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Crumple zone

January 01, 1970

"Crush zone" redirects here. For the geopolitical concept, see Shatter belt (geopolitics).

Crumple zones, crush zones,[1] or crash zones are a structural safety feature used in vehicles, mainly in automobiles, to increase the time over which a change in velocity (and consequently momentum) occurs from the impact during a collision by a controlled deformation; in recent years, it is also incorporated into trains and railcars.[2][3][4][5]

A crash test illustrates how a crumple zone absorbs energy from an impact.
Road Maintenance Truck Impact Attenuator, Auckland, New Zealand
Extent of the crumple zones (blue) and the driver's safety cell (red) of an E217 series train
The crumple zone on the front of these cars absorbed the impact of an offset head-on collision.

Crumple zones are designed to increase the time over which the total force from the change in momentum is applied to an occupant, as the average force applied to the occupants is inversely related to the time over which it is applied. The physics involved can be expressed by the equation:

where is the force, is the time, is the mass, and is the velocity of the body. In SI units, force is measured in Newtons, time in seconds, mass in kilograms, velocity in metres per second, and the resulting impulse is measured in newton seconds (N⋅s).

Typically, crumple zones are located in the front part of the vehicle, to absorb the impact of a head-on collision, but they may be found on other parts of the vehicle as well. According to a British Motor Insurance Repair Research Centre study of where on the vehicle impact damage occurs, 65% were front impacts, 25% rear impacts, 5% left-side, and 5% right-side.[6] Some racing cars use aluminium, composite/carbon fibre honeycomb, or energy absorbing foam[7][8] to form an impact attenuator that dissipates crash energy using a much smaller volume and lower weight than road car crumple zones.[1] Impact attenuators have also been introduced on highway maintenance vehicles in some countries.

On September 10, 2009, the ABC News programs Good Morning America and World News showed a U.S. Insurance Institute for Highway Safety crash test of a 2009 Chevrolet Malibu in an offset head-on collision with a 1959 Chevrolet Bel Air sedan. It dramatically demonstrated the effectiveness of modern car safety design over 1950s design, particularly of rigid passenger safety cells and crumple zones.[9][10]

Early development history edit

The crumple zone concept was originally invented and patented by the Hungarian Mercedes-Benz engineer Béla Barényi in 1937 before he worked for Mercedes-Benz and in a more developed form in 1952.[11] The 1953 Mercedes-Benz "Ponton" was a partial implementation of his ideas,[12] by having a strong deep platform to form a partial safety cell, patented in 1941.[11]

The Mercedes-Benz patent number 854157, granted in 1952, describes the decisive feature of passive safety. Barényi questioned the opinion that had prevailed until then that a safe car had to be rigid. He divided the car body into three sections: the rigid non-deforming passenger compartment and the crumple zones in the front and the rear.[13][14]

The first Mercedes-Benz carbody developed using the patent was the 1959 Mercedes W111 "Tail Fin" Saloon.[11] The safety cell and crumple zones were achieved primarily by the design of the longitudinal members: these were straight in the centre of the vehicle and formed a rigid safety cage with the body panels, the front and rear supports were curved so that they deformed in the event of an accident, absorbing part of the collision energy.[11][15][16][17]

A more recent development for these curved longitudinal members is to be weakened by vertical and lateral ribs to form telescoping "crash can" or "crush tube" deformation structures.

Function edit

 
Activated rear crumple zone
 
Cross section to show the different strength of the metal in a Saab 9000. The safety cell is in stronger metal (red) compared to the crumple zones (yellow).
 
Mazda 121 (re-badged Ford Fiesta) crash test car from the British Transport Research Laboratory
 
Volkswagen Polo after a full frontal crash test into a deformable wall at the Transport Research Laboratory
 
VW Vento / Jetta activated front crumple zone[18]
 
A Toyota Camry after a front impact with a tree. Airbags were deployed.

