Final Report Federal Highway Administration August September Georgetown Pike

Size: px
Start display at page:

Download "Final Report Federal Highway Administration August September Georgetown Pike"

Transcription

1 TECHNICAL REPORT DOCUMENTATION PAGE 1. Report No. 2. Government Accession No. FHW A-RD Title and Subtitle TESTING OF NEW BRIDGE RAIL AND TRANSITION DESIGNS Volume VIII: Appendix G BR27C Bridge Railing 3. Recipient's Catalog No. 5. Report Date June Performing Organization Code 7. Author(s) C. Eugene Buth, T. J. Hirsch, and Wanda L. Menges 9. Performing Organization Name and Address Texas Transportation Institute The Texas A&M University System College Station, Texas Sponsoring Agency Name and Address 8. Performing Organization Report No. Research Foundation Work Unit No. NCP No. 3A5C Contract or Grant No. DTFH61-86-C Type of Report and Period Covered Office of Safety and Traffic Operations R&D Final Report Federal Highway Administration August September Georgetown Pike 14. Sponsoring Agency Code McLean, Virginia Supplementary Notes Research performed in cooperation with DOT, FHW A Research Study Title: Pooled Funds Bridge Rail Study Contracting Officer's Technical Representative (COTR)- Charles F. McDevitt 16. Abstract A combination concrete parapet and metal railing was designed for performance level one of the 1989 Guide Specifications for Bridge Railings. Computed strength of the railing is 18 kips (80 kn) at 40 in (1.02 m) above the deck (sidewalk) or 91 kips (405 kn) at 27 in (686 mm) above the deck (sidewalk). The railing was tested to performance level two and acceptable results were obtained. This volume is the eighth in a series. The other volumes in the series are: Volume 1: Technical Report; Volume II: Appendix A, "Oregon Side Mounted Bridge Railing;" Volume ill: Appendix B, "BR27D Bridge Railing;" Volume IV: Appendix C, "Illinois Bridge Railing;" Volume V: Appendix D, "32-in (813-mm) Concrete Parapet Bridge Railing;" Volume VI: Appendix E, "32-in (813-mm) New Jersey Safety Shape;" Volume VII: Appendix F, "32-in (813-mm) F-Shape Bridge Railing;" Volume IX: Appendix H, "Illinois Side Mount Bridge Rail;" Volume X: Appendix I, "42-in (1.07-m) Concrete Parapet Bridge Railing;" Volume XI: Appendix J, "42- in (1.07-m) F-Shape Bridge Railing;" Volume XII: Appendix K, "Oregon Transition;" Volume XIII: Appendix L, "32-in (813-mm) Thrie-Beam Transition;" and Volume XIV: Appendix M, "Axial Tensile Strength ofthrie and W-Beam Terminal Connectors." W-Beam Terminal Connectors. 17. Key Words Bridge Rail, Longitudinal Barriers, Barrier Collision Forces, Ultimate Strength, Yieldline Analysis, Full-Scale Crash Tests, Highway Safety 19. Security Classif. (of this report) Unclassified Form DOT F (8-69) 20. Security Classif. (of this page) Unclassified 18. Distribution Statement No restrictions. This document is available to the public through the National Technical Information Service 5285 Port Royal Road Springfield, Virginia No. of Pages Price

2 Symbol When You Know Multiply By To Flryd.Symbol Symbol LENGTH LENGTH in inches 25.4 millime~rs mm mm millimeters inches in ft feet meters m m meters 3.28 feet ft yd yards meters m m meters 1.09 yards yd rni miles 1.61 kilometers km km kilometers miles mi AREA ln 1 squareirtches square f1lillimeters mm 1 mm1 square millimeters square inches in 1 ft2 square feet square ~eters mt mz square m eters square feet ft2 ycfl square yards square meters mt mz square meters square yards yd2 ac aaes hectare~. ha 'ha hectares 2.47 acres ac mi 1 square miles 2.59 square ~ilometers km 2 km2 square kilometers square miles mi 2 VOLUME VOLUME AREA _.. _.. fl oz fluidounces milliliters ml ml milliliters fluid ounces floz gal gallons liters L L liters gallons gal Ill ft1 cubic feet cubic m'ters ma ma cubic meters cubic feet ft3 ycf cubic yards cubic meters ma ma cubic meters cubic yards yd' NOTE: Volumes greater than 1000 I shall be shown in m 3 ~ MASS oz ounces grams g g grams ounces oz lb pounds kilogram~ kg kg kilograms pounds lb T shorttons(20001b) megagrams Mg Mg megagrams short tons (2000 lb) T (or me~ric ton ) (or t ) (or n (or metric ton ) TEMPERATURE (exact) TEMPERATURE (exact) OF Fahrenheit 5(F-32)/9 Celcius oc oc Celcius 1.8C +32 Fahrenheit OF temperature or (F-32)/1.8 temperature temperature temperature ILLUMINATION MASS ILLUMINATION fc foot..candles lux lx lx lux foot-candles fc fl foot-lambert& candelatm 2 Cdlm 1 cd/ma candela/m foot-l.amberts fl FORCE and PRESSURE or STRESS FORCE and PRESSURE or STRESS lbf pound force 4.45 newtons N I N newtons poundforce lbf lbflin 2 poundforce per 6.89 kilopas~ls kpa kpa kilo pascals poundforce per lbflin 2 square inch square inch I * Slis the symbol for the International System of U.nits. Appropriate (Revised September 1993) rounding should be made to comply with Section 4 of ASTM E380.

3 TABLE OF CONTENTS Chapter 1. DESIGN OF RAILING 1 2. CRASH TEST PROCEDURES 5 3. FULL-SCALE CRASH TESTS 9 BR27C BRIDGE RAILING ON SIDEWALK Test 7069_ Test Description Test Results Conclusions Test Test Description Test Results Conclusions Test Test Description Test Results Conclusions BR27C BRIDGE RAILING ON DECK Test Test Description Test Results Conclusions Test Test Description Test Results Conclusions iii

4 TABLE OF CONTENTS (Continued) Chapter Pa2e Test Test Description Test Results Conclusions STRENGTH CALCULATIONS REFERENCES 147 iv

5 LIST OF FIGURES Figure.No. 1. Cross section of BR27C bridge railing on sidewalk Cross section of BR27C bridge railing on deck Vehicle/bridge railing geometries for test Vehicle prior to test Vehicle properties for test BR27C bridge railing on sidewalk before test Rear view of BR27C bridge railing on sidewalk BR27C bridge railing on sidewalk after test Damage at posts 5 and 6, test Vehicle after test Summary of resl:llts for test Sequential photographs for test (overhead and front views) Sequential photographs for test (interior and perpendicular views) Vehicle angular displacements for test Vehicle longitudinal accelerometer trace for test (accelerometer located at center-of-gravity) Vehicle lateral accelerometer trace for test (accelerometer located at center-of-gravity) Vehicle vertical accelerometer trace for test (accelerometer located at center-of-gravity) Vehicle/bridge railing geometries for test Vehicle prior to test Vehicle properties for test BR27C bridge railing on sidewalk before test BR27C bridge railing on sidewalk after test Vehicle after test Damage to left rear wheel of vehicle after test Summary of results for test Sequential photographs for test (front and overhead views) Sequential photographs for. test (Perpendicular and interior views) Vehicle angular displacements for test Vehicle longitudinal accelerometer trace for test (accelerometer located at center-of-gravity) Vehicle lateral accelerometer trace for test (accelerometer located at center-of-gravity) Vehicle vertical accelerometer trace for test (accelerometer located at center-of-gravity) v

6 LIST OF FIGURES (Continued) Figure No. 32. Vehicle longitudinal accelerometer trace for test (accelerometer located at front of vehicle) Vehicle lateral accelerometer trace for test (accelerometer located at front of vehicle) Vehicle longitudinal accelerometer trace for test (accelerometer located at rear of vehicle) Vehicle lateral accelerometer trace for test (accelerometer located at rear of vehicle) Vehicle/bridge railing geometries for test Vehicle prior to test Cargo in vehicle for Vehicle properties for test i 40. BR27C bridge railing on sidewalk before test BR27C bridge railing on sidewalk after test Vehicle after test Debris from vehicle after test Summary of results for test Sequential photographs for test (frontal and overhead views) Sequential photographs for test (perpendicular view) Vehicle angular displacements for test Vehicle longitudinal accelerometer trace for test (accelerometer located at center-of~gravity) Vehicle lateral accelerometer trace for test (accelerometer located at center-of-gravity) Vehicle vertical accelerometer trace for test (accelerometer located at center-of-gravity) Vehicle longitudinal accelerometer trace for test ,26 (accelerometer located at front of vehicle) Vehicle lateral accelerometer trace for test (accelerometer located at front of vehicle) Vehicle longitudinal accelerometer trace for test (accelerometer located at rear of vehicle) Vehicle lateral accelerometer trace for test (accelerometer located at rear of vehicle) Vehicle/bridge railing geometries for test Vehicle prior to test Vehicle properties for test BR27C bridge railing on deck before test BR27C bridge railing on deck after test vi

7 LIST OF FIGURES (Continued) Figure No. 60. Vehicle after test Summary of results for test Sequential photographs for test (overhead and frontal views) Sequential photographs for test (perpendicular and interior views) Vehicle angular displacements for test Vehicle longitudinal accelerometer trace for (accelerometer located at center-of-gravity) Vehicle lateral accelerometer trace for test (accelerometer located at center-of-gravity) Vehicle vertical accelerometer trace for test (accelerometer located at center-of-gravity)... " Vehicle/bridge railing geometries for test Vehicle prior to test Vehicle properties for test BR27C bridge railing on deck before test BR27C bridge railing on deck after test Vehicle after test Summary of results for test Sequential photographs for test (overhead and frontal views) Sequential photographs for test (perpendicular and interior views) Vehicle angular displacements for test Vehicle longitudinal accelerometer trace for test (accelerometer located at center-of-gravity).. ~ Vehicle lateral accelerometer trace for test (accelerometer located at center-of-gravity) Vehicle vertical accelerometer trace for test (accelerometer located at center-of-gravity) Vehicle longitudinal accelerometer trace for test (accelerometer located at front of vehicle) Vehicle lateral accelerometer trace for test (accelerometer located at front of vehicle) Vehicle longitudinal accelerometer trace for test (accelerometer located at rear of vehicle) Vehicle lateral accelerometer trace for test (accelerometer located at rear of vehicle) Vehicle prior to test Vehicle/bridge railing geometries for test Vehicle properties for test vii

8 LIST OF FIGURES Figure No BR27C bridge railing on deck before test Test site after test BR27C bridge railing on deck after test Vehicle after test Damage to right side of vehicle, test Summary of results for test Sequential photographs for test (overhead and front views) Sequential photographs for test (side view) Vehicle angular displacements for test Vehicle longitudinal accelerometer trace for test (accelerometer located at center-of-gravity) Vehicle lateral accelerometer trace for test (accelerometer located at center-of-gravity).... Vehicle vertical accelerometer trace for test (accelerometer located at center-of-gravity) ~ Vehicle longitudinal accelerometer trace for test (accelerometer located at front of vehicle) Vehicle lateral accelerometer trace for test (accelerometer located at front of vehicle).... Vehicle longitudinal accelerometer trace for test (accelerometer located at rear of vehicle).... Vehicle lateral accelerometer trace for test (accelerometer located at rear of vehicle) ~ Plan view illustrating some possible failure mechanisms Yieldline failure pattern for concrete parapet viii

9 LIST OF TABLES Table No Evaluation of crash test no Bridge railing performance levels and crash test criteria Evaluation of crash test no Evaluation of crash test no Evaluation of crash test no Evaluation of crash test no Evaluation of crash test no ix

10

11 CHAPTER 1. DESIGN OF RAILING The BR27C railing was originally designed to meet performance level one (1989 Guide Specifications for Bridge Railings when mounted on a 5-ft (1.5-m) wide sidewalk with an 8-in (200-mm) high curb at the face of the sidewalk (figure 1). (1) The design force for this situation was 30 kips (133 kn) of uniformly distributed line force 42-in (1.07-m) long located at least 35 in (890 mm) above the top surface of the sidewalk. An analysis of strength of this railing for force applied at yarious heights is presented in Chapter 4. The railing was eventually tested to performance level two conditions both on the sidewalk and on the deck. Cross-sections of both the curbed and flush-mounted railings are shown in figures 1 and 2. Total height.of the railing is 42 in (1.067 mm). The lower portion pf the railing consists of a 24-in (610-mm) high concrete parapet that is a constant 10-in (250-mm) thick. The upper portion of the railing consists of TS 4 by 4 by 3/16 in (102 by 102 by 2 mm) A500 grade B structural tubing utilized as vertical posts spaced at 6 ft-8 in (2m) on center. One TS 4 by 3 by 1/4 in (102 by 76 by 6 mm) structural tube is utilized as a horizontal rail element mounted to each post with splices at low moment regions. There are six #4 longitudinal bars and #4 vertical bent bars spaced at 8 in (200 nun) on center.. The specified concrete strength was 3,600 psi ( kpa) at 28 days, and the specified steel yield for the reinforcement was 60,000 psi ( kpa). The sidewalk of the BR27C was cantilevered over the existing concrete pavement and supported by 12-in (305-mm) thick vertical concrete walls spaced at 25ft (7.6 m) on center. The deck of the flush mounted BR27C was. cantilevered without any vertical supports. 1

12 TS 4x3x~" GRADE 60 REINFORCING STEEL 3600 PSI CONCRETE ~"9lx8~" LONG ROUND HEAD A307 BOLTS (TESTED) ~ "9l (RECOMMENDED) TS 4x4x~; A500 GR. 6' -f!' C-C o/e"(l)x13" LONG A325.. BOLTS OR A321 THREADED ROD EMBEDDED 1C!' IN CONCRETE PARAPEr 8~x9~x*" A36PLATE 1~" 9 # 4 6 #4 LONGIT. BARS ~ C-C LONGIT. BARS :t" #5 o 4~" c-c ~~f!'~~~~~~~~~~~~~~~~~footing 1~ ~~~-~m'\1 -#;:5;-:::DO::W::E;::LS::-- ;,t----l t #5 1'1' c-c IN 1"9l HOLES ~+- o 24" c-c 1 '.t' IN 1"c& HOLES _...,... I.~---- 3'-ff' ~...-1 '-6" WALL 1 t' THICK i 1 in= 25.4 mm 1 psi = 6.89 kpa Figure 1. Cross section of BR27C bridge railing on sidewalk. 2

13 GRADE 60 REINFORCING STEEL PSI CONCRETE TS 4x3x ~" ASOO GR. 8 ~" x8 ~" LONG ROUND HEAD A307 BOLTS TS 4x4xo/t6' A500 GR. 6'-8" c-c 4 #4 LONGIT. BARS (TOP) 4~" c-c 42" 16" ~:#==:;t=o~- 8 1,h x9 1,h x o/4" 24" I" o/a" x13" LONG A325 BOLTS OR A321 THREADED ROD EMBEDDED 1 0" IN CONCRETE PARAPET 2 2x73/ax%" A36 FLAT BARS 1 1,h" 6 #4 LONGIT. BARS #4 s" c-c A3 6 PLATE 1 #4 LONGIT. BAR 1 in= 25.4mm 1 psi = 6.89 kpa 3 #5 LONGIT. BARS s V2" c-c (BOTTOM) TEST INSTALLATION OVERHANG = 39" Figure 2. Cross section of BR27C bridge railing on deck. 3

14

15 CHAPTER 2. CRASH TEST PROCEDURES The BR27C bridge railing on sidewalk was tested to performance level two requirements. < 1 ) The following nominal test conditions were used: 1,800-lb (817-kg) passenger car 160 mi/h (96.6 km/h) 120 degrees (test ) 5,400-lb (2 452-kg) pickup 160 mi/h (96.6 km/h) j20 degrees (test ) 18,000-lb (8 172-kg) truck j50 mi/h (80.5 km/h) j15 degrees (test ) The BR27C bridge railing on deck was also tested to performance level two requirements. < 1 ) The following nominal test conditions were used: 1,800-lb (817-kg) passenger carj60 mi/h (96.6 km/h) 120 degrees (test ) 5,400-lb ( kg) pickup 160 mi/h (96.6 lqn/h) 120 degrees (test 7069-:33) 18,000-lb (8 172-kg) truck ISO mi/h (80.5 km/h) 115 degrees (test ) Each vehicle. was instrumented with three solid-state angular rate transducers to measure roll, pitch, and yaw rates; a triaxial accelerometer mounted at the vehicle center-ofgravity to measure longitudinal, lateral, and vertical acceleration levels, and a biaxial accelerometer in the rear of the vehicle to measure longitudinal and lateral acceleration levels. In addition, another biaxial accelerometer was mounted forward of the center-ofgravity in the pickup and truck tests. The accelerometers were strain gauge type with a linear millivolt output proportional to acceleration. The electronic signals from the accelerometers and transducers were transmitted to a base station by means of constant band width FM/FM telemetry link for recording on magnetic tape and for display on a real-time strip chart. Provision was made for the transmission of calibration signals before and after the test, and an accurate time reference signal was simultaneously recorded with the data. Pressure sensitive contact switches on the bumper of each vehicle were actuated just prior to impact by wooden dowels to indicate the elapsed time over a known distance to provide a measurement of impact velocity. The initial contact also produced an "event" mark on the data record to establish the exact instant of contact with the curb of the sidewalk. The multiplex of data channels transmitted on one radio frequency was received at a data acquisition station and demultiplexed into separate tracks of Intermediate Range Instrumentation Group (!.R.I. G.) tape recorders. After the test, the data was played back from the tape machines, filtered with an SAE 1211 filter, and digitized using a microcomputer for analysis and evaluation of impact performance. The passenger car and pickup were equipped with one Alderson Research Laboratories Hybrid II, 50th percentile anthropomorphic dummy. The uninstrumented dummy was placed in the driver seat and was restrained with standard restraint equipment. The 18,000.,.lb (8 172-kg) truck carried no dunnny. 5

