New Design Airbag Gas Inflator Driving Airbag Gas Inflator

China New Design Airbag Gas Inflator Driving Airbag Gas Inflator, Find details about China Airbag Tube Inflator, Seat Belt Gas Generator from New Design Airbag Gas Inflator Driving Airbag Gas Inflator

Model NO.
JASD-08
Trademark
JASHINE
Transport Package
Bubble Bag and Carton Box
Specification
Standard
Origin
China
HS Code
3901100001
Model NO.
JASD-08
Trademark
JASHINE
Transport Package
Bubble Bag and Carton Box
Specification
Standard
Origin
China
HS Code
3901100001
New design  airbag gas inflator  Driving airbag gas inflator                                 Applicable airbag volume : 70L
It contains compressed air inside
There is exclude flammable, combustible and explosive materials inside


or Gas toxicity: No
Temperature of gas producer at air outlet: < 280ºC
All fire current: 1.7A/2ms
No-fire current: 0.2mA/10s
Contains an explosive ignition. In the absence of an external source of electrical impulse ignition is impossible.
Environmental test: According with GB
Aging resistance: According with GB
Waterproof: According with GB
Applicable temperature range:-35~85ºC
Service life: 15 years


Quick Details
Item NameAirbag inflator
With LogoNo
Car MakeJASD-08
Product SizeStandard
MOQ5 PCS each type
Coloras picture 
Materialaluminum
Delivery Time5-10 days after receive payment
Payment TermWestern Union PayPal Money gram T/T
ShipmentBy DHL,EMS,UPS,ARAMEX ,By land or by air to Russia.
Packing Neutral Packing.-- one platic bag. And carton

Picture as below:
New Design Airbag Gas Inflator Driving Airbag Gas InflatorNew Design Airbag Gas Inflator Driving Airbag Gas Inflator

New Design Airbag Gas Inflator Driving Airbag Gas Inflator
New Design Airbag Gas Inflator Driving Airbag Gas Inflator
 

Airbag Inflators Basic Description:

The airbag inflator is one of the many components of an airbag system. The main purpose of an airbag is to slow the passenger's forward motion as evenly as possible immediately after a collision. One of the biggest challenges in early efforts to adapt airbags for use in cars was their high price and the technical difficulties involved in storing and releasing the compressed gas. These difficulties included providing sufficient room for gas storage in the car, maintaining the high pressure of the gas during the lifetime of the car, and producing quick and reliable expansion of the bag without causing injuries. These requirements suggested the need to develop an airbag design based on a chemical reaction that would produce nitrogen gas to inflate the airbag. The first automotive airbags developed in the 1970s employed a solid propellant. These airbag inflation systems reacted sodium azide (NaN3) with potassium nitrate (KNO3) in order to produce nitrogen gas. Hot blasts of nitrogen gas inflated the airbag. Because sodium azide is extremely toxic, these chemicals were widely phased out during the 1990s in favor of more efficient, less expensive, and less toxic alternatives. The alternative propellants may incorporate, for example, a combination of nitroguanidine, phase-stabilized ammonium nitrate (NH4NO3) or other nonmetallic oxidizers, and a nitrogen-rich fuel other than azide (e.g. tetrazoles, triazoles, and their salts).

 

When a crash is sensed, the control unit sends an electrical signal to the inflator. The chemical reaction is initiated by the igniter, generating primarily nitrogen gas to fill the airbag causing it to deploy through the module cover. Due to rapid speed change of the vehicles involved in a crash, airbags must inflate rapidly to decrease the risk of occupant injuries by protecting them from hitting the vehicle interior. From the beginning of the crash, the entire deployment process is about 50 milliseconds - faster than the blink of an eye (about 200 milliseconds). Tiny holes in the bag allow the gas to disperse, absorbing the force of the impact on the occupant.


Multi Stage Inflators:


To reduce injury as a result of airbag inflation, advanced technology inflators have been developed with the capability to change the inflation pressure. This helps control the force of deployment based on the intensity of the crash, the size of the occupant, and their position in the vehicle. These inflators consist of two chambers with dual initiators. Thus, by firing either one or both of the initiators, the force of the inflation can be controlled.