Crumple zones work by managing crash energy and increasing the time over which the deceleration of the occupants of the vehicle occurs, while also preventing intrusion into or deformation of the passenger cabin. This better protects car occupants against injury. This is achieved by controlled weakening of sacrificial outer parts of the car, while strengthening and increasing the rigidity of the inner part of the body of the car, making the passenger cabin into a "safety cell", by using more reinforcing beams and higher strength steels. Impact energy that does reach the "safety cell" is spread over as wide an area as possible to reduce its deformation. Volvo introduced the side crumple zone with the introduction of the SIPS (Side Impact Protection System) in the early 1990s.

When a vehicle and all its contents, including passengers and luggage are travelling at speed, they have inertia / momentum, which means that they will continue forward with that direction and speed (Newton's first law of motion).[19] In the event of a sudden deceleration of a rigid framed vehicle due to impact, unrestrained vehicle contents will continue forwards at their previous speed due to inertia, and impact the vehicle interior, with a force equivalent to many times their normal weight due to gravity. The purpose of crumple zones is to slow down the collision to increase the time over which the occupants decelerate so as to decrease the peak force imparted on the occupants over a given time.[20]

Seatbelts restrain the passengers so they don't fly through the windshield, and are in the correct position for the airbag and also increase the time over which the occupants decelerate. Seat belts also absorb passenger inertial energy by being designed to stretch during an impact, again to increase the time over which an occupant decelerates.[21] In short: a passenger whose body is decelerated more slowly due to the crumple zone (and other devices) over a longer time survives much more often than a passenger whose body indirectly impacts a hard, undamaged metal car body which has come to a halt nearly instantaneously. It is like the difference between slamming someone into a wall headfirst (fracturing their skull) and shoulder-first (bruising their flesh slightly) is that the arm, being softer, has tens of times longer to slow its speed, yielding a little at a time, than the hard skull, which isn't in contact with the wall until it has to deal with extremely high pressures. The stretching of seatbelts while restraining occupants during an impact, means that it is necessary to replace them if a vehicle is repaired and put back on the road after a collision. They should also be replaced if their condition has deteriorated e.g. through fraying or mechanical or belt mounting faults. In New Zealand it is officially mandatory to replace worn inertia reel type seatbelts only with "webbing grabber" type belts that have less play and are more effective on older cars.[22] Newer cars have electronically fired pre-tension seatbelts that are timed to work with the airbag firing.[23] Buying used seatbelts is not a good idea even in countries where it is legal to do so, because they may have already been stretched in an impact event and may not protect their new users as they should.

The final impact after a passenger's body hits the car interior, airbag or seat belts is that of the internal organs hitting the ribcage or skull due to their inertia. The force of this impact is the way by which many car crashes cause disabling or life-threatening injury. Other ways are skeletal damage and blood loss, because of torn blood vessels, or damage caused by sharp fractured bone to organs and/or blood vessels. The sequence of speed-reducing technologies—crumple zone — seat belt — airbags — padded/deformable interior—are designed to work together as a system to reduce the peak force of the impact on the outside of the passenger(s)'s body by lengthening the time over which this force is imparted.[23] In a collision, slowing down the deceleration of the human body by even a few tenths of a second drastically reduces the peak force imparted.[14]

 
A US Market Ford Escort that has been involved in an offset head-on collision with a Sport Utility Vehicle – showing the raised point of impact – missing the car crumple zone

A misconception about crumple zones sometimes voiced[citation needed] is that they reduce safety for the occupants of the vehicle by allowing the body to collapse, therefore risking crushing the occupants. In fact, crumple zones are typically located in front of and behind the main body of the car (which forms a rigid "safety cell"), compacting within the space of the engine compartment or boot/trunk. Modern vehicles using what are commonly termed "crumple zones" provide far superior protection for their occupants in severe tests against other vehicles with crumple zones and solid static objects than older models or SUVs that use a separate chassis frame and have no crumple zones.