16 The digitized data from the electronic transducers were then processed using two computer programs: DIGITIZE and PLOT ANGLE. Brief descriptions on the functions of these two computer programs are as follows. The DIGITIZE program uses digitized data from vehicle-mounted linear accelerometers to compute occupant/compartment impact velocities, time of occupant/compartment impact after vehicle impact, and the highest s average ridedown acceleration. The DIGITIZE program also calculates a vehicle impact velocity and the change in vehicle velocity at the end of a given impulse period. In addition, maximum average accelerations over s intervals in each.of the three directions are computed. Acceleration versus time curves for the longitudinal, lateral, and vertical directions are then plotted from the digitized data of the vehicle-mounted linear accelerometers using a commercially available software package (QUATTRO PRO). For each of these graphs, a s average window was calculated at the center of the s interval and plotted with the frrst s average plotted at s... The PLOT ANGLE program uses the digitized data from the yaw, pitch, and roll rate charts to compute angular displacement in degrees at 's intervals and then instructs a plotter to draw a reproducible plot: yaw, pitch, and roll versus time. It should be noted that these angular displacements are sequence dependent with the sequence being yaw-pitch-roll for the data presented herein. These displacements are in reference to the vehicle-fixed coordinate system with the initial position and orientation of the vehicle-fixed coordinate system being that which existed at initial impact. Photographic coverage of the test.included three high-speed cameras: one over head with a field of view perpendicular to the ground and directly over the impact point, one placed to have a field of view parallel to and aligned with the bridge railing system at the downstream end, and a third placed perpendicular to the front of the bridge railing. A highspeed camera was also placed onboard the passenger car and the pickup to record the motions of the dummy placed in the driver seat during the test sequence. A flash bulb activated by pressure sensitive tape switches was positioned on the impacting vehicle to indicate the instant of contact with the curb of the sidewalk and was visible from each camera. The films from these high-speed cameras were analyzed on a computer-linked motion analyzer to observe phenomena occurring during the collision and to obtain timeevent, displacement, and angular data. A 16-mm movie cine, a professional video camera and a 3/4-in (19-mm) videotape recorder along with 35-mm still cameras were used for documentary purposes and to record conditions of the test vehicle and bridge railing system before and after the test. The test vehicles were towed into the test installation using a steel cable guidance and reverse tow system. A steel cable for guiding the test vehicle was stretched along the path, anchored at each end, and threaded through an attachment to the front wheel of the test vehicle. Another steel cable was connected to the test vehicle, passed around a pulley near the impact point, through a pulley on the tow vehicle, and then anchored t~ the ground such that the tow vehicle moved away from the test site. A 2~to-1 speed ratio between the test.and tow vehicle existed with this system. Immediately prior to impact with the bridge 6

17 railing, the test vehicle was released to be free-wheeling and unrestrained. The vehicle remained free-wheeling, i.e., no steering or braking inputs, until the vehicle cleared the immediate area of the test site, at which time brakes on the vehicle were activated to bring the vehicle to a safe and controlled stop. 7

18

19 CHAPTER 3. FULL-SCALE CRASH TESTS BR27C BRIDGE RAILING ON SIDEWALK Test Test Description A 1982 Honda Civic (figures 3 and 4) was used for the crash test. Test inertia mass of the vehicle was 1, 800 lb (817 kg) and its gross static mass was 1, 965 lb (892 kg). The height to the lower edge of the vehicle bumper was 15.0 in (381 mm) and it was 20.5 in (521 mm) to the top of the bumper. Additional dimensions and information on the test vehicle are given in figure 5. The vehicle was directed into the BR27C bridge railing on sidewalk (figures 6 and 7) using the cable reverse tow and guidance system and was released to be free-wheeling and unrestrained just prior to impact. The vehicle impacted the curb of the sidewalk approximately 20ft.(6 m) upstream of post 5 at a speed of 61.7 mi/h (99.3 km/h) and the angle of impact was 18.7 degrees. At approximately s after impact, the left front comer of the vehicle began to deform and at s the right front tire impacted the curb. The vehicle impacted the concrete parapet at s traveling at a speed of 55.5 mi/h (89.3 km/h) and an angle of 18.1 degrees. At s the vehicle began to redirect significantly and at s the right rear tire impacted the curb. The vehicle briefly lost contact with the parapet at s. It became totally airborne and remained as such as it began to travel parallel with the bridge railing at a speed of 50.9 mi/h (81. 9 km/h). The rear of the vehicle contacted the parapet at sand then exited the bridge railing at s traveling at a speed of 50.3 (80.9 km/h) and an exit angle of 1. 0 degrees. As the vehicle exited the bridge railing installation, the brakes were applied. The vehicle yawed clockwise and subsequently came to rest 187ft (57 m) down and 50 ft (15 m) in front of the point of impact. As can be seen in figure 8, the bridge railing system received minimal damage. There was no measurable permanent deformation to the metal railing elements; however, the left comer of the bumper had snagged post 6 (leaving plastic trim). Also, posts 5 and 6 were pulled up such that the washers rotated freely under the nuts on the front side of the railing (see figure 9). There was only cosmetic damage to the concrete parapet, i.e., tire marks on the concrete parapet from post 5 on past post 6 and.then again between posts 8 and 9 where the vehicle contacted the parapet the s. time. The vehicle was in contact with the bridge railing system for ft (3.7 m). The vehicle sustained. damage to the left side as shown in figure 10. Maximum crush at the left front comer at bumper height was 7. 5 in (191 mm). The left front strut was bent and the left front wheel was pushed back reducing the wheelbase on the driver side by 3 in (76 mm). Also, damage was done to the front bumper, hood, left front quarter panel, left rear quarter panel, rear bumper, left front and rear tires and rims, and right front tire. 9

20 Test Results The vehicle impacted the curb of the sidewalk at 61.7 mi/h (99. 3 km/h) and the angle of impact was 18.7 degrees. As the vehicle impacted the concrete parapet, it was traveling at a speed of 55.5 milh (89.3 km/h) and an angle of 18.1 degrees. The speed of the vehicle at the time of parallel was 50.9 mi/h (81. 9 km/h). In determining the effective coefficient of friction which is an assessment of the smoothness of the "vehicle-railing" interaction, it should be noted that vehicle impact speed and angle is used in the calculation. If "vehiclerailing" interaction is interpreted literally, impact at the time of contact with the concrete parapet would be used. However, the curb could be considered to be part of this "vehiclerailing" interaction. Therefore, two assessments could be made: (1) interpreting "vehiclerailing" interaction literally disregarding the impact at the curb and using the speed and angle at which the vehicle impacted the concrete parapet or (2) considering the curb as an element of the "railing" system and using the speed and angle at which the vehicle impacted the curb. The coefficient of friction was calculated both ways for this test. Considering the curb as part of the vehicle-railing interaction the coefficient of friction was 0.38, while it was 0.11 using impact with the concrete parapet in the calculation. The vehicle lost contact with the bridge railing traveling at 50.3 mi/h (80. 9 km/h) and the exit angle between the vehicle path and the bridge railing was 1.0 degrees. Data from the accelerometer located at the center-ofgravity were digitized for evaluation, and occupant risk factors were computed as follows. In the longitudinal direction, occupant impact velocity was 15.3 fils (4.7 m./s) at s, the highest s average ridedown acceleration was -3.8 g between and s, and the maximum s average acceleration was -5.6 g between and s. Lateral occupant impact velocity was 6.5 fils (2.0 mls) at 0~214 s, the highest s occupant ridedown acceleration was g between and s, and the maximum0.050-s average acceleration was -9.3 g between and s. The change in vehicle velocity at loss of contact using impact with the curb was 11.4 mi/h (18.3 km/h) and the change in momentum was 935 lb-sec (4,157 N-s). These data and other pertinent infonnationfrom the test are summarized in figure 11 and table 1. Sequential photographs are shown in figures 12 and 13. Vehicular angular displacements are displayed in figure 14. Vehicular accelerations versus time traces filtered with SAE J211 filters are presented in figures 15 through 17. Conclusions The BR27C bridge railing on sidewalk contained the test vehicle with no lateral movement of the bridge railing. There was no intrusion of railing components into the occupant compartment and no debris to present undue hazard to other traffic. The integrity of the occupant compartment was maintained with no intrusion and no deformation. The vehicle remained upright and relatively stable during the collision. The bridge railing system smoothly redirected the vehicle. The effective coefficient of friction using the curb impact conditions was considered marginal, while using impact conditions with the railing itself was good. The 1989 AASHTO (American Association of State Highway and Transportation Officials) guide specifications sets forth desired limits for occupant risk factors for tests with the 1,800-lb (817-kg) vehicle.< 1 ) The AASHTO specifications recommend a limit of 30 ft/s 10

21 (9.1 ml s) for longitudinal occupant impact velocity and 25 ftl s (7. 6 m/ s) for the lateral occupant impact velocity and a limit of 15 g's for occupant ridedown accelerations in both longitudinal and lateral directions. Although the lateral ridedown acceleration of 17.2 g' s was slightly above the recommended limit, the test was judged acceptable for this category as it was well within the limits of the other three occupant risk factors. The vehicle trajectory at loss of contact indicated minimum intrusion into adjacent traffic lanes. See figure 11 and table 1 for more details. 11

22 Figure 3. Vehicle/bridge railing geometries for test

23 Figure 4. Vehicle prior to test

24 Date: Test No.: VIN: JHMSR5328CS Make: Honda Model: Civic Year: --=:..=19:..:8.::...2 Odometer: Tire Size: P155/80R13 Ply Rating: Bias Ply: _ Bel ted: _ Radial: _x_ r -,---.;--t Accelerometers a P j_ L T Tire Condition: good fair x_ Height of Rea r badly worn - Accelerometer 29 1/2" on Vehicle Geometry - inches a 63" b 30" c 89" d* 53 ] l~" e 28 1/2" f l!iz 5 Tire dia---~...:.-;~ \~heel dia ~ 95" Accelerometers 9--'---- h 34.4 j k 18" l 34 ll2" /2" n 3" j m k g p 53 l.l2 11 r 22 3/4" s 14 ll~" 4-wheel weight for e.g. det. lf 575 rf 530 lr 350 Mass - pounds Curb Test Inertial Ml M MT Note any damage to vehicle prior to test: Crack in windshield (marked) *.d = overa 11 height of vehi c 1 e 1 in= 25.4 nun llb = kg f rr 345 Gross Static ~65..._ Engine Type: _4.J-...:=c..,.y..L.l Engine CID: _ Tran~mission Type: X~~es~~~l~ or Manual FWD or t(~ or 4W< Body Type: ~Ha;;...t~c;.;.,;;h Steering Column Collapse Nechanisrn: Behind wheel units --Convoluted tube -Cyl indrica 1 mesh units -Embedded ba 11 -NOT collapsible -Other energy absorption -Unknown Brakes: Front: Hear: disc_x_ drum_ disc_._ drum_x_ Figure 5. Vehicle properties for test

25 Figure 6. BR27C bridge railing on sidewalk before test

26 Figure 7. Rear view of BR27C bridge railing on sidewalk. 16

27 Figure 8. BR27C bridge railing on sidewalk after test

28 Figure 9. Damage at posts 5 and 6, test

29 Figure 10. Vehicle after test

30 0 "' Test No Date /31/92 Test Installation Installation Length. BR27C Bridge Railing on sidewalk 100 ft (30m) Test Vehicle Honda Civic Vehicle Weight Test Inertia... 1,800 lb (817 kg) Gross Static... 1,965 lb (892 kg) 1--utl Vehicle Damage Classification TAD LFQ3 (1 in = 25.4 mm) CDC FLEK2 & 11LFES2 Maximum Vehicle Crush. 7.5 in {191 mm) Figure 11. Summary of results for test Impact Speed mi/h (99.3 km/h) Impact Angle deg Speed at Parallel 50.9 mi/h (81.9 km/h) Exit Speed mi/h (80.9 km/h) Exit Trajectory deg Vehicle Accelerations (Max sec Avg) at true e.g. Longitudinal g Lateral g Occupant Impact Velocity at true e.g. Longitudinal ft/s (4.7 m/s) Lateral ft/s (2.0 m/s) Occupant Ridedown Accelerations Longitudinal g. Lateral g

31 N 1-' A. B. c. D. E. F. Table 1. Evaluation of crash test no {BR27C bridge railing on sidewalk [1,800 lb (817 kg)l61.7 mi/h (99.3 km/h)l18.7 degrees]} CRITERIA Must contain vehicle Debris shall not penetrate passenger compartment Passenger compartment must have essentially no deformation Vehicle must remain upright Must smoothly redirect the vehicle Effective coefficient of friction u >.35 G. Shall be less than Assessment Good Fair Marginal Occupant Impact Velocity - ft/s Cm/sl Longitudinal lateral 30 (9.2} 25 (7.6} Occupant Ridedown Accelerations - g's Longitudinal Lateral H. Exit angle shall be less than 12 degrees TEST RESULTS Vehicle was contained No debris penetrated passenger compartment No deformation Vehicle did remain upright Vehicle was smoothly redirected ~.38 curb).11 rail) Assessment Marginal Good Occupant Impact Velocity - ft/s Cm/s) Longitudinal Lateral 15.3 (4.7) 6.5 (2.0) Occupant Ridedown Accelerations - g's Longitudinal Lateral Exit angle was 1.0 degrees * A, B, C, D and G are required. E, F, and H are desired. (See table 2) PASS/FAlL* Pass Pass Pass Pass Pass Pass Pass Pass Pass

32 Table 2. Bridge railing performance levels and crash test criteria. (Excerpt from 1989 AASHTO Guide Specifications for Bridge Railings)(I) PERFORMANCE LEVELS TEST SPEEDS-mph 1 2 TEST VEHICLE DESCRIPTIONS AND IMPACT ANGLES Medium Small Pickup Single-Unit Van~ Type Automobile Truck Truck Tractor-Trailer 4 W = 1.8 Kips W=5.4 Kips W = 18.0 Kips W = 50.0 Kips A= 5.4' ± 0.1' A= 8.5' ± 0.1' A= 12.8' ± 0.2' A= 12.5' ± 0.5' B=5.5' B=6.5' B =7.5' B=8.0' Hcg=20"± 1" Hcg=27" ± 1" Hcg=49"± 1" Hcg =See Note 4 e = 20 deg. 6 =20 deg. 6 = 15 deg. R = 0.61 ± 0.01 e = 15 deg. PL PL PL CRASH TEST EVALUATION Required a, b, c, d, g a, b, c, d a, b, c a, b, c CRITERIA 3 Desirable 5 e, f, h e, f, g, h d, e, f, h d, e, f, h Notes: 1. Except as noted, all full-scale tests shall be conducted and reported in accordance with the requirements in NCHRP Report No In addition, the maximum loads that can be transmitted from the bridge railing to the bridge deck are to be determined from static force measurements or ultimate strength analysis and reported. 2. Permissible tolerances on the test speeds and angles are as follows: Speed -1.0 mph mph Angle.; deg deg. Tests that indicate acceptable railing performance but that exceed the allowable upper tolerances will be accepted. 3. Criteria for evaluating bridge railing crash test results are as follows: a~ The test article shall contain the vehicle; neither the vehicle nor its cargo shall penetrate or -go over the installation. Controlled lateral deflection of the test article is acceptable. b. Detached elements, fragments, or other debris from the test article shall not penetrate or show potential for penetrating the passenger compartment or present undue hazard to other traffic. c. Integrity of the passenger compartment must be maintained with no intrusion-and essentially no deformation. d. The vehicle shall remain upright during and.after. collision. e. The test article shall smoothly redirect the vehicle. A redirection is deemed.smooth if the rear of the vehicle or, in the case of a combination vehicle, the rear of the tractor or trailer does not yaw more than 5 degrees away from the railing from time of impact until the vehicle. separates from the railing. f. The smoothness of the vehicle-railing interaction is further assessed by the effective coefficient of friction, JL: Assessment Good Fair >035 Marginal where JL = ( cos6 - VP N)/sine 22

33 Table 2. Bridge railing performance levels and crash test criteria. (Excerpt from 1989 AASHTO Guide Specifications for Bridge Railings) (I) (continued) g. The impact velocity of a hypothetical front-seat passenger against the vehicle interior, calculated from vehicle accelerations and 2.0-ft. longitudinal and 1.0-ft. lateral diplacements, shall be less than: Occupant Impact Velocity-fps Longitudinal 30 Lateral and the vehicle highest 10-ms average accelerations subsequent to the instant of hypothetical passenger impact should be less than: 25 Occupant Ridedown Acceleration-g's Longitudinal Lateral h. Vehicle exit angle from the barrier shall not be more than 12 degrees. Within 100 ft. plus the length of the test vehicle from the point of initial impact with the railing, the railing side of the vehicle shall move no more than 20-ft. from the line of the traffic face of the railing. The brakes shall not be applied until the vehicle has traveled at least 100-ft~ plus the length of the test vehicle from the point of initial impact. 4. Values A and R are estimated values describ.ing the test vehicle and its loading. Values of A and R are described in the figure. below and calculated as follows:, ' Min. Load = 20.5 Kips Lt=30"±1" ~+ 7 = 169"±4" R = W1+W2+W3 w W=Wt +W2+W3+W4+W 5 = total vehicle weight. 4.5' Approx. (Rear most setting.) ~ (Load)= 92" Approx. Hq (Trailer & Load) = 79" ± 1" Hq (Tractor, Trailer, ~ Load) = 64" ± 2" 5. Test articles that do not meet the desirable evaluation criteria shall have their performance evaluated by a designated authority that.will decide whether the test article is likely to meet its intended use requirements. 1 mi = 1.61 km 1 kip = 4.45 kn 1 in= 25.4 mm 23

34 s s 0.1~5 s Figure 12. Sequential photographs for test (overhead and front views). 24

35 s s s s Figure 12. Sequential photographs for test (overhead and front views continued). 25

36 0.,000 s s s s Figure 13. Sequential photographs for test (interior and perpendicular views). 26

37 0.270 s S 0. 44C s s Figure 13. Sequential photographs for test (interior and perpendicular views continued). 27

38 I., (/) Q.) Q.) c... Ol Q.) N , c Q.) E Q.) u CO,... c. (/) r-t I Yaw )( Pitch 0 Roll tl'llcu A VI\W ~ C]) 9~ GS~~J ~ '"0 cc --- I~ Axes are vehicle fixed. Sequence for determining orientation is: 1. Yaw 2. Pitch 3. Roll -3o.o~--~ ~--~---+--~~--+---~--~---- o.o Time (Seconds) PA3.08 Figure 14. Vehicle angular displacements for test

39 CRASH TEST Accelerometer at center-of-gravity 1'\) ~ "Ji) 50.9 z 40 0 ~ 30 w -' w (.) ~ -' <C 0 z a -1o :::J ~ 0-20 z g l ~~~~:~~~::~~~:~~t:~~~~~::~:~::::f==:~:~~~~:~~t:~~:~~~~~:~:~~t=:=~~:~:~~:~~l~ l-- - Test Article: BR27C on Sidewalk Test Vehicle: 1982 Honda CMc Test Inertia Weight: 1,8QO lb Gross Static Weight: 1,9651b Test Speed: 61 ~ 7 mi/h Test Angle: 18.7 degrees t t t t t i i l I! ::::~::::~::::::::::::::::~:::,::::::::::~:::::::~:::::::::::I::::~~::::::::::::::::::::~::,::::::::~:~:::~~::::~:::::::I,I:::~:~::::~:::~::::~::::::::j~:::::::~~::::::::::::~~:r:::~:.:::::~::::~:::::~~~~:::~::::~::~:~:~:::::::~:::: ~j I r i r ~ 1 I_ Jb~Jtuo~... 'or ~ ~~~~~... 1#'0."'''',....,.J t I.-Ill l't u""1v' 'f,.... '\" v',.. 41! i I : i j!! t oooooooooooooooooooooooooi oooooooooooooooooooooooooooooo,.oooooooooooooooooooooooooooooooootooooooooooooooooooooooooooooooooooioooooooooooooooooooooooooooooooooo i i J,. t'! i! I! ~~:~~~~~=~::~I~~~:=~:~:~:~~~r~::::::~=~.:.~~-I~~:~~~:~~~:~:~r::~:~~~~:~=~~~[~:~~~~:~~=:I~:~=~~:~::~~~]~~~:~:~:~~~:~~~: i I i!. 1 l! ' I ' I ~::~::::::::::::::::::::::::::r::~::::::::::::::::::::~::::j:::::~::::::::::~::::::::::::::j~::~::::::~:~:::::::::::::::::i:::::::::::::::::::::~:::::::::j:::::::::::::::~:::::::~:~:~:~~::::~:~:~:~::::::::::::~:r:::::::::::::~:::::::~::::::::: -60 I I I I I I TIME AFTER CONTACT WITH CURB (SECONDS) 1 lb = kg 1 mi/h = ktrl/h r- Class 180 niter - 60iTisec Average I Figure 15. Vehicle longitudinal accelerometer trace for test (accelerometer located at center-of.:.gravity).

