KickIntro.ppt - Page 1 Office of Naval Research Future Naval Capabilities / Advanced Gun Barrel Technology Program Screening Test Fixture Thermal Analysis.

Slides:

Advertisements

Similar presentations

Firearms Notes Forensic Science.

Advertisements

NANMAC is QUALITY PERFORMANCE SOLUTIONS NANMAC is QUALITY PERFORMANCE SOLUTIONS.

ME 340 Project: Fall 2010 Heat Transfer in a Rice Cooker Brad Glenn Mason Campbell.

September 24-25, 2003 HAPL meeting, UW, Madison 1 Armor Configuration & Thermal Analysis 1.Parametric analysis in support of system studies 2.Preliminary.

A look at a firearm, Barrett M caliber sniper rifle By Dustin Mortsolf.

Institute of Aerospace Thermodynamics H. Kamoun, G. Lamanna, B. Weigand Institute of Aerospace Thermodynamics, Universität Stuttgart Stuttgart Germany.

HYBRID Propellant for Small, Medium and Large Caliber Applications

Page 1 First Order Modeling of Cannon Fire Out-of-Battery (FOOB) Recoil Dynamics Presented at the 39th Annual Guns & Ammunition/ Missiles & Rockets Symposium.

The 2006 Naval S&T Partnership Conference is presented by NDIA with technical support from ONR Naval EM Railgun Innovative Naval Prototype 3 August 2006.

Naval Weapons Systems. We Know: How the target is detected, How the target is tracked, How the weapon is launched, How the weapon is propelled, How the.

Analysis of Simple Cases in Heat Transfer P M V Subbarao Professor Mechanical Engineering Department I I T Delhi Gaining Experience !!!

Effects of the Venus Atmosphere on Thermal Insulating Material Performance Michael Pauken, Linda Del Castillo, Jay Polk, Dannah Almasco Jet Propulsion.

Enclosure Fire Dynamics

Sound and Flash Suppressor for Firearms Patent Pending with the United States Patent and Trademark Office. Patent Application 61/370,455.

April 4-5, 2002 A. R. Raffray, et al., Chamber Clearing Code Development 1 Chamber Dynamics and Clearing Code Development Effort A. R. Raffray, F. Najmabadi,

Identified Company (CompositeX) to manufacture Custom Composite Pressure Vessel ● Working pressure 1000psi ● Holds 8 kg Nitrous Oxide ● 700 cubic inch.

Chamber Dynamic Response Modeling Zoran Dragojlovic.

Al 2 O 3 Post Combustion Chamber Post Combustion Chamber ANSYS Thermal Model (Embedded Fuel Grain Concept) Outer radius: 1.25” ( m) Inner radius:

000ppt ATK Thiokol Propulsion A Collaborative Effort for Manufacturing and Testing of GEM Rocket Propellant Mike Rose, Connie Murphy and Rich Muscato Presented.

Fabrice Laturelle, Snecma Moteurs

ONR’s Advanced Gun Barrel Technologies Program

ISIS Second Target Station

Portable Mass Driver Presentation by: Brad Garrison.

M. Yoda, S. I. Abdel-Khalik, D. L. Sadowski, B. H. Mills, and J. D. Rader G. W. Woodruff School of Mechanical Engineering Updated Thermal Performance of.

1 Calorimeter Thermal Analysis with Increased Heat Loads September 28, 2009.

Calorimeter Analysis Tasks, July 2014 Revision B January 22, 2015.

1 Air Force Chemical Equilibrium Specific Impulse (Isp) Code.

USCG 57mm / Mk 3 Gun Mount Test, Evaluation & Certification Program

Firearms Identification Mr. Tomasevich Forensics.

Thermal Model of MEMS Thruster Apurva Varia Propulsion Branch Code 597.

1 What is ballistics? Give 3 examples of how ballistics is used in forensic science.

Mechanical Properties Considerations for Fast Core Propellants

MicroMet Cutting Edge Technology Defence Systems Division.

M9 Pistol Analysis and Modifications

FIREARMS, TOOL MARKS, AND OTHER IMPRESSIONS

 Definition: any material that travels with the ability to injure  Energy is dependent on the velocity, mass, and distance traveled by projectile.