They do tend to come off worse when involved in accidents with SUVs without crumple zones because most of the energy of the impact is absorbed by the vehicle with the crumple zone—however, even for the occupants of the "worse off" car, this will still often be an improvement, as the result of two vehicles without crumple zones colliding will usually be more hazardous to both vehicles' occupants than a collision that is at least partly buffered.[citation needed]

Another problem is "impact incompatibility" where the "hard points" of the ends of chassis rails of SUVs are higher than the "hard points" of cars, causing the SUV to "override" the engine compartment of the car.[18] In order to tackle this problem, more recent SUV/off-roaders incorporate structures below the front bumper designed to engage lower-height car crumple zones.[24] Volvo XC70 low level front safety cross members shown here[25] Volvo's press release about this feature: "Lower cross-member that helps protects lower cars: The front suspension subframe in the new Volvo XC60 is supplemented with a lower cross-member positioned at the height of the beam in a conventional car. The lower cross-member strikes the oncoming car's protective structure, activating its crumple zone as intended so the occupants can be given the maximum level of protection."

Low speed impact absorption edit

The front of the bumper is designed to withstand low speed collisions, e.g. as in parking bumps to prevent permanent damage to the vehicle. This is achieved by elastic elements, such as the front apron. In some vehicles, the bumper is filled with foam or similar elastic substances. This aspect of design has received more attention in recent years as NCAP crash assessment has added pedestrian impacts to its testing regime. The reduction of rigid support structures in pedestrian impact areas has also been made a design objective.

In the case of less severe collisions (up to approx. 20 km/h), the bumper and outer panel design should ensure that the crumple zone and the load-bearing structure of the vehicle is damaged as little as possible and repairs can be carried out as cheaply as possible. For this purpose, so-called crash tubes or crash boxes are used for mounting bumpers. Crashtubes consist of a hollow steel profile, which transforms the incident energy by rolling up the profile.[citation needed]

Computer modelled crash simulation edit

 
VW Polo first successful frontal full car crash simulation (ESI 1986)
 
Visualisation of how a car deforms in an asymmetrical crash using finite element analysis
 
Euro NCAP FRONTAL IMPACT (left-hand drive vehicles)
 
Lotus Evora front crash test showing aluminium chassis crush structure, the height of the rigid front chassis side beams and rigid front cross beam

In the early 1980s, using technology developed for the aerospace and nuclear industries, German car makers started complex computer crash simulation studies, using finite element methods simulating the crash behaviour of individual car body components, component assemblies, and quarter and half cars at the body in white (BIW) stage. These experiments culminated in a joint project by the Forschungsgemeinschaft Automobil-Technik (FAT), a conglomeration of all seven German car makers (Audi, BMW, Ford, Mercedes-Benz, Opel (GM), Porsche, and Volkswagen), which tested the applicability of two emerging commercial crash simulation codes. These simulation codes recreated a frontal impact of a full passenger car structure (Haug 1986) and they ran to completion on a computer overnight. Now that turn-around time between two consecutive job-submissions (computer runs) did not exceed one day, engineers were able to make efficient and progressive improvements of the crash behaviour of the analyzed car body structure. The drive for improved crashworthiness in Europe has accelerated from the 1990s onwards, with the 1997 advent of Euro NCAP, with the involvement of Formula One motor racing safety expertise.

"Sleds" inside safety cells edit

The 2004 Pininfarina Nido Experimental Safety Vehicle locates crumple zones inside the survival cell. Those interior crumple zones decelerate a sled-mounted survival cell.[19] Volvo has also been developing this idea for use in small cars. Their driver's seat is mounted to what is basically a "sled" on a rail, with shock absorbers in front of it. In an impact, the whole "sled" of driving seat and belted-in driver, slides forward up to 8 inches, and the shock absorbers dissipate the peak shock energy of the impact, lengthening the deceleration time for the driver. Simultaneously, the steering wheel and the driver's side dashboard slide forward to make room for the driver, as they are thrown forwards stretching the seatbelt. Combined with a front crumple zone and airbag, this system could greatly reduce the forces acting on the driver in a frontal impact.[26]