40 CRASH TEST Accelerometer at center-of-gravity w 0 80 I I 1 1 1!!! : j. i i i! 70-t~... t ; -t ' t t t Test Article: BR27C on Sidewalk I I i I I! TestVehicle: 1982HondaCMc 60-t.... ~.;....;...:... J... i i i i j Test Inertia Weight: 1,800 lb 50...:. i...;. I...;. I... I :...;. I... Gross Static Weight: 1,9651b _! i i i j Test Speed: 61.7 mi/h.. ~ l... l... L... i.... ~... ~...L... Test Angle: 18.7 degrees!:: :.::. ~ i! : : i,.! i! l l ( 30 :~::::. ::.::~::: '.:.~. :::::::~::1. ::::::.:::::::::. :::.::::.::::::::::~'1 :.:::: :~.::::~:~:: :':::.:::::~:::::. ::::.:::::::::::::::,::::~::::::.::.:::::.:::~:~::.::,:::::::~::::::::::::::::::.::::1 ~ < c 20.. ::.:::::.:::. u ~ ( ~ 1 o ltnh xi - ti ~-IK~: : : : It~-~l~ t :-; r ~-- t : t - -; t h~w ~*~~ II' '..., t...; ~, 1 V '. i "= 0 "' i '. "'! I... t...,......j ~ -10 w ~ 'I I t 'i' r ~ w~;,;,...,!...! I! j!... t '... =... ~...!... i.... i. I I.! i :,,, I I!! : i! I I i -40 i I I l I I i -60 i i!! i i! TIME AFTER CONTACT WITH CURB (SECONDS) 1 lb = kg 1 mi/h = km/h,_.- Class 1 eo niter - 6CHTI58C Average I Figure 16. Vehicle lateral accelerometer.trace for test (accelerometer located at center-of..;gravity).

41 w...,.a (i)' ~ 40 z 0 30 ~ 20 w _, 10 w 0 ~ _, 0 ( -10 ti -20 w > -30 i... l... J CRASH TEST Accelerometer at center-of-gravity...!... i... ;J.... I I I I I ::::::::::~::::::::::::::::::::r~:~::::::~::::::::~:::~:,::::~::::::::::~~:::::::::~::,:::~:~:~:~:~::::~:::::::::::l:::::::~::::::~::::~:~:::::t::::::: l I. I I. I ooooooooooooooooo -1- oooooooooooo'tooooooooooooooooooooooooooooooooo.,.oooooooooooooooooooooooooooo t 't oooooo,::::::.:::::::::r:::::::::::::::::::::::::::j:::::::::::::::::: :::: :: I::::::::::::::::::::::::::::::::I:::::::::::::::::::::::::::::::I:::::: Test Article: BR27C on Sidewalk Test Vehicle: Honda CMc Test Inertia Weight: 1,800 lb Gross Static Weight: 1,9651b Test Speed: 81.7 mi/h Test Angle: 18.7 degrees I i! I ~~~~~~inr1~ ~:m~~~~~~~~~.ot ooooooooooooooooooooooooooooooojoooooooooooooooooooooooooooo oo t - ' 1 r \1 ~! 1 i! ~--~----~r---~~----~ ~ ~~~~ TIME AFTER CONTACT WITH CURB (SECONDS) 1 lb = kg 1 mi/h = km/h 1-Class 1 so niter - 50-msec Average ) Figure 17. Vehicle vertical accelerometer trace for test (accelerometer located at center-of-gravity)~

42 Test Test Description A 1984 GMC Sierra 2500 pickup (figures 18 and 19) was used for the crash test. Test inertia mass of the vehicle was 5,400 lb (2 452 kg) and its gross static mass was 5,568 lb (2 582 kg). The height to the lower edge of the vehicle bumper was 17.0 in ( 432 mm) and it was in (667 mm) to the top of the bumper. Additional dimensions and information on the test vehicle are given in figure 20. The vehicle was directed into the BR27C bridge railing on sidewalk (figure 21) using the cable reverse tow and guidance system and was released to be free-wheeling and unrestrained just prior to impact. The vehicle impacted the curb of the sidewalk approximately 8.8 ft (2.7 m) downstream from the end at a speed of 62~6 mi/h (100.7 km/h) and the angle of impact was 19.4 degrees. As the left front wheel of the vehicle mounted the curb, the tire aired out. At approximately s after impact, the vehicle began to redirect, and at s the left rear tire contacted the curb. The vehicle bumper impacted the concrete parapet (near post 4) at s traveling at a speed of 59.8 mi/h (96.2 km/h) and an angle of 17.9 degrees. At s the right front wheel contacted the curb and the vehicle impacted the metal railing element. By s the vehicle began to redirect significantly, and by s the vehicle was traveling parallel with the bridge railing at a speed of 56.7 mi/h (91.2 km/h). The rear of the vehicle contacted the concrete parapet at s and then exited the bridge railing at s traveling at a speed of 53.5 (86.1 km/h) and an exit angle of 5.4 degrees. As the vehicle exited the bridge railing installation, the. brakes were applied. The vehicle yawed counter-clockwise and subsequently came to rest 210ft (64 m) down and 6ft (2m) in behind of the point of impact. As can be seen in figure 22, the bridge railing system received minimal damage. There was no measurable permanent deformation to the metal railing elements; however, the left comer of the bumper had snagged post 5 and pulled it up such that the washer rotated freely under the nut on the left front side of the railing. There was only cosmetic damage to the concrete parapet, i.e., tire marks on the concrete parapet from post 4 to post 6. The vehicle was in contact with the bridge railing system for a total of 13.0 ft (4.0 m). The vehicle sustained damage to the left side as shown in figures 23 and 24. Maximum crush at the left front comer at bumper height was 12.0 in (305 mm) and the right front comer was deformed outward 7. 0 in (178 mm). The left front wheel was pushed back reducing the wheelbase on the driver side by 2.25 in (57 mm). Also, damage was done to the front bumper, hood, grill, left front quarter panel, left door and glass, left rear quarter panel, rear bumper and tailgate, left front tire and rim, and right front tire. The welds on the left rear rim broke and the tire separated from the rim as shown in figure 24. Test Results The vehicle impacted the curb of the sidewalk at 62.6 mi/h ( km/h) and the angle of impact was 19.4 degrees. As the vehicle impacted the concrete parapet, it was 32

43 traveling at a speed of59.8 milh (96.2 km/h) and an angle of 17.9 degrees. The speed of the vehicle at the time of parallel was 56.7 milh (91.2 km/h). In determining the effective coefficient of friction which is an assessment of the smoothness of the "vehicle-railing" interaction, it should be noted that vehicle impact speed and angle is used in the calculation. If "vehicle-railing" interaction is interpreted literally, impact at the time of contact with the concrete parapet would be used. However, the curb could be considered to be part of this "vehicle-railing" interaction. Therefore, two assessments could be made: (1) interpreting "vehicle-railing" interaction literally disregarding the impact at the curb and using the speed and angle at which the vehicle impacted the concrete parapet or (2) considering the curb as an element of the "railing" system and using the speed and angle at which the vehicle impacted the curb. The coefficient of friction was calculated both ways for this test. Considering the curb as part of the vehicle-railing interaction, the coefficient of friction was 0.11, while it was 0.01 using impact with the concrete parapet in the calculation. The vehicle lost contact with the bridge railing traveling at 53.5 mi/h (86.1 km/h) and the exit angle between the vehicle path and the bridge railing was 5.4 degrees. Data from the accelerometer located at the center-ofgravity were digitized for evaluation, and occupant risk factors were computed as follows. In the longitudinal direction, occupant impact velocity was 12.9 ft/s (3.9 m/s) at s, the highest s average ridedown acceleration was -4.4 g between and s, and the maximum s average acceleration was -4.6 g between and s. Lateral occupant impact velocity was 19.9 ft/s (6.1 m/s) at s, the highest s occupant ridedown acceleration was g between and s, and the maximum s average acceleration was -9.3 g between and s. The change in vehicle velocity at loss of contact using impact with the curb was 9.1 mi/h (14.6 km/h) and the change in momentum was 2,238 lb-sec (9,956 N-s). These data and other pertinent information from the test are summarized in figure 25 and table 3. Sequential photographs of the test period are shown in figures 26 and 27. Vehicular angular displacements are displayed in figure 28. Vehicular accelerations versus time traces filtered with SAE J211 ftlters are presented in figures 29 through 35.. Conclusions The BR27C bridge railing on sidewalk contained the test vehicle with no lateral movement of the bridge railing. There was no intrusion of railing components into the occupant compartment and no debris to present undue hazard to other traffic. The integrity of the occupant compartment was maintained with no intrusion and no deformation. The vehicle remained upright and relatively stable during the collision. The bridge railing system smoothly redirected the vehicle. The effective coefficient of friction was considered good. The 1989 AASHTO guide specifications sets forth desired (but not required) limits for occupant risk factors for tests with the 5,400-lb (2 452-kg) vehicle. (l) The AASHTO specifications recommend a limit of 30 ftl s (9.1 ml s) for longitudinal occupant impact velocity and 25 ft/s (7.6 m/s) for the lateral occupant impact velocity and a limit of 15 g's for occupant ridedown accelerations in both longitudinal and lateral directions. The occupant risk factors were well within the specified limits. The vehicle trajectory at loss of contact 33

44 indicated minimum intrusion into adjacent traffic lanes. See figure 25 and table 3 for more details. 34

45 Figure 18. Vehicle/bridge railing geometries for test

46 Figure 19. Vehicle prior to test

47 Date: Test No. :...:7~0~69"'---=2.:...5 VIN: 1GIGC24MOEJ All on Center Make: ~GM...,C. _ Model: Serra 2500 Year: ~-- Odometer: 95257,7 Tire Size: LT Ply Rating: Bias Ply: X Belted: Radial: Tire Condition: good Accelerometers Height of fp.ir A. 29 3/4 11 badly worn ~:=::===2:=rc-::/=::3;~~==::::::::n -~- B. 31" c. 37 3/4" Vehicle Geometry - inches I~ Acce1erometers I ~. ~.3~ /4".(.. 36" Jo+-,!-r +r~e-- Ti re d i a s j a 72 ll2" b 32" c c;l* 71 1/4 11 e 52 1/ h 70.8 i j 44 1/2" k f.e. m 26 1/4 11 n 3 1/4" p f c 4-wheel weight for e.g. det. lf 1281 rf 1207.er 1371 rr 1541 Mass - pounds Curb Test Inertial Ml M Mr Note any damage to vehicle prior to test: *d = overall height of vehicle Gross Static r 30 1/2 11 s 17 1/2 11 v-a Engine Type: Engine CID: Transmission Type: ~~~~~ or Manual ~ 1~ or RWD or Y4WOC Body Type: P...;::;.U Steering Column Collapse Mechanism: Behind wheel units ---Convoluted tube ---Cylindrical mesh units ---Embedded ball ---NOT collapsible --. Other energy absorption -Unknown Brakes: Fr:-ont: disc_x_ drum Rear: disc drumx lin= 25.4mm 1 lb = kg Figure 20. Vehicle properties for test

48 Figure 21. BR27C bridge railing on sidewalk before test

49 Figure 22. BR27C bridge railing on sidewalk after test

50 Figure 23. Vehicle after test

51 Figure 24. Damage to left rear wheel of vehicle after test

52 .p. N ~ (1 in = 25.4 mm) Test No Date /02/92 Test Installation... BR27C Bridge Railing on sidewalk Installation Length ft { 30 m) Test Vehicle GMC Sierra Vehicle Weight Pickup Test Inertia... 5,400 lb (2,452 kg) Gross Static... 5,568 lb (2,528 kg) Vehicle Damage Classification TAD... 11LFQ4 & 11LD4 CDC... 11FLEK2 & 11LDEW2 Maximum.Vehicle Crush in (305 mm) Figure 25. Summary of results for test Impact Speed mi/h (100.7 km/h) Impact Angle deg Speed at Parallel mi/h (91.2 km/h) Exit Speed mi/h (86.1 km/h) Exit Trajectory deg Vehicle Accelerations (Max~ s~c Avg) at true e.g. Longitudinal g Lateral g Occupant Impact Velocity at true e.g. Longitudinal ft/s (3.9 m/s) Lateral ft/s (6.1 m/s) Occupant Ridedown Accelerations Longitudinal g Lateral g

53 ~ w A. B. c. D. E. F. {B~27C Table 3.. Evaluation of crash test no bridge railing on sidewalk [5,400 lb (2 452 kg)l62.6 mi/h (100.7 km/h)119.4 degrees]} CRITERIA Must contain vehicle Debris shall not penetrate passenger compartment Passenger compartment must have essentially no deform.at ion Vehicle must remain upright Must smoothly redirect the vehicle Effective coefficient of friction u >.35 G. Shall be less than Assessment Good Fair Marginal Occupant Impact Velocity - ft/s On/sl Longitudinal Lateral 30 {9.2) 25 (7.6) Otcupant Ridedown Accelerations - q's Longitudinal Lateral H. Exit angle shall be less than 12 degrees TEST RESULTS Vehicle was contained No debris penetrated passenger compartment.. No deformation Vehicle did remain upright Vehicle was smoothly redirected ~.11 curb).01 rail) Assessment Good Good Occupant Impact Velocity - ft/s (m/sl Longitudinal Lateral 12.9 (3.9) (6.1) Occupant Ridedown Accelerations - g's Longitudinal Lateral Exit angle was 5.4 degrees * A, B, C, and 0 are required. E, F, G, and H are desired. (See table 2) PASS/FAIL* Pass Pass Pass Pass Pass Pass Pass Pass Pass

54 0.000 s Figure 26. Sequential photographs. for test (front and overh~d views). 44

55 0.255 s s s s Figure 26. Sequential photographs for test (front and overhead views continued). 45

56 0.000 s o. 064 s s s Figure 27. Sequential photographs for test (perpendicular and interior views). 46

57 0.255 s s s $ Figure 27. Sequential photographs for test (perpendicular and interior views continued). 47

58 r Yaw )( Pitch 0 Ro 1 ~,., ~ YAW~~ ~~.~ocl ~ 00 (/) Q.) 'Q.) c.. Ol Q.) Cl - +' c Q.) E Q.) u co r-t 0. (/) r-1 Cl Axes are vehicle fixed. Sequence for determining orientation is: 1. Yaw 2. Pitch 3. Roll -28.0~--~--~ ~--~~--+---~--~~ Time (Seconds) PA3.08 Figure 28. Vehicle angular displacements for test

59 ~ ~ eo Jii' z 40 0 ~ w w J 20 ~ 10...J 0 ~ 0-10 ~ (!} -20 z g l CRASH TEST Accelerometer at center-of-gravity I I I I r t t f... I I :,... t l... Test Inertia Weight: 5,400 lb Test Article:. BR27C on Sidewalk I I j I Test Vehicle: 1984 GMC Sierra 2500 Pickup l. l I l Gross Static Weight: 5,5681b... r... T...!... J... J... T... T... Test Speed: mi/ll... l... Test Angle: 19.4 degrees I I l L-... _ J '- -- I t I...! ~... I I,...,. I...,. 1..., 1... i : a I! i I 1l... i ~ i l :.. i : i : ~f~j. '. 11l' tf'/'11luai'f v v If l \-' c u u ' r ' ' '!. i. - l ~l - l " l... f... ~..... :.! ~------~ ~ TIME AFTER CONTACT WITH CURB (SECONDS) llb = kg 1 mi/h = km/h 1-Claaa 1ao nrter - 60i'l18ec Average Figure 29. Vehicle longitudinal accelerometer trace for test (accelerometer located at center"'of-gravity).

60 01 0 eo "Jii'.g 40 z 0 30 ~ ~ 20 w _. UJ 10 (.) S1 0...J CRASH TEST Accelerometer at center-of-gravity :! ; t... -t. j I!! I ~~~~~:::::::~:~:=:f~~~~~~~:~~:~:~~~l~::::~~:~~~:~:~=~\::~~~:::~:~:~:~:~:~1~~:~:~~::: '1- -t t.... l :....t... i t : i... t.... i l Test Article: BR27C on Sidewalk Test Vehicle: 1984 GMC Sierra 2500 Pickup Test Inertia Weight: 5,400 lb Gross Static Weight: 5,5681b Test Speed: 62.6 mi/h Test Angle: 19.4 degrees ~ -10 ~~t~ l r:::~::::~:~~:~:~~::::c~~~~:~~~:~:~~: w ~ ~, I.,... I I! I TIME AFTER CONTACT WITH CURB (SECONDS) lib = kg 1 mi/h = km/h 1-Class 180 nrter - oo-msec Average I Figure 30. Vehicle lateral accelerometer trace for test (accelerometer located at center-of-gravity).

61 CRASH TEST Accelerometer at center-of~gravity (J'1 t-' z 0 ~ w. w 0 ~. ( ~ w > t.A~.\JM.t.UMI~rP!'A/\..aJ, J1 J~ Test Anicle: BR27C on Sidewalk Test Vehicle: 1984 GMC Sierra 2500 Pickup Test rnenia Weight: 5,400 lb Gross Static Weight: 5,5681b Test Speed: 62.8 mi/h Test Angle: 19.4 degrees lib = kg 1 mi/h = km/h 1-Class 180 niter - 50-msec Average I Figure 31. Vehicle vertical accelerometer trace for test (accelerometer located at center-of-.gravity).