Presentation by: Brad Garrison

Hypervelocity Impact Technology Facility (HITF)/SN3 NASA Johnson Space Center GLAST ACD Meteoroid/Debris Shielding Initial Test and Analysis Results NASA.

Design of an Inertial Fusion Energy Target Injection & Tracking System Ronald Petzoldt, Dan Goodin, Mike Hollins, Chuck Gibson, Neil Alexander, and Gottfried.

Presented to: By: Date: Federal Aviation Administration International Aircraft Materials Fire Test Working Group Meeting Task Group Session on Revised.

Firearms Identification. A discipline mainly concerned with determining whether a bullet or cartridge was fired by a particular weapon.

Solar Orbiter EUS: Thermal Design Progress Bryan Shaughnessy, Rutherford Appleton Laboratory 1 Solar Orbiter EUV Spectrometer Thermal Design Progress Bryan.

ERT 216 HEAT & MASS TRANSFER Sem 2/ Dr Akmal Hadi Ma’ Radzi School of Bioprocess Engineering University Malaysia Perlis.

Weapon Propulsion and Architecture Naval Weapons Systems.

Entrained-flow Gasifier Model Development Larry Baxter, Bing Liu, Humberto Garcia.

Page 1 of 19 Design Improvements and Analysis to Push the Heat Flux Limits of Divertors M. S. Tillack, X. R. Wang, J A. Burke and the ARIES Team Japan-US.

1 What is ballistics? Give examples of how ballistics is used in forensic science.

C osmic R Ay T elescope for the E ffects of R adiation CRaTER Pre-Ship Review (I-PSR) Thermal Analysis Christine Cottingham LM/GSFC 545 Hume Peabody GSFC.

FIREARMS, TOOL MARKS, AND OTHER IMPRESSIONS

BCP Analysis Update Thomas Jones 22/7/16.

Produktentwicklung und Maschinenelemente

SiD Solenoid Status and Plans

CFD-Team Weekly Meeting - 8th March 2012

Melissa Jablonski, John Geaney

Firearms Identification

Firearms Identification

Agenda Overview Tactical Employment ATK 25mm Barrett HEDP System

High Temperature Aging Test Data for Double Base Propellant using an Advanced Stabilizer May 15, 2018.

BELLRINGER: What do you know?

Firearms Identification Mr. Tomasevich Forensics.

Ballistics Chapter 15.

VLT Meeting, Washington DC, August 25, 2005

Heat Transfer in common Configuration

Detailed Design Presentation

Firearms: Form, Function, and Physics

Egyptian Atomic Energy Authority (EAEA), Egypt

Presentation transcript:

KickIntro.ppt - Page 1 Office of Naval Research Future Naval Capabilities / Advanced Gun Barrel Technology Program Screening Test Fixture Thermal Analysis Presenter: Martin T. Bacigalupo United Defense, L.P Co-Author: Brad Hoilien United Defense L.P

KickIntro.ppt - Page 2 Agenda AGBT Program Thermal Model Description Thermal Analysis Test Results / Model Calibration Path Forward

KickIntro.ppt - Page 3 Background Future Naval Capabilities / Advanced Gun Barrel Technology (FNC / AGBT) is being run by the Office of Naval Research (ONR) to upgrade existing barrel capabilities for Naval gun propulsion missions One of the FNC / AGBT program objectives is to develop technologies to increase barrel erosion life A task has been funded by the FNC / AGBT program to develop a refractory coated gun barrel for transition into the AGS as part of the spiral design process As part of the refractory coated barrel task a series of screening test were conducted to down select coating materials A thermal analysis, presented herein, was conducted to guide the design of the screening test fixture

KickIntro.ppt - Page 4 Screening Test Fixture A 45 mm gun test fixture was designed, fabricated, & used by United Defense to test refractory coating materials / application processes –The test fixture contains a removable insert located at the origin of rifle –The inner bore of six inserts were lined with candidate material coatings –The inner bore of one insert was lined with chrome Used as a baseline to verify the design of the fixture –50 firings were conducted for each insert

KickIntro.ppt - Page 5 Screening Test Fixture Barrel Insert Chamber Projectile Thermocouples (3)