See also edit

References edit

  1. ^ a b Grabianowski, Ed (2008-08-11). "HowStuffWorks "How Crumple Zones Work"". HowStuffWorks. System1. Retrieved 2011-09-23.
  2. ^ Paul Dvorak (2003-11-06). . Machine Design. Archived from the original on 2013-03-18. Retrieved 2016-07-17.
  3. ^ Grabianowski, Ed (2008-08-11). "How Crumple Zones Work - Design Compromises". HowStuffWorks. System1. Retrieved 2016-07-17.
  4. ^ "Physics in the Crumple Zone | Plastics Helps Save Lives". Plastics-car.com. Retrieved 2016-07-17.
  5. ^ (PDF). Archived from the original (PDF) on 2007-03-06. Retrieved 2016-07-17.
  6. ^ A. Robinson; W.A. Livesey (2006). The Repair of Vehicle Bodies P.406. 5th Edition. Butterworth-Heinemann. ISBN 978-0-7506-6753-1.
  7. ^ "Standard Impact Attenuator Design". Retrieved 2016-07-17.
  8. ^ "Standard Impact Attenuator". Retrieved 2016-07-17.
  9. ^ Stark, Lisa (2009-09-10). "Highway Safety Exclusive: Car Crashes, Travel Deaths Prevented by Technology — ABC News". Abcnews.go.com. Retrieved 2011-09-23.
  10. ^ Neff, John. "Pics Aplenty: IIHS reveals before and after of Malibu/Bel Air crash". Autoblog.com. Retrieved 2011-09-23.
  11. ^ a b c d The crumple zone man – AutoSpeed
  12. ^ Raiciu, Tudor (18 October 2017). "How Crumple Zones Work". AutoEvolution. SoftNews Net SRL, Romania. Retrieved 2019-06-11.
  13. ^ "Inventors Gallery: Biography Barényi". German Patent and Trade Mark Office. 2004. He divided the car body into three sections: the rigid non-deforming passenger compartment and the crumple zones in the front and the rear. They are designed to absorb the energy of an impact (kinetic energy) by deformation during collision
  14. ^ a b Grabianowski, Ed (2008-08-11). "How Crumple Zones Work - Force of Impact". HowStuffWorks. System1. Retrieved 2019-06-11.
  15. ^ . Archived from the original on 2019-06-09. Retrieved 2017-03-16.
  16. ^ Archived at Ghostarchive and the : Historischer Werbefilm Mercedes Benz zum Thema Sicherheit 1960er Jahre S/W [Historic commercial, safety-themed Mercedes-Benz film; 1960s B&W] (in German).
  17. ^ Béla Barényi – a history of safety - Mercedes-Benz original.
  18. ^ a b Wenzel, T.; Ross, M. (2003). (PDF). Transportation Research Board. Archived from the original (PDF) on 2008-03-09. Retrieved 2008-03-09. {{cite journal}}: Cite journal requires |journal= (help)
  19. ^ a b "How Crumple Zones Work". autoevolution. 26 May 2009. Retrieved 2016-07-17.
  20. ^ . AutoRacing1.com. 2001-02-26. Archived from the original on 2016-03-08. Retrieved 2016-07-17.
  21. ^ "Seatbelt Physics". Hyperphysics.phy-astr.gsu.edu. Retrieved 2016-07-17.
  22. ^ "A Tragic Lack of Restraint" (PDF). Retrieved 2016-07-17.
  23. ^ a b Hillier, Victor Albert Walter; Coombes, Peter (2004). Hillier's Fundamentals of Motor Vehicle Technology. Nelson Thornes. ISBN 9780748780822.
  24. ^ . Archived from the original on 2016-08-03.
  25. ^ "The new Volvo XC60 crowns Volvo's long safety tradition".
  26. ^ Grabianowski, Ed (2008-08-11). "HowStuffWorks "Preventing Fatalities in Auto Racing"". HowStuffWorks. System1. Retrieved 2012-07-16.