62 (J1 N CRASH TEST Accelerometer at front of vehicle 80 I I i.. 70-f...;... t... t..... t...,... Test Article: BR27C on Sidewalk : :i::::::::::::::::::::::::::l::::::::::::::::::::::::::::l:::::::::::::::::::::::::::::::l::::::::::::::::::::::::::::::::l:::::::::::: 0 ~ w..j w (.) ~..J <( z Q ~ (!) z g Test Vehicle: 1984 GMC Sierra 2500 Pickup Test Inertia Weight: 5,400 lb Gross Static Weight: 5,5681b Test Speed: 62.6 mi/h Test Angle: 19.4 degrees TIME AFTER CONTACT WITH CURB (SECONDS) llb = kg 1 mi/h = km/h 1-.- Class 1 BO niter - 60-msec Average I Figure 32. Vehicle longitudinal accelerometer trace for test (accelerometer located at front of vehicle).

63 U"1 w y;- 50 ~ 40 z 0 30 ~ 20 w _. w 10 0 ~ 0 _. CE -1o w ~ CRASH TEST Accelerometer at front of vehicle 80 I i... f... t t Test Article: BR27C on Sidewalk T... t ,... Test Inertia Weight: 5,400 lb -40 I l j I Test Vehicle: 1984 GMC Sierra 2500 Pickup i I I i Gross Static Weight: 5,5681b... T... T... T... r Test Spee(l : 62.6 mi/h... l... l... L... l... Test Angle: 19.4 degrees t......, i : i!...j:~::~~:::::~:::::::::~..!....::..:::.:~:~::::t::~:~:::::::..::::::::.:::::.j..:..:~:~::::::::~:::::::~::t::~~:::::::::::::~:::::::::t::::~:~::::::::::::::::::::::::l:::::::::::~:~:::::::::::::::::: : i i j j j...! l... l... l... l... J... I 1 I I I I I -50 :::::::::::~:::~:::::~::::::l~:::::::::::::::::::::::::::::j:::::~:~:::::::~::::::~~::::j:::::::::::::::::~:::::::::::::::f:::~::::::::::~~:::::::::::::::j:::::::~::::::::::~::::::::::::j:::~~~:~:::::::::~::::::::::l:~::::::::::::::::::::::::::::::: -60 I o~2 o.3 o.4 o.s o.e TIME AFTER CONTACT WITH CURB (SECONDS) 1 lb = kg 1 mi/h = km/h j-class 1 eo niter - 50-msec Average 1 Figure 33. Vehicle lateral accelerometer trace. for test (accelerometer located at front of vehicle).

64 CRASH TEST Accelerometer at rear of vehicle ao I I I. I 70-l t.. -r t t..! i : l ~ :i:: ::::::::::::::t:::::::::::-::::::!:::::::::::::::::::1::::::::::::::\::::::~ Test Article: BR27C on Sidewalk Test Vehicle: 1984 GMC Sierra 2500 Pickup Test Inertia Weight: 5,400 lb Gross Static Weight: 5,5681b Test Speed: 62.6 mi/h Test Angle: 19.4 degrees (J"1.J::=o ~ ~ w () ~ ~::::r:::~:~ ::: t ' -- -r:~::::~:~:::::::::::::~::::r~:::::~::~:::::::::::~:~:: ~ - - t : t::.. I..I!. l I l I G -20. t.. t f. r t t..! z I i i I I I I 60 I I I : I : : TIME AFTER CONTACT WITH CURB (SECONDS) lib = kg 1 mi/h == km/h 1-Class HIO niter - 50-msec Average I Figure 34. Vehicle.longitudinal accelerometer trace for test (accelerometer located at rear of vehicle).

65 CRASH TEST Accelerometer at rear of vehicle (J1 (J1 80 : i i : j i I! 70-f. t J L f t 60 -f...;... L...; i i! I Test Inertia Weight: 5,400 lb... l... Test Article: BR27C on Sidewalk... L... Test Vehicle: 1984 GMC Sierra 2500 Pickup... l...;... J... Gross Static Weight: 5,5681b..-...!. I j! Test Speed: 62.6 mi/h 50~ ~ 40.:... { t... ~... J... Test.Angle: 19.4 degrees z 0 ~ 30+ L. -..l....l...i... ~ J i... -!! i i! 1 : ~ 20+ -t- -t-- -t Y... -t- - - t w... w 0 ~... ~ -10 w -20 ~ r , r... r ~... I I i I! 1 I A~'M'l~-A:b: ,.... i i i I i I i i I I i I I :::::~:::::::::::::::::::::::::l~::::::::::::::::::::::::~:::j::~::::::~:::::~::::::::::~::j:::~:::::::::::... :~::::~:::::I~:~::::::~::::::::::::::::::~J:~:::::::~::::~:~::::::::~::J::::~::::::::::::::~::~~::::::I::~:::::::::~::::::::::::::::::: 60 I I I I I I TIME AFTER CONTACT WITH CURB (SECONDS) llb = kg 1 mi/h = km/h 1-.- Class 180 ftlter - 60-msec Average J Figure 35. Vehicle lateral accelerometer trace for test (accelerometer located. at rear of vehicle).

66 Test Test Description A 1980 Ford single-unit truck (figures 36 through 38) was used for the crash test. The empty weight of the vehicle was 10,550 lb ( kg) and its test inertia weight was 18,000 lb (8 172 kg). The height to the lower edge of the vehicle bumper was 18.5 in (470 mm) and it was 30.5 in (775 mm) to the top of the bumper. Additional dimensions and information on the test vehicle are given in figure 39. The vehicle was directed into the BR27C bridge railing on sidewalk (figure 40) using the cable reverse tow and guidance system and was released to be free-wheeling and unrestrained just prior to impact. The vehicle impacted the curb of the sidewalk approximately 24.5 ft (7.5 m) downstream from the end at a speed of 51.0 mi/h (82.0 km/h) and the angle of impact was 13.7 degrees. At approximately s after impact, the vehicle began a slight counter-clockwise yaw, and at s the left rear tire contacted the curb of the sidewalk. The vehicle bumper impacted the concrete parapet 3 ft (1 m) downstream of post. 7 at s traveling at a speed of 47.9 mi/h (77.1 km/h) and an angle of 14.4 degrees. At s the left front wheel contacted the parapet, and at s the right front wheel and part of the hub broke loose from the axle. By s the vehicle began to redirect, and at s the axle contacted the curb. The vehicle was moving parallel with the bridge railing by s traveling at a speed of 44.8 mi/h (72.1 km/h). The rear of the vehicle contacted the concrete parapet at s; and as the vehicle continued forward, the lower edge of the cargo box of the vehicle pulled the metal railing off posts 10 through 14. The front of the cab dropped off the end of the curb at s; and as the vehicle exited the test site, it rode over the dislodged axle and driveshaft. The vehicle subsequently came to rest 195ft (59 m) down from the point of impact. As can be seen in figure 41, the bridge railing system received moderate damage. There was no measurable permanent deformation to the metal railing elements in the immediate impact.area; however the bolts connecting. the railing to. the posts from 10 through 14 were sheared as a result of vertical load from the cargo box. There was only cosmetic damage to the concrete parapet, i.e., tire marks on the concrete parapet from post midway of posts 7 & 8 to post 11. and from posts 13 to 14. The vehicle was. in contact with the bridge railing system for a total of 63 ft (19m). The vehicle sustained damage to the left side as shown in figure 42. Maximum crush at the left front comer at bumper height was 6.0 in (152 mm). The front axle broke loose and became separated from the vehicle as did the driveshaft (see figure 43). There was damage to the springs and shocks, steering box, front bumper, left front quarter panel, left door, and left front tire and rim. The lower edge of the left side of the cargo box was also damaged. 56

67 Test Results The vehicle impacted the curb of the sidewalk at 51.0 mi/h (82. 0 km/h) and the angle of impact was 13.7 degrees. As the vehicle impacted the concrete parapet, it was traveling at a speed of mi/h (77.1 km/h) and an angle of 14.4 degrees. The speed of the vehicle at time of parallel was 44.8 mi/h (72.1 km/h). In determining the effective coefficient of friction which is an assessment of the smoothness of the "vehicle-railing" interaction, it should be noted that vehicle impact speed and angle is used in the calculation. If "vehiclerailing" interaction is interpreted literally, impact at the time of contact with the concrete parapet would be used. However, the curb could be considered to be part of this "vehiclerailing" interaction. Therefore, two assessments could be made: (1) interpreting "vehiclerailing" interaction literally disregarding the impact at the curb and using the speed and angle at which the vehicle impacted the concrete parapet or (2) considering the curb as an element of the "railing" system and using the speed and angle at which tlie vehicle impacted the curb. The coefficient of friction was calculated both ways for this test.. Considering the curb as part of the vehicle-railing interaction the coefficient of friction was 0.40, while it was 0.14 using impact with the concrete parapet in the calculation. Data from the accelerometer located at the center-of-gravity were digitized for evaluation and occupant risk factors were computed as follows. In the longitudinal direction, occupant impact velocity was 8.2 ft/s (2.5 m/s) at s, the highest s average ridedown acceleration was -2.9 g between and s, and the maximum s average acceleration was -1.9 g between and s. Lateral occupant impact velocity was 9.4 ftls (2.9 m/s) at s, the highest soccupant ridedown acceleration was -6.9 g between and s, and the maximum s average acceleration was -2.9 g between and s. These data and other pertinent infonnation from the test are summarized in figure 44 and table 4. Sequential photographs are shown in figures 45 and 46. Vehicular angular displacements are displayed in figure 47. Vehicular accelerations versus time traces filtered with SAE J21l fj.lters are presented in figures 48 through 54. Conclusions The BR27C bridge railing on sidewalk contained the test vehicle with minimal-lateral movement of the bridge railing. There was no intrusion of railing components into the occupant compartment and no debris to present undue hazard to other traffic. The integrity of the occupant compartment was maintained. with no intrusion and no deformation. The vehicle remained upright and relatively stable during the collision. The bridge railing system smoothly redirected the vehicle. The effective coefficient of friction was considered marginal to good. The vehicle trajectory at loss of contact indicated minimum intrusion into adjacent traffic lanes. See figure 44 and table 4 for more details. 57

68 .' Figure 36. Vehicle/bridge railing geometries for test

69 Figure 37. Vehicle prior to test

70 Figure 38. Cargo in vehicle for

71 FORD VIN: F70HVHH0429 TIRE SIZE: 11R-22.5 FRONT AXLE to HCG 122.6" ~. ~.. Accelerometers 1-- // 18'4",_j. r -// \ ---, I 11'7~ 11 0'1.- 26'10" :)IIIIo-; I i ~, EMPTY WEIGHTS Weight on Front Axle Weight on Rear Axle TOTAL EMPTY WEIGHT 1 in= 25.4 mm 1 lb = kg Weight LF _.._.:z...,lll RF... I LR RR LOADED WEIGHTS on Front Axle : LF 3540 Weight on Rear Axle : RF TOTAL LOADED WEIGHT Figure 39. Vehicle properties for test RF 3670 RR 5570

72 Figure 40. BR27C bridge railing on sidewalk before test

73 Figure 41. BR27C bridge railing on sidewalk after test

74 Figure 42. Vehicle after test

75 Figure 43. Debris from vehicle after test

76 0"1 0'\ (1 in = 25.4 mm) ~ 8" Test No Date /08/92 Test Installation. BR27C Bridge Railing on sidewalk Installation Length ft (30 m) Test Vehicle. Vehicle Weight Empty Weight Test Inertia Maximum Vehicle Crush Ford Single-Unit Truck.. 10,550 lb (4,790 kg).. 18,000 lb (8,172 kg) 12.0 in (305 mm) Impact Speed mi/h {82.0 km/h) Impact Angle deg Speed at Parallel 44.8 mi/h (72.1 km/h) Exit Speed... N/A Exit Trajectory.. 0 deg Vehicle Accelerations {Max. O.OSO;..sec Avg) at true e.g. Longitudinal g Lateral g Occupant Impact Velocity at true e.g. Longitudinal ft/s (2.5 m/s) Lateral ft/s {2.9 m/s) Occupant Ridedown Accelerations Longitudinal g Lateral g Figure 44. Summary of results for test 7069~26.

77 '-I "' A. B. c. D. E. Table 4. Evaluation of crash test no {BR27C bridge railing on sidewalk (18,000 lb (8 172 kg)l51.0 mi/h (82.0 km/h)l13.7 degrees]} CRITERIA Must contain vehicle Debris shall not penetrate passenger compartment Passenger compartment must have essentially no deformation Vehicle must remain upright Must smoothly redi~ect the vehicle F. Effective coefficient of friction u >.35 G. Shall be less than Assessment Good Fair Marginal Occupant Impact Velocity - ft/s (m/s) Longitudinal Lateral 30 (9.l} 25 (7.6) Occupant Ridedown Accelerations - g's Longitudinal Lateral H. Exit angle shall be less than 12 degrees TEST RESULTS Vehicle was contained No debris penetrated passenger compartment No deformation Vehicle did remain upright Vehicle was smoothly redirected _jj_.40 curb).14 (Impact@ rail) Assessment Marginal Good Occupant Impact Velocity - ft/s (m/s) Longitudinal Lateral 8.2 (2.5) 9.4 (2.9) Occupant Ridedown Accelerations - g's Longitudinal Lateral Exit angle was 0 degrees PASS/FAIL* *A, B, and Care required. D, E, F, and Hare desired. G is not applicable for this test.(see table 2) Pass Pass Pass Pass Pass Pass N/A N/A Pass

78 0.000 s s s s. Figure 45. Sequential photographs for test (frontal and o.yerhead views). 68

79 0.433 s s s 0~722 s Figure 45. Sequential photographs for test (frontal and overhead views continued). 69

80 0.000 s s s s s s s Figure 46. Sequential photographs for test (perpendicular view). 70

81 (f) (1) (1) L Ol (1)... 0 t-' - +' c (1) E (1) u (Q r-1 a. (f) r I Yaw X Pitch 0 Rol J I., tl'llcil.~ VAW ~. rzj"" ~.;!---- ~~ ~ --~',noll Axes are vehicle fixed. Sequence for determining orientation is: Yaw Pitch 3. Ro o..j._...;..;_, ;r ~ o.o Time (Seconds) PA3.08 Figure 47. Vehicle angular displacements for test

82 -...1 I') (j)' g z 0 ~ _, w w 0 ~ _, <C z c. eo cu ::::> 10 f'- (!) 20 z CRASH TEST Accelerometer at center-of-gravity i! i i : : ;... L.... J... l......j... Test Article: BR27C on Sidewalk.. j : : : I I I I Test Vehicle: 1980 Ford Single Unit Truck I..I I I.. r T... T... r... Empt Weight: 1 o,55o lb... J... J... Test Inertia Weight: 18,000 lb..... ~... l~... ~... J I! l I Test Speed: 51.0 mi/h - t l.. t l Test Angle: 13.7 degrees TIME AFTER CONTACT WITH CURB (SECONDS) 1 lb = kg 1 mi/h = kmlh r==-ci88&-180n~er - 60-msec Average I Figure 48. Vehicle longitudinal accelerometer trace fot test (accelerometer located at center-of-gravity).

83 ~ :g 40 z ~ w..j w s ~ 0 w..j ~ 10 w t- : CRASH TEST Accelerometer at center-of-gravity I! I I.-~= ~ ~ ~ Test Article: BR27C on Sidewalk f : : : i I I I Test Vehicle: 1980 Ford Single-Unit Truck f... Empty Weight: 1 o.s so lb... t i... l...l... J... Test Inertia Weight: 18; 000 lb l i I I Test Speed: 51.0 mi/h... J,... J... ~... i... Test Angle: 13.7 degrees c.....).... ~... ~.... 1::::::::::::::.::::::::::::::::::\:::::~::::::::::::::::::::::::::j::::::::::::::::::::::::::::::::::\::::::::::~:::::::::::::::::::::j:::::::::::::::::::::~:~::::::t::~:~:::::::::: : ;.. " t t; fit#' e ~MV\1' ~'i'*~,.... Af..~AA. JA.~~a' f 6~ i ::::::::::::::::::~:::::::::::::t::::::::::::::~:~:~::::::::::t::::::::~:::::::::::::::::~:t::::::::::::::::::::~:::::::::t::~::~::::::::::::::::::::::::t::::::::::::::::~::::::::~~t:::::::::::::::::::::::::::::~::r:::::::::::::::::::::::::~::~: TIME AFTER CONTACT WITH CURB (SECONDS) lib = kg 1 mi/h = km/h 1-Class 180 niter - 60-msec Average I Figure 49. Vehicle lateral accelerometer trace for.test (accelerometer located at center-of-gravity).

84 CRASH TEST Accelerom eter at center-of-gravity.....p. "(;;' s z 0 ~ w -' w 0 ~ -' ( i= a: w > 0 IU I l I I = = : ~ 4 4 -l... Test Article: B R27C on Sidewalk I : : :!!!! Test Vehicle: 1980 Ford Single-Unit Truck...,... t... t Empty" Weight: 1'0,550 lb... t... l... J... J... l.... Test lnertia Weight: 18, 000 lb ~ I I I Test Speed: 51.0 mi/h } Test Angle: 13.7 degrees! i i : ~~~~~~~:::~~::~:~~~t~~~~~~:~:::~~:::j:~~:~~~~~~~~~~t:=~~~~~~:~:~~~~~t~~~~~~:~::~:~l~::~:::::~:~::~::::~l=~::~~~~~~~~:t~:~:~:~:~~~~-- - -f f- - l L :! t r t r l r TIME AFTER CONTACT WITH CURB (SECONDS) lib = kg 1 mi/h = km/h ~-. -. Class 1 eo niter - 50-msec Average 1 Figure 50.. Vehicle vertical accelerometer. trace for test (accelerometer located at center-of-gravity)

85 CRASH TEST Accelerometer at front of vehicle 80!...,;J (J1 '0' s z 0 ~ w..j w 0 <(..J ~ 0 ;:) f (!) z 9 Test Article: BR27C on Sidewalk Test Vehicle: 1980 Ford Single--Unit Truck Empty Weight: 10,550 lb Test Inertia Weight: 18,000 lb Test Speed: 51.0 ml/h Test Angle: 13.7 degrees! v--.- '--' "V "' ~:~:~~~:~~:~~:~~~t~~~:::~:~:=~~:l~~:~~~::::::::~~:~l5t.~::::xt~:~:~:~~:~~::~::~:~=~~:~:~~~t~~~:~~:~:::::~t~::~:~:~~:~~:::~: I I!! I i I i.. i i i i i ~.. 60 : : : : :, : ~ ~7 0.8 TIME AFTER CONTACT WITH CURB (SECONDS) lib= kg 1 mi/h. = km/h (-. -. Class 1so niter - 60-msec Average 1 Figure 51. Vehicle longitudinal accelerometer trace for test (accelerometer located at front of vehicle).