KickIntro.ppt - Page 6 Screening Test Objective The objective of the screening tests was to assess the candidate coatings under conditions similar to those of a large caliber gun barrel The test fixture design (i.e. gun), ballistic analysis, thermal analysis were iterated until the fixture replicated the environment within a large caliber gun barrel –Thermal response of a chrome lined insert simulates that of a large caliber gun barrel at the origin of rifle –Chemical reaction between gases and insert walls simulate that of a large caliber gun barrel –Mechanical loading of the insert simulates that of a large caliber gun barrel at the origin of rifle

KickIntro.ppt - Page 7 Thermal Analysis Description A United Defense proprietary gun barrel thermal model was used to predict temperature response within the 45 mm test fixture’s insert –Same model used for AGS gun barrel thermal analysis –Generates an axially varying interior ballistic solution using XKTCNOVA –Uses ballistic solution to generate transient convective coefficients –Applies transient convective coefficients to the inner bore –Calculates temperature response of barrel and liner material

KickIntro.ppt - Page 8 Thermal Analysis Results Test fixture design goal was to match the temperature profile from a large caliber gun with a single 45mm firing Analysis indicated that two ballistic solutions would provide an acceptable match with the large caliber gun profiles Continuous 10 RPM Single Firing Analysis of the baseline chrome lined insert

KickIntro.ppt - Page 9 Resulting Fixture Design Results of the thermal analysis indicated that two ballistic configuration would provide an acceptable match with the large caliber gun profiles –Option kg of M30A1 propellant (large caliber gun grain) 10 kg projectile 3 liter chamber –Option kg M6 propellant (large caliber gun grain) 7.5 kg projectile 3 liter chamber

KickIntro.ppt - Page 10 Round Establishment Test Prior to testing the candidate materials a series of firing were conducted to –Calibrate the thermal model –Select a ballistic (i.e. round) configuration 45mm round establishment tests –Conducted using a chrome lined insert –Thermal model calibrated “On the Fly” and used to guide selection of the propellant (mass and type) and projectile

KickIntro.ppt - Page 11 Thermal Model Calibration Propellant: 1.2 kg of M30A1 Projectile: 7.4 kg Propellant: 1.2 kg of M30A1 Projectile: 7.4 kg Propellant: 1.0 kg of M30A1 Projectile: 7.4 kg Propellant: 1.0 kg of M30A1 Projectile: 7.4 kg Temperature measurements taken on back wall of insert (~0.4” from inner bore) Thermal model predictions calibrated with measurements Calibrated thermal model used to estimate “near bore” insert temperature response Temperature measurements taken on back wall of insert (~0.4” from inner bore) Thermal model predictions calibrated with measurements Calibrated thermal model used to estimate “near bore” insert temperature response Thermal analysis conducted “On the Fly” to guide round configuration:

KickIntro.ppt - Page 12 Near Bore Temperatures 1.2 kg of m30a1 with 7.4 kg projectile  Acceptable agreement 1.1 kg of m30a1 with 7.4 kg projectile  Marginally acceptable agreement 1.0 kg of m30a1 with 7.4 kg projectile  Marginally acceptable agreement 1.2 kg of m30a1 with 7.4 kg projectile  Acceptable agreement 1.1 kg of m30a1 with 7.4 kg projectile  Marginally acceptable agreement 1.0 kg of m30a1 with 7.4 kg projectile  Marginally acceptable agreement

KickIntro.ppt - Page 13 Further Thermal Model Calibration Depth of thermally altered layer  7 mils Steel transition temperature (1340 o F) exceeded for depth < ~7 mils Post-Test Material Inspection Calibrated Thermal Analysis Depth of thermally altered layer compares well with results of thermal analysis Round Establishment Tests: Chrome Lined Insert

KickIntro.ppt - Page 14 Selected Round Configuration The calibrated thermal analysis indicated that 1.2 kg of M30A1 with a 7.4 kg projectile would provide the best possible match with that of 10 rpm continuous firings in a large caliber gun –Resulting operating condition was undesirable 1.0 kg of M30A1 with a 7.4 kg projectile was selected as the round configuration –Provided excellent match with the single firing large caliber gun temperature response –Resulted in acceptable operating conditions

KickIntro.ppt - Page 15 Summary A thermal analysis was performed to guide the design of a 45mm test fixture for the FNC / AGBT refractory coated barrel program The thermal analysis was successfully calibrated and used “On the Fly” to guide the selection of round configuration Analysis of results for the candidate coating materials is still in progress