External links edit

  • Before and after crash between 1959 Bel Air and 2009 Malibu
  • Have crash tests ever used live (or dead) human occupants? - Howstuffworks.com
  • How Crash Testing Works - Howstuffworks.com
  • Why is it still necessary to crash test vehicles? - Howstuffworks.com
  • BBC News - How the dead have helped the living
  • How Force, Power, Torque and Energy Work - Howstuffworks.com
  • Béla Barényi – a history of safety - Mercedes-Benz original
  • Crash Engineering and Safety Design - engineeringclicks.com

January 01, 1970
crumple, zone, crush, zone, redirects, here, geopolitical, concept, shatter, belt, geopolitics, crush, zones, crash, zones, structural, safety, feature, used, vehicles, mainly, automobiles, increase, time, over, which, change, velocity, consequently, momentum,. Crush zone redirects here For the geopolitical concept see Shatter belt geopolitics Crumple zones crush zones 1 or crash zones are a structural safety feature used in vehicles mainly in automobiles to increase the time over which a change in velocity and consequently momentum occurs from the impact during a collision by a controlled deformation in recent years it is also incorporated into trains and railcars 2 3 4 5 A crash test illustrates how a crumple zone absorbs energy from an impact Road Maintenance Truck Impact Attenuator Auckland New Zealand Extent of the crumple zones blue and the driver s safety cell red of an E217 series train The crumple zone on the front of these cars absorbed the impact of an offset head on collision Crumple zones are designed to increase the time over which the total force from the change in momentum is applied to an occupant as the average force applied to the occupants is inversely related to the time over which it is applied The physics involved can be expressed by the equation F avg D t m D v displaystyle F text avg Delta t m Delta v where F displaystyle F is the force t displaystyle t is the time m displaystyle m is the mass and v displaystyle v is the velocity of the body In SI units force is measured in Newtons time in seconds mass in kilograms velocity in metres per second and the resulting impulse is measured in newton seconds N s Typically crumple zones are located in the front part of the vehicle to absorb the impact of a head on collision but they may be found on other parts of the vehicle as well According to a British Motor Insurance Repair Research Centre study of where on the vehicle impact damage occurs 65 were front impacts 25 rear impacts 5 left side and 5 right side 6 Some racing cars use aluminium composite carbon fibre honeycomb or energy absorbing foam 7 8 to form an impact attenuator that dissipates crash energy using a much smaller volume and lower weight than road car crumple zones 1 Impact attenuators have also been introduced on highway maintenance vehicles in some countries On September 10 2009 the ABC News programs Good Morning America and World News showed a U S Insurance Institute for Highway Safety crash test of a 2009 Chevrolet Malibu in an offset head on collision with a 1959 Chevrolet Bel Air sedan It dramatically demonstrated the effectiveness of modern car safety design over 1950s design particularly of rigid passenger safety cells and crumple zones 9 10 Contents 1 Early development history 2 Function 3 Low speed impact absorption 4 Computer modelled crash simulation 5 Sleds inside safety cells 6 See also 7 References 8 External linksEarly development history editThe crumple zone concept was originally invented and patented by the Hungarian Mercedes Benz engineer Bela Barenyi in 1937 before he worked for Mercedes Benz and in a more developed form in 1952 11 The 1953 Mercedes Benz Ponton was a partial implementation of his ideas 12 by having a strong deep platform to form a partial safety cell patented in 1941 11 The Mercedes Benz patent number 854157 granted in 1952 describes the decisive feature of passive safety Barenyi questioned the opinion that had prevailed until then that a safe car had to be rigid He divided the car body into three sections the rigid non deforming passenger compartment and the crumple zones in the front and the rear 13 14 The first Mercedes Benz carbody developed using the patent was the 1959 Mercedes W111 Tail Fin Saloon 11 The safety cell and crumple zones were achieved primarily by the design of the longitudinal members these were straight in the centre of the vehicle and formed a rigid safety cage with the body panels the front and rear supports were curved so that they deformed in the event of an accident absorbing part of the collision energy 11 15 16 17 A more recent development for these curved longitudinal members is to be weakened by vertical and lateral ribs to form telescoping crash