86 CRASH TEST Accelerometer at front of vehic1e -...! m '(i) g 80 i i z 0 30 ~ w w 10 0 ~ ~ -10 w t- =s Test Article: BR27C on Sidewalk Test Vehicle: 1980 Ford Single-Unit Truck... Empty Weight: 10,550 lb Test Inertia Weight: 18,000 lb Test Speed: 51.0 rnilh Test Angle: 13.7 degrees! ::~:::::::::~::::T::::::~:::::~:::~::::~:~::r::::::::::~~::::::::::::~:T~:::::::::::::::~::::::::::::r:::~::::~:::::::::::::::::::::! i i : ~...,....,.4 0A U4~.J.?. "! 0 t ~... ~... J./l...(:\.,....,.J~ J\i {\ ~ e 4Jl.c r 1 u \f! ; v _... v - ~.. -~x r.. A v "'"r... v :::::::::::~~:::::::::::::::::::r:::~::::::::::~:~::::~:::::::r::::~:::::::::::::::::::::::::r:::::i:::~:::r::j::~:::::::::::::::::~::::::::r:::::::::~:::::::::::::::::::r:::::::::~::::~:::::::::::t::~:::::::::::::~::::~:::::::: l I t I! I I : 1 : I : : : TIME AFTER CONTACT WITH CURB (SECONDS) 1lb = kg 1 mi/h = km/h crass 180 niter - 5CHnaec Average 1 Figure 52. Vehicle lateral accelerometer trace for test (accelerometer located at front of vehicle).

87 CRASH TEST Accelerometer at rear of vehicle : : : :! f i ::1:1 ~::2:~:~:~=~~~::~;:-~nttTruck ~,.! ~ - i _.. ~ SO.j Test Inertia.. We. ight.: 18,000 lb Test Speed: 51.0 mi/h ;; 40 Test Angle: 13.7 degrees 0 i= 30-l t ;...-t... ~... ~ ~ 20-f ~... f... t...-t... ~... ~...jll... w 0 u 10 <(...J <( z 0 :::> t f..... A....,... t... ~...,... rvwy- i... t... i... t ;.... (!) -20-J......;...;...j f...j... j..., z g -30-J...f...;...;...;... t..... ~...,.. J j.....;....; ;.... j.. l J ~...-j...-j ,,v b 0~ llb = kg 1 mi/h = km/h TIME AFTER CONTACT WITH CURB (SECONDS) FCi&s8100n~er - - ~sac Average 1 Figure 53. Vehicle longitudinal accelerometer trace for test (accelerometer located ~t rear of vehicle).

88 CRASH TEST Accelerometer at rear of vehicle """-.~ co 8o = : : 1 ' '(i) 40 s z 30 0 ~ 20 ~ w u ~ 0 ~ w Test Article: BA27C on Sidewalk Test Vehicle: 1980 Ford Single-Unit Truck Empty Weight: 10,550 lb Test Inertia Weight: 18,000 lb Test Speed: 51.0 mi/h Test Angte: 13.7 degrees ~... o.,\1... VJ. ''= 4,., v,,... c.. ~ i~~~rr, ~,~:...,v., ~ ~L ~,.,~NJ~ tj n J\.Q A. : ~' ~- ~.. v no wu f\1 \Jlt/i SJr '" TIME AFTER CONTACT WITH CURB (SECONDS) 1lb = kg 1 mi/h = km/h 1- - Class 1 ac:j filter - so.nlsec Average 1 Figure 54. Vehicle lateral accelerometer trace. for test (accelerometer located at rear of vehicle).

89 BR27C BRIDGE RAILING ON DECK Test Test Description A 1983 Honda Civic (figures 55 and 56) was used for the crash test. Test inertia mass of the vehicle was 1, 800 lb (817 kg) and its gross static mass was 1, 970 lb (894 kg). The height to the lower edge of the vehicle bumper was in (362 mm) and it was in (502 mm) to the top of the bumper. Additional dimensions and information on the test vehicle are given in figure 57. The vehicle was directed into the BR27C bridge railing on deck (figure 58) using the cable reverse tow and guidance system and was released to be free-wheeling and unrestrained just prior to impact. The vehicle impacted the bridge railing 1.1 ft (335 mm) downstream from post 3 (or 17.8 ft (5.4 m) from the end of the bridge. railing) at a speed of 60.3.milh (97. 0 km/h) and the a~gle of impact was 19.8 degrees. At s after impact; the front of the vehicle began to deform to the right, and at s the vehicle began to redirect. The roof of the vehicle began to deform at s after impact. By s the vehicle was traveling parallel to the bridge railing at a speed of 53.6 mi/h (86.2 km/h), and at s the rear of the vehicle impacted the bridge railing. The vehicle lost contact with the bridge railing at s traveling at 50.6 milh (81.4 km/h) and 6.6 degrees. The brakes on the vehicle were applied at 1.4 s after impact and the vehicle subsequently came to rest 210ft (64 m) down from and 120ft (37m) in front of the point of impact. As can be seen in figure 59, the bridge railing received minimal damage. There was no deformation to the metal railing element. The vehicle was in contact with the bridge railing for 9.9 ft (3.0 m). The vehicle sustained damage to the right side as shown in figure 60. Maximum crush at the right front comer at bumper height was 6.5 in (165 mm) and there was a 1.0-in (25-mm) dent into the occupant compartment at the frrewall. The passenger door was deformed outward approximately 1.3 in (33 mm) and the wheelbase on the right side was reduced 3.0 in (76 mm). There was an 8-in by 14-in by 7/16-in (203-mm by 356-mm. by 11- mm.) deep dent in the roof just over the right rear passenger location. The right front strut and sway bar were damaged and the instrument panel was bent. Also, damage was done to the front bumper, hood, grill, radiator, fan, right front quarter panel, right front rim, right door, right rear quarter panel, and right rear rim. Test Results Impact speed was 60.3 mi/h (97.0 km/h) and the angle of impact was 19.8 degrees. The speed of the vehicle at time of parallel was 53.6 mi/h (86.2 km/h) and the coefficient of friction was The vehicle lost contact with the bridge railing traveling at 50.6 mi/h (81.4 km/h) and the exit angle between the vehicle path and the bridge railing was 6.6 degrees. Data from the accelerometer located at the center-of-gravity were digitized for 79

90 evaluation and occupant risk factors were computed as follows. In the longitudinal direction, occupant impact velocity was 14.5 ft/s (4.4 m/s) at s, the highest s average ridedown acceleration was -1.2 g between and s, and the maximum s average acceleration was -5.7 g between and s. Lateral occupant impact velocity was 24.6 ftls (7.5 m/s) at s, the highest s occupant ridedown acceleration was 12.7 g between and s, and the maximum s average acceleration was 12.2 g between and s. The change in vehicle velocity at loss of contact was 9.7 mi/h (15.6 km/h) and the change in momentum was 795 lb-sec {3,537 N-s). These data and other pertinent information from the test are summarized in figure 61 and table 5. Sequential photographs are shown in figures 62 and 63. Vehicular angular displacements are displayed in figure 64. Vehicular accelerations versus time traces filtered with SAE J211!titers are presented in figures 65 through 67. Conclusions. The BR27C bridge railing on deck contained the test vehicle with no lateral movement of the bridge railing. There was no intrusion of railing components into the occupant compartment although there was a l-in (25-mm) dent into the occupant compartment at the rtrewall. The vehicle remained upright.and relatively stable during the collision. The bridge railing redirected the vehicle and the effective coefficient of friction was considered good. Velocity change of the vehicle during the collision was 9.7 milh (15.6 km/h). The 1989 AASHTO guide specifications sets forth required limits for occupant risk factors for tests with the 1,800-lb (817-kg) vehicle.< 1 > The AASHTO specifications recommend a limit of 30 ftl s (9.1 ml s) for longitudinal occupant impact velocity and 25 ftl s (7. 6 mls) for the lateral occupant impact velocity. The occupant impact velocities and the occupant ridedown accelerations were within the limits. The vehicle trajectory at loss of contact indicated minimum intrusion into adjacent traffic lanes. See figure 50 and table 4 for more details. 80

91 Figure.55. Vehicle/bridge railing geometries for test

92 Figure 56. Vehicle prior to test

93 Date: Test No.: VIN: JHMSL5326DS Make: Honda Model: Civic Year: 19S3 Odometer: Tire Size: 165/70SL13 Ply Rating: Bias Ply: _ Belted: Radial: X ---- Accelerometers Tire Condition: good fair X badly worn _ i -r---t a P L_ Vehicle Geometry - inches a b c d* e f Tire di a~---foll~~ Wheel dia----++~ j m 4-wheel weight for e.g. det. Mass - pounds b lf Curb Ml 1153 M2 650 MT c f rf 544.e.r 329 Test Inertial ]800 Note any damage to vehicle prior to test: *d = overall height of vehicle 1 in= 25.4mm 1 lb = kg rr 341 Gross Static Jq70 g h i j k e. 38'' m n 3.25" p r s Engine Type: 4-Gas Engine CIO: 8_1_C_,I_D Transmission Type: -PJJ(X1C<XXXKX Manual FWD X;(j{~~XMMXX4t»>< Body Type: 3 Door Steering Column Collapse Mechanism: Behind wheel units ---Convoluted tube -Cylindrical mesh units -Embedded ba 11 -NOT collapsible --Other energy absorption -Unknown Brakes: Front: Rear: disc~ drum disc_ drum _x_ Figure 57. Vehicle properties for test

94 Figure 58. BR27C bridge railing on deck before test

95 Figure 59. BR27C bridge railing on deck after test

96 Figure 60. Vehicle after test

97 00 """-~ 2-4" (1 In = 25.4 mm) "}~ 0"~ Test No Date /14/92 Test Installation... BR27C Bridge Railing on deck Installation Length ft (30 m) Test Vehi~le Honda Civic Vehicle Weight Test Inertia... 1,800 lb (817 kg) Gross Static... 1,970 lb (894 kg) Vehicle Damage Classification TAD RFQ5 CDC FREK3 & OIRYEW4 Maximum Vehicle Crush. 6.5 in (165 mm) Figure 61. Summary of results for test Impact Speed mi/h (97.0 km/h) Impact Angle deg Speed at Parallel mi/h (86.2 km/h) Exit Speed mi/h (81.4 km/h) Exit Trajectory deg Vehicle Accelerations (Max sec Avg) at true e.g. Longitudinal g Lateral g Occupant Impact Velocity at true e.g. Longitudinal ft/s (4.4 m/s} Lateral ft/s (7.5 m/s) Occupant Ridedown Accelerations Longitudinal g Lateral g

98 00 00 A. B. c. D. E. Table 5. Evaluation of crash test no {BR27C bridge railing on deck [1,800 lb (817 kg)j60.3 mi/h (97.0 km/h)l19.8 degrees]} CRITERIA Must contain vehicle Debris shall not penetrate passenger compartment Passenger compartment must have essentially no deformation Vehicle must remain upright Must smoothly redirect the vehicle F. Effective coefficient of friction u >.35 G. Shall be less than Assessment Good Fair Marginal Occupant Impact Velocity - ft/s (m/s) longitudinal lateral 30 (9.2) 25 (7.6) Occupant Ridedown Accelerations - q's longitudinal lateral H. Exit angle shall be less than 12 degrees TEST RESULTS Vehicle was contained No debris penetrated passenger compartment Minimal deformatiori (1 in) Vehicle did remain upright Vehicle was smoothly redirected _J,L.15 Assessment Good Occupant Impact Velocity - ft/s (m/s) Longitudinal Lateral 14.5 (4.4} 24.6 (7.5) Occupant Ridedown Accelerations - g's longitudinal Lateral Exit angle was 6.6 degrees * A, B, C, D and G are required. E, F, and H are desired. (See table 2) PASS/FAIL* Pass Pass Pass Pass Pass Pass Pass Pass Pass

99 0.000 s s s s Figure 62. Sequential photographs for test (overhead and frontal views). 89

100 0.148 s s s s Figure 62. Sequential photographs for test (overhead and frontal views continued). 90

101 0.000 s s s s Figure 63. Sequential photographs for test (perpendicular and interior views). 91

102 0.148 s s s s Figure 63. Sequential photographs for test (perpendicular and interior views continued). 92

103 -(/) Q) Q) (_ Q') Q) (.C) D w - +> c Q) E Q) u m, (/) r-1 D I Yaw X Pitch 8 Roll l llcii I., A YAW ~ ~ ~ "',. 0 cc --- I~ Axes are vehicle fixed. Sequ~nce for determining orientation is: 1. Yaw 2J Pitch 3. Roll -2B.QL---~---+~~~--+---~ ~~--T---~-- O.O Time (Seconds) PA3.08 Figure 64. Vehicle angular displacements for test

104 CRASH TEST Accelerometer at center-of-gravity 1..0 ~ s (j) eo! 70 t~ f t l. i Test Anicle: BR27C on Deck!! l! l Test Vehicle: 1983 Honda CMc r... i i r.. i.. Test tneni~ wei~ht: 1,8oo tb 50 z ~ w w 0 10 ~ <( z 0-10 :::> f- ~ 20 z T!.... j!... i!.... [!... i...! Gross Test Speed: Static We1ght: 60.3 mi/h 1,970 lb.. :.. l.... J...;... J... L I! I I l (....,.....,...., t r r..., ~II\; ~ Aff ~ : 0e4 0 ' ' A. M o n ' ftcf~~.:::.:.~.~r...:..:...:... :n:.:.. ~.:~.i :~.~.: ~::.J... l Test Angle: 19.8 degrees :::::::-~::::::J::-~::::::::-~::t:::::::::::::::::E::::::::::::=:l::::::::::::::t..::::::::::::::J:::~_::::::::~:~..:E~..:: :~::::::::::::... r... r...,... r... r r... r! : i I i I i i. i I ~ TIME AFTER IMPACT (SECONDS) lib = kg l mi/h = km/h 1-Class 1 so fllter - 60-msec Average 1 Figure 65. Vehicle longitudinal accelerometer trace for (accelerometer located at center-of-gravity).

105 \ y;.9 40 z 0 30 ~ 20 w _J w 10 0 ~ 0..J ~ -10 w ~ CRASH TEST Accelerometer at center-of-gravity...!... ~... ~...;.i... J... ~~:~~~~~:~~~:::::~~~~~~~~::::~~~~::::~:~!:~:~:~~~:::~:::~:::::~:J~~~~~:::~~::~~~~:::j~:~~~~~::::~~~~::j::~~:... i-....,...,... t... I i I! I! :! '~'"''"""'"""'"'""'"""'..., I l l l.:.... t....:.... : I I I I : I : I r t - j :. Test Article: BR27C on Deck Test Vehicle: 1983 Honda Civic Test Inertia Weight: 1,800 lb Gross Static Weight: 1,970 lb Test Speed: 60.3 mi/h Test Angle: 19.8 degrees TIME AFTER IMPACT (SECONDS) llb = kg 1 mi/h = km/h 1- Class 180 niter - 60-m8BC Average I Figure 66. Vehicle lateral accelerometer trace for test (accelerometer located at center-of-gravity).

106 80 70-f... T CRASH TEST Accelerometer at center~of-gravity : I I I!. = T!... t i...! r... i r... Test Article: BR27C on Deck,, I. I I. I I Test Vehicle: 1983 Honda Civic : : i i I I I Test Inertia Weight: 1,800 lb 50...:, i... i I i i Gross Static Weight: 1,970 lb 4...:,...: ~ I l i I j Test Speed: 60.3 mi/h CJ) \.0 m :;;; ( ~ < 0 IJ ~ ( It 10 h ~ I ' I I r ~~--- :c: : -~-~------~-r-~--~~--~-:- :-- ~ - r i ~ - -:-hlfl ~~~-j--. ( <C..J ( -10 lr= w >... t_.,l.! t ! r:::::::::::::::::::::::::::::::r:::::::::::::~:~::::::::~::::r:::::::::::::::::::::::::~::::r::::::::::::::::::::::~::::::::...;.... l I >... I I.;. i... I, lb = kg 1 mi/h = km/h TIME AFTER IMPACT (SECONDS),_ Class 180 niter - oo-msec Average I Figure 67. Vehicle vertical accelerometer trace for test (accelerometer located at center-of-gravity).

