126 [Ref 4]. The
capability of detecting propellant grain cracks in-situ and in real time will
improve warfighter safety and reduce total ownership costs for energetic
devices. PHASE I: Develop, design, and
demonstrate potential alternatives for a sensor system to detect cracking in a
propellant grain and transmit the sensor data through a hermetically sealed
rocket case. Perform an analysis of alternatives and demonstrate feasibility of
selected approach. Evaluation criteria are listed in the Description above.
Produce prototype plans to be developed under Phase II. PHASE II: Develop a prototype
system that is capable of surviving and operating as designed while installed
in a hermetically sealed rocket case, such as the MK 109 Canopy Jettison Rocket
Motor. Demonstrate system capability to detect cracks in propellant grains and
transmit data transmission through a hermetically sealed rocket motor. Validate
a 10-year useful service life in an ordnance device through modeling and/or
analysis. Demonstrate capability for system to be capable of storing recorded
data for download at end of ordnance service life. Demonstrate compatibility of
the developed sensor system with the propellant grain and other construction
materials. Ensure the individual sensor systems be as small as possible, but
not to exceed 2� x 3� X 0.080� thick. Ensure that the developed system meets
DoD Hazard of Electromagnetic Radiation to Ordnance (HERO) when installed in
the ordnance device. PHASE III DUAL USE
APPLICATIONS: Complete the tests specified in accordance with MIL-P-83126 [Ref
4] and transition the developed sensor for use on the F/A-18 canopy remover
rocket motor (MK 109) Super Hornet and other propellant actuated devices. This
technology will be of benefit to commercial CAD/PAD devices such as automobile
and airliner gas generators and commercial space applications. REFERENCES: 1. Liu, C.T. �Effects of
cyclic loading sequence on cumulative damage and constitutive behavior of a
composite solid propellant�, 28th Structures, Structural Dynamics and Materials
Conference, Structures, Structural Dynamics, and Materials and Co-located
conferences. https://doi.org/10.2514/6.1987-776 2. Liu, C.T. �Evaluation of
damage fields near crack tips in a composite solid propellant.� Journal of
Spacecraft and Rockets, 1991, Vol. 28, No. 1, pp. 64-70. https://doi.org/10.2514/3.26210 3. Military Specification
(MIL)-P-83126A, Propulsion Systems, Aircrew Escape, Design Specification For,
(08 Feb 1980). http://everyspec.com/MIL-SPECS/MIL-SPECS-MIL-P/MIL-P-83126A_9078/ 4. Tang, B., Liu, C.T., and
Henneke, E.G. �Acousto-ultrasonic technique applied to filled-polymer damage
assessment.� Journal of Spacecraft and Rockets, 1995, Vol. 32, No 5, pp. 866-9.
https://doi.org/10.2514/3.26697 KEYWORDS: Propellant Grain
Cracks; Data Transmission; Sensor System; MK109 Canopy Jettison Rocket Motor;
Environmental Exposure/testing; Composite Propellant
|