can or crush tube deformation structures Function edit nbsp Activated rear crumple zone nbsp Cross section to show the different strength of the metal in a Saab 9000 The safety cell is in stronger metal red compared to the crumple zones yellow nbsp Mazda 121 re badged Ford Fiesta crash test car from the British Transport Research Laboratory nbsp Volkswagen Polo after a full frontal crash test into a deformable wall at the Transport Research Laboratory nbsp VW Vento Jetta activated front crumple zone 18 nbsp A Toyota Camry after a front impact with a tree Airbags were deployed Crumple zones work by managing crash energy and increasing the time over which the deceleration of the occupants of the vehicle occurs while also preventing intrusion into or deformation of the passenger cabin This better protects car occupants against injury This is achieved by controlled weakening of sacrificial outer parts of the car while strengthening and increasing the rigidity of the inner part of the body of the car making the passenger cabin into a safety cell by using more reinforcing beams and higher strength steels Impact energy that does reach the safety cell is spread over as wide an area as possible to reduce its deformation Volvo introduced the side crumple zone with the introduction of the SIPS Side Impact Protection System in the early 1990s When a vehicle and all its contents including passengers and luggage are travelling at speed they have inertia momentum which means that they will continue forward with that direction and speed Newton s first law of motion 19 In the event of a sudden deceleration of a rigid framed vehicle due to impact unrestrained vehicle contents will continue forwards at their previous speed due to inertia and impact the vehicle interior with a force equivalent to many times their normal weight due to gravity The purpose of crumple zones is to slow down the collision to increase the time over which the occupants decelerate so as to decrease the peak force imparted on the occupants over a given time 20 Seatbelts restrain the passengers so they don t fly through the windshield and are in the correct position for the airbag and also increase the time over which the occupants decelerate Seat belts also absorb passenger inertial energy by being designed to stretch during an impact again to increase the time over which an occupant decelerates 21 In short a passenger whose body is decelerated more slowly due to the crumple zone and other devices over a longer time survives much more often than a passenger whose body indirectly impacts a hard undamaged metal car body which has come to a halt nearly instantaneously It is like the difference between slamming someone into a wall headfirst fracturing their skull and shoulder first bruising their flesh slightly is that the arm being softer has tens of times longer to slow its speed yielding a little at a time than the hard skull which isn t in contact with the wall until it has to deal with extremely high pressures The stretching of seatbelts while restraining occupants during an impact means that it is necessary to replace them if a vehicle is repaired and put back on the road after a collision They should also be replaced if their condition has deteriorated e g through fraying or mechanical or belt mounting faults In New Zealand it is officially mandatory to replace worn inertia reel type seatbelts only with webbing grabber type belts that have less play and are more effective on older cars 22 Newer cars have electronically fired pre tension seatbelts that are timed to work with the airbag firing 23 Buying used seatbelts is not a good idea even in countries where it is legal to do so because they may have already been stretched in an impact event and may not protect their new users as they should The final impact after a passenger s body hits the car interior airbag or seat belts is that of the internal organs hitting the ribcage or skull due to their inertia The force of this impact is the way by which many car crashes cause disabling or life threatening injury Other ways are skeletal damage and blood loss because of torn blood vessels or damage caused by sharp fractured bone to organs and or blood vessels The sequence of speed reducing technologies crumple zone seat belt airbags padded deformable interior are designed to work together as a system to reduce the peak force of the impact on the outside of the passenger s s body by lengthening the time over which this force is imparted 23 In a collision slowing down the deceleration of the human body by even a few tenths of a second drastically reduces the peak force imparted 14 nbsp A US Market Ford Escort that has been involved in an offset head on collision with a Sport Utility