107 Test Test Description A 1985 Chevrolet Custom Deluxe pickup (figures 68 and 69) was used for the. crash test. Test inertia mass of the vehicle was 5,400 lb (2 452 kg) and its gross static mass was 5,570 lb (2 529 kg). The height to the lower edge of the vehicle bumper was 18.0 in (457 mm) and it was 27.0 in (686 mm) to the top of the bumper. Additional dimensions and information on the test vehicle are given in figure 70. The vehicle was directed into the BR27C bridge railing on deck (figure 71) using the cable reverse tow and guidance system and was released to be free-wheeling and unrestrained just prior to impact. The vehicle impacted the bridge railing 1.9 ft (519 mm) downstream from post 3 (or 18.6 ft (5.7 m) from the end of the bridge railing) at a speed of 55.3 mi/h (89. 0 km/h) and the angle of impact was 19.6 degrees..... At s after impact, the vehicle bumper began to ride up the barrier, and at s the vehicle began to redirect. The bumper went between the concrete beam and lower metal railing element at s, and at the vehicle made contact with post 4. By s the vehicle was traveling parallel to. the bridge railing at a speed of mi/h (77.1 km/h), and at s the rear of the vehicle impacted the bridge railing. The vehicle lost contact with the bridge railing at s traveling at 44.8 mi/h (72.1 km/h) and 6.5 degrees. The brakes on the vehicle were applied at 1.1 s after impact and the vehicle subsequently came to rest 225ft (68.6 m) down from and 5 ft (2m) behind the.point of impact. As can be seen in figure 72, the bridge railing received minimal damage. There was 0.5-in (13-mm) deformation to the lower metal railing element and there was a hairline crack in the concrete beam 17.5 in ( 445 mm) down from post 3. The vehicle was in contact with the bridge railing for 11.0 ft (3.4 m). The vehicle sustained damage to the right side as shown in figure 73. Maximum crush at the right front comer at bumper height was 9.0 in (229 mm) and there was a 0.5-in (1.3-cm) dent into the occupant compartment at the frrewall. The wheelbase on the right side was reduced 2.0 in (51 mm). The sway bar was damaged and the frame was bent. Also, damage was done to the front bumper, hood, grill, radiator, fan, right front quarter panel, right front tire and rim, right door, right rear quarter panel, rear bumper, right rear rim, and left front quarter panel. Test Results Impact speed was 55.3 mi/h (89.0 kmlh) and the angle of impact was 19.6 degrees. The speed of the vehicle at time of parallel was 47.9 mi/h (77.1 kmlh) and the coefficient of friction was The vehicle lost contact with the bridge railing traveling at 44.8 mi/h (72.1 km/h) and the exit angle between the vehicle path and the bridge railing was 6.5 degrees. Data from the accelerometer located at the center-of-gravity were digitized for evaluation and occupant risk factors were computed as follows. In the longitudinal direction, occupant impact velocity was 11.6 ft/s (3.5 mls) at s, the highest s average 97

108 ridedown acceleration was -2.2 g between and s, and the maximum s average acceleration was -4.9 g between and s. Lateral occupant impact velocity was 20.1 ft/s (6.1 m/s) at s, the highest s occupant ridedown acceleration was 8.1 g between and s, and the maximum s average acceleration was 9.3 g between and s. The change in vehicle velocity at loss of contact was 10.5 mi/h (16.9 km/h) and the change in momentum was 2,583 lb-sec (11,487 N-s). These data and other pertinent information from the test are summarized in figure 74 and table 6. Sequential photographs are shown in figures 75 and 76. Vehicular angular displacements are displayed in figure 77. Vehicular accelerations versus time traces filtered at SAE J211 (Class 180) are presented in figures 78 through 84. Conclusions The BR27C bridge railing on deck contained the test vehicle with no lateral movement of the bridge railing. There was no intrusion of railing components into the occupant compartment although there was a 0.5-in (13-mm) dent into the occupant compartment at the ftrewall. The vehicle remained upright and relatively stable during the collision. The bridge railing redirected the vehicle and the effective coefficient of friction was considered good. Velocity change of the vehicle during the collision was 10.5 mi/h (16.9 km/h). The 1989 AASHTO guide specifications sets forth desired (but not required) limits for occupant risk factors for tests with the 5,400-lb (2 452-kg) vehicle.< 1 > The AASHTO specifications recommend a limit of 30 ft/s (9.1 m/s) for longitudinal occupant impact velocity and 25 ftl s (7. 6 ml s) for the lateral occupant impact velocity. The occupant impact velocities and the occupant ridedown accelerations were within the limits. The vehicle trajectory at loss of contact indicated minimum intrusion into adjacent traffic lanes. See figure 7 4 and table 6 for more details. 98

109 Figure 68. Vehicle/bridge railing geometries for test

110 Figure 69. Vehicle prior to test

111 Date: Test No.: VIN: 2GCGC24WGF Make: Chevrolet Model: PU Custom Deluxevear: 1985 Odometer: Tire Size: lt 235/85 r16ply Rating: Bias Ply: Belted: Radi a 1 : ---- Tire Condition: good _ Accelerometers fair badly worn _ a Vehicle Geometry - inches a b c d* I~ = e f g h i j 45.5" k l m 2Z 11 n 3" f c l-whee 1. weight for c. g. det. tf 1290 rf 1330 lr 1340 rr 1440 tass - pounds Curb Test Inertial Gross Static Ml Mz MT ote any damage to vehicle prior to test: d = overall height of vehicle p r 3]" s lz 511 Engine Type: _v_-_8 Engine CID: 7.4 Liter Transmission Type: Automatic ~*X~ KNllXW RWO 9:t<X~ Body Type: _P_4 Steering Column Collapse Mechanism: sehind wheel units -convo 1 uted tube -Cylindrical mesh units -Embedded ba 11 -NOT collapsible --Other energy absorption -unknown Brakes: Front: Rear: disc_!_ drum_ disc_ drum~ Figure 70. Vehicle properties for test

112 Figure 71. BR27C bridge railing on deck before test

113 Figure 72. BR27C bridge railing on deck after test

114 Figure 73. Vehicle after test

115 ~ 0 ()1 2"'" (1 in = 25.4 mm) Test No. Date /16/92 Impact Speed mi/h (89.0 km/h) Impact Angle deg Speed at Parallel mi/h (77.1 km/h) mi/h (72.1 km/h) Exit Trajectory deg Test Installation.. BR27C Bridge Railing Exit Speed on deck Installation length 100 ft (30 m) Vehicle Accelerations (Max sec Avg) at true e.g. Test Vehicle Chevrolet Longitudinal g Vehicle Weight Pickup Lateral g Test Inertia... 5,400 lb (2,452 kg) Occupant Impact Velocity at true e.g. Gross Static... 5,570 lb (2,529 kg) Longitudinal ft/s (3.5 m/s) Vehicle Damage Classification Lateral ft/s (6.1 m/s) TAD RFQ4 & 01RD2 CDC..... ' FREK2 & 01RDEW2 Maximum Vehicle Crush. 9.0 in (229 mm) Figure 74. Summary of results for test Occupant Ridedown Accelerations Longftudinal g Lateral g

NCHRP Report 350 Test 4-12 of the Modified Thrie Beam Guardrail

NCHRP Report 350 Test 4-12 of the Modified Thrie Beam Guardrail NCHRP Report 350 Test 4-12 of the Modified Thrie Beam Guardrail PUBLICATION NO. FHWA-RD-99-065 DECEMBER 1999 Research, Development, and Technology Turner-Fairbank Highway Research Center 6300 Georgetown

More information

Development of Combination Pedestrian-Traffic Bridge Railings

Development of Combination Pedestrian-Traffic Bridge Railings TRANSPORTATION RESEARCH RECORD 1468 41 Development of Combination Pedestrian-Traffic Bridge Railings D. LANCE BULLARD, JR., WANDA L. MENGES, AND C. EUGENE BUTH Two bridge railing designs have been developed

More information

Performance Level 1 Bridge Railings

Performance Level 1 Bridge Railings 80 TRANSPORTATION RESEARCH RECORD 1500 Performance Level 1 Bridge Railings DEAN C. ALBERSON, WANDA L. MENGES, AND C. EUGENE BUTH Twenty-three states, FHW A, and the District of Columbia sponsored the project

More information

TEXAS TRANSPORTATION INSTITUTE THE TEXAS A & M UNIVERSITY SYSTEM COLLEGE STATION, TEXAS 77843

TEXAS TRANSPORTATION INSTITUTE THE TEXAS A & M UNIVERSITY SYSTEM COLLEGE STATION, TEXAS 77843 NCHRP REPORT 350 ASSESSMENT OF EXISTING ROADSIDE SAFETY HARDWARE by C. Eugene Buth, P.E. Senior Research Engineer Wanda L. Menges Associate Research Specialist and Sandra K. Schoeneman Research Associate

More information

14. Sponsoring Agency Code McLean, Virginia

14. Sponsoring Agency Code McLean, Virginia TECHNICAL REPORT DOCUMENTATION PAGE I. Report No. 2. Government Accession No. FHWA-RD-93-069 4. Title and Subtitle TESTING OF NEW BRIDGE RAIL AND TRANSITION DESIGNS Volume XII: Appendix K Oregon Transition

More information

FHW A-RD TESTING OF NEW BRIDGE RAIL AND TRANSITION DESIGNS Volume IX: Appendix H Illinois Side Mount Bridge Railing

FHW A-RD TESTING OF NEW BRIDGE RAIL AND TRANSITION DESIGNS Volume IX: Appendix H Illinois Side Mount Bridge Railing TECHNICAL REPORT DOCUMENTATION PAGE 1. Report No. 2. Goverrunent Accession No. FHW A-RD-93-066 4. Title and Subtitle TESTING OF NEW BRIDGE RAIL AND TRANSITION DESIGNS Volume IX: Appendix H Illinois Side

More information

Office of Safety & Traffic Operations R&D Federal Highway Administration August September Georgetown Pike

Office of Safety & Traffic Operations R&D Federal Highway Administration August September Georgetown Pike TECHNICAL REPORT DOCUMENTATION PAGE I. Report No. 2. Government Accession No. FHWA-RD-93-067 4. Title and Subtitle TESTING OF NEW BRIDGE RAIL AND TRANSITION DESIGNS Volume X: Appendix I 42-in (1.07-m)

More information

TEXAS TRANSPORTATION INSTITUTE THE TEXAS A & M UNIVERSITY SYSTEM COLLEGE STATION, TEXAS 77843

TEXAS TRANSPORTATION INSTITUTE THE TEXAS A & M UNIVERSITY SYSTEM COLLEGE STATION, TEXAS 77843 NCHRP REPORT 350 TEST 3-11 OF THE STEEL-BACKED TIMBER GUARDRAIL by D. Lance Bullard, Jr., P.E. Associate Research Engineer Wanda L. Menges Associate Research Specialist and Sandra K. Schoeneman Research

More information

NCHRP REPORT 350 TEST 4-12 OF THE MASSACHUSETTS S3-TL4 STEEL BRIDGE RAILING MOUNTED ON CURB AND SIDEWALK

NCHRP REPORT 350 TEST 4-12 OF THE MASSACHUSETTS S3-TL4 STEEL BRIDGE RAILING MOUNTED ON CURB AND SIDEWALK TEXAS TRANSPORTATION INSTITUTE NCHRP REPORT 350 TEST 4-12 OF THE MASSACHUSETTS S3-TL4 STEEL BRIDGE RAILING MOUNTED ON CURB AND SIDEWALK by C. Eugene Buth Research Engineer and Wanda L. Menges Associate

More information

TEXAS TRANSPORTATION INSTITUTE THE TEXAS A & M UNIVERSITY SYSTEM COLLEGE STATION, TEXAS

TEXAS TRANSPORTATION INSTITUTE THE TEXAS A & M UNIVERSITY SYSTEM COLLEGE STATION, TEXAS NCHRP REPORT 350 TEST 4-21 OF THE ALASKA MULTI-STATE BRIDGE RAIL THRIE-BEAM TRANSITION by C. Eugene Buth Senior Research Engineer William F. Williams Assistant Research Engineer Wanda L. Menges Associate

More information

Texas Transportation Institute The Texas A&M University System College Station, Texas

Texas Transportation Institute The Texas A&M University System College Station, Texas 1. Report No. FHWA/TX-05/9-8132-P7 4. Title and Subtitle TL-4 CRASH TESTING OF THE F411 BRIDGE RAIL 2. Government Accession No. 3. Recipient's Catalog No. 5. Report Date October 2004 Technical Report Documentation

More information

TEXAS TRANSPORTATION INSTITUTE THE TEXAS A & M UNIVERSITY SYSTEM COLLEGE STATION, TEXAS 77843

TEXAS TRANSPORTATION INSTITUTE THE TEXAS A & M UNIVERSITY SYSTEM COLLEGE STATION, TEXAS 77843 NCHRP REPORT 350 TEST 3-11 OF THE NEW YORK DOT PORTABLE CONCRETE BARRIER WITH I-BEAM CONNECTION (RETEST) by Roger P. Bligh, P.E. Assistant Research Engineer Wanda L. Menges Associate Research Specialist

More information

GUARDRAIL TESTING MODIFIED ECCENTRIC LOADER TERMINAL (MELT) AT NCHRP 350 TL-2. Dean C. Alberson, Wanda L. Menges, and Rebecca R.

GUARDRAIL TESTING MODIFIED ECCENTRIC LOADER TERMINAL (MELT) AT NCHRP 350 TL-2. Dean C. Alberson, Wanda L. Menges, and Rebecca R. GUARDRAIL TESTING MODIFIED ECCENTRIC LOADER TERMINAL (MELT) AT NCHRP 350 TL-2 Dean C. Alberson, Wanda L. Menges, and Rebecca R. Haug Prepared for The New England Transportation Consortium July 2002 NETCR

More information

MASH Test 3-11 on the T131RC Bridge Rail

MASH Test 3-11 on the T131RC Bridge Rail TTI: 9-1002-12 MASH Test 3-11 on the T131RC Bridge Rail ISO 17025 Laboratory Testing Certificate # 2821.01 Crash testing performed at: TTI Proving Ground 3100 SH 47, Building 7091 Bryan, TX 77807 Test

More information

Form DOT F (8-72) Texas Transportation Institute The Texas A&M University System College Station, Texas

Form DOT F (8-72) Texas Transportation Institute The Texas A&M University System College Station, Texas 1. Report No. FHWA/TX-02/4162-1 Technical Report Documentation Page 2. Government Accession No. 3. Recipient's Catalog No. 4. Title and Subtitle EVALUATION OF TEXAS GRID-SLOT PORTABLE CONCRETE BARRIER

More information

Virginia Department of Transportation

Virginia Department of Transportation TEST REPORT FOR: Virginia Department of Transportation SKT SP 350 50 (15.24 m) System PREPARED FOR: Virginia Department of Transportation 1401 E. Broad St. Richmond, VA 23219 TEST REPORT NUMBER: REPORT

More information

CRASH TEST AND EVALUATION OF 3-FT MOUNTING HEIGHT SIGN SUPPORT SYSTEM

CRASH TEST AND EVALUATION OF 3-FT MOUNTING HEIGHT SIGN SUPPORT SYSTEM TTI: 9-1002-15 CRASH TEST AND EVALUATION OF 3-FT MOUNTING HEIGHT SIGN SUPPORT SYSTEM ISO 17025 Laboratory Testing Certificate # 2821.01 Crash testing performed at: TTI Proving Ground 3100 SH 47, Building

More information

14. Sponsoring Agency Code McLean, Virginia

14. Sponsoring Agency Code McLean, Virginia TECHNICAL REPORT DOCUMENTATION PAGE 1. Report No. 2. Government Accession No. FHW A-RD-93-061 4. Title and Subtitle TESTING OF NEW BRIDGE RAIL AND TRANSITION DESIGNS Volume IV: Appendix C Illinois 2399-1

More information

FAAC International, Inc.

FAAC International, Inc. TEST REPORT FOR: FAAC International, Inc. J 355 HA M30 (K4) Bollard TESTED TO: ASTM F 2656-07 Standard Test Method for Vehicle Crash Testing of Perimeter Barriers Test M30 PREPARED FOR: FAAC International,

More information

MASH08 TEST 3-11 OF THE ROCKINGHAM PRECAST CONCRETE BARRIER

MASH08 TEST 3-11 OF THE ROCKINGHAM PRECAST CONCRETE BARRIER Proving Ground Report No. 400001-RPC4 Report Date: July 2009 MASH08 TEST 3-11 OF THE ROCKINGHAM PRECAST CONCRETE BARRIER by C. Eugene Buth, P.E. Research Engineer William F. Williams, P.E. Assistant Research

More information

Texas Transportation Institute The Texas A&M University System College Station, Texas

Texas Transportation Institute The Texas A&M University System College Station, Texas 1. Report No. FHWA/TX-04/9-8132-1 4. Title and Subtitle TESTING AND EVALUATION OF THE FLORIDA JERSEY SAFETY SHAPED BRIDGE RAIL 2. Government Accession No. 3. Recipient's Catalog No. 5. Report Date February

More information

A MASH Compliant W-Beam Median Guardrail System

A MASH Compliant W-Beam Median Guardrail System 0 0 0 0 0 A MASH Compliant W-Beam Median Guardrail System By A. Y. Abu-Odeh, R. P. Bligh, W. Odell, A. Meza, and W. L. Menges Submitted: July 0, 0 Word Count:, + ( figures + tables=,000) =, words Authors:

More information

STI Project: Barrier Systems, Inc. RTS-QMB Longitudinal Barrier. Page 38 of 40 QBOR1. Appendix F (Continued) Figure F-3

STI Project: Barrier Systems, Inc. RTS-QMB Longitudinal Barrier. Page 38 of 40 QBOR1. Appendix F (Continued) Figure F-3 Barrier Systems, Inc. RTS-QMB Longitudinal Barrier STI Project: QBOR1 Page 38 of 40 Appendix F (Continued) Figure F-3 t=.500sec 115 meters overall 37.1 Impact Severity (kj).. 141.6 Angle (deg).. 25 Speed

More information

MASH TEST 3-11 OF THE TxDOT T222 BRIDGE RAIL

MASH TEST 3-11 OF THE TxDOT T222 BRIDGE RAIL TTI: 9-1002-12 MASH TEST 3-11 OF THE TxDOT T222 BRIDGE RAIL ISO 17025 Laboratory Testing Certificate # 2821.01 Crash testing performed at: TTI Proving Ground 3100 SH 47, Building 7091 Bryan, TX 77807 Test

More information

NCHRP Report 350 Crash Testing and Evaluation of the S-Square Mailbox System

NCHRP Report 350 Crash Testing and Evaluation of the S-Square Mailbox System TTI: 0-5210 NCHRP Report 350 Crash Testing and Evaluation of the S-Square Mailbox System ISO 17025 Laboratory Testing Certificate # 2821.01 Crash testing performed at: TTI Proving Ground 3100 SH 47, Building

More information

VULCAN BARRIER TL-3 GENERAL SPECIFICATIONS

VULCAN BARRIER TL-3 GENERAL SPECIFICATIONS VULCAN BARRIER TL-3 GENERAL SPECIFICATIONS I. GENERAL A. The VULCAN BARRIER TL-3 (VULCAN TL-3) shall be a highly portable and crashworthy longitudinal barrier especially suited for use as a temporary barrier

More information

MASH TEST 3-11 OF THE TxDOT SINGLE SLOPE BRIDGE RAIL (TYPE SSTR) ON PAN-FORMED BRIDGE DECK

MASH TEST 3-11 OF THE TxDOT SINGLE SLOPE BRIDGE RAIL (TYPE SSTR) ON PAN-FORMED BRIDGE DECK TTI: 9-1002 MASH TEST 3-11 OF THE TxDOT SINGLE SLOPE BRIDGE RAIL (TYPE SSTR) ON PAN-FORMED BRIDGE DECK ISO 17025 Laboratory Testing Certificate # 2821.01 Crash testing performed at: TTI Proving Ground

More information

Texas Transportation Institute The Texas A&M University System College Station, Texas

Texas Transportation Institute The Texas A&M University System College Station, Texas 2. Government Accession No. 3. Recipient's Catalog No. 1. Report No. FHWA/TX-03/0-4138-3 4. Title and Subtitle PERFORMANCE OF THE TXDOT T202 (MOD) BRIDGE RAIL REINFORCED WITH FIBER REINFORCED POLYMER BARS

More information

CRASH TESTING OF RSA/K&C ANTI-RAM FOUNDATION BOLLARD PAD IN ACCORDANCE WITH U.S. DEPARTMENT OF STATE DIPLOMATIC SECURITY SD-STD-02.