Vehicle showing the raised point of impact missing the car crumple zone A misconception about crumple zones sometimes voiced citation needed is that they reduce safety for the occupants of the vehicle by allowing the body to collapse therefore risking crushing the occupants In fact crumple zones are typically located in front of and behind the main body of the car which forms a rigid safety cell compacting within the space of the engine compartment or boot trunk Modern vehicles using what are commonly termed crumple zones provide far superior protection for their occupants in severe tests against other vehicles with crumple zones and solid static objects than older models or SUVs that use a separate chassis frame and have no crumple zones They do tend to come off worse when involved in accidents with SUVs without crumple zones because most of the energy of the impact is absorbed by the vehicle with the crumple zone however even for the occupants of the worse off car this will still often be an improvement as the result of two vehicles without crumple zones colliding will usually be more hazardous to both vehicles occupants than a collision that is at least partly buffered citation needed Another problem is impact incompatibility where the hard points of the ends of chassis rails of SUVs are higher than the hard points of cars causing the SUV to override the engine compartment of the car 18 In order to tackle this problem more recent SUV off roaders incorporate structures below the front bumper designed to engage lower height car crumple zones 24 Volvo XC70 low level front safety cross members shown here 25 Volvo s press release about this feature Lower cross member that helps protects lower cars The front suspension subframe in the new Volvo XC60 is supplemented with a lower cross member positioned at the height of the beam in a conventional car The lower cross member strikes the oncoming car s protective structure activating its crumple zone as intended so the occupants can be given the maximum level of protection Low speed impact absorption editThe front of the bumper is designed to withstand low speed collisions e g as in parking bumps to prevent permanent damage to the vehicle This is achieved by elastic elements such as the front apron In some vehicles the bumper is filled with foam or similar elastic substances This aspect of design has received more attention in recent years as NCAP crash assessment has added pedestrian impacts to its testing regime The reduction of rigid support structures in pedestrian impact areas has also been made a design objective In the case of less severe collisions up to approx 20 km h the bumper and outer panel design should ensure that the crumple zone and the load bearing structure of the vehicle is damaged as little as possible and repairs can be carried out as cheaply as possible For this purpose so called crash tubes or crash boxes are used for mounting bumpers Crashtubes consist of a hollow steel profile which transforms the incident energy by rolling up the profile citation needed Computer modelled crash simulation edit nbsp VW Polo first successful frontal full car crash simulation ESI 1986 nbsp Visualisation of how a car deforms in an asymmetrical crash using finite element analysis nbsp Euro NCAP FRONTAL IMPACT left hand drive vehicles nbsp Lotus Evora front crash test showing aluminium chassis crush structure the height of the rigid front chassis side beams and rigid front cross beam In the early 1980s using technology developed for the aerospace and nuclear industries German car makers started complex computer crash simulation studies using finite element methods simulating the crash behaviour of individual car body components component assemblies and quarter and half cars at the body in white BIW stage These experiments culminated in a joint project by the Forschungsgemeinschaft Automobil Technik FAT a conglomeration of all seven German car makers Audi BMW Ford Mercedes Benz Opel GM Porsche and Volkswagen which tested the applicability of two emerging commercial crash simulation codes These simulation codes recreated a frontal impact of a full passenger car structure Haug 1986 and they ran to completion on a computer overnight Now that turn around time between two consecutive job submissions computer runs did not exceed one day engineers were able to make efficient and progressive improvements of the crash behaviour of the analyzed car body structure The drive for improved crashworthiness in Europe has accelerated from the 1990s onwards with the 1997 advent of Euro NCAP with the involvement of Formula One motor racing safety expertise Sleds inside safety cells editThe 2004 Pininfarina Nido Experimental Safety Vehicle locates crumple zones