CRASH TESTING OF RSA/K&C ANTI-RAM FOUNDATION BOLLARD PAD IN ACCORDANCE WITH U.S. DEPARTMENT OF STATE DIPLOMATIC SECURITY SD-STD-02. CRASH TESTING OF RSA/K&C ANTI-RAM FOUNDATION BOLLARD PAD IN ACCORDANCE WITH U.S. DEPARTMENT OF STATE DIPLOMATIC SECURITY SD-STD-02.01 REVISION A Prepared for RSA Protective Technologies, LLC FINAL REPORT

More information

REPORT NUMBER: 301-CAL SAFETY COMPLIANCE TESTING FOR FMVSS 301 FUEL SYSTEM INTEGRITY HONDA MOTOR COMPANY 2007 HONDA ACCORD 4-DOOR SEDAN

REPORT NUMBER: 301-CAL SAFETY COMPLIANCE TESTING FOR FMVSS 301 FUEL SYSTEM INTEGRITY HONDA MOTOR COMPANY 2007 HONDA ACCORD 4-DOOR SEDAN REPORT NUMBER: 301-CAL-07-05 SAFETY COMPLIANCE TESTING FOR FMVSS 301 FUEL SYSTEM INTEGRITY HONDA MOTOR COMPANY 2007 HONDA ACCORD 4-DOOR SEDAN NHTSA NUMBER: C75304 CALSPAN TEST NUMBER: 8832-F301-05 CALSPAN

More information

CRASH TEST AND EVALUATION OF TEMPORARY WOOD SIGN SUPPORT SYSTEM FOR LARGE GUIDE SIGNS

CRASH TEST AND EVALUATION OF TEMPORARY WOOD SIGN SUPPORT SYSTEM FOR LARGE GUIDE SIGNS TTI: 9-1002-15 CRASH TEST AND EVALUATION OF TEMPORARY WOOD SIGN SUPPORT SYSTEM FOR LARGE GUIDE SIGNS ISO 17025 Laboratory Testing Certificate # 2821.01 Crash testing performed at: TTI Proving Ground 3100

More information

REPORT NUMBER: 301-MGA SAFETY COMPLIANCE TESTING FOR FMVSS 301R FUEL SYSTEM INTEGRITY REAR IMPACT

REPORT NUMBER: 301-MGA SAFETY COMPLIANCE TESTING FOR FMVSS 301R FUEL SYSTEM INTEGRITY REAR IMPACT REPORT NUMBER: 301-MGA-2011-008 SAFETY COMPLIANCE TESTING FOR FMVSS 301R FUEL SYSTEM INTEGRITY REAR IMPACT MAZDA MOTOR CORPORATION 2011 MAZDA 2 SPORT MT NHTSA NUMBER: CB5400 PREPARED BY: MGA RESEARCH CORPORATION

More information

Texas Transportation Institute The Texas A&M University System College Station, Texas

Texas Transportation Institute The Texas A&M University System College Station, Texas 1. Report No. FHWA/TX-07/0-5527-1 4. Title and Subtitle DEVELOPMENT OF A LOW-PROFILE TO F-SHAPE TRANSITION BARRIER SEGMENT 2. Government Accession No. 3. Recipient's Catalog No. Technical Report Documentation

More information

CRASH TEST REPORT FOR PERIMETER BARRIERS AND GATES TESTED TO SD-STD-02.01, REVISION A, MARCH Anti-Ram Bollards

CRASH TEST REPORT FOR PERIMETER BARRIERS AND GATES TESTED TO SD-STD-02.01, REVISION A, MARCH Anti-Ram Bollards CRASH TEST REPORT FOR PERIMETER BARRIERS AND GATES TESTED TO SD-STD-02.01, REVISION A, MARCH 2003 Anti-Ram Bollards Prepared for: RSA Protective Technologies, LLC 1573 Mimosa Court Upland, CA 91784 Test

More information

CRASH TEST REPORT FOR PERIMETER BARRIERS AND GATES TESTED TO SD-STD-02.01, REVISION A, MARCH Anti-Ram Bollards

CRASH TEST REPORT FOR PERIMETER BARRIERS AND GATES TESTED TO SD-STD-02.01, REVISION A, MARCH Anti-Ram Bollards CRASH TEST REPORT FOR PERIMETER BARRIERS AND GATES TESTED TO SD-STD-02.01, REVISION A, MARCH 2003 Anti-Ram Bollards Prepared for: RSA Protective Technologies, LLC 1573 Mimosa Court Upland, CA 91784 Test

More information

MASH TEST 3-37 OF THE TxDOT 31-INCH W-BEAM DOWNSTREAM ANCHOR TERMINAL

MASH TEST 3-37 OF THE TxDOT 31-INCH W-BEAM DOWNSTREAM ANCHOR TERMINAL TTI: 9-1002 MASH TEST 3-37 OF THE TxDOT 31-INCH W-BEAM DOWNSTREAM ANCHOR TERMINAL ISO 17025 Laboratory Testing Certificate # 2821.01 Crash testing performed at: TTI Proving Ground 3100 SH 47, Building

More information

REPORT NUMBER: 301-MGA SAFETY COMPLIANCE TESTING FOR FMVSS 301R FUEL SYSTEM INTEGRITY REAR IMPACT

REPORT NUMBER: 301-MGA SAFETY COMPLIANCE TESTING FOR FMVSS 301R FUEL SYSTEM INTEGRITY REAR IMPACT REPORT NUMBER: 301-MGA-2010-007 SAFETY COMPLIANCE TESTING FOR FMVSS 301R FUEL SYSTEM INTEGRITY REAR IMPACT NISSAN MOTOR COMPANY LTD 2010 NISSAN CUBE NHTSA NUMBER: CA5205 PREPARED BY: MGA RESEARCH CORPORATION

More information

BarrierGate. General Specifications. Manual Operations General Specifications

BarrierGate. General Specifications. Manual Operations General Specifications BarrierGate General Specifications Manual Operations General Specifications BarrierGate GENERAL SPECIFICATIONS I. GENERAL A. The BarrierGate system (the gate) shall be designed and manufactured by Energy

More information

RSA Protective Technologies

RSA Protective Technologies TEST REPORT FOR: RSA Protective Technologies K12 Surface Mounted Bollard System TESTED TO: ASTM F 2656-07 Standard Test Method for Vehicle Crash Testing of Perimeter Barriers Test M50 PREPARED FOR: Battelle

More information

VULCAN BARRIER TL-3 GENERAL SPECIFICATIONS

VULCAN BARRIER TL-3 GENERAL SPECIFICATIONS VULCAN BARRIER TL-3 GENERAL SPECIFICATIONS I. GENERAL A. The VULCAN BARRIER TL-3 (VULCAN TL-3) shall be a highly portable and crashworthy longitudinal barrier especially suited for use as a temporary barrier

More information

REPORT NUMBER: 301-MGA SAFETY COMPLIANCE TESTING FOR FMVSS 301R FUEL SYSTEM INTEGRITY REAR IMPACT

REPORT NUMBER: 301-MGA SAFETY COMPLIANCE TESTING FOR FMVSS 301R FUEL SYSTEM INTEGRITY REAR IMPACT REPORT NUMBER: 301-MGA-2010-005 SAFETY COMPLIANCE TESTING FOR FMVSS 301R FUEL SYSTEM INTEGRITY REAR IMPACT NISSAN MOTOR COMPANY LTD 2010 NISSAN CUBE NHTSA NUMBER: CA5201 PREPARED BY: MGA RESEARCH CORPORATION

More information

February 8, In Reply Refer To: HSSD/CC-104

February 8, In Reply Refer To: HSSD/CC-104 February 8, 2008 200 New Jersey Avenue, SE. Washington, DC 20590 In Reply Refer To: HSSD/CC-04 Barry D. Stephens, P.E. Sr. Vice President Engineering Energy Absorption Systems, Inc. 367 Cincinnati Avenue

More information

TEXAS TRANSPORTATION INSTITUTE THE TEXAS A & M UNIVERSITY SYSTEM COLLEGE STATION, TEXAS

TEXAS TRANSPORTATION INSTITUTE THE TEXAS A & M UNIVERSITY SYSTEM COLLEGE STATION, TEXAS TEXAS TRANSPORTATION INSTITUTE Test Level 2 Evaluation of the RENCO Ren-Gard 815 Truck Mounted Attenuator by C. Eugene Buth Senior Research Engineer and Wanda L. Menges Associate Research Specialist Contract

More information

REPORT NUMBER: 301-MGA SAFETY COMPLIANCE TESTING FOR FMVSS 301R FUEL SYSTEM INTEGRITY REAR IMPACT

REPORT NUMBER: 301-MGA SAFETY COMPLIANCE TESTING FOR FMVSS 301R FUEL SYSTEM INTEGRITY REAR IMPACT REPORT NUMBER: 301-MGA-2007-002 SAFETY COMPLIANCE TESTING FOR FMVSS 301R FUEL SYSTEM INTEGRITY REAR IMPACT NISSAN MOTOR CO., LTD. 2006 NISSAN PATHFINDER LE 4X2 NHTSA NUMBER: C65200 PREPARED BY: MGA RESEARCH

More information

Universal TAU-IIR Redirective, Non-Gating, Crash Cushion

Universal TAU-IIR Redirective, Non-Gating, Crash Cushion TB 110927 Rev. 0 Page 1 of 5 Product Specification Universal TAU-IIR Redirective, Non-Gating, Crash Cushion I. General The Universal TAU-IIR system is a Redirective, Non-Gating Crash Cushion in accordance

More information

Evaluation of the Sequential Dynamic Curve Warning System Summary of Full Report Publication No. FHWA-15-CAI-012-A November 2015

Evaluation of the Sequential Dynamic Curve Warning System Summary of Full Report Publication No. FHWA-15-CAI-012-A November 2015 Evaluation of the Sequential Dynamic Curve Warning System Summary of Full Report Publication No. FHWA-15-CAI-012-A November 2015 Source: ISU/TTI Notice This document is disseminated under the sponsorship

More information

Evaluation and Design of ODOT s Type 5 Guardrail with Tubular Backup

Evaluation and Design of ODOT s Type 5 Guardrail with Tubular Backup Evaluation and Design of ODOT s Type 5 Guardrail with Tubular Backup Draft Final Report Chuck A. Plaxico, Ph.D. James C. Kennedy, Jr., Ph.D. Charles R. Miele, P.E. for the Ohio Department of Transportation

More information

Manual for Assessing Safety Hardware

Manual for Assessing Safety Hardware American Association of State Highway and Transportation Officials Manual for Assessing Safety Hardware 2009 vii PREFACE Effective traffic barrier systems, end treatments, crash cushions, breakaway devices,

More information

ASTM F TEST M30 ON THE RSS-3000 DROP BEAM SYSTEM

ASTM F TEST M30 ON THE RSS-3000 DROP BEAM SYSTEM Proving Ground Test Report No.: 510602-RSS3 Test Report Date: January 2014 ASTM F2656-07 TEST M30 ON THE RSS-3000 DROP BEAM SYSTEM by Dean C. Alberson, Ph.D., P.E. Research Engineer Michael S. Brackin,

More information

DEVELOPMENT OF A MASH TL-3 MEDIAN BARRIER GATE

DEVELOPMENT OF A MASH TL-3 MEDIAN BARRIER GATE TTI: 9-1002 DEVELOPMENT OF A MASH TL-3 MEDIAN BARRIER GATE ISO 17025 Laboratory Testing Certificate # 2821.01 Crash testing performed at: TTI Proving Ground 3100 SH 47, Building 7091 Bryan, TX 77807 Research/Test

More information

Product Specification. ABSORB 350 TM TL-2 Non-Redirective, Gating, Crash Cushion Applied to Quickchange Moveable Barrier

Product Specification. ABSORB 350 TM TL-2 Non-Redirective, Gating, Crash Cushion Applied to Quickchange Moveable Barrier TB 000612 Rev. 0 Page 1 of 9 Product Specification ABSORB 350 TM TL-2 Non-Redirective, Gating, Crash Cushion Applied to Quickchange Moveable Barrier I. General The ABSORB 350 TM TL-2 System is a Non-Redirective,

More information

REPORT NUMBER: 301-CAL SAFETY COMPLIANCE TESTING FOR FMVSS 301 FUEL SYSTEM INTEGRITY REAR IMPACT FORD MOTOR COMPANY 2009 FORD F150 2-DOOR PICKUP

REPORT NUMBER: 301-CAL SAFETY COMPLIANCE TESTING FOR FMVSS 301 FUEL SYSTEM INTEGRITY REAR IMPACT FORD MOTOR COMPANY 2009 FORD F150 2-DOOR PICKUP REPORT NUMBER: 301-CAL-09-03 SAFETY COMPLIANCE TESTING FOR FMVSS 301 FUEL SYSTEM INTEGRITY REAR IMPACT FORD MOTOR COMPANY 2009 FORD F150 2-DOOR PICKUP NHTSA NUMBER: C90206 CALSPAN TRANSPORTATION SCIENCES

More information

PR V2. Submitted by. Professor MIDWEST Vine Street (402) Submitted to

PR V2. Submitted by. Professor MIDWEST Vine Street (402) Submitted to FINAL REPORT PR4893118-V2 ZONE OF INTRUSION STUDY Submitted by John D. Reid, Ph.D. Professor Dean L.. Sicking, Ph.D., P.E. Professorr and MwRSF Director MIDWEST ROADSIDE SAFETY FACILITY University of Nebraska-Lincoln

More information

Transportation Institute

Transportation Institute .JIIIIIII"" Texas Transportation Institute SUMMARY OF TESTING ON 'l'he RENCO TRUCK MOUNTED ATTENUATOR by Wanda L. Menges Associate Research Specialist C. Eugene Buth, P.E. Senior Research Engineer and

More information

TEST REPORT No. 2 ALUMINUM BRIDGE RAIL SYSTEMS. Prepared for. The Aluminum Association Inc. 818 Connecticut Avenue Washington, D.C.

TEST REPORT No. 2 ALUMINUM BRIDGE RAIL SYSTEMS. Prepared for. The Aluminum Association Inc. 818 Connecticut Avenue Washington, D.C. TEST REPORT No. 2 ALUMNUM BRDGE RAL SYSTEMS Prepared for The Aluminum Association nc. 818 Connecticut Avenue Washington, D.C. 26 by C. E. Buth Research Engineer G. G. Hayes Assoc. Research Physicist and

More information

VERIFICATION & VALIDATION REPORT of MGS Barrier Impact with 1100C Vehicle Using Toyota Yaris Coarse FE Model

VERIFICATION & VALIDATION REPORT of MGS Barrier Impact with 1100C Vehicle Using Toyota Yaris Coarse FE Model VERIFICATION & VALIDATION REPORT of MGS Barrier Impact with 1100C Vehicle Using Toyota Yaris Coarse FE Model CCSA VALIDATION/VERIFICATION REPORT Page 1 of 4 Project: CCSA Longitudinal Barriers on Curved,

More information

Technical Report Documentation Page Form DOT F (8-72) Reproduction of completed page authorized

Technical Report Documentation Page Form DOT F (8-72) Reproduction of completed page authorized 1. Report No. FHWA/TX-05/0-4162-3 4. Title and Subtitle 2. Government Accession No. 3. Recipient's Catalog No. DEVELOPMENT OF LOW-DEFLECTION PRECAST CONCRETE ARRIER 5. Report Date January 2005 Technical

More information

REPORT NUMBER: 301-CAL SAFETY COMPLIANCE TESTING FOR FMVSS 301 FUEL SYSTEM INTEGRITY REAR IMPACT MAZDA MOTOR CORPORATION 2008 MAZDA CX-9 SUV

REPORT NUMBER: 301-CAL SAFETY COMPLIANCE TESTING FOR FMVSS 301 FUEL SYSTEM INTEGRITY REAR IMPACT MAZDA MOTOR CORPORATION 2008 MAZDA CX-9 SUV REPORT NUMBER: 301-CAL-08-03 SAFETY COMPLIANCE TESTING FOR FMVSS 301 FUEL SYSTEM INTEGRITY REAR IMPACT MAZDA MOTOR CORPORATION 2008 MAZDA CX-9 SUV NHTSA NUMBER: C85401 CALSPAN TRANSPORTATION SCIENCES CENTER

More information

MASH TEST 3-10 ON 31-INCH W-BEAM GUARDRAIL WITH STANDARD OFFSET BLOCKS

MASH TEST 3-10 ON 31-INCH W-BEAM GUARDRAIL WITH STANDARD OFFSET BLOCKS TTI: 9-1002 MASH TEST 3-10 ON 31-INCH W-BEAM GUARDRAIL WITH STANDARD OFFSET BLOCKS ISO 17025 Laboratory Testing Certificate # 2821.01 Crash testing performed at: TTI Proving Ground 3100 SH 47, Building

More information

June 5, In Reply Refer To: HSSD/B-178. Mr. Kevin K. Groeneweg Mobile Barriers LLC Genesee Trail Road Golden, CO Dear Mr.