inside the survival cell Those interior crumple zones decelerate a sled mounted survival cell 19 Volvo has also been developing this idea for use in small cars Their driver s seat is mounted to what is basically a sled on a rail with shock absorbers in front of it In an impact the whole sled of driving seat and belted in driver slides forward up to 8 inches and the shock absorbers dissipate the peak shock energy of the impact lengthening the deceleration time for the driver Simultaneously the steering wheel and the driver s side dashboard slide forward to make room for the driver as they are thrown forwards stretching the seatbelt Combined with a front crumple zone and airbag this system could greatly reduce the forces acting on the driver in a frontal impact 26 See also editAutomobile safety Guard rail Automotive safety Traffic barrier Crash test New Car Assessment ProgramReferences edit a b Grabianowski Ed 2008 08 11 HowStuffWorks How Crumple Zones Work HowStuffWorks System1 Retrieved 2011 09 23 Paul Dvorak 2003 11 06 Will the crash zone crumple FEA tells Machine Design Archived from the original on 2013 03 18 Retrieved 2016 07 17 Grabianowski Ed 2008 08 11 How Crumple Zones Work Design Compromises HowStuffWorks System1 Retrieved 2016 07 17 Physics in the Crumple Zone Plastics Helps Save Lives Plastics car com Retrieved 2016 07 17 Investigating how crumple zones incorporated into modern trains make them much safer in collisions PDF Archived from the original PDF on 2007 03 06 Retrieved 2016 07 17 A Robinson W A Livesey 2006 The Repair of Vehicle Bodies P 406 5th Edition Butterworth Heinemann ISBN 978 0 7506 6753 1 Standard Impact Attenuator Design Retrieved 2016 07 17 Standard Impact Attenuator Retrieved 2016 07 17 Stark Lisa 2009 09 10 Highway Safety Exclusive Car Crashes Travel Deaths Prevented by Technology ABC News Abcnews go com Retrieved 2011 09 23 Neff John Pics Aplenty IIHS reveals before and after of Malibu Bel Air crash Autoblog com Retrieved 2011 09 23 a b c d The crumple zone man AutoSpeed Raiciu Tudor 18 October 2017 How Crumple Zones Work AutoEvolution SoftNews Net SRL Romania Retrieved 2019 06 11 Inventors Gallery Biography Barenyi German Patent and Trade Mark Office 2004 He divided the car body into three sections the rigid non deforming passenger compartment and the crumple zones in the front and the rear They are designed to absorb the energy of an impact kinetic energy by deformation during collision a b Grabianowski Ed 2008 08 11 How Crumple Zones Work Force of Impact HowStuffWorks System1 Retrieved 2019 06 11 1959 Mercedes Benz W111 Fintail Mercedes Benz Archived from the original on 2019 06 09 Retrieved 2017 03 16 Archived at Ghostarchive and the Wayback Machine Historischer Werbefilm Mercedes Benz zum Thema Sicherheit 1960er Jahre S W Historic commercial safety themed Mercedes Benz film 1960s B amp W in German Bela Barenyi a history of safety Mercedes Benz original a b Wenzel T Ross M 2003 Are SUVs Safer than Cars An Analysis of Risk by Vehicle Type and Model PDF Transportation Research Board Archived from the original PDF on 2008 03 09 Retrieved 2008 03 09 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help a b How Crumple Zones Work autoevolution 26 May 2009 Retrieved 2016 07 17 Mark Cipolloni Page AutoRacing1 com 2001 02 26 Archived from the original on 2016 03 08 Retrieved 2016 07 17 Seatbelt Physics Hyperphysics phy astr gsu edu Retrieved 2016 07 17 A Tragic Lack of Restraint PDF Retrieved 2016 07 17 a b Hillier Victor Albert Walter Coombes Peter 2004 Hillier s Fundamentals of Motor Vehicle Technology Nelson Thornes ISBN 9780748780822 2008 Volvo V70 XC70 First Drive Motor Trend Archived from the original on 2016 08 03 The new Volvo XC60 crowns Volvo s long safety tradition Grabianowski Ed 2008 08 11 HowStuffWorks Preventing Fatalities in Auto Racing HowStuffWorks System1 Retrieved 2012 07 16 External links editBefore and after crash between 1959 Bel Air and 2009 Malibu Crumple Zones in Automobiles Crumple Zones How Do Crumple Zones Work Have crash tests ever used live or dead human occupants Howstuffworks com How Crash Testing Works Howstuffworks com Why is it still necessary to crash test vehicles Howstuffworks com BBC News How the dead have helped the living How Force Power Torque and Energy Work Howstuffworks com Bela Barenyi a history of safety Mercedes Benz original The fundamental dynamics of violence in car crashes The physics The engineering John Cadogan of autoexpert com au Crash Engineering and Safety Design engineeringclicks com Portals nbsp Cars nbsp Trains Retrieved from https en wikipedia org w index php title Crumple zone amp oldid 1219928424, wikipedia, wiki, book, books, library,

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