June 5, In Reply Refer To: HSSD/B-178. Mr. Kevin K. Groeneweg Mobile Barriers LLC Genesee Trail Road Golden, CO Dear Mr. June 5, 2008 1200 New Jersey Avenue, SE. Washington, DC 20590 In Reply Refer To: HSSD/B-178 Mr. Kevin K. Groeneweg Mobile Barriers LLC 24918 Genesee Trail Road Golden, CO 80401 Dear Mr. Groeneweg: This

More information

REPORT NUMBER: 301-CAL SAFETY COMPLIANCE TESTING FOR FMVSS 301 FUEL SYSTEM INTEGRITY REAR IMPACT

REPORT NUMBER: 301-CAL SAFETY COMPLIANCE TESTING FOR FMVSS 301 FUEL SYSTEM INTEGRITY REAR IMPACT REPORT NUMBER: 301-CAL-09-01 SAFETY COMPLIANCE TESTING FOR FMVSS 301 FUEL SYSTEM INTEGRITY REAR IMPACT HYUNDAI MOTOR COMPANY 2009 HYUNDAI ACCENT 4-DOOR SEDAN NHTSA NUMBER: C90503 CALSPAN TRANSPORTATION

More information

SAFETY COMPLIANCE TESTING FOR FMVSS NO. 214S SIDE IMPACT PROTECTION (STATIC)

SAFETY COMPLIANCE TESTING FOR FMVSS NO. 214S SIDE IMPACT PROTECTION (STATIC) REPORT NUMBER 214-GTL-09-002 SAFETY COMPLIANCE TESTING FOR S SIDE IMPACT PROTECTION (STATIC) MAZDA MOTOR CORPORATION 2009 MAZDA 3, PASSENGER CAR NHTSA NO. C95400 GENERAL TESTING LABORATORIES, INC. 1623

More information

OPTIMIZATION OF THRIE BEAM TERMINAL END SHOE CONNECTION

OPTIMIZATION OF THRIE BEAM TERMINAL END SHOE CONNECTION TTI: 9-1002-15 OPTIMIZATION OF THRIE BEAM TERMINAL END SHOE CONNECTION ISO 17025 Laboratory Testing Certificate # 2821.01 Pendulum testing performed at: TTI Proving Ground 3100 SH 47, Building 7091 Bryan,

More information

CRASH TEST OF MILE POST MARKER. T. J. Hirsch Research Engineer. and. Eugene Buth Assistant Research Engineer. Research Report Number 146-8

CRASH TEST OF MILE POST MARKER. T. J. Hirsch Research Engineer. and. Eugene Buth Assistant Research Engineer. Research Report Number 146-8 CRASH TEST OF MILE POST MARKER by T. J. Hirsch Research Engineer and Eugene Buth Assistant Research Engineer Research Report Number 146-8 Studies of Field Adaption of Impact Attenuation Systems Research

More information

Remote Combination Adaptive Driving Equipment Investigation Dynamic Science, Inc. (DSI), Case Number G 1990 Ford Bronco Arizona October

Remote Combination Adaptive Driving Equipment Investigation Dynamic Science, Inc. (DSI), Case Number G 1990 Ford Bronco Arizona October Remote Combination Adaptive Driving Equipment Investigation Dynamic Science, Inc. (DSI), Case Number 2007-76-131G 1990 Ford Bronco Arizona October 2007 This document is disseminated under the sponsorship

More information

July 10, Refer to: HSA-10/CC-78A

July 10, Refer to: HSA-10/CC-78A July 10, 2003 Refer to: HSA-10/CC-78A Barry D. Stephens, P.E. Senior Vice President of Engineering ENERGY ABSORPTION Systems, Inc. 3617 Cincinnati Avenue Rocklin, California 95765 Dear Mr. Stephens: Your

More information

Development of a Low-Profile Portable Concrete Barrier

Development of a Low-Profile Portable Concrete Barrier 36 TRANSPORTATION RESEARCH RECORD 1367 Development of a Low-Profile Portable Concrete Barrier TODD R. GUIDRY AND W. LYNN BEASON A low-profile portable concrete barrier (PCB) has been developed for use

More information

1962: HRCS Circular 482 one-page document, specified vehicle mass, impact speed, and approach angle for crash tests.

1962: HRCS Circular 482 one-page document, specified vehicle mass, impact speed, and approach angle for crash tests. 1 2 3 1962: HRCS Circular 482 one-page document, specified vehicle mass, impact speed, and approach angle for crash tests. 1973: NCHRP Report 153 16-page document, based on technical input from 70+ individuals

More information

MASH TEST 3-21 ON TL-3 THRIE BEAM TRANSITION WITHOUT CURB

MASH TEST 3-21 ON TL-3 THRIE BEAM TRANSITION WITHOUT CURB TTI: 9-1002-12 MASH TEST 3-21 ON TL-3 THRIE BEAM TRANSITION WITHOUT CURB ISO 17025 Laboratory Testing Certificate # 2821.01 Crash testing performed at: TTI Proving Ground 3100 SH 47, Building 7091 Bryan,

More information

Evaluation of Barriers for Very High Speed Roadways

Evaluation of Barriers for Very High Speed Roadways TTI: 0-6071 Evaluation of Barriers for Very High Speed Roadways ISO 17025 Laboratory Testing Certificate # 2821.01 Crash testing performed at: TTI Proving Ground 3100 SH 47, Building 7091 Bryan, TX 77807

More information

REPORT NUMBER: 305-MGA

REPORT NUMBER: 305-MGA REPORT NUMBER: 305-MGA-2011-001 SAFETY COMPLIANCE TESTING FOR FMVSS 305 Electric Powered Vehicles: Electrolyte Spillage and Electrical Shock Protection HONDA MOTOR CO., LTD 2011 HONDA CR-Z 3-DR HATCHBACK

More information

REPORT NUMBER: 305-MGA

REPORT NUMBER: 305-MGA REPORT NUMBER: 305-MGA-2011-004 SAFETY COMPLIANCE TESTING FOR FMVSS 305 Electric Powered Vehicles: Electrolyte Spillage and Electrical Shock Protection NISSAN MOTOR CO., LTD. 2011 NISSAN LEAF 5-DR HATCHBACK

More information

W-Beam Guiderail Transition from Light to Heavy Posts

W-Beam Guiderail Transition from Light to Heavy Posts TRANSPORTATION RESEARCH RECORD 1198 55 W-Beam Guiderail Transition from Light to Heavy Posts DONALD G. HERRING AND JAMES E. BRYDEN Two full-scale crash tests evaluated a transition between lightand heavy-post

More information

AASHTO Manual for Assessing Safety Hardware, AASHTO/FHWA Joint Implementation Plan Standing Committee on Highways September 24, 2015

AASHTO Manual for Assessing Safety Hardware, AASHTO/FHWA Joint Implementation Plan Standing Committee on Highways September 24, 2015 AASHTO Manual for Assessing Safety Hardware, 2015 AASHTO/FHWA Joint Implementation Plan Standing Committee on Highways September 24, 2015 Full Scale MASH Crash Tests (NCHRP 22-14(02)) Conducted several

More information

COMPLIANCE TESTING FOR FMVSS 207 SEATING SYSTEMS

COMPLIANCE TESTING FOR FMVSS 207 SEATING SYSTEMS REPORT NO. COMPLIANCE TESTING FOR FMVSS 207 SEATING SYSTEMS 2008 CHEVROLET IMPALA 4-DOOR NHTSA NO.C80102 PREPARED BY: KARCO ENGINEERING, LLC 9270 HOLLY ROAD ADELANTO, CALIFORNIA 92301 September 24, 2008

More information

SAFETY COMPLIANCE TESTING FOR FMVSS 202a Head Restraints

SAFETY COMPLIANCE TESTING FOR FMVSS 202a Head Restraints FINAL REPORT NUMBER 202a-MGA-10-003 SAFETY COMPLIANCE TESTING FOR FMVSS 202a FORD MOTOR COMPANY 2010 Lincoln MKT MPV NHTSA No. CA0213 MGA RESEARCH CORPORATION 446 Executive Drive Troy, Michigan 48083 Test

More information

W-Beam Approach Treatment at Bridge Rail Ends Near Intersecting Roadways

W-Beam Approach Treatment at Bridge Rail Ends Near Intersecting Roadways TRANSPORTATION RESEARCH RECORD 1133 51 W-Beam Approach Treatment at Bridge Rail Ends Near Intersecting Roadways M. E. BRONSTAD, M. H. RAY, J. B. MAYER, JR., AND c. F. MCDEVITT This paper is concerned with

More information

The Center for Auto Safety

The Center for Auto Safety TEST REPORT FOR: The Center for Auto Safety 40 mph Vehicle to Vehicle 30% Offset Rear Impact 40 mph Vehicle to Vehicle 30% Offset Rear Impact 1996 Jeep Grand Cherokee Limited 1988 Ford Taurus PREPARED

More information

I I TEXAS TRANSPORTATION INSTITUTE THE TEXAS A & M UNIVERSITY SYSTEM COLLEGE STATION, TEXAS

I I TEXAS TRANSPORTATION INSTITUTE THE TEXAS A & M UNIVERSITY SYSTEM COLLEGE STATION, TEXAS TEXAS TRANSPORTATON NSTTUTE Testing and Evaluation of the Vermont W-Beam Guardrail Terminal for Low Speed Areas by Althea G. Arnold Assistant Research Engineer Wanda L. Menges Associate Research Specialist

More information

SAFETY COMPLIANCE TESTING FOR FMVSS 225 Child Restraint Anchorage Systems

SAFETY COMPLIANCE TESTING FOR FMVSS 225 Child Restraint Anchorage Systems FINAL REPORT NUMBER 225-MGA-06-007 SAFETY COMPLIANCE TESTING FOR FMVSS 225 TOYOTA MOTOR CORPORATION 2006 TOYOTA HIGHLANDER NHTSA No. C65101 MGA RESEARCH CORPORATION 446 Executive Drive Troy, Michigan 48083

More information

REPORT NO. TR-P NC SAFETY COMPLIANCE TESTING FOR FMVSS 223 REAR IMPACT GUARDS 2007 TRANSFREIGHT TECHNOLOGY NHTSA NO.

REPORT NO. TR-P NC SAFETY COMPLIANCE TESTING FOR FMVSS 223 REAR IMPACT GUARDS 2007 TRANSFREIGHT TECHNOLOGY NHTSA NO. REPORT NO. SAFETY COMPLIANCE TESTING FOR FMVSS 223 REAR IMPACT GUARDS 2007 TRANSFREIGHT TECHNOLOGY NHTSA NO. RIG 009 PREPARED BY: KARCO ENGINEERING, LLC. 9270 HOLLY ROAD ADELANTO, CALIFORNIA 92301 SEPTEMBER

More information

SAFETY COMPLIANCE TESTING FOR FMVSS 225 Child Restraint Anchorage Systems

SAFETY COMPLIANCE TESTING FOR FMVSS 225 Child Restraint Anchorage Systems FINAL REPORT NUMBER 225-MGA-06-002 SAFETY COMPLIANCE TESTING FOR FMVSS 225 GENERAL MOTORS CORPORATION 2006 HUMMER H3 NHTSA No. C60102 MGA RESEARCH CORPORATION 446 Executive Drive Troy, Michigan 48083 Test

More information

Sponsored by Roadside Safety Research Program Pooled Fund Study No. TPF-5(114)

Sponsored by Roadside Safety Research Program Pooled Fund Study No. TPF-5(114) Proving Ground Test Report No. 405160-23-2 Test Report Date: February 2012 MASH TEST 3-11 OF THE W-BEAM GUARDRAIL ON LOW-FILL BOX CULVERT by William F. Williams, P.E. Associate Research Engineer and Wanda

More information

Aesthetically Pleasing Steel Pipe Bridge Rail

Aesthetically Pleasing Steel Pipe Bridge Rail TRANSPORTA TJON RESEARCH RECORD 1319 Aesthetically Pleasing Steel Pipe Bridge Rail T. J. HIRSCH, c. E. BUTH, AND DARRELL KADERKA Research has developed railings to withstand impact loads from vehicles

More information

The Center for Auto Safety

The Center for Auto Safety TEST REPORT FOR: The Center for Auto Safety 50 mph Vehicle to Vehicle 30% Offset Rear Impact 50 mph Vehicle to Vehicle 30% Offset Rear Impact 1999 Jeep Grand Cherokee Laredo 1987 Ford Taurus PREPARED FOR:

More information

PERFORMANCE EVALUATION OF THE FREE-STANDING TEMPORARY BARRIER UPDATE TO NCHRP 350 TEST NO (2214TB-1)

PERFORMANCE EVALUATION OF THE FREE-STANDING TEMPORARY BARRIER UPDATE TO NCHRP 350 TEST NO (2214TB-1) PERFORMANCE EVALUATION OF THE FREE-STANDING TEMPORARY BARRIER UPDATE TO NCHRP 350 TEST NO. 3-11 (2214TB-1) Submitted by Karla A. Polivka, M.S.M.E., E.I.T. Research Associate Engineer Dean L. Sicking, Ph.D.,

More information

Advances in Simulating Corrugated Beam Barriers under Vehicular Impact

Advances in Simulating Corrugated Beam Barriers under Vehicular Impact 13 th International LS-DYNA Users Conference Session: Automotive Advances in Simulating Corrugated Beam Barriers under Vehicular Impact Akram Abu-Odeh Texas A&M Transportation Institute Abstract W-beam

More information

SAFETY COMPLIANCE TESTING FOR FMVSS 110 TIRE SELECTION AND RIMS

SAFETY COMPLIANCE TESTING FOR FMVSS 110 TIRE SELECTION AND RIMS REPORT NUMBER 110-STF-09-001 SAFETY COMPLIANCE TESTING FOR TIRE SELECTION AND RIMS GENERAL MOTORS CORPORATION 2009 CHEVROLET IMPALA FOUR-DOOR PASSENGER CAR NHTSA NO. C90100 U.S. DOT SAN ANGELO TEST FACILITY

More information

Development and Validation of a Finite Element Model of an Energy-absorbing Guardrail End Terminal

Development and Validation of a Finite Element Model of an Energy-absorbing Guardrail End Terminal Development and Validation of a Finite Element Model of an Energy-absorbing Guardrail End Terminal Yunzhu Meng 1, Costin Untaroiu 1 1 Department of Biomedical Engineering and Virginia Tech, Blacksburg,

More information

SUMMARY CHANGES FOR NCHRP REPORT 350 GUIDELINES [NCHRP (02)] Keith A. Cota, Chairman Technical Committee on Roadside Safety June 14, 2007

SUMMARY CHANGES FOR NCHRP REPORT 350 GUIDELINES [NCHRP (02)] Keith A. Cota, Chairman Technical Committee on Roadside Safety June 14, 2007 SUMMARY CHANGES FOR NCHRP REPORT 350 GUIDELINES [NCHRP 22-14 (02)] Keith A. Cota, Chairman Technical Committee on Roadside Safety June 14, 2007 BACKGROUND Circular 482 (1962) First full scale crash test

More information

PERFORMANCE EVALUATION OF THE PERMANENT NEW JERSEY SAFETY SHAPE BARRIER UPDATE TO NCHRP 350 TEST NO (2214NJ-2)

PERFORMANCE EVALUATION OF THE PERMANENT NEW JERSEY SAFETY SHAPE BARRIER UPDATE TO NCHRP 350 TEST NO (2214NJ-2) PERFORMANCE EVALUATION OF THE PERMANENT NEW JERSEY SAFETY SHAPE BARRIER UPDATE TO NCHRP 350 TEST NO. 4-12 (2214NJ-2) Submitted by Karla A. Polivka, M.S.M.E., E.I.T. Research Associate Engineer Dean L.

More information

SAFETY COMPLIANCE TESTING FOR FMVSS 225 Child Restraint Anchorage Systems

SAFETY COMPLIANCE TESTING FOR FMVSS 225 Child Restraint Anchorage Systems FINAL REPORT NUMBER 225-MGA-10-003 SAFETY COMPLIANCE TESTING FOR FMVSS 225 NISSAN MOTORS 2010 NISSAN ROGUE NHTSA No. CA5202 MGA RESEARCH CORPORATION 446 Executive Drive Troy, Michigan 48083 Test Date:

More information

ROBUST PROJECT Norwegian Public Roads Administration / Force Technology Norway AS

ROBUST PROJECT Norwegian Public Roads Administration / Force Technology Norway AS ROBUST PROJECT Norwegian Public Roads Administration / Force Technology Norway AS Evaluation of small car - RM_R1 - prepared by Politecnico di Milano Volume 1 of 1 January 2006 Doc. No.: ROBUST-5-002/TR-2004-0039

More information

REPORT NUMBER: 301-MGA SAFETY COMPLIANCE TESTING FOR FMVSS NO. 301 FUEL SYSTEM INTEGRITY

REPORT NUMBER: 301-MGA SAFETY COMPLIANCE TESTING FOR FMVSS NO. 301 FUEL SYSTEM INTEGRITY REPORT NUMBER: 301-MGA-2009-004 SAFETY COMPLIANCE TESTING FOR FMVSS NO. 301 FUEL SYSTEM INTEGRITY GIRARDIN MINIBUS, INC. 2008 GIRARDIN G5 SCHOOL BUS NHTSA NO.: C80902 PREPARED BY: MGA RESEARCH CORPORATION

More information

PERFORMANCE EVALUATION OF THE FREE-STANDING TEMPORARY BARRIER UPDATE TO NCHRP 350 TEST NO WITH 28" C.G. HEIGHT (2214TB-2)

PERFORMANCE EVALUATION OF THE FREE-STANDING TEMPORARY BARRIER UPDATE TO NCHRP 350 TEST NO WITH 28 C.G. HEIGHT (2214TB-2) PERFORMANCE EVALUATION OF THE FREE-STANDING TEMPORARY BARRIER UPDATE TO NCHRP 350 TEST NO. 3-11 WITH 28" C.G. HEIGHT (2214TB-2) Submitted by Karla A. Polivka, M.S.M.E., E.I.T. Research Associate Engineer

More information

TECHNICAL MEMORANDUM Texas Transportation Institute Texas A&M Research Foundation FEASIBILITY OF CONCRETE PIPE CRASH CUSHIONS

TECHNICAL MEMORANDUM Texas Transportation Institute Texas A&M Research Foundation FEASIBILITY OF CONCRETE PIPE CRASH CUSHIONS V\,-e:;q" TTS TECHNICAL MEMORANDUM 55-16 Texas Transportation Institute Texas A&M Research Foundation ' '7, '..,... ----- ----- n,,,_. ' ' '.. J., ( ' t:: FEASIBILITY OF CONCRETE PIPE CRASH CUSHIONS A

More information

YOUR CLEAR CHOICE FOR PREMIUM PACKAGING SOLUTIONS

YOUR CLEAR CHOICE FOR PREMIUM PACKAGING SOLUTIONS YOUR CLEAR CHOICE FOR PREMIUM PACKAGING SOLUTIONS Unit of Length Milli (mm) to Inches MM Decimal of inch Approx. Inch MM Decimal of inch Approx. inch 1 0.0394 3/64 14 0.5512 9/16 2 0.0787 5/64 15 0.5906

More information

Remote, Redesigned Air Bag Special Study FOR NHTSA S INTERNAL USE ONLY Dynamic Science, Inc., Case Number ( E) 1998 Buick Century Colorado

Remote, Redesigned Air Bag Special Study FOR NHTSA S INTERNAL USE ONLY Dynamic Science, Inc., Case Number ( E) 1998 Buick Century Colorado Remote, Redesigned Air Bag Special Study FOR NHTSA S INTERNAL USE ONLY Dynamic Science, Inc., Case Number (1998-075-803E) 1998 Buick Century Colorado October, 1998 Technical Report Documentation Page 1.

More information

SAFETY COMPLIANCE TESTING FOR FMVSS 110 TIRE SELECTION AND RIMS

SAFETY COMPLIANCE TESTING FOR FMVSS 110 TIRE SELECTION AND RIMS REPORT NUMBER 110-STF-10-004 SAFETY COMPLIANCE TESTING FOR FMVSS 110 TIRE SELECTION AND RIMS MAZDA MOTOR CORPORATION 2010 MAZDA 6 FOUR-DOOR PASSENGER CAR NHTSA NO. CA5402 U.S. DOT SAN ANGELO TEST FACILITY

More information

JRS Dynamic Rollover Test Toyota Camry

JRS Dynamic Rollover Test Toyota Camry Page 1 of 60 JRS Dynamic Rollover Test 2007 Toyota Camry Hybrid Version Sponsored By: Automotive Safety Research Institute Charlottesville, VA. Introduction Page 2 of 60 Center for Injury Research conducted

More information